4.0 Exponent Property Review
First let’s start with a review of what exponents are. Recall that 3 means taking four 3’s and multiplying
them together. So we know that 3 3 × 3 × 3 × 3 81. You might also recall that in the number 3 , three is
called the base and four is called the exponent. Other reminds include that any number to the zero power is equal
to one (so 50 = 1) and any number is equal to itself to the first power (so 5 = 5).
Sometimes it is easier to leave a number written as an exponent. For example, it is much easier to write
5 instead of 95,367,431,640,625. Not only is sometimes simpler to write a number using exponents, but many
operations are easier when the numbers are written as exponents.
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Multiplying Numbers with the Same Base
Let’s examine the problem 3 × 3 and write the answer as an exponent. Yes, we could multiply it out as
a standard form number, 81 × 81 = 6561, but let’s keep it in exponential form to see if it is any easier.
First, let’s expand the problem: 3 × 3 = 3 × 3 × 3 × 3 × 3 × 3 × 3 × 3 . Notice that the only
operation that is happening here is multiplication and that we are multiplying the same number. That means we
can say the following: 3 × 3 = 3 × 3 × 3 × 3 × 3 × 3 × 3 × 3 = 3t . In short we see that 3 × 3 = 3t . Do
you see a rule that we could generalize from this?
Let’s look at another example but this time with a variable.
s × = × × × × × × × × × × = Can you find a rule that we can use when multiplying two exponent numbers with the same base? Yes, we
can add the exponents. In other words, I D × I { = I D˜{ = I would be a quicker way to show work for this
problem. Generalizing this, we have the rule that  × ž = ˜ž .
Will this work with numbers without the same base? Let’s find out by looking at 5 × 2C . Many people
think that 5 × 2C = 10D , but we know that 5 × 2C = 25 × 8 = 200 and that 10D = 100,000. So we see that
5 × 2C = 10D is not true. Therefore we know that we can only add the exponents when we have the same base.
In fact, if asked to simplify 4 × 7 we would either have to multiply it out as a regular number or else leave
it alone if we wanted it written using exponents.
Dividing Numbers with the Same Base
If multiplying numbers with the same base meant that we could add the exponents, what rule do you think
we will discover when dividing numbers with the same exponent? Let’s find out by looking at an example.
4s 4 × 4 × 4 × 4 × 4 × 4 × 4
4D
4×4×4×4×4
180
Note that since only multiplication and division is happening, five of fours in the denominator will “cancel”
(they actually become one since four divided by four is one, we just call it “canceling”) with five of the fours in the
numerator. That means we get the following:
4s 4 × 4 × 4 × 4 × 4 × 4 × 4 4 × 4
= 4
4D
4×4×4×4×4
1
Let’s look at one more example using variables before generalizing a rule for dividing exponent numbers
with the same base.
}{ } × } × } × } × } × } } × } × } × }
=
=
= }
}
}×}
1
It looks like our rule is similar to the multiplication of exponent numbers with the same base, but this time
1Ÿ
we subtract the exponents. This gives us the general rule of 1 = …ž . For now we will only deal with division
cases where the numerator exponent is larger than the denominator, but think ahead to what would happen if the
denominator’s exponent were larger. What do you think would happen?
A Power to a Power
We can also take exponents themselves to a power. For example, think of the problem (2C ) . Following
our order of operations, we know that we have to do the parentheses first which means we get (2C ) 8 64.
However, what if we wanted to leave our answer as a number to a power? Note the following:
(2C ) (2C )(2C ) (2 × 2 × 2) × (2 × 2 × 2) 2{
Again, can you see a rule here? Let’s look at an example with a variable to help again.
(F )C (F )(F )(F ) (F × F × F × F) × (F × F × F × F) × (F × F × F × F) F
For a power to a power when using the same base we get the rule that you can multiply the exponents.
This generalizes to (  )ž ž .
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Negative Exponents
We just learned that when we divide exponent numbers with the same base we can subtract the exponents.
We only examined problems where the numerator had a higher exponent than the denominator, but what would
happen if the denominator had the higher exponent? Let’s look.
5C
5×5×5
=
D
5
5×5×5×5×5
Notice that three of the fives will “cancel” (remember that they really become one because five divided by
five is one). That means we are left with the following:
5C
5×5×5
1
1
=
=
= D
5
5×5×5×5×5 5×5 5
However, by following our rule from last time we know that we can also subtract the exponents which gives
us:
D
D
5C
= 5…
5D
Since D• = 5… and also D• = D‘ , by the transitive property we know that 5… = D‘ . We can now generalize
this rule to say the following for any positive integer <:
…z =
1
z
Negative Exponent as the Reciprocal
Another helpful way to think about negative exponents is as the reciprocal. Remember that the reciprocal
of an integer is one over that integer because a number times its reciprocal must equal one. So 4… means the
reciprocal of 4 which is ‘ or {. (Notice that 4 × ‘ 1 proving that we have the reciprocal.)
One last note is that except for scientific notation, we never leave negative exponents in a solution. We
also take the reciprocal so that our exponent is positive. Let’s look at a few more examples. Notice that we can
evaluate the integer powers, but the variables to a power we have to leave the exponent.
3…C = C = s
} …C = ¢
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2… =  = {
10…D = 0• = 00,000
K …s = £ ’
F… = ¤¡¡
13… = C¡ = C
 … = ¥¡ = ¥
Negative Exponent Operations
Now that we know negative exponents mean reciprocal, we can perform operations with negative
exponents just like we did with positive exponents. Consider the following example of the multiplication rule.
Notice that we still added the exponents, but just need to write our answer as a fraction if we have a negative
exponent left after multiplication.
(5C )(5…D ) = 5C ˜ …D = 5… =
1
1
=
5
25
4s 4…D = 4s ˜ …D = 4 = 16
Now let’s look at a division example. Remember that we found we can subtract the exponents as long as
we have the same base.
5
= 5 … … = 5 = 625
5…
4…
1
1
= 4… … C = 4… = =
C
4
4
256
Finally we can see that the power to a power rule still works with negative exponents. We simply multiply
the exponents.
2C … = 2…{ =
1
1
=
{
2
64
3… … = 3 = 81
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Lesson 4.0
4.0
Evaluate the following exponents operations giving your answer as a fraction where necessary.
1. 5C × 5…
5.
9.
¨•
¨§¡
‘
© § ‚
©
¦ §• ‚¦  
§’
2. (12% 12…s 3.
6. … …D
7. 2C …{ × 2 s
8. 12 × 12…
11. 5…C × 5%
12. 0… 0
10.
§‘
¦‘
4.
× 4…0
Determine if the following equations are true. Justify your answer.
13. 12… × 12s = 12…t × 12C
14.
1 §•
1 §
16. 50 = 5…D …
17.
{§– ×{“
{
19.
© §–
©‘
= h × h …0
20.
1•
1’
=
‘
s§ ‚
s
=
15. ) …D = ) … D
{§‘
{ª
= 7 × 7
18. Os × Os = O…s 21.
C×C
C¡ª
= 3D …
Determine the appropriate exponent to make the equation true.
22. 2D × 2 ? 2…{ × 2C
23.
«–
«§‘
25. (5 )… (5C ) ?
26.
ž§‘ מ“
ž•
28.
184
¬ §‘
¬?
ℎC × ℎ…D
29.
{‘ ‚
{–
?
«?
«‘
24. (3… )C (3… ) ?
ž?
ž
6…t × 6t
27. 9 × 9…t (9 ? )C
30.
C§
C ? ×C­
(3s )…