Nature of Science 2016 - 2017 Fifth Grade SCIENCE Curriculum Map Volusia County Schools Next Generation Sunshine State Standards 1 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Authorization for reproduction of this document is hereby granted. All trademarks and trade names found in this publication are the property of their respective owners and are not associated with the publisher of this publication. Questions regarding use of this publication should be sent to the following: Volusia County Schools Elementary Science Department Becki Lucas Elementary Science Specialist [email protected] DeLand, Florida 2 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Table of Contents I. Next Generation Sunshine State Standards A. Fifth Grade Overview……...…………………………………………………....………….. B. Fifth Grade Instructional Scope and Sequence………………..………………………… 4 5 II. Making Connections A. Health/Language Arts/Mathematics/Technology…………………………….……..….…. B. Standards for Mathematical Practice…………………………………..…………………. 6 7 III. Science Process Skills: Basic and Integrated……………………………………………… 8 IV. 5E Learning Cycle: An Instructional Model…………….………………............................. 9 V. Webb’s Depth of Knowledge A. Model of Cognitive Complexity..................................................................................... B. Question Stems……………………………………………………………………………... 10 11 VI. “Fair Game” Benchmarks Reference for grades 3 and 4…………………………………. 13 VII. Units of Study A. Introduction to Practice of Science.………………………………….…………………..... B. Space……………...………………………………………………………………………….. C. Weather & Climate...…………………………………………………………………….…... D. Matter…………..….………………………………………………………………….………. E. Energy & Motion...………………………………………………………………….………... F. Life……………..…….……………………………………………………………….……….. G. Practice of Science….…………………………………………………………………….…. 15 19 22 26 29 34 39 VIII. Appendices Appendix A: Appendix B: Appendix C: Appendix D: Formative Assessment Strategies………………………………………..…… Digital Program Access Information…………………………………………... Read Works………………………………………………………………….….. Supplemental Literature…………………………………………………….….. 41 51 52 54 IX. Glossary of Terms for the Science Curriculum Map……………..………………..………. 56 3 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Next Generation Sunshine State Standards The Next Generation Sunshine State Standards for science are organized by grade level for grades K-8 and by Bodies of Knowledge for grades 9-12. Eighteen Big Ideas are encompassed in grades K-12 and build in rigor and depth as students advance. Each grade level includes benchmarks from the four Bodies of Knowledge (Nature of Science, Life Science, Earth and Space Science, and Physical Science). Fifth Grade Overview Fifth Grade focuses instructional delivery for science within the following twelve (12) Big Ideas/Standards: Nature of Science Big Idea 1 – The Practice of Science Big Idea 2 – The Characteristics of Scientific Knowledge Earth and Space Science Big Idea 5 – Earth in Space and Time Big Idea 7 – Earth Systems and Patterns Physical Science Big Idea 8 – Properties of Matter Big Idea 9 – Changes in Matter Big Idea 10 – Forms of Energy Big Idea 11 – Energy Transfer and Transformations Big Idea 13 – Forces and Changes in Motion Life Science Big Idea 14 – Organization and Development of Living Organisms Big Idea 15 – Diversity and Evolution of Living Organisms Big Idea 17 – Interdependence 4 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Fifth Grade Instructional Scope and Sequence *All required and optional assessments are available through DOD and Canvas Instructional Instructional Scope Sequence Weeks of Instruction Body of Knowledge Weeks 1 – 4 Introduction to Practice of Science August 15 – September 9 Nature of Science Weeks 5 – 6 Space September 12 – September 23 Weeks 7 – 12 Weather & Climate September 26 – November 4 Weeks 13 – 17 Matter November 7 – December 9 Weeks 18 – 24 Energy & Motion December 12 – February 3 Week 25 STEM February 6 - 10 Interdisciplinary Weeks 26 – 29 Life February 13 – March 9 Life Science Weeks 30 – 33 Practice of Science March 20 – April 13 Nature of Science Weeks 34 - 35 Fair Game Assist/Finishing Touches April 17 – 28 All Week 36 Statewide Science Assessment May 1 – 5 All Weeks 37-39 STEM May 8 – May 26 Interdisciplinary Earth and Space Science Physical Science Formative Assessment Strategies are included on pages 41-50. Digital Program Access Information is included on page 51. What is STEM Week? STEM Week is a period of time dedicated to the implementation of an interdisciplinary, standards-rich experience that poses an age-appropriate, real-world problem to be solved through collaborative and creative measures. S T the ability to use scientific knowledge and processes to understand the natural world as well as the ability to participate in decisions that affect it 5 the ability to know how to use new technologies, understand how new technologies are developed, and have the skills to analyze how new technologies affect us, our nation, and the world Volusia County Schools Elementary Science Department E M the ability to understand how technologies are developed via the engineering design process using problem-based lessons in a manner that integrates lessons across multiple subjects the ability to analyze, reason, and communicate ideas effectively as they pose, formulate, solve, and interpret solutions to mathematical problems in a variety of situations Grade 5 Science Curriculum Map October 2016 MAKING CONNECTIONS Health (NGSSS) / Language Arts (LAFS) / Mathematics (MAFS) / Technology (ISTE) HEALTH Students will: HE.5.C.1.6 Explain how human body parts and organs work together in healthy body systems, including the endocrine and reproductive systems. LANGUAGE ARTS Students will: LAFS.5.RI.1.3 Explain the relationship or interactions between two or more individuals, events, ideas, or concepts in a historical, scientific, or technical text based on specific information in the text. LAFS.5.RI.2.4 Determine the meaning of general academic and domain-specific words and phrases in a text relevant to a grade 5 topic or subject area. LAFS.5.RI.4.10 By the end of the year, read and comprehend information texts, including history/social studies, science, and technical texts, at the high end of the grades 4-5 text complexity band independently and proficiently. LAFS.5.SL.1.1 Engage effectively in a range of collaborative discussions (one-on-one, in groups, and teacher-led) with diverse partners on grade 5 topics and texts, building on others’ ideas and expressing their own clearly. a. Come to discussions prepared, having read or studied required material; explicitly draw on that preparation and other information known about the topic to explore ideas under discussion. b. Follow agreed-upon rules for discussions and carry out assigned roles. c. Pose and respond to specific questions by making comments that contribute to the discussion and elaborate on the remarks of others. d. Review the key ideas expressed and draw conclusions in light of information and knowledge gained from the discussions. LAFS.5.W.3.8 Recall relevant information from experiences or gather relevant information from print and digital sources; summarize or paraphrase information in notes and finished work, and provide a list of sources. LAFS.5.W.3.9 Draw evidence from literary or informational texts to support analysis, reflection, and research. a. Apply grade 5 Reading standards to literature (e.g., “Compare and contrast two or more characters, settings, or events in a story or a drama, drawing on specific details in the text [e.g., how characters interact]”). b. Apply grade 5 Reading standards to information texts (e.g., “Explain how an author uses reasons and evidence to support particular points in a text, identifying which reasons and evidence support which point[s]”). MATHEMATICS Students will: MAFS.5.G.1.1 Use a pair of perpendicular number lines, called axes, to define a coordinate system, with the intersection of the lines (the origin) arranged to coincide with the 0 on each line and a given point in the plane located by using an ordered pair of numbers, called its coordinates. Understand that the first number indicates how far to travel from the origin in the direction of one axis, and the second number indicates how far to travel in the direction of the second axis, with the convention that the names of the two axes and the coordinates correspond (e.g., x-axis and x-coordinate, y-axis and y-coordinate). MAFS.1.MD.2.2 Make a line plot to display a data set of measurements in fractions of a unit (1/2, 1/4, 1/8). Use operations on fractions for this grade to solve problems involving information presented in line plots. For example, given different measurements of liquid in identical beakers, find the amount of liquid each beaker would contain if the total amount in all the beakers were redistributed equally. TECHNOLOGY Students will: Creativity and innovation Demonstrate creative thinking, construct knowledge, and develop innovative products and processes using technology. Communication and collaboration Use digital media and environments to communicate and work collaboratively, including at a distance, to support individual learning and contribute to the learning of others. Research and informational fluency Apply digital tools to gather, evaluate, and use information. Critical thinking, problem solving, and decision making Use critical thinking skills to plan and conduct research, manage projects, solve problems, and make informed decisions using appropriate digital tools and resources. Digital Citizenship Understand human, cultural, and societal issues related to technology and practice legal and ethical behavior. Technology operations and concepts Demonstrate a sound understanding of technology concepts, systems, and operations. 6 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 MAKING CONNECTIONS Standards for Mathematical Practice Students will: Make sense of problems and persevere in solving them. (SMP.1) Solving a mathematical problem involves making sense of what is known and applying a thoughtful and logical process which sometimes requires perseverance, flexibility, and a bit of ingenuity. Reason abstractly and quantitatively. (SMP.2) The concrete and the abstract can complement each other in the development of mathematical understanding: representing a concrete situation with symbols can make the solution process more efficient, while reverting to a concrete context can help make sense of abstract symbols. Construct viable arguments and critique the reasoning of others. (SMP.3) A well-crafted argument/critique requires a thoughtful and logical progression of mathematically sound statements and supporting evidence. Model with mathematics. (SMP.4) Many everyday problems can be solved by modeling the situation with mathematics. Use appropriate tools strategically. (SMP.5) Strategic choice and use of tools can increase reliability and precision of results, enhance arguments, and deepen mathematical understanding. Attend to precision. (SMP.6) Attending to precise detail increases reliability of mathematical results and minimizes miscommunication of mathematical explanations. Look for and make use of structure. (SMP.7) Recognizing a structure or pattern can be the key to solving a problem or making sense of a mathematical idea. Look for and express regularity in repeated reasoning. (SMP.8) Recognizing repetition or regularity in the course of solving a problem (or series of similar problems) can lead to results more quickly and efficiently. 7 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Science Process Skills: Basic and Integrated Observing: using your senses to gather information about an object or event; a description of what is actually perceived; information that is considered to be qualitative data Measuring: using standard measures or estimations to describe specific dimensions of an object or event; information considered to be quantitative data Inferring: formulating assumptions or possible explanations based upon observations Classifying: grouping or ordering objects or events into categories based upon characteristics or defined criteria Predicting: guessing the most likely outcome of a future event based upon a pattern of evidence Communicating: using words, symbols, or graphics to describe an object, action, or event Formulating Hypotheses: stating the proposed solutions or expected outcomes for experiments; proposed solutions to a problem must be testable Identifying Variables: stating the changeable factors that can affect an experiment; important to change only the variable being tested and keep the rest constant Defining Variables: explaining how to measure a variable in an experiment Designing Investigations: designing an experiment by identifying materials and describing appropriate steps in a procedure to test a hypothesis Experimenting: carrying out an experiment by carefully following directions of the procedure so the results can be verified by repeating the procedure several times Acquiring Data: collecting qualitative and quantitative data as observations and measurements Organizing Data: making data tables and graphs for data collected Analyzing Investigations: interpreting data, identifying errors, evaluating the hypothesis, formulating conclusions, and recommending further testing when necessary 8 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 5E Learning Cycle: An Instructional Model ENGAGEMENT EXPLORATION EXPLANATION ELABORATION EVALUATION The engagement phase of the model is intended to capture students’ interest and focus their thinking on the concept, process, or skill that is to be learned. The exploration phase of the model is intended to provide students with a common set of experiences from which to make sense of the concept, process or skill that is to be learned. The explanation phase of the model is intended to grow students’ understanding of the concept, process, or skill and its associated academic language. The elaboration phase of the model is intended to construct a deeper understanding of the concept, process, or skill through the exploration of related ideas. The evaluation phase of the model is intended to be used during all phases of the learning cycle driving the decision-making process and informing next steps. During this engagement phase, the teacher is on center stage. During the exploration phase, the students come to center stage. During the explanation phase, the teacher and students share center stage. During the elaboration phase, the teacher and students share center stage. During the evaluation phase, the teacher and students share center stage. What does the teacher do? • create interest/curiosity • raise questions • elicit responses that uncover student thinking/prior knowledge (preview/process) • remind students of previously taught concepts that will play a role in new learning • familiarize students with the unit What does the teacher do? • provide necessary materials/tools • pose a hands-on/minds-on problem for students to explore • provide time for students to “puzzle” through the problem • encourage students to work together • observe students while working • ask probing questions to redirect student thinking as needed What does the teacher do? • ask for justification/clarification of newly acquired understanding • use a variety of instructional strategies • use common student experiences to: o develop academic language o explain the concept • use a variety of instructional strategies to grow understanding • use a variety of assessment strategies to gauge understanding What does the teacher do? • provide new information that extends what has been learned • provide related ideas to explore • pose opportunities (examples and non-examples) to apply the concept in unique situations • remind students of alternate ways to solve problems • encourage students to persevere in solving problems What does the teacher do? • observe students during all phases of the learning cycle • assess students’ knowledge and skills • look for evidence that students are challenging their own thinking • present opportunities for students to assess their learning • ask open-ended questions: o What do you think? o What evidence do you have? o How would you explain it? What does the student do? What does the student do? What does the student do? What does the student do? What does the student do? • show interest in the topic • reflect and respond to questions • ask self-reflection questions: o What do I already know? o What do I want to know? o How will I know I have learned the concept, process, or skill? • make connections to past learning experiences • manipulate materials/tools to explore a problem • work with peers to make sense of the problem • articulate understanding of the problem to peers • discuss procedures for finding a solution to the problem • listen to the viewpoint of others • generate interest in new learning • explore related concepts • apply thinking from previous learning and experiences • interact with peers to broaden one’s thinking • explain using information and experiences accumulated so far • participate actively in all phases of the learning cycle • demonstrate an understanding of the concept • solve problems • evaluate own progress • answer open-ended questions with precision • ask questions Evaluation of Exploration The role of evaluation during the exploration phase is to gather an understanding of how students are progressing towards making sense of a problem and finding a solution. • record procedures taken towards the solution to the problem • explain the solution to a problem • communicate understanding of a concept orally and in writing • critique the solution of others • comprehend academic language and explanations of the concept provided by the teacher • assess own understanding through the practice of self-reflection Evaluation of Explanation The role of evaluation during the explanation phase is to determine the students’ degree of fluency (accuracy and efficiency) when solving problems. Strategies and procedures used by students during this phase are highlighted during explicit instruction in the next phase. Conceptual understanding, skill refinement, and vocabulary acquisition during this phase are enhanced through new explorations. Application of new knowledge in unique problem solving situations during this phase constructs a deeper and broader understanding. The concept, process, or skill is formally explained in the next phase of the learning cycle. The concept, process, or skill is elaborated in the next phase of the learning cycle. The concept, process, or skill has been and will be evaluated as part of all phases of the learning cycle. Evaluation of Engagement The role of evaluation during the engagement phase is to gain access to students’ thinking during the pre-assessment event/activity. Conceptions and misconceptions currently held by students are uncovered during this phase. These outcomes determine the concept, process, or skill to be explored in the next phase of the learning cycle. 9 Volusia County Schools Elementary Science Department Evaluation of Elaboration The role of evaluation during the elaboration phase is to determine the degree of learning that occurs following a differentiated approach to meeting the needs of all learners. Grade 5 Science Curriculum Map October 2016 Webb’s Depth of Knowledge (DOK) Model of Cognitive Complexity LOW COMPLEXITY Level 1 MODERATE COMPLEXITY Level 2 HIGH COMPLEXITY Level 3 HIGH COMPLEXITY Level 4 (Recall) (Basic Application of Concepts and Skills) (Strategic Thinking & Complex Reasoning) (Extended Thinking & Complex Reasoning) This level is the recall of information such as a fact, definition, or term, as well as performing a simple science process or procedure. Level 1 only requires students to demonstrate a rote response; use a well-known formula; follow a set, well-defined procedure (like a recipe); or perform a clearly defined series of steps. Some examples are: • Recall or recognize a fact, term, or property. • Represent in words or diagrams a scientific concept or relationship. • Provide or recognize a standard scientific representation for simple phenomena. • Perform a routine procedure, such as measuring length. • Identify familiar forces (e.g., pushes, pulls, gravitation, friction, etc.). • Identify objects and materials as solids, liquids, and gases. This level includes the engagement of some mental processing beyond recalling or reproducing a response. The content knowledge or process involved is more complex than in Level 1. Level 2 requires that students make some decisions as to how to approach the question or problem. Level 2 activities include making observations, and collecting data; classifying, organizing, and comparing data; and representing and displaying data in tables, graphs, and charts. Some examples are: • Specify and explain the relationships among facts, terms, properties, and variables. • Identify variables, including controls, in simple experiments. • Distinguish between experiments and systematic observations. • Describe and explain examples and non-examples of science concepts. • Select a procedure according to specified criteria, and perform it. • Formulate a routine problem given data and conditions. • Organize and represent data. This level requires reasoning, planning, using evidence, and a higher level of thinking than the previous two levels. The cognitive demands at Level 3 are complex and abstract because the multi-step task requires more demanding reasoning than Level 2. Level 3 activities include drawing conclusions from observations; citing evidence and developing a logical argument for concepts; explaining phenomena in terms of concepts; and using concepts to solve non-routine problems. Some examples are: • Identify research questions and design investigations for a scientific problem. • Design and execute an experiment or systematic observation to test a hypothesis or research question. • Develop a scientific model for a complex situation. • Form conclusions from experimental data. • Cite evidence that living systems follow the laws of conservation of mass and energy. • Explain the physical properties of the sun and its dynamic nature and connect them to conditions and events on Earth. This level has the same high cognitive demands as Level 3 with the additional requirement that students work over an extended period of time or with extended effort. Students are required to make several connections—relating ideas within the content area or among content areas—and have to select or devise one approach among many alternatives for how the situation or problem can be solved. It is important to note that the extended time period is not a distinguishing factor if the required work is only repetitive and does not require the application of significant conceptual understanding and higher-order thinking. Some examples are: • Based on provided data from a complex experiment that is novel to the student, deduce the fundamental relationship among several variables. • Conduct an investigation, from specifying a problem to designing and carrying out an experiment and analyzing data and forming conclusions. • Produce a detailed report of a scientific experiment or systematic observation, and infer conclusions based upon evidence obtained. More information about Florida’s DOK levels is available online at http://www.cpalms.org/cpalms/dok.aspx. 10 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 is the recall of information such as a fact, definition, or term as well as performing a simple science process or procedure. Level 1 only requires students to demonstrate a rote response, restate information in their own words, and/or follow or perform a well-defined procedure. Level 1 Recall or Reproduction… Adapted from the Florida Interim Assessment Item Bank and Test Platform Levels of Depth of Knowledge for Science Level 2 Basic Application… Adapted from the Florida Interim Assessment Item Bank and Test Platform Levels of Depth of Knowledge for Science Some Examples of Level 2 Performance Read and interpret information from a simple graph. Designate and explain the relationships among facts, terms, properties, and variables (e.g., compare physical properties of solids, liquids, and gases). Identify variable and controls in simple experiments. Distinguish between experiments and systematic observations. Describe and explain examples and nonexamples of science concepts (e.g., flowering and non-flowering plants). Select a procedure according to specified criteria, and perform it. Formulate a routine problem given data and conditions. Question Stems Explain how _____ affected _____. Apply what you have learned to _____. Compare/contrast. How would you classify _____? What could you use to classify? How are _____ alike? Different? Summarize. What do you notice about _____? What do you observe? Infer? What are some examples of _____? What are some non-examples of _____? Given the data, what was the testable question? What variable is being tested? What is the control group? What procedure would you use? is engaging in a mental process that goes beyond basic recall or reproduction, requiring two or more steps before giving a response. Students are asked to apply their knowledge of content on a simple level. Level 2 requires student to make some decisions as to how to approach a question or problem such as to classify, organize, and compare data. Some Examples of Level 1 Performance Recall or recognize a fact, term, or property (e.g., how speed is determined). Represent a scientific concept or relationship in words or diagrams. Retrieve information from a chart, table, diagram, or graph. Recognize a standard scientific representation of a simple phenomenon (e.g., water cycle model). Identify common examples of topics, objects, and materials (e.g., familiar forces and invertebrates). Perform a routine procedure such as measuring length. Question Stems What is (was) _____? What _____ did you use? What are some examples of _____? How many _____? Identify the _____? Make a listing of _____? Why did you choose _____? How would you describe _____? How can you recognize _____? When did _____ happen? Recall what happened. What happened when _____? Retell. Draw. Select or retrieve _____? What data represents _____? Which _____ has the most? Least? Read your data table, chart, or graph. Is _____ on the graph? What pattern is seen when _____? Grade 5 Science Curriculum Map October 2016 Volusia County Schools Elementary Science Department 11 Adapted from the Florida Interim Assessment Item Bank and Test Platform Levels of Depth of Knowledge for Science Level 4 Extended Thinking… Adapted from the Florida Interim Assessment Item Bank and Test Platform Levels of Depth of Knowledge for Science Some Examples of Level 4 Performance Relate scientific concepts to other content areas (e.g., impact of environment changes). Develop generalizations of the results obtained and apply them to new situations (e.g., predict the weather in a particular place and time). Select or devise an approach among many alternatives for how a situation or problem is to be solved. Analyze multiple sources of evidence. Apply understanding in a new way, provide argument or justification for the application (e.g., using inertia). Conduct an investigation, from specifying a problem to designing and carrying out an experiment and analyzing data and forming conclusions. Question Stems/Tasks What information can you gather to support your idea about _____? Apply information from one text to another text to develop a persuasive argument. Write a research paper/thesis on a topic from multiple sources. Judge the value of material for a given purpose. Consider multiple lines of inquiry to explain a particular scientific theory (e.g., conservation of mass and inertia). Produce a detailed report of a scientific experiment or systematic observation, and infer conclusions based upon evidence obtained. Provide time for extended thinking. Assess through performance and open-ended activities. requires the same high cognitive demands as Level 3 with the additional requirement that students work over an extended period of time and/or with extended effort. Level 4 assessment items require significant thought. Level 3 Strategic Thinking… Some Examples of Level 3 Performance requires reasoning, planning, using evidence, and complex and abstract thinking. The complexity results from there being multiple correct responses in which student justification is necessary and thorough. Level 3 asks students to cite evidence when developing a logical argument and to explain scientific phenomena in terms of concepts. Design and execute an experiment or systematic observation to test a hypothesis or research question. Design and develop a scientific model to explain a scientific concept or theory. Form conclusions from experimental data. Cite evidence for scientific theory (e.g., energy is neither lost nor created within food chains and electrical circuits). Compare information within or across data sets (several monthly temperature graphs of the same city). Explain how political, social, and economic concerns can affect science, and vice versa. Explain the properties of the sun and its position within the solar system and then connect this knowledge to the condition and events occurring on Earth. Question Stems What conclusions can you draw? How would you test _____? What would the outcome be if _____? What features of the graph should be considered when _____? What question could we ask now? What evidence should be considered? Explain your thinking when there is more than one answer. Elaborate. Formulate a reason as to why _____? Which facts support _____? What is the best answer? Why? How would you adapt _____ to create a different _____? How is _____ related to _____? Grade 5 Science Curriculum Map October 2016 Volusia County Schools Elementary Science Department 12 “Fair Game” Benchmark Reference for grades 3 and 4 Expected learning from grades 3 and 4 that is “fair game” on the State-wide Science Assessment (SSA) in grade 5. Refer to this section when formulating an action plan based upon student performance on the beginning- and mid-year progress monitoring tool. LIFE SCIENCE Plants (SC.3.L.14.1, SC.3.L.14.2, SC.4.L.16.1) • plant structures and their functions (food production, support, water/nutrient absorption and transportation, and reproduction) • plants’ responses to stimuli (heat, light, and gravity) • reproduction of flowering (seeds) and nonflowering plants such as moss and ferns (spores) • parts of a flower (e.g., stamen, pistil, ovary, petals, pollen/sperm, eggs) • germination, pollination, fertilization, seed dispersal Plant and Animal Classification (SC.3.L.15.1, SC.3.L.15.2) • classification of flowering and non-flowering plants into major groups (those who produce seeds and those who produce spores) • classification of animals into vertebrates (fish, mammals, birds, reptiles, amphibians) and invertebrates (only arthropods) according to physical characteristics and behaviors (e.g., those which give live birth vs. those which lay eggs, cold-blooded vs. warm-blooded, lungs vs. gills) Heredity (SC.4.L.16.2, SC.4.L.16.3) • characteristics (traits) of plants are inherited by offspring from parents (e.g., type of plant, color of flower, leaf shape, size) • characteristics (traits) of animals are inherited by offspring from parents (e.g., freckles, height, dimples, eye color) • characteristics (traits) of animals are learned/acquired by the environment (e.g., hair color and length, playing an instrument, reading) • examples of animal behaviors may be shaped by heredity or learning o instinctive behaviors: hibernation, migration, hunting, protecting young o learned behaviors: using tools, language, hunting, playing sports, writing Plant and Animal Life Cycles (SC.4.L.16.4) • life cycle of flowering and non-flowering plants (seed, seedling, mature adult, reproduction) • life cycle of insects that go through complete metamorphosis/4-stages (egg, larva, pupa, adult) • life cycle of insects that go through incomplete metamorphosis/3-stages (egg, nymph, adult) • life cycle of animals (egg, embryo, infant, adolescent, adult) Seasonal Changes (SC.3.L.17.1, SC.4.L.17.1) • animals respond (are adapted) to changing seasons (e.g., clothing, hibernation, migration, shedding, birth, color change) • seasonal changes (e.g., dormancy, leaves changing color and falling) in Florida plants compared to those in other regions of the country • seasonal changes (e.g., color change, body covering change, hibernation, migration) in Florida animals compared to those in other regions of the country Life’s Energy (SC.3.L.17.2, SC.4.L.17.2, SC.4.L.17.3) • energy is transferred from the sun through a food chain (flow of energy) • plants are producers that make their own food using carbon dioxide, water, and energy from the sun • animals are consumers that obtain energy from the plants and/or animals they eat • types of consumers (carnivore, herbivore, omnivore) 13 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 “Fair Game” Benchmark Reference Grades 3-4 Expected learning from grades 3 and 4 that is “fair game” on the State-wide Science Assessment (SSA) in grade 5. EARTH SCIENCE Rocks and Minerals (SC.4.E.6.1, SC.4.E.6.2) • physical properties of common earth-forming minerals (hardness, color, luster, cleavage, and streak color) • role of minerals in the formation of rocks • three categories of rocks (igneous formed from molten rock; sedimentary pieces of other rocks/sediment cemented together and fossilized organisms; metamorphic formed from heat and pressure) Renewable and Nonrenewable Resources (SC.4.E.6.3, SC.4.E.6.6) • renewable and nonrenewable resources found on Earth • natural resources found in Florida (water, phosphate, oil, limestone, silica, wind, and solar energy) Weathering and Erosion (SC.4.E.6.4) • process of physical weathering (breaking down of rock by wind, water, ice, temperature change, and plants) • process of erosion (movement of rock by gravity, wind, water, and ice) Heat Loss/Heat Gain (SC.3.E.6.1) • energy from the sun can heat objects (heat gain) and when the sun is not present, heat may be lost (heat loss). • sun’s presence, visible or not visible, will impact objects (e.g., size, shape, state, color, temperature). PHYSICAL SCIENCE Volume and Water Displacement (SC.3.P.8.2) • measure volume of solids by calculating the amount of water displaced in a container (graduated cylinder) • used for both regular and irregular shapes (wooden cube, shell, rock, coin, marble, dice) Heat Flow (SC.4.P.11.1) • heat flows from a hot object to a cold object and that heat flow may cause materials to change temperature. Resources that may support the review and remediation of these concepts throughout the school year include, but are not limited to, the following: • • • • • HMH Think Central (digital resource for grades 3 and 4) SRE: Science inSpiRE (support located on Canvas) Making LIFE Easier (lessons located on Canvas) Florida Achieves FOCUS (support located on Canvas) Florida COACH Standards-based Instruction (printed resource for grades 3, 4, and 5) 14 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 NGSSS BODY OF KNOWLEDGE: NATURE OF SCIENCE Unit of Study: Introduction to Practice of Science PACING: Weeks 1 – 4 August 15 – September 9 Kindergarten – SC.K.N.1.1, SC.K.N.1.2, SC.K.N.1.3, SC.K.N.1.4, SC.K.N.1.5 First Grade – SC.1.N.1.1, SC.1.N.1.2, SC.1.N.1.3, SC.1.N.1.4, SC.1.E.5.3 Second Grade – SC.2.N.1.1, SC.2.N.1.2, SC.2.N.1.3, SC.2.N.1.4, SC.2.N.1.5, SC.2.N.1.6 Third Grade – SC.3.N.1.1, SC.3.N.1.2, SC.3.N.1.3, SC.3.N.1.4, SC.3.N.1.5, SC.3.N.1.6, SC.3.N.1.7 Fourth Grade – SC.4.N.1.1, SC.4.N.1.2, SC.4.N.1.3, SC.4.N.1.4, SC.4.N.1.5, SC.4.N.1.6, SC.4.N.1.7, SC.4.N.1.8, SC.4.N.2.1, SC.4.E.6.5 Prerequisite Learning Topics Week 1 Introduction to Science Learning Targets/Skills Note: Learning targets beginning with “review” indicate instruction from previous grades. Benchmarks Recognize and explain that science is grounded in empirical observations that are testable; explanation must always be linked with evidence. SC.5.N.2.1 Recognize and explain the difference between personal opinion/interpretation and verified observation. SC.5.N.1.6 Students will: • set up a science notebook that will be used all year by students. • explain that science is grounded on evidence-based observations that are testable. • review the difference between verified observations (evidence) and inferences (explanations linked to evidence). • explain the difference between verified observation (fact) and personal opinion/ interpretation (bias). o o • Also assesses SC.3.N.1.7 SC.4.N.1.7 Vocabulary evidence explanations inference verified observation personal opinion/ interpretation science science notebook scientist verified observation – an objective statement of which has been tested and supported by observable and/or measurable evidence/facts (data) personal opinion/interpretation – a subjective statement of a thought that may be based on logic and reason but is not necessarily based on testable evidence/facts distinguish between examples of empirical evidence (observations) and personal opinion/interpretation (a viewpoint based on one’s own judgment of the facts; a bias). Teacher Hints for “Introduction to Science”: • • • • • The State Science Safety Manual (Animals in the Classroom Guidelines) can be accessed at http://www.fldoe.org/contact-us/search.stml?q=Animal+in+the+Classroom. Students may prepare for the Solar System and Weather topic learning targets (beginning Week 6) by starting each morning with work routines which include collecting data on weather, seasons, star patterns, and moon phases. Students could take turns collecting different types of data during different times of the year. Begin planning investigations that incorporate Fair Game benchmarks within your instruction of 5th grade Nature of Science benchmarks such as incorporating SC.3.L.14.1 (plant structure and function) and SC.3.L.14.2 (plants responding to heat, light, and/or gravity) with SC.5.N.1.1. Empirical evidence (data) is a source of knowledge acquired by means of observation or experimentation. Students need to be able to distinguish between examples of verified observations, inferences, and personal opinions/interpretations using evidence/facts. March April May • • • Average Weather Data Over Three Months Air Temp. Rainfall 20˚C 2 cm 22 ˚C 4.5 cm 23 ˚C 3 cm verified observation – There was 1.5 cm more precipitation in April than in May. inference – The data shows that there is not a relationship between air temperature and rainfall. personal opinion/interpretation – March is the month to do outside activities; March had more dry days than any other month. 15 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Define a problem, use appropriate reference materials to support scientific understanding, plan and carry out scientific investigations of various types such as: systematic observations, experiments requiring the identifications of variables, collecting and organizing data, interpreting data in charts, tables, and graphics, analyze information, make predictions, and defend conclusions. Weeks 2-4 Introduction to Science Process This topic is continued on the next page. 05 Science SMT 1 to be administered during Week 2. Students will: • generate testable questions that will generate observable and measurable data. • formulate a testable hypothesis based on information gathered from research. • design a scientific investigation individually or in teams through a variety of methods • use scientific tools during investigations to observe and measure physical properties. • explain that all conditions in an experiment outside the manipulated variable must be controlled or kept the same (ensure that the results of an experiment can be explained ONLY by the variable being tested and not by some other factor). • evaluate another’s written procedure or experimental setup. • collect and record observable and measureable data in science notebooks. • organize data in appropriate forms of record keeping (e.g., charts, tables, graphs). • interpret and analyze data that has been collected. • generate appropriate explanations based on evidence gathered (e.g., “My hypothesis was/was not supported by the evidence because…” or “The data gathered during my experiment did/did not support my hypothesis because…”). • apply explanations to real world connections (application). SC.5.N.1.1 Also assesses SC.3.N.1.1 SC.4.N.1.1/1.6 o o o o Recognize and explain that when scientific investigations are carried out, the evidence produced by those investigations should be replicable by others. SC.5.N.2.2 Recognize and explain the need for repeated experimental trials. SC.5.N.1.3 Students will: • recognize that the results of experimental trials can vary even when common tools and procedures are used. • discuss the reason for differences that may occur in data across groups as a result of using different tools and/or procedures. • explain the need for repeated experimental trials or large experimental groups (to ensure the results are accurate, reliable, and valid). • explain what is needed in order to repeat and replicate a scientific investigation (documented scientific procedures). • recognize that when an experiment is replicated, it should produce similar results. • distinguish the difference between repetition and replication. accurate communicate experimental design experimental groups experimental setup investigation mass/weight prediction record keeping reliable repeated observation repeated trials repetition/repeated replication/replicable results scientific method Also assesses SC.3.N.1.2/1.5 SC.4.N.1.2/1.5 o o o o question/problem research hypothesis experiment materials procedure data/evidence results conclusion application scientific tools o o o o o o o o o o o o o o o o balance beaker eye dropper flask forceps goggles graduated cylinder hand lens meter stick microscope ruler scale spring scale stopwatch tape measure thermometer temperature time valid variable volume 16 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 SC.5.N.1.4 control group experiment experimental group Explain the difference between an experiment and other types of scientific investigation. SC.5.N.1.2 Recognize and explain that authentic scientific investigation frequently does not parallel the steps of “the scientific method”. SC.5.N.1.5 exploration research scientific method systematic observations types of scientific investigations Identify a control group and explain its importance in an experiment. Students will: • identify the control group in an experiment (a test group where the variable is NOT applied; considered to be the “normal condition” within the context of an experiment). • explain the importance of a control group (to yield baseline data by which all other data will be compared). Weeks 2-4 Introduction to Science Process Students will: • explain that an authentic scientific investigation frequently does not parallel the steps of “the scientific method”. • explain the difference between an experimental investigation and other types of scientific investigation. Also assesses SC.4.N.1.3 o comparative o descriptive o experimental experimental investigation – used when one variable is defined/known and a test is done descriptive investigation – used to observe, describe, or identify o comparative investigation – used to compare, differentiate, or classify Teacher Hints for “Introduction to Science Process”: • Digital textbook resources can be accessed through V-Portal. See page 51 for access information. • Students need to understand that scientists do not only learn from performing investigations but also from reading non-fiction references materials, such as journals, newspapers, reference books, etc. This research is beneficial before writing a hypothesis or creating an investigation. • Investigations that follow the “scientific method” typically include a question/problem (or purpose), hypothesis, experiment (materials and procedures), results, conclusion (analysis of results), and application. Other investigations may include creating and using models, repeated observations, research, inquiry, problem/solution, and the engineering process. • Some of the experimental investigations performed in the classroom should model 10 repeated trials (expectation for the elementary science fair/expo process). It may be more appropriate, at times, to use a large experimental group (10 or more in a group) instead of repeated trials. • When experimenting, students will need to understand the need to manipulate one variable, to control variables (keeping all other conditions constant) and to test a control group (the normal condition within the context of the experiment). For example, when trying to determine which type of soil supports the growth of marigolds, the following would need to be considered in the design of the experiment: o o o o o • • • • The variable being manipulated would be different types of soil. The variables that need to be controlled would be soil amount, water amount, plant container, plant size, and sunlight exposure. The possible control group that would need to be tested is the soil that is most prevalent in the area where the marigolds will be planted. Repetition (multiple trials yielding stable and consistent data; reliability) differs from replication (experiment done by others to measure accuracy of data). As scientists, students will be making observations and inferences in all types of investigations. Data that is collected through the five senses (observable/qualitative) and through the use of scientific and measurement tools (measurable/quantitative) become their observations. Students make inferences when they interpret or give their own meaning to the data they have collected. Students should work on common investigations so that they are able to compare their results across groups. When differences arise, have students compare the different methods each group used to gather their data. While conducting investigations, students will use scientific tools. Metric measurements should be used when measuring these physical properties of matter: o o o o o mass/weight in grams, kilograms – balance scale/pan balance, spring scale volume in milliliters, liters – graduated cylinder (most accurate), beaker, flask, measuring cup linear in centimeters, meters, kilometers – ruler, meter stick, meter tape time in seconds – stop watch heat energy in Fahrenheit and Celsius – thermometer 17 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Resource Alignment Week 1 Introduction to Science HMH Teacher’s Edition HMH Leveled Readers HMH Inquiry Flipchart/Labs HMH Think Central ScienceSaurus AIMS Science (Florida-specific) pp. 1A – 20A Any Leveled Reader can be used for this unit but a suggested Reader is Fossils: Records of History How Do Scientists Learn About the Natural World?, p. 3 Think Like a Scientist and Compare Models, p. 4 How Does the Body Stay Cool?, p. 34 Test the Waters and That’s Fishy, p. 42 What Is Science? How Do Scientists Learn About the Natural World? pp. 2–27, 38–56, 60–73, 380-393 Earth Science Station Model, p. 181 Temperature Tally, p. 201 Highs and Lows, p. 209 Formative Assessment Probes Safari Montage Introducing the Process of Investigative Science Nature of Science Introducing the Process of Investigative Science CPALMS Florida Achieves FOCUS Dancing Spaghetti (similar to Dancing Raisins) Canvas Web Resources 18 www.thehappyscientist.com See your Science Cadre Member for login information. Happy Scientist: What is Science? Video Volusia County Schools Elementary Science Department Weeks 2-4 Introduction to Science Process pp. 21A-56 How Do You Perform a Controlled Experiment?, p. 5 How Can Scientists Learn from Observations?, p. 7 What Are Some Types of Investigations? How Do You Perform a Controlled Experiment? What Are Some Science Tools? How Can Scientists Learn from Observations? pp. 2–27, 38–56, 60–73, 380-393 Physical Science Clipping Along With Variables, p. 361 Catapults, p. 409 By Golly by Gum, p. 47 Volume 2 Boiling Time and Temperature, p. 53 Sciences As Inquiry In Action Freezing Ice, p. 59 Rollercoaster Investigations Introduction to the Nature Journal Bird Beaks Investigating Variables Lunar Landers: Exploring Gravity Transformation of Energy: Constructing an Electromagnet You Be The Judge Are We Like Robots Tower of Power Bridge to Perfection The Practice of Science: SC.5.N.1.1 Characteristics of Scientific Knowledge: SC.5.N.2.1 Characteristics of Scientific Knowledge: SC.5.N.2.2 Justin’s New Dog Alka Seltzer Investigation The Three Little Pigs Mini-Board Calvin and Hobbs The Leaky Swimming Pool Chew on This Happy Scientist: Floating Cups Video Happy Scientist Floating Cups Study Unit Experiment Scholastic Study Jams: Scientific Theory & Evidence Scholastic Study Jams: Scientific Methods Scholastic Study Jams: Identify Outcomes & Make Predictions Brain Pop: Scientific Method Grade 5 Science Curriculum Map October 2016 NGSSS BODY OF KNOWLEDGE: NATURE OF SCIENCE/EARTH AND SPACE SCIENCE Unit of Study: Space PACING: Weeks 5 – 6 September 12 – September 23 Kindergarten – SC.K.E.5.5, SC.K.E.5.6 First Grade – SC.1.E.5.1, SC.1.E.5.4 Second Grade – none Third Grade – SC.3.E.5.1, SC.3.E.5.2, SC.3.E.5.3 Fourth Grade – none Prerequisite Learning Topics Learning Targets/Skills Week 5 Solar System Benchmarks Distinguish among the following objects of the Solar System – sun, planets, moons, asteroids, comets – and identify Earth’s position in it. SC.5.E.5.3 Recognize the major common characteristics of all planets and compare/contrast the properties of inner and outer planets. SC.5.E.5.2 Students will: • review that Earth rotates on its axis one time every 24 hours. • review that Earth revolves (orbits) around the sun in one year. • review how the appearance of the moon changes each night. • review how patterns of stars (constellations) appear to shift across the sky nightly. • review that different star patterns can be seen in different seasons. • distinguish among the following objects in the Solar System: sun, planets, moons, asteroids, and comets. • identify the position and sequential order of objects within the Solar System in relation to the sun using models (e.g., Earth, other planets, inner/outer planets, asteroid belt, stars, moons). • identify major common characteristics of all planets (tilt on an axis, mass, gravity, revolving/orbiting around a star, rotation, presence of an atmosphere). • compare the similarities among and differences between the characteristics of inner and outer planets (composition, size, atmospheres, relative temperature, moons, rings, relative length of year based on distance from the sun). Embedded Nature of Science SC.5.N.1.1 SC.5.N.1.6 SC.5.N.2.1 SC.5.N.2.2 Vocabulary atmosphere asteroid belt asteroids axis comet composition o terrestrial/rocky/ solid o gaseous Earth gravity mass moon orbit planets o inner o outer revolution/revolve rotation/rotate Solar System star star pattern/ constellation sun tilt Teacher Hints for “Solar System”: • Students will have to know the relationships that exist between planet distance from the sun and the effects of this distance. Therefore, if students are given two planets and asked which planet is hotter, they should recognize which planet is closer to the sun in order to make this comparison and draw conclusions. • Sky Map is an app available on an Android (a free app at this time). It will show you where all of the constellations and planets are in the sky at your current location, day or night. It is a good way to explain that even though we cannot see the stars, they are still present. • Distinguish between asteroids (large space rocks that orbit the sun) and comets (chunks of frozen gases, rock ice, and dust that orbit the sun). • Students will not have to memorize quantitative data about each planet, they will not be assessed on the causes of seasons, and they will not have to identify star patterns in relation to specific seasons. However, they will need to know that the stars appear to shift because the Earth is rotating and revolving, not the stars. • Have students observe and record data on the shape of the moon (what we can see) over a two month period. Students will not have to know the names of the moon phases, just recognize how the phases change over time (e.g., from new moon to 1st quarter moon to full moon to 3rd or last quarter moon, and back again to the new moon). 19 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Recognize that a galaxy consists of gas, dust, and many stars, including any objects orbiting the stars. Identify our home galaxy as the Milky Way. Students will: • review that the sun is a star that emits energy in the form of light and heat. • review that stars are made of gases. • review how stars can be different: brightness, size, temperature/color. • review how a star’s appearance (brightness and size) is affected by its distance from Earth. • describe the composition of a galaxy (gas, dust, and many stars, including any objects orbiting the stars). • identify our home galaxy as the Milky Way. Week 6 Galaxies SC.5.E.5.1 Also assesses SC.3.E.5.1/5.2/5.3 dust galaxy gas Milky Way Embedded Nature of Science SC.5.N.1.1 SC.5.N.1.6 SC.5.N.2.1 Teacher Hints for “Galaxies”: • Students will not need to know specific star names or star patterns/constellations, objects orbiting stars, or the chemical make-up of stars. Statewide Science Assessment may use names of stars or star patterns in the item stems but students will not need to memorize the names of stars or star patterns. • The appearance of a star’s brightness is dependent upon its distance from Earth. A star that is closer to Earth will appear to be brighter than a star that is farther away. • The appearance of a star’s size is dependent on its distance from Earth. A star that is closer to Earth appears to be larger than a star of similar size that is farther away. • Students will not have to identify galaxies by name other than the Milky Way galaxy and will not need to know galaxies by their type. 20 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Resource Alignment Week 5 Solar System HMH Teacher’s Edition HMH Leveled Readers HMH Inquiry Flipchart/Labs HMH Think Central ScienceSaurus AIMS Science (Florida-specific) Formative Assessment Probes Safari Montage CPALMS Florida Achieves FOCUS Web Resources 21 Week 6 Galaxies pp. 61A-82A pp. 83-94 Earth and Beyond (see page 61F TE for additional options) Earth and Beyond (see p. 61F TE for additional options) Making a Scale Model, p. 8 How Do We Observe Objects in the Solar System?, p. 9 What Objects Are Part of the Solar System? How Do We Observe Objects in the Solar System? pp. 218 - 226 – 234 Earth Science Lining Up the Planet, p. 41 Can You Planet?, p. 47 Planetary Logic, p. 67 Asteroids, Comets, and Meteors, p. 85 Planet Trivia, p. 9 Volume 1 Gazing at the Moon, p. 177 Going Through a Phase, p. 183 Bill Nye: The Planets Characteristics of the Solar System Planets & the Solar System This Place is Pretty Big. Where Am I Planets In Space in the Universe? Water Planet FOSS Module Astronomy for Kids Storm on Saturn Sun, Moon & Stars FOSS Module The Comet that Came In From the Common Core & Margot’s Venus Cold A Closer Look at the Inner & Outer What Causes the Phases of the Planets Moon Earth in Space and Time: SC.5.E.5.3 Happy Scientist: Global Science Scholastic Study Jams: Our Solar System: Inner Planets Scholastic Study Jams: Our Solar System: Outer Planets Scholastic Study Jams: A Day on Earth Brain Pop: Solar System Mr. Parr’s Science Song: Moon Phases Mr. Parr’s Science Song: Planets Around a Star Mr. Parr’s Science Song: Solar System Song Volusia County Schools Elementary Science Department What Are Stars and Galaxies? pp. 234-237 Earth Science Generating Galaxies, p. 17 Bill Nye: Outer Space Universe – Chapters 1-4 Hubble Telescope Solar System Exploration Galaxies and Solar System Earth and Space in Time: SC.5.E.5.1 Scale Model Video – Size of Planets and Stars Scholastic Study Jams: The Universe Brain Pop: Galaxies Brain Pop: Life Cycle of Stars Mr. Parr’s Science Song: Galaxies Song Grade 5 Science Curriculum Map October 2016 NGSSS BODY OF KNOWLEDGE: NATURE OF SCIENCE/EARTH AND SPACE SCIENCE Unit of Study: Weather & Climate PACING: Weeks 7 – 12 September 26 – November 4 Kindergarten – none First Grade – none Second Grade – SC.2.E.7.1, SC.2.E.7.2, SC.2.E.7.3, SC.2.E.7.4, SC.2.E.7.5, SC.2.P.8.4, SC.2.P.8.5 Third Grade – none Fourth Grade – none Prerequisite Learning Topics Learning Targets/Skills Benchmarks Create a model to explain the parts of the water cycle. Water can be a gas, a liquid, or a solid and can go back and forth from one state to another. SC.5.E.7.1 Recognize that the ocean is an integral part of the water cycle and is connected to all of Earth’s water reservoirs via evaporation and precipitation processes. SC.5.E.7.2 Students will: • review that water and the sun’s energy are renewable resources found on Earth. • review how water changes its state through warming and cooling processes. • create and label the parts of various 2- and 3-D models of the water cycle (evaporation, condensation, precipitation, runoff, collection). • investigate the water cycle using various 3-D models. • explain the changes that occur to water as it moves from one part of the water cycle to another (e.g., evaporation-liquid water changes to water vapor, condensation-water vapor changes to liquid water). • describe the role of the sun in the water cycle (provides the heat energy required for evaporation). • describe the role of the oceans in the water cycle (provides most of the water for the water cycle). • explain that oceans are connected to all bodies of water on Earth via the evaporation and precipitation processes. Weeks 7-8 Water Cycle Embedded Nature of Science SC.5.N.1.1 SC.5.N.1.2 SC.5.N.1.5 SC.5.N.1.6 SC.5.N.2.1 SC.5.N.2.2 Vocabulary collection condensation evaporation freshwater heat gain/warming heat loss/cooling liquid water precipitation reservoir resources o renewable o nonrenewable runoff saltwater solid water/ice states of matter water cycle water vapor/gas Teacher Hints for “Water Cycle”: • Students will need to be exposed to various representations and/or stages of the water cycle (i.e. puddles, wet jeans hanging on a clothesline, water in a swimming pool, water in a fish tank, glass of ice tea, sealed plastic bag of water). • In grade 3, students explored the physical changes of water. Review this foundational knowledge for the water cycle by defining and explaining vocabulary associated with matter changes: o o o o • • • melting – changing from a solid (ice) to a liquid (water) due to a heat gain evaporating – changing from a liquid (water) to a gas (vapor) due to a heat gain condensing – changing from a gas (vapor) to a liquid (water) due to a heat loss freezing – changing from a liquid (water) to a solid (ice) due to a heat loss Condensation may take the forms of a cloud, fog, dew, frost, and/or humidity. This is an appropriate time to review renewable/nonrenewable resources that were taught in Grade 4 because water and the sun’s energy are renewable resources. Include a discussion of Florida’s renewable resources of sun, wind, and water as well as Florida’s non-renewable resources of phosphate, silica, limestone, and oil. SSA will not assess following terms: transpiration, infiltration, percolation, and reservoir. However, some terms, such as the term reservoir (collection), are not assessed on SSA but are good words to use instructionally. Earth’s bodies of water include, but are not limited to oceans, lakes, rivers, ponds, streams, and puddles. 22 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Recognize how air temperature, barometric pressure, humidity, wind speed and direction, and precipitation determine the weather in a particular place and time. Students will: • review measuring temperature using dual thermometers (Celsius and Fahrenheit). • describe each of the components that determine the weather in a particular place and time (air temperature, air pressure, humidity, wind speed and direction, and precipitation). • match weather data collection tools to the component of weather it measures (thermometer-air temperature, anemometer-wind speed, barometer-air pressure, wind vane-wind direction, rain gauge-precipitation, hygrometer-humidity). • collect and record daily weather data using selected tools for the next two weeks. • describe relationships that exist between components of weather: o o o o • Weeks 9-10 o Weather o • o o o o o o air pressure air temperature humidity precipitation wind direction wind speed weather tools o o o o o o As the air temperature increases, the humidity increases. If the air pressure drops rapidly, the air temperature increases. When the humidity increases, the chances for rain are greater. As the air temperature approaches freezing, the chance of snow is greater. barometer thermometer hygrometer rain gauge wind vane anemometer Cooler temperatures, higher pressure, and little or no humidity are components of fair weather. Warmer temperatures, lower pressure, and higher humidity are components of stormy weather. Winds blowing from Canada toward Florida will bring cooler air with lower humidity and less chance for precipitation. identify and describe how air temperature, air pressure, humidity, wind speed and direction, and precipitation varies at different times (season to season). Distinguish among the various forms of precipitation (rain, snow, sleet, and hail), making connections to the weather in a particular place and time. Students will: • identify cloud types (cumulus, cirrus, stratus, and cumulonimbus) and their relationship to weather (e.g., cumulonimbus clouds are associated with stormy weather). • explain how different types of precipitation form (rain, snow, sleet, and hail). • explain the conditions necessary for different types of precipitation to form (e.g. hail develops during strong thunderstorms). • discuss relationships that exist amongst weather, location, and season (e.g., a strong thunderstorm may produce hail in Florida during spring and summer). Recognize that some of the weather-related differences, such as temperature and humidity, are found among different environments, such as swamps, deserts, and mountains. Students will: • compare the weather conditions of different environments: desert, grassland, rainforest, tundra, wetland, swamps, and mountains (e.g., the weather over a desert is more likely to be dry and hot, and the weather over a swamp is more likely to be warm and rainy). 23 Embedded Nature of Science SC.5.N.1.1 SC.5.N.1.6 SC.5.N.2.1 SC.5.N.2.2 environment fair weather stormy weather weather components identify and describe how air temperature, air pressure, humidity, wind speed and direction, and precipitation determine the weather in a particular place. o Teacher Hints for this topic are on the next page. SC.5.E.7.3 Volusia County Schools Elementary Science Department SC.5.E.7.4 Embedded Nature of Science SC.5.N.1.6 SC.5.N.2.1 SC.5.E.7.5 Embedded Nature of Science SC.5.N.2.1 cirrus cloud cumulonimbus cumulus erosion hail rain seasons sleet snow stratus desert environments forest grassland mountains rainforest swamps tundra wetland Grade 5 Science Curriculum Map October 2016 Teacher Hints for “Weather”: • You may want to have students track the weather elements (air temperature, air pressure, humidity, cloud cover, etc.) on a class chart and in their student notebook. • In scenarios, wind speeds will be shown in miles per hour (mph). • Students will need to know how clouds are related to weather and that cumulus, cirrus, stratus, and cumulonimbus clouds are all associated with certain kinds of weather conditions. Students should be aware that clouds have names but they will not have to differentiate among the different types of clouds. • Distinguish between how sleet and hail form: o sleet - precipitation that freezes near the ground that often begins as rain or snow o hail - precipitation that is chunks/balls of ice that usually falls during a thunderstorm • • Assessment items will use the term air pressure rather than barometric pressure. This is a good time to review weathering and erosion, a concept that is only taught in Grade 4. Weathering may occur as a result of precipitation falling onto Earth’s surface and as it flows, chip and break rock. Erosion may occur as water is flowing over Earth’s surface, moving bits of rock from one place to another. SC.5.E.7.6 climate Describe characteristics (temperature and precipitation) of different climate zones as they relate to latitude, climate zone elevation, and proximity to bodies of water. elevation Students will: Embedded Weeks 11-12 environment Nature of Science • identify the location of major climate zones (polar, tropical, and temperate) on a globe and equator SC.5.N.1.1 on different maps. latitude SC.5.N.2.1 Climate polar • locate the equator (0 degrees latitude) and Florida on a globe and on different maps. temperate • distinguish between environments and climate zones (e.g. the tundra environment is tropical OPTIONAL located within the polar zone, the rainforest environment is within the tropical zone). 05 VST 1 available to administer at the end of the Earth/Space Unit (Week 12) • • • • describe air temperature and precipitation of different climate zones. describe how air temperature and precipitation relate to latitude (distance from equator) within a climate zone. describe how air temperature and precipitation relate to elevation (e.g., mountains and valleys) within a climate zone. describe how air temperature and precipitation relate to the proximity to bodies of water (e.g., coastal vs. inland, ocean currents) within a climate zone. Teacher Hints for “Climate”: • Students should have practice locating the equator and tropical, temperate, and polar zones on different maps. Students should be able to identify the different environments located within each zone. At the elementary level, students need to recognize Florida as being in the temperate zone. • Students should have exposure to topographic maps in order to feel how elevation is represented on a map. • Students will not require specific knowledge of geographic locations and will not need to know about cold and warm fronts. SC.5.E.7.7 natural disasters Design a family preparedness plan for natural disasters and identify the reasons for having such a plan. preparedness Students will: • recognize that Florida’s temperate climate, proximity to the ocean, and geography make it vulnerable to a number of potential natural disaster threats (e.g., hurricanes, tropical storms, tornadoes, wildfires, flooding). • design a family preparedness plan for natural disasters. • identify the reasons for having family preparedness plans. Enrichment Teacher Hints for “Enrichment (Family Preparedness Plan)”: • Some resources that could be used as a home-school connection activity are provided below. o o Creating a severe weather plan. http://www.floridadisaster.org/family/) AIMS Earth Science (Coordinating a Plan – pages 347-358) 24 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Resource Alignment Weeks 7-8 Water Cycle HMH Teacher’s Edition HMH Leveled Readers HMH Inquiry Flipchart/Labs HMH Think Central ScienceSaurus AIMS Science (Florida-specific) Formative Assessment Probes Safari Montage CPALMS Florida Achieves FOCUS Web Resources 25 Weeks 9-10 Weather Weeks 11-12 Climate pp. 97A-114A pp. 115A-142A pp. 143-158 Sun, Rain, Hurricane, What Makes Weather? (pp. 8 – 11) (see page 97F TE for additional options) Watching the Water Cycle and An Icy Observation, p. 11 What Happens During the Water Cycle, p. 12 What Is the Water Cycle? What Happens During the Water Cycle? pp. 187–193 Earth Science Checking on the Water Cycle, p.103 The Mini Water Cycle, p.111 Moving Raindrops, p. 117 Sun, Rain, Hurricane, What Makes Weather? (see page 97F TE for additional options) Sun, Rain, Hurricane, What Makes Weather? (see page 97F TE for additional options) Volume 1 Wet Jeans, p. 155 Bill Nye: Water Cycle The Water Cycle Water’s Cycle I Can Read the Sky! and When the Wind Blows, p. 13 How Can We Observe Weather Patterns?, p. 15 Find the Freezing Point, p. 17 How Do We Measure Weather? How Do Weather Patterns Help Us Predict Weather? How Can We Observe Weather Patterns? pp. 198–215 Earth Science Precipitation, p. 135 Temperature Tally, p. 201 Decimal Downpour, p. 137 Highs & Lows, p. 209 Station Model, p. 181 Wind Ways, p. 219 Precipitation Forecasting, p. 338 What Factors Affect Climate? pp. 216–217 Earth Science The Great-Moderator, p. 285 Elevated Differences, p. 293 Heating of Land & Water, p. 283 Eyewitness: Weather Real World Science: Weather and Climate Bill Nye: Climates Climates and Seasons Water Cycle Water Cycle in a Bag The Hydrologic Cycle Water Cycle Game The Water Cycle - Back and Forth The Water Cycle -Back and Forth (Part 2) Why Does Rain Fall? Changes to Land Looking at Weathering and Erosion An Everglades Visit Anita: Balance Climate Earth Systems & Patterns: SC.5.E.7.1 Earth Systems & Patterns: SC.5.E.7.3 Happy Scientist: Model of the Water Cycle Happy Scientist: Water Cycle Scholastic Study Jams: The Water Cycle Brain Pop: Water Cycle Mr. Parr’s Science Song: Water Cycle Happy Scientist: Measuring Lightning Happy Scientist: Building Rain Gauge Happy Scientist: Building Rain Gauge Part 2 Scholastic Study Jams: Clouds & Precipitation Scholastic Study Jams: Weather Instruments Scholastic Study Jams: Air Pressure & Wind Mr. Parr’s Science Song: Weather Instruments Mr. Parr’s Science Song: (Storm) Clouds Hazardous Weather: A Florida Guide Volusia County Schools Elementary Science Department Brain Pop: Clouds Scholastic Study Jams: Weather & Climate Brain Pop: Climate Types Grade 5 Science Curriculum Map October 2016 NGSSS BODY OF KNOWLEDGE: NATURE OF SCIENCE/PHYSICAL SCIENCE Unit of Study: Matter PACING: Weeks 13 – 17 November 7 – December 9 Kindergarten – SC.K.P.8.1, SC.K.P.9.1 First Grade – SC.1.P.8.1, SC.1.E.5.3 Second Grade – SC.2.P.8.1, SC.2.P.8.2, SC.2.P.8.3, SC.2.P.8.4, SC.2.P.8.6, SC.2.P.9.1 Third Grade – SC.3.P.8.1, SC.3.P.8.2, SC.3.P.8.3, SC.3.P.9.1 Fourth Grade – SC.4.P.8.1, SC.4.P.9.1 Prerequisite Learning Topics Learning Targets/Skills Weeks 13-14 Properties of Matter Benchmarks Compare and contrast the basic properties of solids, liquids, and gases, such as mass, volume, color, texture, and temperature. SC.5.P.8.1 Students will: • review by describing and classifying a material as a solid, liquid, or gas. • review how to use the water displacement method to find the volume of regular- and irregular-shaped solids. • justify the reasoning for the classification of materials based on shape, mass (weight) and volume (water displacement). • recognize that physical properties include both observable and measurable properties. • compare and contrast the observable properties of solids, liquids, and gases (e.g., shape, color, hardness, texture, taste, attraction to magnets). • compare and contrast the measurable properties of solids, liquids, and gases (e.g., mass, volume, temperature). Embedded Nature of Science SC.5.N.1.1 SC.5.N.1.5 SC.5.N.1.6 SC.5.N.2.1 SC.5.N.2.2 Vocabulary attract/repel classification displace gas liquid magnetic mass physical properties o observable o measurable states of matter Also assesses SC.3.P.8.1/8.2/8.3 SC.4.P.8.1 o solid o liquid o gas temperature volume water displacement Teacher Hints for “Properties of Matter”: • A solid has a definite shape but a collection of solids may take the shape of the container that holds them and will also pour, a property we often associate with liquids (sand, rice, sugar, salt). • Check for student understanding of measurable physical properties: time (min. and sec.), linear (cm, m, km), mass (mg, g, kg), volume (mL, L), and temperature (ºC, ºF). Use the listing of scientific tools from Weeks 2-4 to identify the physical properties of matter. Students need exposure to dual thermometers, which show ˚C and ˚F on the same thermometer. They will not convert temperature from Celsius to Fahrenheit and vice versa. • The water displacement method is a technique used to measure the volume of an object by calculating how much water it displaces, or pushes aside when placed into a sample of water. To determine the volume of an object, subtract the final water level from the starting water level. SC.5.P.9.1 chemical change Investigate and describe that many physical and chemical changes are affected by temperature. condense Students will: decay • review the causes for the weathering of rocks (ice wedging, precipitation and flowing water, Weeks 15-16 evaporate Embedded abrasion of particles carried by the wind, plant roots, temperature change) freeze Nature of Science SC.5.N.1.1 melt • review the causes for the erosion of rocks (gravity, ice/glaciers, flowing water, wind). Changes in SC.5.N.1.4 physical change • review by describing visible signs of a chemical change that may occur (odor, color change, SC.5.N.1.5 Matter physical weathering temperature change, gas production/fizzing sound). SC.5.N.1.6 temperature change Teacher Hints for this topic are on the next page. 26 • • • review by comparing the similarities and differences of physical and chemical changes. investigate and describe that many physical changes to solids and liquids are affected by temperature change (e.g., melting, freezing, evaporating, condensing, dissolving). investigate and describe how temperature can cause a chemical change that results in the formation of a new material with different characteristics (e.g., baking, grilling, frying, toasting, decaying plant and animal matter, rusting, releasing of carbon dioxide). Volusia County Schools Elementary Science Department SC.5.N.2.1 SC.5.N.2.2 Also assesses SC.3.P.9.1 SC.4.P.9.1 Grade 5 Science Curriculum Map October 2016 Teacher Hints for “Changes in Matter”: • Check out Changing States (http://www.bbc.co.uk/schools/scienceclips/ages/9_10/changing_state.shtml) for support of ways objects undergo change. • Evidence of a chemical change may include a color change, a gas or solid formation, new odor presence, temperature change, and different characteristics in the material. • Please note that evidence of a color change does not always indicate that a chemical change has occurred. For example, the addition of food coloring to water change the water color but is only a physical change. A new substance does not form. SC.5.P.8.3 dissolve Demonstrate and explain that mixtures of solids can be separated based on observable properties of their parts filter/filtration such as particle size, shape, color, and magnetic attraction. magnetic attraction SC.5.P.8.2 Investigate and identify materials that will dissolve in water and those that will not and identify the conditions mixture that will speed up or slow down the dissolving process. particle size Embedded retain properties Students will: Nature of Science Week 17 sieve SC.5.N.1.1 • demonstrate and explain how mixtures of solids can be separated based on observable sort SC.5.N.1.4 properties of their parts (e.g., particle size, shape, color, magnetic attraction) through surface area SC.5.N.1.5 Mixtures • • • sorting, screening-sieve, filtration, magnets, and evaporation. investigate common household materials (liquids or solids) that will dissolve in water (e.g., salt, sugar, drink mixes) and those that will not (e.g., rice, beans, cooking oil, lard). recognize that not all parts of a mixture will dissolve. investigate the conditions (temperature, stirring/shaking, surface area) that will speed up or slow down the dissolving process and/or chemical reactions (e.g., heat speeds up reactions and the dissolving process). SC.5.N.1.6 SC.5.N.2.1 SC.5.N.2.2 Teacher Hints for “Mixtures”: • Be sure to include materials that are magnetic in mixtures that are being separated (e.g., iron filings, paper clips, staples, screws, nails). • Providing experiences with dissolving solids in liquids (e.g., salt and water, sand and water) and liquids in liquids (e.g., oil and water, food coloring and water). • Ask students to record physical properties of 3-4 substances before combining to make a mixture. Discuss whether each substance retain its physical properties or not. • Provide students an experience to separate a mixture that includes solids and liquids that do and don’t dissolve (e.g., water, salt, sand, iron filings, and gravel). • Warmer temperatures, vigorous stirring/shaking, and a greater amount of surface area exposed will speed up the rate at which a substance will both dissolve and react (e.g., Alka-Seltzer will dissolve faster when placed in warm water, stirred, and/or broken/crushed into smaller pieces). • Liquids that will not dissolve in water include, but are not limited to, cooking oil, mineral oil, baby oil. • Solids that will not dissolve in water include, but are not limited to, sand, pepper, flour, corn starch, baby powder, marbles. • The term solutions is no longer assessed. Refer to these special mixtures as mixtures that dissolve. Students will not have to differentiate between a mixture and a solution. SC.5.P.8.4 atoms Explore the scientific theory of atoms (also called atomic theory) by recognizing that all matter is composed of parts that are too small to be seen without. Students will: • define atoms as the building blocks of matter. • recognize that all matter is composed of parts that are too small to be seen with ordinary microscopes. Enrichment Teacher Hints for “Enrichment”: • Students will not be assessed on Enrichment benchmarks. In regards to this content, students will no longer be assessed on atoms or the atomic theory. Teachers may instruct this content post-SSA and in preparation for middle school. 27 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Resource Alignment Weeks 13-14 Properties of Matter HMH Teacher’s Edition HMH Leveled Readers HMH Inquiry Flipchart/Labs HMH Think Central ScienceSaurus AIMS Science (Florida-specific) Canvas Safari Montage pp. 179A-194 pp. 195A-210A It Is Good to Know About Matter (pp. 2-7) (see p. 163F TE for additional options) Making Measurements and Get Detailed, p. 6 It Is Good to Know About Matter (see p. 163F TE for additional options) Student Guide pp. 8-9 and pp. 14-15 Observe Some Chemical Changes and Shhhh! Secret Messages, p. 18 How Can Temperature Change Matter?, p. 19 How Does Matter Change? How Can Temperature Change Matter? pp. 260–267 Physical Science Solids, Liquids, and Gases, Oh Why?, p. 37 Mixed Reactions, p. 85 Change Matters, p. 181 Volume 1: Volume 2: Is It Melting?, p. 73 What’s In the Bubbles?, Beach Sand, p. 163 pp. 65-70 Mountain Age, p. 169 It Is Good to Know About Matter (pp. 10-13) (see p. 163F TE for additional options) What Are Solids, Liquids, and Gases? pp. 242–247 Physical Science Oh Dear What Can This Matter Be?, p. 27 Volume 2: Comparing Cubes, p. 19 Web Resources 28 An Inky Mixture and Does It Dissolve, p. 20 What Affects the Speed of Dissolving?,p. 21 What Are Mixtures and Solutions? What Affects the Speed of Dissolving? pp. 256-259 Physical Science Does It Dissolve?, p. 99 A Sorted Mixture, p. 143 Measurement Stations Slime Experiment Properties of Matter Bill Nye: Phases of Matter Changes In Properties of Matter Changes In States of Matter Bill Nye: Chemical Reactions Elements, Compounds, & Mixtures: Ch. 4 Elements, Compounds, & Mixtures: Ch. 5 Elements, Compounds, & Mixtures: Ch. 6 3 Methods for Measuring Volume Properties of Matter Rava’s Florida Fusion Catering Change Matters: Physical & Chemical Changes Inventions & Innovations MEA Shady Day MEA Cooking In the Chemical Kitchen Physical Properties of Solids What It’s Made of: Solute or Mixture To Dissolve or Not To Dissolve (Part I) To Dissolve or Not To Dissolve (Part II) Solve The Dissolving Problem Kelly’s Café: Mixing it Up!! Salt: Up Close And Personal Properties of Matter: SC.5.P.8.1 Properties of Matter: SC.5.P.8.3 Changes in Matter: SC.5.P.9.1 Happy Scientist: Matter Happy Scientist: Mass and Weight Happy Scientist: Egg States Scholastic Study Jams: Properties of Matter Scholastic Study Jams: Solids, Liquids, & Gases BrainPop: Measuring Matter Brain Pop: States of Matter Mr. Parr’s Science Song: 4 States of Matter Happy Scientist: Dry Ice Happy Scientist: A Watched Pot Scholastic Study Jams: Physical & Chemical Changes of Matter Scholastic Study Jams: Energy & Matter Brain Pop: Property Changes Brain Pop: Matter Changing States Happy Scientist: Sorting Salt and Pepper Happy Scientist: Iron Cereal Scholastic Study Jams: Mixtures Brain Pop: Compounds and Mixtures Mr. Parr’s Science Song: Mixtures Separating CPALMS Florida Achieves FOCUS Week 17 Mixtures pp. 163A-178 Volume 1: Ice Cubes in a Bag, p. 49 Lemonade, p. 55 Is It Matter?, p. 79 Formative Assessment Probes (Page Keeley) Weeks 15-16 Changes in Matter Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 NGSSS BODY OF KNOWLEDGE: NATURE OF SCIENCE/PHYSICAL SCIENCE Unit of Study: Energy & Motion PACING: Weeks 18 – 25 December 12 – February 5 Kindergarten – SC.K.P.10.1, SC.K.P.12.1, SC.K.P.13.1, SC.K.E.5.1 First Grade – SC.1.P.12.1, SC.1.P.13.1, SC.1.E.5.2 Second Grade – SC.2.P.10.1, SC.2.P.13.1, SC.2.P.13.2, SC.2.P.13.3, SC.2.P.13.4 Third Grade – SC.3.P.10.1, SC.3.P.10.2, SC.3.P.10.3, SC.3.P.10.4, SC.3.P.11.1, SC.3.P.11.2, SC.3.E.5.4, SC.3.E.6.1 Fourth Grade – SC.4.P.8.4, SC.4.P.10.1, SC.4.P.10.2, SC.4.P.10.3, SC.4.P.10.4, SC.4.P.11.1, SC.4.P.11.2, SC.4.P.12.1, SC.4.P.12.2 Prerequisite Learning Topics Learning Targets/Skills Benchmarks Investigate and describe some basic forms of energy, including light, heat, sound, electrical, chemical, and mechanical. Students will: • investigate and describe some basic forms of energy, including light, heat (thermal), sound, electrical, chemical, and mechanical (energy of motion). o o o o Weeks 18-19 o o o o Energy o review how light travels in a straight line until it strikes an object (opaque, translucent, transparent) and then is reflected/bounced, bent, or absorbed. review that things that give off light often also give off heat. review that heat is produced when one object rubs against another (friction). review that sound is produced by vibrations and that pitch depends on how fast or slow an object vibrates. review that heat flows from a hot object to a cold object. review common materials that conduct heat well or poorly. review that mechanical energy is stored at a position or released in motion. explain that electrical energy is the flow of a charge/current through a material. explain that chemical energy is stored or released in a chemical reaction (e.g., a source is from the foods animals eat). SC.5.P.10.1 Embedded Nature of Science SC.5.N.1.1 SC.5.N.1.4 SC.5.N.2.1 SC.5.N.2.2 Also assesses SC.3.P.10.1/10.3/10.4 SC.3.P.11.1/11.2 SC.4.P.10.1/10.3 SC.5.P.10.2 Investigate and explain that energy has the ability to cause motion or create change. Students will: • identify and describe examples where energy has caused motion and/or created change (e.g., twirling pinwheel, boiling water, cooking food, turning on a lamp, freezing water, melting chocolate, plant/animal decay, vibration of a radio speaker). • explain the relationship between energy, motion, and change. Embedded Nature of Science SC.5.N.1.1 SC.5.N.2.1 SC.5.N.2.2 Also assesses SC.3.P.10.2 SC.4.P.10.2/10.4 Vocabulary absorb bend change conduct/conductor energy o o o o o o chemical electrical heat (thermal) light mechanical sound friction heat flow heat gain heat loss insulator (poor conductor) motion opaque pitch reflect sound translucent transparent vibration Teacher Hints for “Energy”: • Energy has the ability to cause motion or create change. • Plants use energy from the sun to make their own food. Animals consume plants as food for their energy. Food (from plants and animals) is then transformed to chemical energy in the animal’s body so that it may be used. For example, humans consume food and convert this source into chemical energy. • The terms kinetic and potential energy are no longer taught in elementary. Mechanical energy is the energy of position and motion. • In a complete circuit, there is a power source in which the energy will flows from and back to this source. • A foldable, such as multi-page flipbook, may be a way for students to organize the information of all the different types of energy taught in grades 3, 4, and 5. • Review renewable and nonrenewable energy resources, focusing on resources found in Florida: sun, air/wind, water, phosphate, oil, limestone, silica (sand). • Present a scenario and ask for evidence of change due to some kind of energy being applied (e.g., pushing someone down a slide, a stick moving along with a current). • An object that is put into motion will always change its original position and sometimes its direction. 29 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Weeks 20-21 Investigate and explain that electrical energy can be transformed into heat, light, and sound energy, as well as the energy of motion. SC.5.P.10.4 Investigate and explain that an electrically-charged object can attract an uncharged object and can either attract or repel another charged object without any contact between the objects. SC.5.P.10.3 Students will: • investigate and explain that electrical energy can be transformed into heat, light, sound, and mechanical energy (e.g., lamp, heater, generator, motor, stove, mobile device). • investigate static electricity (a buildup of electrical charges on an object). • explain that opposite electrical charges attract (pull towards each other) and like electrical charges repel (push apart) without any contact needed between the objects. • explain that an electrically-charged object, whether positively or negatively charged, will attract an uncharged (neutral) object. SC.5.P.11.1 Investigate and illustrate the fact that the flow of electricity requires a closed circuit (a complete loop). Electricity Embedded Nature of Science SC.5.N.1.1 SC.5.N.1.4 SC.5.N.1.5 SC.5.N.2.1 SC.5.N.2.2 Students will: • determine the source of energy for a circuit. • investigate and illustrate the fact that the flow of electricity requires a closed circuit (a complete loop) when constructing a simple circuit. • distinguish between open and closed circuits. • determine which circuit from a visual representation can carry electricity to power an object and which circuit cannot. Embedded Nature of Science SC.5.N.1.1 SC.5.N.1.4 SC.5.N.1.5 SC.5.N.2.1 SC.5.N.2.2 attract electric charge o negative o positive o neutral electricity repel static electricity transformation closed circuit conductors electricity insulator (poor conductor) open circuit simple circuit SC.5.P.11.2 Identify and classify materials that conduct electricity and materials that do not. Students will: • identify and classify materials that are good conductors (e.g., copper, water, aluminum foil) and insulators/poor conductors (e.g., plastic, rubber, glass, wood) of electricity. Embedded Nature of Science SC.5.N.1.1 SC.5.N.1.4 SC.5.N.2.1 SC.5.N.2.2 Teacher Hints for “Electricity”: • Electricity learning targets are specific to grade 5. Students should be given hands-on, minds-on experiences in both static and current electricity. • Make learning connections between the similarities of magnetism and static electricity. Neither requires contact for motion or a change in position to occur. Both involve the property of attraction and repulsion. Students just need a conceptual understanding of static electricity, not how matter gains or loses electrons. For example, a conceptual understanding includes knowing the direction of movement caused by a negatively charged balloon being placed near a positively charged balloon. • Students should build complete electrical circuits and then investigate open and closed circuits. • Electrical energy flows from the energy source, such as a battery, to the light source, and then returns to the energy source before flowing to the light source again. • Students should investigate making a circuit with one wire, one bulb, and one battery. • Students learn that electrical energy may transform to light, sound, and/or mechanical energy through experiences with static and current electricity. 30 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Identify familiar forces that cause objects to move, such as pushes or pulls, including gravity acting on falling objects. 05 Science SMT 2 to be administered during Week 22. Weeks 22-24 Students will: • review that gravity is a force that can be overcome. • review examples of magnetic attraction and repulsion. • identify familiar forces (pushes, pulls, friction, gravity, magnetism) that cause or hinder movement of objects. • identify two or more forces acting upon an object in a scenario. • interpret the effect of two or more forces acting upon an object. • recognize that friction is a force that resists movement. Embedded Nature of Science SC.5.N.1.1 SC.5.N.2.1 SC.5.N.2.2 Also assesses SC.3.E.5.4 SC.4.P.8.4 Investigate and describe that the greater the force applied to it, the greater the change in motion of a given object. SC.5.P.13.2 Investigate and explain that when a force is applied to an object but it does not move, it is because another opposing force is being applied by something in the environment so that the forces are balanced. SC.5.P.13.4 Students will: • measure force in Newtons (N) using a spring scale. • demonstrate that a force may change an object’s original position. • investigate that the greater the force applied to an object, the greater the change in motion of a given object. Force and Motion SC.5.P.13.1 o o • Embedded Nature of Science SC.5.N.1.1 SC.5.N.1.4 SC.5.N.1.5 SC.5.N.2.1 SC.5.N.2.2 attract/attraction balanced forces direction distance force friction gravity magnetism motion newton (N) position pull push repel/repulsion speed spring scale unbalanced forces the amount of force applied to an object affects the speed and/or distance at which it moves force affects the direction an object moves investigate and explain the effect balanced and unbalanced forces have on motion. balanced forces are present when an object does not move because opposing forces are holding the object in place (e.g., a book laying on a table is being acted upon by the table pushing up on the book from below and gravity pushing down from above). o unbalanced forces are present when an object does move because one of the opposing forces moves the object from its original position. Investigate and describe that the more mass an object has, the less effect a given force will have on the object’s motion. o OPTIONAL 05 VST 2 available to administer at the end of the Physical Science Unit (Week 24). Students will: • investigate and describe the relationship among mass, force, and motion. o o objects with greater mass require more force to move compared with objects of less mass (and the reverse). more force is required to slow down an object in motion with greater mass compared to an object with less mass (and the reverse). SC.5.P.13.3 Embedded Nature of Science SC.5.N.1.1 SC.5.N.1.4 SC.5.N.1.5 SC.5.N.2.1 SC.5.N.2.2 Teacher Hints for “Force and Motion”: • A force may cause motion and/or a rotation. When an object has moved, it has changed its original position. • When a force is applied to an object but it does not move, it is because another opposing force is being applied by something in the environment. These forces are balanced. A game of tug-of-war illustrates the idea of balanced and unbalanced forces. • Magnets were introduced in grades 2 and 4. Students may need some review in grade 5 predicting the causes and effects of magnet movements. • Students will not need to know specific Newton Laws, but they will need to have a conceptual understanding of force and motion addressed within these laws. • A spring scale measures the force of gravity on an object (its weight). The spring inside stretches according to the object’s weight hanging on the hook of the spring scale. Week 25 STEM Week 31 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Resource Alignment Weeks 18-19 Energy HMH Teacher’s Edition HMH Leveled Readers HMH Inquiry Flipchart/Labs pp. 303A-328 It Takes Energy (see p. 227F TE for additional options) Charge It! How Electricity Works (see p. 227F and 281F TE for additional options) Static Cereal! and A Big Charge!, p. 25 How Do Electric Charges Interact?, p. 26 What Is an Electric Circuit?, p. 28 Compare Two Circuits, p. 29 What Is Electricity? How Do Electric Charges Interact? How Do We Use Electricity? What Is an Electric Circuit? What Are Electric Circuits, Conductors and Insulators? pp. 295-307 Forces at Work (pp. 2 – 9) Motion and Movement (see p. 303F TE for additional options) On A Roll and Make It Easier, p. 30 How Do Forces Affect Motion?, p. 31 What Are Balanced and Unbalanced Forces?, p. 32 Physical Science Static Strokes, p. 251 Sparky’s Light Kit, p. 269 Path Finders, p. 275 Make a Switch, p. 287 Conductor or Insulator?, p. 333 Physical Science Dart Data, p. 351 How Heavy? How Far?, p. 397 Bumper Cars, p. 385 Catapults, p. 409 Blockbuster Forces, p. 421 On Board With Force, p. 429 Tug Teams, p. 451 Seeing Sound Energy and Light Travels. p. 23 What Changes Can Energy Cause?, p. 24 Formative Assessment Probes (Page Keeley) 32 pp. 284–293; 308-333 Physical Science Forms of Energy, p. 191 Hole Cards, p. 193 Tuning Into Sound, p. 207 Mechanical Energy, p. 213 Ball on a Roll, p. 215 Rubber Band Shoot, p. 221 Week 25 What are Forces? How Do Forces Affect Motion? What Are Balanced and Unbalanced Forces? pp. 270-279 Volume 1: Can It Reflect Light?, p. 25 Making Sound, p. 43 The Mitten Problem, p. 103 Objects and Temperature, p. 109 Volume 2: Ice-Cold Lemonade, p. 77 Mixing Water, p. 83 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 STEM Week pp. 247A-276; 281A-300 HMH Think Central AIMS Science (Florida-specific) Weeks 22-24 Force and Motion pp. 227A-246A What Is Energy? What Changes Can Energy Cause? ScienceSaurus Weeks 20-21 Electricity Resource Alignment Weeks 18-19 Energy Weeks 20-21 Electricity Weeks 22-24 Force and Motion Week 25 Electricity Lab Canvas Safari Montage CPALMS Web Resources 33 Electricity Bill Nye: Electrical Currents The Magic School Bus: Gets Charged Forces Bill Nye: Motion Forces and Movement Transformation of Electrical Energy Enlightening Explorations Part I Electricity AND Energy The Shocking Truth About Circuits: An Engineering Design Challenge Let There Be Light! Let It Flow Making Connections! How Does Electricity Flow? Forms of Energy: SC.5.P.10.1 Forms of Energy: SC.5.P.10.2 Forms of Energy: SC.5.P.10.4 Happy Scientist: Solar Power Happy Scientist: Taking a Marshmallow Apart Scholastic Study Jams: Heat Scholastic Study Jams: Light Scholastic Study Jams: Sound Scholastic Study Jams: Light Absorption, Reflection, & Refraction Brain Pop: Forms of Energy Brain Pop: Heat Brain Pop: Light Brain Pop: Sound Happy Scientist: Simple Circuit Happy Scientist: Bird on a Wire Scholastic Study Jams: Electricity Scholastic Study Jams: Current Electricity & Electric Currents Brain Pop: Current Electricity Brain Pop: Electricity Brain Pop: Electric Circuits Happy Scientist: The Old Tablecloth Trick Pendulum Inquiry Magnets 1: Magnetic Pick Ups Blast Off: An Engineering Design Challenge Forces XTreme Rollercoasters Newton’s First Law of Motion (Part II) Wondrous Water Parks Sunshine Beach Hotel MEA Newton’s First Law of Motion (Part III) Lunar Landers: Exploring Gravity Newton’s Third Law of Motion Forces and Changes in Motion: SC.5.P.13.1 Forces and Changes in Motion: SC.5.P.13.2 Happy Scientist: High Bounce Scholastic Study Jams: Force & Motion Scholastic Study Jams: Gravity & Inertia Brain Pop: Force Brain Pop: Acceleration Mr. Parr’s Science Song: Motion Song Mr. Parr’s Science Song: Newton’s Laws of Motion Mr. Parr's Science Song: Friction Mr. Parr’s Science Song: Weight, Mass, and Gravity Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 STEM Week Florida Achieves FOCUS Sound Bill Nye: Heat The Science of Disney Imagineering: Energy Transformation of Energy: Constructing an Electromagnet Shady Day MEA Sammy’s Solar Fountains Exploring the Six Forms of Energy Solar Energy QR Hunt Enlightening Explorations, Part 1 The Shocking Truth About Circuits: An Engineering Design Challenge Soccer Team Uniform Decision NGSSS BODY OF KNOWLEDGE: NATURE OF SCIENCE/LIFE SCIENCE Unit of Study: Life PACING: Weeks 26 – 29 February 13 – March 9 Kindergarten – SC.K.L.14.1, SC.K.L.14.3 First Grade – SC.K.L.14.3, SC.1.L.16.1 Second Grade – SC.2.L.14.1, SC.2.L.17.1, SC.2.L.17.2 Third Grade – SC.3.L.15.1, SC.3.L.15.2, SC.3.L.17.1 Fourth Grade – SC.4.L.16.2, SC.4.L.16.3, SC.4.L.17.1, SC.4.L.17.4 Prerequisite Learning Topics Week 26-27 Human Body Organs and Functions Learning Targets/Skills Benchmarks Identify the organs in the human body and describe their functions, including the skin, brain, heart, lungs, stomach, liver, intestines, pancreas, muscles and skeleton, reproductive organs, kidneys, bladder, and sensory organs. SC.5.L.14.1 Students will: • identify the organs in the human body: brain, heart, lungs, stomach, liver, small intestine, large intestine, pancreas, muscles, skeleton, kidneys, bladder, and reproductive organs (ovaries, testes), sensory organs (eyes, ears, nose, tongue, and skin). • describe the function(s) of the body parts mentioned above (e.g., stomach breaks down food into nutrients, pancreas produces chemicals that aid in digestion, liver cleans blood by removing toxins). Vocabulary human body organs brain heart lungs stomach liver small intestine large intestine pancreas muscles skeleton (internal) kidneys bladder reproductive organs ovaries testes o sensory organs eyes ears nose tongue skin o o o o o o o o o o o o o Teacher Hints for “Human Body Organs and Functions”: • Diagrams of the reproductive organs will not be used on the SSA or the district assessment. Teachers are instructed to refrain from using the rubber band books in the AIMS Life Book entitled, the Male Reproductive System and the Female Reproductive System. • Students will NOT need to match body structures with the body system to which it belongs, but they will need to identify the structure and their function(s) for the following individual organs: brain, lungs, stomach, liver, large intestine, small intestine, pancreas, muscle, skeleton, testes, ovaries, kidneys, bladder, and sensory organs. • Students do NOT need to know the names of the bones or muscles, but will need to know the function(s) of the skeleton and muscles. • Items will not require specific knowledge of the parts of organs although instruction of these parts may lead to a more complete understanding of each organ. 34 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Compare and contrast the function of organs and other physical structures of plants and animals, including humans, for example: some animals have skeletons for support – some with internal skeletons other with exoskeletons – while some plants have stems for support. SC.5.L.14.2 Students will: • review plant structures and their functions. Also assesses SC.3.L.15.1 SC.3.L.15.2 o o o o o Week 28 Structure/ Function Comparison • review animal classification and attributes for each group. o o • • flower/ fruit – reproduction seed/spore - reproduction leaf/needle – food production stem –supports the plant, transports water and nutrients root – supports the plant, absorbs water and nutrients exoskeleton food production invertebrates ovary/egg pistil pollen/sperm reproduction stamen vertebrates vertebrates – mammals, birds, reptiles, amphibians, and reptiles invertebrates – include arthropods (segmented bodies, jointed legs, covering/exoskeleton) hard outer differentiate the function(s) of organs in animals (e.g., exoskeleton vs. internal skeleton, lungs vs. gills, nose vs. antenna, skin vs. scales). compare structure/function of plants and animals that serve similar roles limited to the following: skin to plant covering, skeleton to stem, reproductive organs to a flower (pistil, ovary, eggs, pollen/sperm, stamen). Teacher Hints for “Structure/Function Comparison”: • Make a comparison between animal and plant sexual reproduction structure/function: o o • • plant female structures of pistil, ovary, eggs with human structures of ovary and eggs plant male structures of pollen/sperm, stamen with human structures of testes and sperm Florida Achieves FOCUS Org/Dev of Living Organisms SC.5.L.14.2: First and Second Assessments will guide you in how structure/function comparison content may translate to assessment item stems. Reviewing plant and animal structure/function, plant behaviors, animal classification, and food chains will assist students with the benchmark targets in this unit. ScienceSaurus pages 76-97, 107, 126-131, and 133-155 may serve as a reference. 35 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Week 29 Adaptations OPTIONAL 05 VST 3 available to administer at the end of the Life Science Unit (Week 29) Compare and contrast adaptations displayed by animals and plants that enable them to survive in different environments such as life cycles variations, animal behaviors and physical characteristics. SC.5.L.17.1 Describe how, when the environment changes, differences between individuals allow some plants and animals to survive and reproduce while others die or move to new locations. SC.5.L.15.1 Students will: • review food chains (e.g., sun grass rabbit fox). • review the classification of consumers as herbivores, carnivores, or omnivores. • distinguish between physical and behavioral adaptations displayed by animals and plants. • explain how adaptations displayed by plants and animals enable them to survive in different environments. Embedded Nature of Science SC.5.N.2.1 o o o • • • physical characteristics (e.g., body/stem covering, body fat, leaf shape, body shape, teeth, claws, acute eyesight/hearing). behaviors (e.g., dormancy, root growth, color change, climb, hide) life cycles variations (e.g., complete and incomplete metamorphosis, seasonal dormancy, a seed’s germination following extreme environmental conditions) Also assesses SC.3.L.17.1 SC.4.L.16.2/16.3 SC.4.L.17.1/17.4 adaptation o physical o behavioral camouflage carnivore competition consumer environment food chain herbivore hibernation migration omnivore population predator prey producer resources identify ways an environment changes (e.g., disease, fire, drought, pollution, human intervention, climate, increased predators, increased competition for food). describe structures and behaviors that plants and animals use in a changing environment. explain that physical and behavioral adaptations of plants and animals are used in changing environments to enable some plants and animals to survive and reproduce while others die or move to new locations. Teacher Hints for “Adaptations”: • Physical adaptations are those structures/features physically on plants and animals that allow them to survive and reproduce within their environment. Examples of these adaptations include waxy coating on cacti that allow them to retain water and wide feet on some desert animals that prevent them from sinking into the sand. • Behavioral adaptations are those behaviors exhibited by plants and animals that allow them to survive and reproduce within their environment. Examples of these adaptations include plants growing their roots deeper into the soil in search of water during drought conditions and lizards purposefully breaking off their tails in order to escape their predators. • Living things go through stages of growth and development called a life cycle. Students have learned in previous grade levels about life cycles. Review animal and plant life cycles, including the two insect life cycles of complete and incomplete metamorphosis. • Florida Achieves FOCUS Interdependence: SC.5.L.17.1 First and Second Assessments will guide you in how content on adaptations may translate to assessment item stems. 36 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Resource Alignment Weeks 28-29 Structure/Function Comparisons Adaptations Week 26-27 Human Body Organs and Functions HMH Teacher’s Edition HMH Leveled Readers HMH Inquiry Flipchart/Labs HMH Think Central ScienceSaurus AIMS Science (Florida-specific) Formative Assessment Probes (Page Keeley) pp. 333A – 386 pp. 391A - 490 Amazing Cells, Amazing Bodies Changes in Ecosystems Plants and How They Grow Heredity Hunting for Beans and Compost in a Bag, p. 37 How Does Drought Affect Plant Growth?, p. 38 Gobbling Up Your Greens and Animal Adaptations, p. 39 Why Do Bird Beaks Differ?, p. 40 Cold as Ice and Putting a Foot Down, p. 41 How Do Environmental Changes Affect Organisms? How Does Drought Affect Plants? What Is Adaptation? Why Do Bird Beaks Differ? What Are Some Adaptations to Life on Land? What Are Some Adaptations to Life in Water? pp. 76–97 Muscle Burnout and Circulate!, p. 35 The Power of Chewing and Planimal, p. 36 What Are Organs and Body Systems? What Body Parts Enable Movement, Support, Respiration, and Circulation? What Body Parts Enable Digestion, Waste Removal, and Reproduction? pp. 104–125 Life Science p. 17–209 (Choose the human structure lessons from AIMS that will complete your unit.) Volume 1 Is It Living?, p. 123 Volume 2 Is It a Plant?, p. 93 Safari Montage 37 Volusia County Schools Elementary Science Department Life Science Planimals, p. 243 Salt Water Survival, p. 259 Life Cycle Adaptations, p. 283 Table Manners, p. 315 Saguaro Study, p. 347 Beat the Heat, p. 357 Environmental Adaptations, p. 370 Volume 1: Is It an Animal?, p. 117 Volume 2: Plants in the Dark and Light, p. 107 Habitat Change, p. 143 Plant and Animal Adaptations All About Plant Pollination: Fruit, Flowers, and Seeds Grade 5 Science Curriculum Map October 2016 Resource Alignment Week 26-27 Human Body Organs and Functions CPALMS Florida Achieves FOCUS Web Resources 38 Weeks 28-29 Structure/Function Comparisons Adaptations Systems of the Human Body Kidney Filtering Walk, Run, Jump Name That Organ! Is My Epidermis Showing? Body Swatter Work That Body – Human Organs MEA Frankenchicken Are We Like Robots? Bird Buffet (Animal Survival) It’s All Happening At the Zoo Cicada Invasion Part 1: Pond Life Exploring Habitats! Exploring Adaptations! Arctic Animals & A Changing Climate What’s New At The Zoo? An Engineering Design Project Panther Protection101 Interplanetary Zoo Preying On Beans Survival of the Fittest Seed Starters I Will Survive! An Engineering Design Project Environmental Differences Sell This Habitat! Animal Tracks Org/Dev of Living Organisms: SC.5.L.14.1 Org/Dev of Living Organisms: SC.5.L.14.2 Interdependence: SC.5.L.17.1 Adaptations PowerPoints Scholastic Study Jams: Animal Adaptations Brain Pop: Behavior Brain Pop: Migration Brain Pop: Hibernation Brain Pop: Camouflage Brain Pop: Food Chains Brain Pop: Metamorphosis Brain Pop: Amphibians Brain Pop: Gills Brain Pop: Vertebrates Mr. Parr’s Science Song: Food Chain Song Mr. Parr’s Science Song: Energy Roles Mr. Parr’s Science Song: It Starts With Producers Mr. Parr’s Science Song: Life Cycles Mr. Parr’s Science Song: Adaptations Life Size Body and Organs Activity Happy Scientist: Reading a Skeleton Scholastic Study Jams: The Human Body Scholastic Study Jams: Skeletal System Scholastic Study Jams: The Circulatory System Scholastic Study Jams: Respiratory System Scholastic Study Jams: The Nervous System Scholastic Study Jams: Muscular System Scholastic Study Jams: The Immune System Scholastic Study Jams: The Digestive System Brain Pop: Brain Brain Pop: Heart Brain Pop: Skin Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 NGSSS BODY OF KNOWLEDGE: NATURE OF SCIENCE Unit of Study: Practice of Science PACING: Weeks 30 – 39 March 20 – May 26 Kindergarten – SC.K.N.1.1, SC.K.N.1.2, SC.K.N.1.3, SC.K.N.1.4, SC.K.N.1.5 First Grade – SC.1.N.1.1, SC.1.N.1.2, SC.1.N.1.3, SC.1.N.1.4, SC.1.E.5.3 Second Grade – SC.2.N.1.1, SC.2.N.1.2, SC.2.N.1.3, SC.2.N.1.4, SC.2.N.1.5, SC.2.N.1.6 Third Grade – SC.3.N.1.1, SC.3.N.1.2, SC.3.N.1.3, SC.3.N.1.4, SC.3.N.1.5, SC.3.N.1.6, SC.3.N.1.7 Fourth Grade – SC.4.N.1.1, SC.4.N.1.2, SC.4.N.1.3, SC.4.N.1.4, SC.4.N.1.5, SC.4.N.1.6, SC.4.N.1.7, SC.4.N.1.8, SC.4.N.2.1, SC.4.E.6.5 Prerequisite Learning Topics Learning Targets/Skills Benchmarks Return to page 18 to access the Practice of Science Resource Alignment suggestions that were not used during the Introduction to Practice of Science at the start of the school year. Week 30 Science Recognize and explain that science is grounded in empirical observations that are testable; explanation must always be linked with evidence. SC.5.N.2.1 Recognize and explain the difference between personal opinion/interpretation and verified observation. SC.5.N.1.6 Students will: • explain that science is grounded on evidence-based observations that are testable. • review the difference between verified observations (evidence) and inferences (explanations linked to evidence). • explain the difference between verified observation (fact) and personal opinion/ interpretation (bias). Also assesses SC.3.N.1.7 SC.4.N.1.7 o o • distinguish between examples of empirical evidence (observations) and personal opinion/interpretation (a viewpoint based on one’s own judgment of the facts; a bias). Students will: • generate testable questions that will generate observable and measurable data. • formulate a testable hypothesis based on information gathered from research. • design a scientific investigation individually or in teams through a variety of methods • use scientific tools during investigations to observe and measure physical properties. • explain that all conditions in an experiment outside the manipulated variable must be controlled or kept the same (ensure that the results of an experiment can be explained ONLY by the variable being tested and not by some other factor). • evaluate another’s written procedure or experimental setup. • collect and record observable and measureable data in science notebooks. • organize data in appropriate forms of record keeping (e.g., charts, tables, graphs). • interpret and analyze data that has been collected. • generate appropriate explanations based on evidence gathered (e.g., “My hypothesis was/was not supported by the evidence because…”). • apply explanations to real world connections (application). Science Process This topic is continued on the next page. 39 evidence explanations inference verified observation personal opinion/ interpretation science verified observation – an objective statement of which has been tested and supported by observable and/or measurable evidence/facts (data) personal opinion/interpretation – a subjective statement of a thought that may be based on logic and reason but is not necessarily based on testable evidence/facts. Define a problem, use appropriate reference materials to support scientific understanding, plan and carry out scientific investigations of various types such as: systematic observations, experiments requiring the identifications of variables, collecting and organizing data, interpreting data in charts, tables, and graphics, analyze information, make predictions, and defend conclusions. Weeks 31-33 Vocabulary Volusia County Schools Elementary Science Department SC.5.N.1.1 Also assesses SC.3.N.1.1 SC.4.N.1.1/1.6 communicate data (evidence) experimental design/ experimental setup hypothesis investigation prediction problem (question) procedures record keeping research scientific tools variable Grade 5 Science Curriculum Map October 2016 SC.5.N.1.4 control group experiment experimental group Explain the difference between an experiment and other types of scientific investigation. SC.5.N.1.2 Recognize and explain that authentic scientific investigation frequently does not parallel the steps of “the scientific method”. SC.5.N.1.5 exploration research scientific method systematic observations types of scientific investigations Identify a control group and explain its importance in an experiment. Students will: • identify the control group in an experiment (a test group where the variable is NOT applied; considered to be the “normal condition” within the context of an experiment). • explain the importance of a control group (to yield baseline data by which all other data will be compared). Weeks 31-33 Students will: • explain that an authentic scientific investigation frequently does not parallel the steps of “the scientific method”. • explain the difference between an experimental investigation and other types of scientific investigation. Science Process OPTIONAL 05 VST 4 available to administer at the end of the Nature of Science Unit (Week 33) Also assesses SC.4.N.1.3 o experimental investigation – used when one variable is defined/known and a test is done o descriptive investigation – used to observe, describe, or identify o comparative investigation – used to compare, differentiate, or classify Recognize and explain that when scientific investigations are carried out, the evidence produced by those investigations should be replicable by others. SC.5.N.2.2 SC.5.N.1.3 Recognize and explain the need for repeated experimental trials. Students will: • recognize that the results of experimental trials can vary even when common tools and procedures are used. • discuss the reason for differences that may occur in data across groups as a result of using different tools and/or procedures. • explain the need for repeated experimental trials or large experimental groups (to ensure the results are accurate, reliable, and valid). • explain what is needed in order to repeat and replicate a scientific investigation (documented scientific procedures). • recognize that when an experiment is replicated, it should produce similar results. • distinguish the difference between repetition and replication. Also assesses SC.3.N.1.2/1.5 SC.4.N.1.2/1.5 o comparative o descriptive o experimental accurate experimental groups reliable repeated observation repeated trials repetition/repeated replication/replicable results valid “Fair Game” Assist and “Finishing Touches” for SSA Weeks 34-35 Utilize progress monitoring data and information on pp. 13-14 to identify “fair game” content review necessary for final SSA preparation. Week 36 Administration of STATEWIDE SCIENCE ASSESSMENT Weeks 37-39 STEM Week 40 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Formative Assessment Strategies Science K-5 Adapted from Page Keeley’s Science Formative Assessment: 75 Practical Strategies for Linking Assessment, Instruction, and Learning Strategy Name Description A & D Statements Agreement Circles A & D Statements analyze a set of “fact or fiction” statements. First, students may choose to agree or disagree with a statement or identify whether they need more information. Students are asked to describe their thinking about why they agree, disagree, or are unsure. In the second part, students describe what they can do to investigate the statement by testing their ideas, researching what is already known, or using other means of inquiry. Agreement Circles provide a kinesthetic way to activate thinking and engage students in scientific argumentation. Students stand in a circle as the teacher reads a statement. While standing, they face their peers and match themselves up in small groups of opposing beliefs. Students discuss and defend their positions. After some students defend their answers, the teacher can ask if others have been swayed. If so, stand up. If not, what are your thoughts? Why did you disagree? After hearing those who disagree, does anyone who has agreed want to change their minds? This should be used when students have had some exposure to the content. Additional Information Statement How can you find out? All magnets have 2 poles. __agree __disagree __it depends __not sure My thoughts: Energy 1. Energy is a material that is stored in an object. 2. When energy changes from one form to another, heat is usually given off. 3. Energy can never be created or destroyed. 4. Something has to move in order to have energy. Annotated Student Drawings are student-made, labeled illustrations that visually represent and describe students’ thinking about scientific concepts. Younger students may verbally describe and name parts of their drawings while the teacher annotates them. Annotated Student Drawings 41 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Strategy Name Card Sorts Chain Notes Commit and Toss Description Additional Information Card Sorts is a sorting activity in which students group a set of cards with pictures or words according to certain characteristics or category. Students sort the cards based on their preexisting ideas about the concepts, objects, or processes on the cards. As students sort the cards, they discuss their reasons for placing each card into a designated group. This activity promotes discussion and active thinking. Chain Notes is a strategy that begins with a question printed at the top of a paper. The paper is then circulated from student to student. Each student responds with one to two sentences related to the question and passes it on to the next student. A student can add a new thought or build on a previous statement. Commit and Toss is a technique used to anonymously and quickly assess student understanding on a topic. Students are given a question. They are asked to answer it and explain their thinking. They write this on a piece of paper. The paper is crumpled into a ball. Once the teacher gives the signal, they toss, pass, or place the ball in a basket. Students take turns reading their "caught" response. Once all ideas have been made public and discussed, engage students in a class discussion to decide which ideas they believe are the most plausible and to provide justification for the thinking. What is Matter? Matter is all around us. Matter makes up everything. Matter has volume and takes up space. You can feel and see matter. Solids and Holes Lance has a thin, solid piece of material. He places it in water. It floats. He takes the material out and punches holes all the way through it. What do you think Lance will observe when he puts the material with holes back in the water? A. B. C. D. It will sink. It will barely float. It will float the same as it did before the holes were punched. It will neither sink nor float. It will bob up and down in the water. Explain your thinking. Describe the reason for the answer you selected. Concept Card Mapping 42 Concept Card Mapping is a variation on concept mapping. Students are given cards with the concepts written on them. They move the cards around and arrange them as a connected web of knowledge. This strategy visually displays relationships between concepts. Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Strategy Name Description Concept Cartoons are cartoon drawings that visually depict children or adults sharing their ideas about common everyday science. Students decide which character in the cartoon they agree with most and why. This formative assessment is designed to engage and motivate students to uncover their own ideas and encourage scientific argumentation. Concept Cartoons are most often used at the beginning of a new concept or skill. These are designed to probe students’ thinking about everyday situations they encounter that involve the use of science. Not all cartoons have one “right answer.” Students should be given ample time for ideas to simmer and stew to increase cognitive engagement. Data Match provides students with a data set from a familiar investigation and several statements about data. Students use evidence from the data to determine which statements are accurate. This strategy provides students with an opportunity to consider what constitutes evidence, practice interpreting data, and consider how confident they are in interpreting results of an inquiry. Concept Cartoons Data Match www.pixton.com Where We Put the Ice Cube How Many Minutes It Took to Melt On the blacktop in the sun 3 On the blacktop in the shade On the grass 7 10 On the metal side 2 On the dirt underneath the slide 5 Which of these statements match your results? The ice cube on the grass took longest to melt. The metal slide was hotter than the dirt underneath the slide. The ice cube melted faster on the blacktop in the sun than on the shaded blacktop. Ice placed on dark things melts faster than ice placed on light things. Ice melts faster on some surfaces than on others. Fact First Questioning 43 Additional Information Fact First Questioning is a higher-order questioning technique used to draw out students’ knowledge. It takes a factual “what” question and turns it into a deeper “how” or “why” question. Teachers state the fact first and then ask students to elaborate, enabling deeper thinking processes that lead to a more enduring understanding of science concepts. Volusia County Schools Elementary Science Department Examples of Fact First Questions Glucose is a form of food for plants. Why is glucose considered a food for plants? A cell is called the basic unit of life. Why is the cell called the basic unit of life? The patterns of stars in the night sky stay the same. Why do the patterns of stars in the night sky stay the same? Sandstone is a sedimentary rock. Why is sandstone considered a sedimentary rock? Grade 5 Science Curriculum Map October 2016 Strategy Name Familiar Phenomenon Probes Description Additional Information Familiar Phenomenon Probes is a strategy involving two-tiered questions consisting of a selected response section and a justification for the selected response. They engage students in thinking about scientific ideas related to the phenomenon and committing to a response that matches their thinking. The distracters (wrong choices) include commonly held misconceptions that children have in science. What’s in the Bubbles? Hannah is boiling water in a glass tea kettle. She notices large bubbles forming on the bottom of the kettle that rise to the top and wonders what is in the bubbles. She asks her family what they think, and this is what they may say: Dad: Calvin: Grandma: Mom: Lucy: They are bubble of heat. The bubbles are filled with air. The bubbles are an invisible form of water. The bubbles are empty. There is nothing inside them. The bubbles contain oxygen and hydrogen that separated from the water. Which person do you most agree with and why? Explain your thinking. First Word-Last Word is a variation of acrostic poetry. Students construct statements about a concept or topic before and after instruction that begins with the designated letter of the alphabet. The acrostic format provides a structure for them to build their idea statements off different letters that make up the topic word. First Word-Photosynthesis Plants make their own food. Happens in cells Other animals eat plants. The roots take up food and water. Oxygen is breathed in through leaves. Sunlight makes food for plants. First Word-Last Word You can’t make your own food. Needs water, sunlight, oxygen, and minerals The leaves, roots, and stems are all parts that make food. Have to have sun and water Energy comes from the sun. Sunlight turns plants green. It happens in all plants. Soil is used by plants to make food. 44 Volusia County Schools Elementary Science Department Last Word-Photosynthesis Producers such as plants use energy from the sun to make their food. Happens in cells that have structures called chloroplasts Organisms that eat plants are using energy from the plant. The roots take water up to the leaves where it reacts with sunlight and carbon dioxide. Oxygen is given off during photosynthesis and is used by plants and animals for respiration. Sunlight provides the energy so plants can make food. You need to have cells with chloroplast and chlorophyll to make food. Needs water, carbon dioxide and sunlight to make food The leaf is the food making part. Have to have sunlight, water, and carbon dioxide Energy comes from sunlight. Sunlight is trapped in the chlorophyll. It is necessary life process for all plants. Soil holds the water for plants and gives some minerals. Grade 5 Science Curriculum Map October 2016 Strategy Name Description Fist to Five asks students to indicate the extent of their understanding of a scientific concept by holding up a closed fist (no understanding), one finger (very little understanding), and a range up to five fingers (understand completely and can easily explain it to someone else). Fist to Five provides a simple feedback opportunity for all students in a class to indicate when they do not understand a concept or skill and need additional support for their learning. Four Corners is a kinesthetic strategy. The four corners of the classroom are labeled: Strongly Agree, Agree, Disagree and Strongly Disagree. Initially, the teacher presents a science statement to students and asks them to go to the corner that best aligns with their thinking. Students then pair up to defend their thinking with evidence. The teacher circulates and records student comments. Next, the teacher facilitates a whole group discussion. Students defend their thinking and listen to others’ thinking before returning to their desks to record their new understanding. Frayer Model is a strategy that graphically organizes prior knowledge about a concept into an operational definition, characteristics, examples, and non-examples. It provides students with the opportunity to clarify what they are thinking about the concept and to communicate their understanding. Fist to Five Four Corners Frayer Model Additional Information I do not understand it. I understand some of it. Friendly Talk Probes 45 Volusia County Schools Elementary Science Department I understand it completely. I understand it and can explain it. Agree Strongly Agree Strongly Disagree Disagree Definition Characteristics Living Things Examples Friendly Talk Probes is a strategy that involves a selected response section followed by justification. The probe is set in a real-life scenario in which friends talk about a science-related concept or phenomenon. Students are asked to pick the person they most agree with and explain why. This can be used to engage students at any point during a unit. It can be used to access prior knowledge before the unit begins, or assess learning throughout and at the close of a unit. I understand most of it. Non-examples Talking about Gravity Two friends are talking about gravity. Ben says, “Gravity needs atmosphere or air. If there is no air or atmosphere, there will be no gravity.” Kelly says, “Gravity doesn’t need an atmosphere or air. If there is no air or atmosphere, there will still be gravity.” Which friend do you agree with?__________ Describe your thinking. Explain why you agree with one friend and disagree with the other. Grade 5 Science Curriculum Map October 2016 Strategy Name Give Me Five Human Scatterplot I Used to Think… But Now I Know… Justified List Description Additional Information Give Me Five is a simple, quick technique for inviting and valuing public reflection and welcoming feedback from the students. Students should be given time to quietly reflect, perhaps through a quick write. Teacher selects five “volunteers” to share their reflection. 1. NOTE: Deliberately select students for the purpose of reinforcing correct understanding and addressing misconceptions. 4. Human Scatterplot is a quick, visual way for teacher and students to get an immediate classroom snapshot of students’ thinking and the level of confidence students have in their ideas. Teachers develop a selective response question with up to four answer choices. Label one side of the room with the answer choices. Label the adjacent wall with a range of low confidence to high confidence. Students read the question and position themselves in the room according to their answer choice and degree of confidence in their answer. I Used to Think…But Now I Know is a self-assessment and reflection exercise that helps students recognize if and how their thinking has changed at the end of a sequence of instruction. An additional column can be added to include…And This Is How I Learned It to help students reflect on what part of their learning experiences helped them change or further develop their ideas. Justified List begins with a statement about an object, process, concept or skill. Examples that fit or do not fit the statement are listed. Students check off the items on the list that fit the statement and provide a justification explaining their rule or reasons for their selections. This can be done individually or in small group. Small groups can share their lists with the whole class for discussion and feedback. Pictures or manipulatives can be used for English-language learners. 2. 3. 5. What was the most significant learning you had during today’s lesson? How “in the zone” do you feel right now as far as understanding the concept? How did today’s lesson help you better understand the concept? What was the high point of this week’s activities on the concept? How well do you think today’s science discussion worked in improving your understanding of the concept? I USED TO THINK… BUT NOW I KNOW… Making Sound All of the objects listed below make sounds. Put an X next to the objects you think involve vibration in producing sound. ____guitar strings ____drum ____piano ____dripping faucet ____flute ____wind ____hammer ____crumpled paper ____thunderstorm ____barking dog ____screeching brakes Explain your thinking. What “rule” or reasoning did you use to decide which objects involve vibration? 46 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Strategy Name K-W-L Variations Learning Goals Inventory (LGI) Look Back Muddiest Point 47 Description K-W-L is a general technique in which students describe what they Know about a topic, what they Want to know about a topic, and what they have Learned about the topic. It provides an opportunity for students to become engaged with a topic, particularly when asked what they want to know. K-W-L provides a self-assessment and reflection at the end, when students are asked to think about what they have learned. The three phrases of K-W-L help students see the connections between what they already know, what they would like to find out, and what they learned as a result. Learning Goals Inventory (LGI) is a set of questions that relate to an identified learning goal in a unit of instruction. Students are asked to “inventory” the learning goal by accessing prior knowledge. This requires them to think about what they already know in relation to the learning goal statement as well as when and how they may have learned about it. The LGI can be given back to students at the end of the instructional unit as a self-assessment and reflection of their learning. Look Back is a recount of what students learned over a given instructional period of time. It provides students with an opportunity to look back and summarize their learning. Asking the students “how they learned it” helps them think about their own learning. The information can be used to differentiate instruction for individual learners, based on their descriptions of what helped them learn. Muddiest Point is a quick-monitoring technique in which students are asked to take a few minutes to jot down what the most difficult or confusing part of a lesson was for them. The information gathered is then to be used for instructional feedback to address student difficulties. Volusia County Schools Elementary Science Department Additional Information K This is what I already KNOW W This is what I WANT to find out L This is what I LEARNED What do you think the learning goal is about? List any concepts or ideas you are familiar with related to this learning goal. List any terminology you know of that relates to this goal. List any experiences you have had that may have helped you learn about the ideas in this learning goal. What I Learned How I Learned it Scenario: Students have been using a hand lens to make observations of the details on a penny. Teacher states, “I want you to think about the muddiest point for you so far when it comes to using a hand lens. Jot it down. I will use the information you give me to think about ways to help you better use the hand lens in tomorrow’s lesson.” Grade 5 Science Curriculum Map October 2016 Strategy Name Odd One Out Paint The Picture Partner Speaks Description Additional Information Odd One Out combines similar items/terminology and challenges students to choose which item/term in the group does not belong. Students are asked to justify their reasoning for selecting the item that does not fit with the others. Odd One Out provides an opportunity for students to access scientific knowledge while analyzing relationships between items in a group. Paint the Picture visually depicts students’ thinking about an idea in science without using any annotations. This involves giving the students a question and asking them to design a visual representation that reveals their thinking and answers the question. Paint the Picture provides an opportunity for students to organize their thinking and represent their thinking in a creative, unique visual format. Partner Speaks provides students with an opportunity to talk through an idea or question with another student before sharing with a larger group. When ideas are shared with the larger group, pairs speak from the perspective of their partner’s ideas. This encourages careful listening and consideration of another’s ideas. Properties of Matter: In each set, circle the Odd One Out and describe why it does not fit with the others. Which Is the Odd One? weight density length color Why Is It the Odd One Out? What role do minerals play in the formation of a rock? minerals rock Today we are going to investigate how objects float and sink in water. - What do you think affects whether an object floats or sinks in water? What can you do to change how an object floats or sinks? Turn to your partner and take turns discussing ideas. Pass the Question A Picture Tells a Thousand Words 48 Pass the Question provides an opportunity for students to collaborate in activating their own ideas and examining other students’ thinking. Students begin by working together in pairs to respond to a question. Time is allotted for partial completion of their responses. When the time is up, they exchange their partially completed response with another pair. Students are provided time to finish, modify, add to, or change it as they deem necessary. Pairs then group to give feedback to each other on the modifications. A Picture Tells a Thousand Words is a technique where students are digitally photographed during an inquiry-based activity or investigation. They are given the photograph and asked to describe and annotate what they were doing and learning in the photo. Images can be used to spark student discussions, explore new directions in inquiry, and probe their thinking as it relates to the moment the photograph was taken. Volusia County Schools Elementary Science Department What are the phases of the moon? Can sound travel through a solid? What is the difference between temperature and humidity? Are science tools helpful? How can you measure matter? Grade 5 Science Curriculum Map October 2016 Strategy Name Description Question Generating Sticky Bars Thinking Logs Question Generating is a technique that switches roles from the teacher as the question generator to the student as the question generator. The ability to formulate good questions about a topic can indicate the extent to which a student understands ideas that underlie the topic. This technique can be used any time during instruction. Students can exchange or answer their own questions, revealing further information about the students’ ideas related to the topic. Additional Information • • • • • • • Sticky Bars is a technique that helps students recognize the range of ideas that students have about a topic. Students are presented with a short answer or multiple-choice question. The answer is anonymously recorded on a Post-it note and given to the teacher. The notes are arranged on the wall or whiteboard as a bar graph representing the different student responses. Students then discuss the data and what they think the class needs to do in order to come to a common understanding. Thinking Logs is a strategy that informs the teacher of the learning successes and challenges of individual students. Students choose the thinking stem that would best describe their thinking at that moment. Provide a few minutes for students to write down their thoughts using the stem. The information can be used to provide interventions for individuals or groups of students as well as match students with peers who may be able to provide learning support. • • • • • • • • • • • Think-Pair-Share Question Generating Stems: Why does___? How does___? What if___? What could be the reason for___? What would happen if___? How does___compare to___? How could we find out if___? I was successful in… I got stuck… I figured out… I got confused when…so I… I think I need to redo… I need to rethink… I first thought…but now I realize… I will understand this better if I… The hardest part of this was… I figured it out because… I really feel good about the way… Think-Pair-Share is a technique that combines thinking with communication. The teacher poses a question and gives individual students time to think about the question. Students then pair up with a partner to discuss their ideas. After pairs discuss, students share their ideas in a small-group or whole-class discussion. (Kagan) NOTE: Varying student pairs ensures diverse peer interactions. 49 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016 Strategy Name Description Traffic Light Cups is a monitoring strategy that can be used at any time during instruction to help teachers gauge student understanding. The colors indicate whether students have full, partial, or minimal understanding. Students are given three different-colored cups, asked to self-assess their understanding about the concept or skill they are learning, and display the cup that best matches their understanding. Two-Minute Paper is a quick way to collect feedback from students about their learning at the end of an activity, field trip, lecture, video, or other type of learning experience. Teacher writes two questions on the board or on a chart to which students respond in two minutes. Responses are analyzed and results are shared with students the following day. Traffic Light Cups Two-Minute Paper Two Stars and a Wish 50 Green Yellow Red • • • • I understand this very well. I understand most of it but could use a little help. Help. I don’t get it. What was the most important thing you learned today? What did you learn today that you didn’t know before? What important question remains unanswered for you? What would help you learn better tomorrow? Two Stars and a Wish is a way to balance positive and corrective feedback. The first sentence describes two positive commendations for the student’s work. The second sentence provides one recommendation for revision. This strategy could be used teacher-tostudent or student-to-student. 3-2-1 is a technique that provides a structured way for students to reflect upon their learning. Students respond in writing to three reflective prompts. This technique allows students to identify and share their successes, challenges, and questions for future learning. Teachers have the flexibility to select reflective prompts that will provide them with the most relevant information for data-driven decision making. 3-2-1 Additional Information Volusia County Schools Elementary Science Department Sample 1 • • • 3 – Three key ideas I will remember 2 – Two things I am still struggling with 1 – One thing that will help me tomorrow Sample 2 Grade 5 Science Curriculum Map October 2016 DIGITAL PROGRAM ACCESS INFORMATION The Elementary Science Department highly recommends the use of the following digital resources for purposes of planning, delivery of instruction, formative and summative assessment, and/or professional development. Access information and a brief description of each are provided. Science Fusion Think Central Username/Login: district email address Password: Pa$5word Access the HMH Think Central tile through V-Portal. Science Fusion Think Central platform provides teachers with digital access to the district-adopted textbook resource. It contains digital lessons and labs that parallel the hard copy materials providing students with multiple exposures to the context of science content. A wealth of additional instructional resources organized by grade, unit, and lesson are available for easy teacher access. If you need access assistance, contact Felecia Martinez (Extension 20686) If you need technical assistance, call 800-323-9239. The Happy Scientist (www.thehappyscientist.com) Contact your Elementary Curriculum Cadre Science Leader for assistance with access information (username and password). The Happy Scientist website is a rich collection of videos, photographs, experiments, questions of the day, blogs, and SO much more. The content is aligned to the NGSSS for science and is easy to navigate. If you need assistance with science experiments and videos, email [email protected]. If you need assistance with the website, email [email protected]. CPALMS (www.cpalms.org) iCPALMS (www.cpalms.org) Florida Students (www.floridastudents.org) CPALMS is an online toolbox of information, vetted resources, and interactive tools that helps educators effectively implement teaching standards. It is the State of Florida’s official source for standards information and course descriptions. Florida Students is your source for Florida Standards Student Tutorials and Resources. ICPALMS is a powerful portal linking teachers across the state to online tools for planning and implementing instruction. Based on adopted standards governing what students must learn, these tools will, in turn, connect educators with thousands of existing resources for teaching science, making this an innovative system like no other. For user support by phone, call 855-826-8236. 51 Volusia County Schools Elementary Science Department This site is new to CPALMS and full of resources located from all over the web to support learning in language arts, mathematics, SCIENCE, and civics. Be on the lookout for new Florida tutorials designed for Florida educators. Grade 5 Science Curriculum Map October 2016 Read Works http://www.readworks.org Science Topics to Explore: Each topic is 1 to 2 pages long and includes text-based questions for students to answer. Remember that you need to register and receive a password to get into Read Works. It’s quick and FREE! Name of Topic Hard Rocks Hard Rocks Grade Level (NGSSS) 4 4 Aliens Invade Animal’s Get Ready Calling All Spiders Climbing The Walls Habitats – How Habitats Affect Us Leaping Lemurs Play Time Sneaky Sssnakes 4/5 3/4/5 5 3/5 5 Electricity & Energy – Energy Electricity & Energy – Energy – The Light Bulb Lights Out 5 5 Explore Our Solar System Asteroid Attack 3 5 Magnetism – Magnets – Types and Uses 4 The Science of Fun 5 52 5 5 3 5 Grade Level (CCSS) Lexile multiple skill & strategy cause and effect 5 6 860 860 cause and effect multiple skill & strategy multiple skill & strategy multiple skill & strategy multiple skill & strategy 5 3 5 4 3 910 690 900 750 580 nocturnal behavior-survival reptiles-cold-blooded ENERGY wind-sun-fossil fuels light bulb-Thomas Edison multiple skill & strategy multiple skill & strategy multiple skill & strategy 5 6 4 870 1000 680 multiple skill & strategy multiple skill & strategy 4 4 780 750 carbon monoxide-hypothermia-power outage SPACE planets-sun-orbit asteroid-comet MAGNETISM magnetic force-electromagnets multiple skill & strategy 5 870 main idea multiple skill & strategy 3 5 550 840 multiple skill & strategy 4 820 multiple skill & strategy 4 760 Key Words ROCKS & MINERALS diamonds-minerals diamonds-minerals-crystals ANIMALS plants-animals-harmful migrate-hibernate-adaptations arachnids-species-organs-predators gecko-adaptations habitats-adaptations MOTION gravity-center of gravity-law of motionfriction-heat-energy Volusia County Schools Elementary Science Department Reading Skills Grade 5 Science Curriculum Map October 2016 Name of Topic Climates: An Introduction to Climates Climates: Climate Zones High and Dry The Whys of Weather: Clouds The Whys of Weather: Rain Weather: An Introduction to Weather Weather: Meteorology & Weather Maps Weather: The Water Cycle Weather: Types of Clouds Weather: Wind Winter Worries and Health Hazards Pumping Up the Heart Skin: The Great Protector The Human Body: The Human Brain The Human Body: The Human Heart The Human Body: The Human Lung The Human Body: Your Vision Understanding How the Brain Works What’s Inside 53 Grade Level (NGSSS) Grade Level (CCSS) Lexile multiple skill & strategy 4 770 multiple skill & strategy multiple skill & strategy multiple skill & strategy multiple skill & strategy multiple skill & strategy 4 6 3 3 4 800 1020 550 520 700 5 tropical-desert-temperature-polar weathering-sediment-aquifer water vapor-condensation condensation-precipitation atmosphere-humidity-temperature-air pressure cold fronts-warm fronts multiple skill & strategy 4 740 5 5 5 5 condensation-precipitation cumulus-stratus-cirrus circulation-sun-air frostbite-hypothermia multiple skill & strategy multiple skill & strategy multiple skill & strategy multiple skill & strategy 4 4 4 4 680 620 730 770 5 5 5 HUMAN BODY heart-muscle-beat largest organ brain-control center-signals multiple skill & strategy multiple skill & strategy multiple skill & strategy 5 4 4 880 720 760 5 blood-oxygen-carbon dioxide multiple skill & strategy 4 720 5 oxygen-chambers-carbon dioxide multiple skill & strategy 4 760 5 5 pupil-retina memory-emotions-learning-pain multiple skill & strategy multiple skill & strategy 3 5 620 870 5 brain-neurons-cerebellum-brainstemcortex multiple skill & strategy 5 870 5 5 4/5 5 5 5 Key Words WEATHER/CLIMATE climate-weather-temperature-rainfall Volusia County Schools Elementary Science Department Reading Skills Grade 5 Science Curriculum Map October 2016 Supplemental Literature TITLE A Cool Drink of Water Ant, Ant, Ant! (An Insect Chant) Bartholomew and the Oobleck Bugs Are Insects Butternut Hollow Pond Down the Drain: Conserving Water Dr. Xargle's Book of Earlets Electrical Circuits Erosion (The Weather Report series) Girls Think of Everything: Stories of Ingenious Inventions by Women Grand Canyon: A Trail Through Time House for a Hermit Crab AUTHOR Barbara Kerley April Pulley Sayre Dr. Seuss Annie Rockwell Brian J. Heinz Anita Ganeri and Chris Oxlade Jeanne Willis Lewis Parker Virgina Castleman How People Learned to Fly If I Built a Car Imaginative Inventions Inventing the Automobile Kids' Paper Airplane Book Oil Spill! Catherine Thimmesh Linda Vieira Eric Carle Fran Hodgkins Chris Van Dusen Charise Mericle Harper Erinn Banting Ken Blackburn and Jeff Lammers Melvin Berger Pancakes, Pancakes! Eric Carle Papa, Please Gete the Moon for Me Popcorn Prince William Eric Carle Elaine Landau Gloria Rand Rice Rice is Life Rise the Moon Seashells by the Seashore Seven Blind Mice Sheep in a Jeep Somewhere in the World Right Now Sound (Energy Works! Series) The Moon Book The Perfect Pet 54 Volusia County Schools Elementary Science Department Louise Spilsbury Rita Golden Gelman Eileen Spinelli Marianne Berkes Ed Young Nancy Shaw Stacey Schuett Jenny Karpelenia Gail Gibbons Margie Palatini CONCEPT/SKILL science inquiry, water conservation science Inquiry and life science matter science inquiry and life science, invertebrates science Inquiry, Life Science science inquiry, water conservation observation, inferencing, scientific process electricity, circuits, transferring of energy erosion, Scientific inquiry/process, model building STEM erosion, weathering observation, classification science inquiry, science and technology, force and motion, physical science science inquiry inquiry, technological design, STEM science inquiry science inquiry, science and technology, force and motion, physical science life science, changes in environment that affect animal life, conducting experiment chemical changes, chemical energy, predictions, conduction of heat, heat energy, electrical energy moon phases scientific process life science, changes in environment that affect animal life, conducting experiment scientific process and inquiry, variables scientific process and inquiry, variables moon phases observation, classification observation, inferencing, scientific process science inquiry, force and motion, science and technology seasons and phases of the moon physical science, science and technology Moon phases, observations, data collection Science Inquiry and life science Grade 5 Science Curriculum Map October 2016 TITLE The Popcorn Book The Remarkable Farkle McBride Too Many Toys Turtle Watch Turtle, Turtle, Watch Out AUTHOR CONCEPT/SKILL Tomie dePaola John Lithgow David Shannon Saviour Pirotta Scientifc Process Physical science, sound energy, science and technology Electricity, cirucuits, transferring of energy Life science, life cycles Life science, life cycles, changes in environment that affect animal life Life science, adapatations, Life science, relationships between animals Science Inquiry, Life Science April Pulley Sayre Weird Friends: Unlikely Allies in the Animal Kingdom What's Eating You? Parasites- The Inside Story White Owl, Barn Owl Jose Aruego and Ariane Dewey Nicola Davies Nicola Davies Website with ELA skill questions tied to the Max Axiom graphic novels: https://sites.google.com/a/share.brevardschools.org/aulakh-science-resources/max-axiom GRAPHIC NOVELS from Capstone Curriculum/Redbrick Learning TITLE World of Food Chains with Max Axiom, The Lessons in Science Safety with Max Axiom Solid Truth About the States of Matter with Max Axiom Powerful World of Energy with Max Axiom, The Investigating the Scientific Method with Max Axiom Crash Course in Forces and Motion with Max Axiom Adventures in Sound with Max Axiom Attractive Story of Magnetism with Max Axiom, The Illuminating World of Light with Max Axiom, The Refreshing Look at Renewable Energy with Max Axiom Understanding Photosynthesis with Max Axiom Dynamic World of Chemical Reactions with Max Axiom The Whirlwind World of Hurricanes with Max Axiom Clara Barton: Angel of the Battlefield Elizabeth Blackwell: America's First Woman Doctor Issac Newton and the Laws of Motion Jane Goodall Marie Curie and Radioactivity 55 Volusia County Schools Elementary Science Department AUTHOR Liam O'Donnell Donald Lemke and Thomas Adamson Agnieszka Biskup Agnieszka Biskup and Cynthia Martin Donald Lemke and Thomas Adamson Emily Sohn Emily Sohn Barbara Shultz and Cynthia Martin Emily Sohn Barbara Shultz and Cynthia Martin Liam O'Donnell Agnieszka Biskup Emily Sohn Allison Lassieur Trina Robbins Andrea Gianopoulos Katherine Krohn Connie Colwell Miller CONCEPT/SKILL food Chains science Safety matter energy science Process forces and Motion sound magnetism, forces light energy plants, energy matter, chemical reactions, energy weather scientist scientist scientist scientist scientist Grade 5 Science Curriculum Map October 2016 GLOSSARY OF TERMS The Science Curriculum Map has been developed by teachers for ease of use during instructional planning. Terminology found within the framework of the curriculum map is defined below. Next Generation Sunshine State Standards (NGSSS): a set of content and process science standards that define with specificity what teachers should teach and students should know and be able to do; adopted by the Florida State Board of Education in 2008 NGSSS Body of Knowledge: the broadest organizational structure used to group content and concepts within the curriculum map and include the following: Nature of Science, Earth Science, Physical Science and Life Science (also known as Reporting Category) Standard/Big Idea: an overarching organizational structure used to describe the scope of a selected group of benchmarks; for example, The Characteristics of Science Knowledge, Earth Systems and Patterns, Forms of Energy, and Interdependence Unit of Study: an overarching organizational sub-structure comprised of a collection of topics used to group content and concepts for a more narrow focus Topics: a grouping of benchmarks and skills that form a subset of scientific concepts covered in each unit of study Benchmarks: the required NGSSS expectations presented in the course descriptions posted on CPALMS by FLDOE Learning Targets/Skills: the content knowledge, processes, and enabling skills that will ensure successful mastery of the benchmarks Vocabulary: the content terminology and other academic language and phrases that support mastery of the learning targets and skills; for teacher- and student-use alike Prerequisite Learning: the benchmarks assigned to previous grade levels that support learning within the current grade level Pacing: a recommendation of time frames for initial delivery of instruction and assessment in preparation for that occurs on the grade 5 Statewide Science Assessment (SSA) including “fair game” content review Teacher Hints: a listing of considerations when planning for instruction; may include suggestions or ideas for review Resource Alignment: a listing of available, high quality and benchmark-aligned materials including labs, strategies, lessons, and videos from textbook and other media sources STEM Week: a period of time dedicated to the implementation of an interdisciplinary, standards-rich experience that poses an ageappropriate, real-world problem to be solved through collaborative and creative measures Formative Assessment Strategies: techniques that can be used before, during, and after instruction to evaluate student learning The District Science Office recommends that all students engage in hands-on, minds-on science experiences DAILY. 56 Volusia County Schools Elementary Science Department Grade 5 Science Curriculum Map October 2016
© Copyright 2025 Paperzz