JOURNAL OF PETROLOGY
VOLUME 42
NUMBER 11
PAGES 2015–2032
2001
P–T–t Evolution of Ultrahigh-Temperature
Granulites from the Saxon Granulite Massif,
Germany. Part II: Geochronology
ROLF L. ROMER1∗ AND JOCHEN RÖTZLER2
1
GEOFORSCHUNGSZENTRUM POTSDAM, TELEGRAFENBERG, D-14473 POTSDAM, GERMANY
2
INSTITUT FÜR GEOWISSENSCHAFTEN, UNIVERSITÄT POTSDAM, POSTFACH 60 15 53, 14415 POTSDAM, GERMANY
RECEIVED JANUARY 28, 2000; REVISED TYPESCRIPT ACCEPTED APRIL 16, 2001
Granulite-facies metamorphism in the structurally lower part of
the Saxon Granulite Massif culminated at 1010–1060°C and
>22 kbar. Ultrahigh-temperature conditions persisted even after a
significant drop in pressure. We dated monazite, zircon, rutile,
garnet and apatite from felsic granulite by U–Pb, biotite from
retrogressed felsic granulite by Rb–Sr, and titanite from mafic
granulite by U–Pb. Zircon and titanite give within analytical
uncertainties the same age at 341·5 ± 0·8 Ma (2) and 342·0
± 0·8 Ma (2), respectively, demonstrating (1) a similar closure
temperature for both minerals in dry systems and (2) a closure
temperature for titanite considerably higher than 550°C. Monazite
plots discordantly and yields a 207Pb/206Pb age at 338·0 ±
0·5 Ma (2), which represents a minimum age because of the
possibility of excess 206Pb. Rutile, garnet and apatite have little
radiogenic lead and show a wide range of apparent 206Pb/238U
ages, which reflects initial isotopic heterogeneities originating from
the reaction history rather than later disturbances. Biotite yields an
Rb–Sr age at 323·0 ± 2·3 Ma (2). The age data in combination
with the P–T path demonstrate that exhumation of the Saxon
Granulite Massif to a middle- to upper-crustal level proceeded at
a fast average rate (>9–18 mm/yr) and subsequently slowed down
significantly (<2 mm/yr).
Ionic diffusion in crystals depends on a variety of factors
such as distribution of crystal defects and impurities,
dissolution and recrystallization reactions, activity of the
involved chemical elements, and temperature and pressure (e.g. Lasaga, 1981; Chakraborty, 1997). The rate of
ionic diffusion in a crystal structure increases significantly
with rise in temperature (e.g. Lasaga, 1981; Chakraborty
& Ganguly, 1990; Chakraborty, 1997; O’Brien, 1997).
Fast diffusion implies that a mineral easily re-equilibrates
with its surroundings and gets rid of ions that do not fit
well into its crystal structure. At high temperature, the
increased overall diffusivity of cations may, to an even
larger extent, apply to radiogenic daughter isotopes, as
these ions have been displaced from their original structural site by recoil and now occur in structural sites that
have a damaged surrounding (e.g. Nasdala et al., 2001)
and these ions may have a different ion radius and charge
than their parents (e.g. Hofmann & Giletti, 1970; Watson
et al., 1985; Cherniak et al., 1991; Smith & Giletti, 1997).
Therefore, the daughter isotope tends to be lost from the
crystal structure. For a geochronological system, this
implies that the mineral is resetting its age continuously.
This concept is well known for minerals that reset their
radiogenic clocks at rather low temperatures, as for
instance the Rb–Sr and K–Ar systems of micas (e.g.
Dodson, 1973; Jäger, 1973; Dahl, 1997). For rocks that
experienced very high metamorphic temperatures, the
problem arises of whether any mineral yields its crystallization age or they all provide cooling ages only.
Problems related to the isotopic dating of ultrahightemperature (UHT) metamorphism are illustrated on a
sample suite from the Saxon Granulite Massif (SGM),
which is part of the Bohemian Massif. The samples have
experienced metamorphic temperatures that are much
higher than the suggested temperatures of isotopic closure
∗Corresponding author. Telephone: + 49-331-288-1405. Fax: + 49331-288-1474. E-mail: [email protected]
 Oxford University Press 2001
KEY WORDS:
exhumation; geochronology; Saxony; UHT granulites
INTRODUCTION
JOURNAL OF PETROLOGY
VOLUME 42
NUMBER 11
NOVEMBER 2001
Table 1: U–Pb data from mineral samples from granulite samples G97-1 and G97-3 from Waldheim, Saxon
Granulite Massif, Germany
Samplea Weight Concentrations
(mg)
(ppm)
206
Pb/204Pb Radiogenic Pb (at. %)c
Atomic ratiosc
Apparent ages (Ma)d
measured
U
Pbtot
ratiosb
206
Pb
207
Pb
208
Pb
206
Pb/238U
207
Pb/235U
207
Pb/206Pb
206
Pb/238U
207
Pb/235U
207
Pb/206Pb
G97-1e
Monazite
1
0·315
4930
1069
1381
20·70
1·10
78·20
0·05127
0·37632
0·05324
322
324
339
2
0·083
5630
973
1337
23·95
1·28
74·78
0·04716
0·34603
0·05322
297
302
338
3
0·100
7670
1098
945
29·14
1·55
69·31
0·04718
0·34612
0·05321
297
302
338
4
0·235
3700
923
1220
18·40
0·98
80·62
0·05244
0·38477
0·05322
330
331
338
5
0·291
5790
875
1787
29·59
1·57
68·84
0·05112
0·37500
0·05321
321
323
338
6
0·213
5640
1020
1276
24·34
1·30
74·36
0·05019
0·36837
0·05323
316
318
339
7
0·191
228
12·6
770
92·17
4·90
2·93
0·05460
0·40019
0·05316
343
342
336
8
0·163
301
15·8
1714
92·18
4·91
2·91
0·05450
0·39987
0·05321
342
342
338
9
0·435
200
10·6
1872
91·50
4·87
3·63
0·05434
0·39849
0·05319
341
341
337
10
0·403
227
12·6
695
91·92
4·91
3·17
0·05417
0·39915
0·05343
340
341
347
11
0·162
155
8·88
455
93·55
4·98
1·47
0·05433
0·39883
0·05324
341
341
339
12
0·251
128
6·82
1045
92·40
4·92
2·68
0·05428
0·39872
0·05327
343
343
340
18·916 34·76
0·96
64·28
0·07308
0·27835
0·02452
455
—
—
—
Zircon
Garnet
13
3·601
0·45
0·393
14
4·612
7·48
19·729 84·67
4·07
11·26
0·05496
0·36441
0·04802
345
—
15
5·381
0·902
1·610
21·073 71·24
3·78
24·98
0·07394
0·54022
0·05297
460
—
—
16
4·525
0·614
0·559
23·495 80·85
5·10
14·05
0·06887
0·59911
0·06301
429
—
—
17
2·296
0·132
0·505
19·287 39·74
2·72
57·54
0·05372
0·49126
0·06519
337
—
—
18·75
Rutile
18
0·299
22·7
8·06
28·669 91·44
4·93
3·62
0·05087
0·37719
0·05374
320
—
—
19
0·301
18·5
4·91
33·302 94·23
4·27
1·50
0·05231
0·32570
0·04512
329
—
—
20
0·520
18·3
4·04
38·608 91·03
4·43
4·54
0·05500
0·36819
0·04851
345
—
—
21
0·367
10·1
18·551 79·17
6·51
14·32
0·05183
0·59680
0·08060
326
—
—
22
0·332
4·76
3·44
22·359 81·35
4·44
14·21
0·04321
0·32609
0·05461
273
—
—
23
0·392
14·64
13·80
21·774 71·01
3·59
25·40
0·04851
0·33909
0·05065
305
—
—
0·502
8·15
7·16
22·375 71·64
4·64
23·72
0·05251
0·46929
0·06473
330
—
—
Apatite
24
136·9
f
G-97-3
Titanite
25
1·872
128·9
11·0
154·0
77·37
4·12
18·51
0·05438
0·39883
0·05319
341
341
337
26
0·782
167·6
11·8
327·8
78·49
4·18
17·33
0·05447
0·40015
0·05328
342
342
341
27
0·956
6·22
281·2
75·24
2·05
20·13
0·05455
0·40173
0·05341
342
343
346
28
1·146
9·41
376·4
76·55
4·08
19·37
0·05449
0·40062
0·05332
342
342
342
83·22
133·1
2016
ROMER AND RÖTZLER
UHT GRANULITES IN SAXONY: GEOCHRONOLOGY
Granulite Massif. Combined with our P–T data (Rötzler
& Romer, 2001), the isotopic ages demonstrate that
exhumation of the Saxon Granulite Massif to a middleto upper-crustal level proceeded at a very high rate,
whereas subsequent exhumation to the surface occurred
at a much lower rate. Our data demonstrate, furthermore,
that literature values for temperature ranges of isotopic
closure for titanite, and possibly monazite, are in conflict
with our observations, and that reaction histories in
minerals with low parent/daughter ratio may have a
significant influence on the geochronological system of
these minerals.
GEOLOGICAL SETTING
Fig. 1. Simplified geological map of the Saxon Granulite Massif
showing sample location, distribution of UHT rocks and granitoids
(e.g. Rötzler, 1992). Post-metamophic granitoids emplaced into the
granulite are dated at 333 Ma (Nasdala et al., 1996; Kröner et al., 1997).
Locations and ages of U–Pb zircon dating of the granulite are indicated
in the figure; lithologies and literature sources are given in parentheses.
gr, monzogranite. f, felsic granulite; m, mafic granulite; um, ultramafic
rock; K, Kröner et al. (1998); N, Nasdala et al. (1996); Q , von Quadt
(1993). The oldest metamorphic ages in the lowermost unit of the
cover, i.e. the cordierite gneisses, are 340 Ma (location not indicated
by the authors; Vavra et al., 1999) and are obtained on anatectic melts.
of most minerals. Thus, UHT metamorphism should
have wiped out the chronological memory of all phases.
We dated minerals, which supposedly encompass a wide
range of temperature of isotopic closure and should
yield a range of cooling ages, from three samples that
experienced the same metamorphic history (Rötzler &
Romer, 2001) to constrain both the age of the metamorphic peak and the exhumation history of the Saxon
The Saxon Granulite Complex and overlying structural
units of lower metamorphic grade constitute the Saxon
Granulite Massif, an oval-shaped dome structure within
the Variscan basement at the northwestern margin of
the Bohemian Massif (Fig. 1). The internal structure
of the SGM shows an excision of large parts of the
metamorphic zonation between the Granulite Complex
and the overlying units, but also between the overlying
units (e.g. Rötzler, 1992, and therein). The granulitefacies metamorphism has culminated at ultrahigh-temperature high-pressure conditions (Rötzler et al., 1994;
Hagen et al., 1995; Rötzler & Romer, 2001). Geochemical
and isotopic data demonstrate that the Granulite Complex, as the core of the dome structure, is almost exclusively composed of meta-igneous rocks (e.g. Rötzler,
1992, and therein; Kroner, 1995). The ages of the protoliths and the high-grade metamorphism are poorly constrained. Zircons from felsic granulites, analysed by
SHRIMP ion microprobe, evaporation, and vapour digestion and conventional dissolution techniques, show (1)
a
Mineral concentrates were obtained using standard mineral separation techniques and separation by hand under the
binocular microscope. Zircon, garnet and rutile were dissolved with 52% HF in Parr autoclaves at 220°C for 4 days, dried
and transferred overnight into chloride form using 6N HCl at 220°C in the autoclave. Monazite was dissolved in H2SO4 on
the hot plate at 220°C overnight. Titanite was dissolved in 52% HF on the hot plate at 160°C overnight. Apatite was dissolved
in warm 7N HNO3. Ion-exchange chromatography for zircon samples was as described by Krogh (1973). Pb and U of all
other minerals were separated and purified using the HCl–HBr and HCl–HNO3 procedures, respectively, described by, e.g.
Tilton (1973) and Manhès et al. (1978). Pb and U were analysed on a Finnigan MAT262 multi-collector mass spectrometer
using Faraday collectors and a secondary-electron multiplier.
b
Lead isotope ratios corrected for mass discrimination with 0·1%/a.m.u.
c
Lead corrected for mass discrimination, blank and initial lead. The common lead isotopic composition was assumed to
correspond to that of leached alkali feldspar (see Table 3): 206Pb/204Pb = 18·31±0·03, 207Pb/204Pb = 15·59±0·02, 208Pb/204Pb =
38·41±0·04. During the measurement period total blanks were <30 pg for lead and <1 pg for uranium for samples analysed
with a 205Pb–235U mixed tracer. Uncertainties of isotope ratios were calculated taking into consideration the following
uncertainties: measurement errors, 30% for fractionation correction, 50% for blank level, uncertainties on common lead and
blank lead composition, and 205Pb/206Pb = 21·693 for isotopic tracer composition. The calculation was performed by Monte
Carlo modelling of 1000 random normally distributed datasets that fit above uncertainty limits, allowing for error correlation
when appropriate.
d
Apparent ages were calculated using the constants of Jaffey et al. (1971) recommended by IUGS (Steiger & Jäger, 1977).
For samples with low 206Pb/204Pb, the calculated apparent 207Pb/235U and 207Pb/206Pb ages are highly uncertain (because of
207
Pb/204Pbsample close to 207Pb/204Pbinitial), and therefore are not shown.
e
German National Grid 5659910/4571330 (Pfaffenberg hill), map 4944 (Waldheim).
f
German National Grid 5660625/4571250 (Waldheim station), map 4944 (Waldheim).
2017
JOURNAL OF PETROLOGY
VOLUME 42
inherited Precambrian components, (2) cores with ages
around 480 Ma that are interpreted as protolith ages,
and (3) abundant metamorphic zircon with ages around
340 Ma that are thought to reflect near-peak granulitefacies conditions (von Quadt, 1993; Nasdala et al., 1996;
Kröner et al., 1998). In addition, there are zircon data
yielding ages around 405 Ma (conventional and evaporation) and 465–460 Ma, 380–365 Ma and 320–315 Ma
(all SHRIMP ages), as well as monazite U–Pb ages at
315 Ma (see Nasdala et al., 1996; Baumann et al., 1997;
Reinhardt & Vavra, 1997; Kröner et al., 1998; Vavra et
al., 1998). Whole-rock and mineral isochron Sm–Nd ages
from granulites and ultramafic rocks at 470 Ma, 380 Ma
and >340 Ma were interpreted as the age of the protolith
and two high-pressure metamorphic events, respectively,
leaving open whether the latter reflect stages on a single
P–T loop or polymetamorphism (von Quadt, 1993).
Variably deformed monzogranites, which post-date the
metamorphic peak, intruded the SGM at 333 Ma (zircon
U–Pb SHRIMP, Nasdala et al., 1996; Kröner et al., 1997).
NUMBER 11
NOVEMBER 2001
Table 2: Silicate trace lead isotope data from
granulite samples G97-1 and G97-3 from
Waldheim, Saxon Granulite Massif, Germany
Samplea
206
Pb/204Pbb
207
Pb/204Pbb
208
Pb/204Pbb
238
U/204Pbb
G97-1
1
Fsp
18·312
15·602
38·395
—
2
Fsp
18·299
15·582
38·432
—
3
Apatite
18·551
15·613
38·455
4
Apatite
22·359
15·815
39·118
95
5
Apatite
21·774
15·769
39·651
72
6
Apatite
22·374
15·856
39·758
78
7
Garnet
18·852
15·608
39·419
8
Garnet
19·728
15·661
38·602
4·7
7·4
26
9
Garnet
21·071
15·739
39·382
37
10
Garnet
23·520
15·922
39·319
76
11
Garnet
19·223
15·654
39·739
17
12
Rutile
28·772
16·156
38·828
206
13
Rutile
33·599
16·283
38·658
292
14
Rutile
39·009
16·598
39·446
376
METAMORPHIC PETROLOGY
Sample description
G97-3
15
Diopside
21·643
15·779
38·556
—
Our study is based on rock samples taken from two
outcrops within >1 km distance in Waldheim. Two
samples (G97-1 and G97-2) are from a railway cut at
Pfaffenberg hill, whereas the third (G97-3) was collected
NE of Waldheim station (Fig. 1, Tables 1 and 3). Sample
G97-1 represents a new occurrence of sapphirine (Rötzler
& Romer, 2001) different in mineralogy from already
known localities for this mineral in the SGM (see Grew,
1986, 1989).
16
Diopside
19·380
15·665
38·376
—
17
Titanite
155·5
22·89
71·24
2520
18
Titanite
334·4
32·43
108·2
5800
19
Titanite
289·0
30·05
110·3
4960
20
Titanite
384·0
35·09
130·9
6710
Sapphirine-bearing granulite (G97-1)
The fine-grained matrix of this rock shows a granoblastic
lobate texture of mesoperthite, plagioclase and quartz,
with accessory apatite, graphite, zircon, monazite, rutile,
pyrrhotite and pyrite. Zircon and monazite are part of
the peak assemblage, whereas apatite occurs in two
generations. Elongate porphyroblasts and ribbons of
quartz define a distinct foliation. Garnet is megacrystic,
has inclusions of quartz, plagioclase, perthite, biotite,
kyanite, pyrrhotite, rutile and zircon, and partially shows
higher Ca contents in the core than at the rims (Rötzler
& Romer, 2001). Kyanite is usually megacrystic and is
either overgrown by sapphirine + spinel + plagioclase
or pseudomorphed by sillimanite. Garnet in part shows
replacement by sapphirine + spinel + plagioclase. Sporadically, sapphirine + spinel are cut or overgrown by
minor biotite that is also found at rims and within
a
Apatite, garnet, rutile and titanite dissolved as described in
Table 1. Alkali feldspar was ground and leached with a 20:1
HBr–HF solution for 2 min. Pb was separated and purified as
described by Tilton (1973).
b
Lead isotope analyses were performed at GeoForschungsZentrum using a Finnigan MAT262 multicollector
mass spectrometer. The lead isotopic composition is corrected for mass discrimination with 0·1%/a.m.u. 2 uncertainties are <0·1%. With the exception of feldspar and
diopside, the data originated from the same samples as those
presented in Table 1. Slight differences in 206Pb/204Pb are
due to corrections for blank and isotopic tracer, which are
performed for the ratios presented in Table 1, but not for
those shown in Table 1.
fractures of garnet [for additional information, see Rötzler
& Romer (2001)].
Retrogressed felsic granulite (G97-2)
This rock is a retrograde product of the typical felsic
granulite. It has a granoblastic inequigranular texture
and experienced the same metamorphic evolution as
the sapphirine-bearing granulites, except for a distinct
retrogression that led to extensive formation of biotite.
2018
ROMER AND RÖTZLER
UHT GRANULITES IN SAXONY: GEOCHRONOLOGY
Table 3: Biotite and alkali feldspar Rb–Sr data
from granulite sample G97-2 from Waldheim,
Saxon Granulite Massif, Germany
Samplea
Rb (ppm)b Sr (ppm)b
87
Rb/86Srb
87
Sr/86Src
G97-2d
1
Feldspar
2
Green
94·4
28·4
9·55
0·763007±24
1015
6·29
591
3·43858±6
981
5·99
603
3·48875±8
biotite
3
Brown
biotite
a
Alkali feldspar and biotite were separated under the binocular microscope, then washed in distilled H2O and acetone
before dissolution in 52% HF.
b
Concentrations were determined with a mixed 84Sr–87Rb
tracer. Sr was analysed in static mode on a Finnigan
MAT262 multi-collector mass spectrometer, Rb was analysed
on a VG 54-R single-collector mass spectrometer. 87Rb/86Sr is
known better than 1%.
c
Sr is normalized with 86Sr/88Sr = 0·1194 and adjusted to 87Sr/
86
Sr = 0·710256 for strontium reference material NBS987.
d
German National Grid 5659675/4571300 (Pfaffenberg hill),
map 4944 (Waldheim).
Red–brown or greenish biotite replaces garnet, which
locally occurs as relict crystals. Biotite is also invariably
overgrown on sillimanite and commonly mantled by
plagioclase, suggesting that biotite was formed by the
reaction Grt + Sil + Kfsss + H2O → Bt + Pl + Qtz.
Late alterations include the overgrowth of haematite and
muscovite on feldspar and of chlorite on biotite.
Garnet–clinopyroxene rock (G97-3)
This fine- to medium-grained rock contains the restricted
peak assemblage garnet + clinopyroxene + titanite +
apatite that forms a granoblastic polygonal texture. Apart
from homogeneous dark green areas of clinopyroxene
with scattered garnet, this rock contains millimetre-thick
bands with concentrations of garnet. Titanite and apatite
commonly occur enclosed in both clinopyroxene and
garnet. Early plagioclase occurs in interstices between
clinopyroxene, from which it may have exsolved. It also
occurs as blebs within clinopyroxene. Late hydration
must have involved the introduction of potassium by
fluids, as plagioclase is largely overgrown by muscovite.
P–T path
The P–T path for the Saxon granulites (Fig. 2) has been
presented in detail by Rötzler & Romer (2001). It is
constrained by phase equilibria and phase compositions
Fig. 2. P–T path for the dated samples. Apart from phase equilibria
in these samples, the path is in accord with data obtained from samples
elsewhere in the Saxon Granulite Complex [for details see Rötzler &
Romer (2001) and references therein]. Bold border lines of the shaded
fields correspond to 1 uncertainties; open borders imply that the
values are not well constrained; gradual shading reflects that P–T
conditions are well constrained only toward more intense shading [all
data from Rötzler & Romer (2001)].
of the samples here dated, by recalculated estimates from
Rötzler et al. (1994) and by data from Rötzler (1992).
These P–T estimates demonstrate that metamorphism in
the Saxon Granulite Complex culminated in UHT–HP
conditions of 1010–1060°C and >22 kbar. The peak
mineral assemblages and isothermal-decompression assemblages related to the exhumation of the Saxon granulites define a clockwise loop, where UHT conditions
persisted even after a significant pressure drop (Fig. 2).
Retrograde hydrous phases are characteristic for the P–T
loop once the rocks have reached intermediate to low
pressure. The granulites seem to have experienced pronounced cooling at little pressure change only after they
had reached a middle- to upper-crustal level (Fig. 2).
GEOCHRONOLOGY
Sapphirine-bearing granulite (G97-1)
Zircon crystals in this rock are multifaceted short-prismatic to equant, as is typical for zircon from high-grade
metamorphic rocks (e.g. Vavra et al., 1994). There is no
indication of inherited grains or partially resorbed older
zircon. Six zircon samples are concordant (Fig. 3; Table
1). The best-constrained age estimate of these six samples
is the weighted 206Pb/238U age at 341·5 ± 0·8 Ma (2;
Fig. 3). This age is a minimum age for the crystallization
2019
JOURNAL OF PETROLOGY
VOLUME 42
Fig. 3. U–Pb zircon and monazite age data for the sapphirine-bearing
granulite G97-1. Insets show apparent 206Pb/238U and 207Pb/206Pb ages,
respectively. Data from Table 1. (For discussion see text.) All data plotted
and calculated using ISOPLOT (Ludwig, 1994). All uncertainties are
given at 2 level.
of zircon. It represents either a cooling age or a crystallization age, depending on whether the temperature
for isotopic closure of the U–Pb system of zircon is
lower or higher than the temperature at which zircon
crystallized.
The U–Pb system of monazite is disturbed and all six
samples are discordant (Fig. 3; Table 1). The discordia
intersects the concordia at 338·2 ± 1·4 Ma (2;
MSWD = 0·382). The weighted 207Pb/206Pb age of all
six samples is 338·0 ± 0·5 Ma (2; Fig. 3, inset). This
is a minimum age for the crystallization of monazite, as
(1) the monazite might have crystallized at a temperature
considerably higher than its commonly assumed closure
temperature for lead diffusion (710–750°C; see Copeland
et al., 1988; Parrish, 1990; Dahl, 1997) and (2) there
might have been excess 206Pb. Excess 206Pb originates
from 230Th (e.g. Mattinson, 1973; Schärer, 1984), which
is an intermediate member of the 238U decay series and
eventually decays to 206Pb. Excess 206Pb can be accounted
for by using the 232Th/238U of monazite and the rock
(see Schärer, 1984), provided the observed Th/Urock is
representative for the original crystallization environment
of monazite. For Th/Urock >2·0, which falls in the range
NUMBER 11
NOVEMBER 2001
characteristic for felsic rocks, the weighted 207Pb/206Pb
age of all six samples becomes 341·1 ± 1·1 Ma (2; Fig.
3, inset), which is within analytical uncertainties identical
with the age obtained for zircon. It should be noted that
the scatter of the data is increased by this correction
procedure, which might hint that a Th/Urock of 2·0
already results in an overcorrection. Lower Th/Urock
requires a larger correction, and thus results in even
larger scatter. Thus, the best age estimate for the monazite
is bracketed by the minimum age at 338·0 ± 0·5 Ma
and the age at 341·1 ± 1·1 Ma (2). Actually, as any
correction for excess 206Pb results in enhanced scatter of
the data about the discordia line, it is likely that excess
lead does not contribute significantly to the lead of these
monazite samples, in which case Th/Urock was larger
than two. For Th/Urock >3·5, the U–Pb age of monazite
is beyond analytical uncertainties lower than the U–Pb
zircon age. Th/U of the whole-rock sample was not
determined, as this ratio may be strongly affected by U
mobility at the surface and—even for undisturbed Th/
U values—it never is clear whether the value for the
bulk sample is representative for the surrounding of
monazite. Therefore, the extent to which 206Pb excess
affects the intercept age of monazite remains unresolved.
In the discussion, we use in a first step the monazite
minimum age (no excess 206Pb) to illustrate the exhumation and cooling history of the Saxon granulites.
In a second step, we focus on the effect of an older
monazite age for the exhumation and cooling histories
and for the temperature of isotopic closure of monazite
in dry systems.
Garnet has a low and highly variable U content, but
rather high common lead contents (0·3–18 ppm; Table
1). Therefore, its lead isotopic composition is rather
unradiogenic. The U–Pb system of garnet yields concordant data, largely because of the large uncertainty of
the 207Pb/235U ratio, which originates from the uncertainty
of the estimated initial lead composition. The apparent
206
Pb/238U age, however, differs between the various
garnet samples and ranges between 337 and 460 Ma
(Table 1), which implies that the U–Pb system of garnet
carries inherited components or the various samples did
not have a common isotopic composition of initial lead.
During sample preparation, special care was taken to
avoid any garnet fragments that might contain inclusions;
therefore, we consider the presence of inclusions as
unlikely. This is also corroborated by the following argument. The apparent U–Pb garnet ages in part are
much older than the U–Pb age of monazite, zircon
and titanite, despite textural evidence of a common
crystallization history and age. Furthermore, electron
microprobe BSE imaging did not reveal submicroscopic
inclusions of inherited zircon or monazite in garnet. The
206
Pb/238U age discrepancy among the various garnet
fractions is also reflected in the 206Pb/204Pb–238U/204Pb
2020
ROMER AND RÖTZLER
UHT GRANULITES IN SAXONY: GEOCHRONOLOGY
and 206Pb/204Pb–207Pb/204Pb diagrams (Fig. 4). Two reference lines are shown in the 206Pb/204Pb–238U/204Pb
diagram (Fig. 4a). They are fitted through the isotopic
composition of the alkali feldspar and garnet samples to
yield the steepest and the flattest slope, respectively. The
flatter reference line corresponds to an age at 337 Ma,
which by and large agrees with the zircon, titanite and
monazite ages. The steeper reference line corresponds
to an age at 460 Ma. If all garnet samples had formed
during the same event, and thus, have the same age, the
initial lead isotopic composition would have to vary
among the various samples. The extreme values for the
initial isotopic composition of garnet are given by the
isotopic composition of alkali feldspar ( 206Pb/204Pb =
18·31) and 206Pb/204Pb >18·85 (i.e. the least radiogenic
garnet sample; see Fig. 4b and c). In this case, all garnet
data represent mixtures and the reference lines for 337
and 460 Ma probably represent mixing lines without age
significance. Heterogeneous initial lead isotopic composition of garnet may also explain the anomalously high
scatter of the data in the 206Pb/204Pb–207Pb/204Pb diagram.
The anomalous behaviour of lead is paralleled by the
Th/U signature of garnet as reflected in the 206Pb/
204
Pb–208Pb/204Pb diagram (Fig. 4b). The reference lines
connecting the isotopic composition of garnet with that
of alkali feldspar correspond to Th/U340 Ma values that
range from 0·5 to 6·0 (Fig. 4b).
Rutile has little radiogenic lead, which is due to high
contents of common lead (3·1–8·0 ppm) rather than low
contents of uranium (18·2–22·5 ppm; Table 1). The
206
Pb/238U age of the rutile samples, therefore, is sensitive
to the correction of common lead. Using the lead isotopic
composition of alkali feldspar (Table 2) for the common
lead composition results in apparent 206Pb/238U ages
ranging between 320 ± 4 Ma and 345 ± 4 Ma (Table
1). This variation in apparent age cannot be removed
by choosing different values for the common lead isotopic
composition or higher or lower blank levels. For instance,
using a common lead composition with 206Pb/204Pb
>18·0 results in apparent 206Pb/238U ages ranging from
329 to 350 Ma. In any case, the U–Pb age of rutile
remains ambiguous, as a result of the unknown and
potentially heterogeneous nature of the initial lead isotope
composition.
Apatite is a rarely used phase in U–Pb geochronology,
as this mineral has a rather low closure temperature for
dry systems (>400–450°C; Watson et al., 1985; Cherniak
et al., 1991), which may be even lower in wet systems
(see Romer, 1996), and tends to recrystallize and thereby
lose lead even at low temperatures. The four apatite
samples (Table 1) have contrasting 206Pb/238U ages ranging from 273 to 330 Ma, which implies either that there
has been lead loss in some samples after the ambient
temperature had fallen below the closure temperature of
apatite or that the initial lead isotopic composition in
Fig. 4. Pb and U–Pb systematics of garnet, apatite, alkali feldspar and
diopside. Data from Table 2. (a) 206Pb/204Pb–238U/204Pb diagram. Data
for garnet and apatite scatter. The garnet data fall between reference
lines for 337 Ma and 460 Ma. (b) 208Pb/204Pb–206Pb/204Pb diagram. The
large scatter of the data reflects highly variable Th/U after crystallization
or highly heterogeneous initial lead. Th/Ucalc values calculated for T =
340 Ma are shown for reference. (c) 207Pb/204Pb–206Pb/204Pb diagram.
A regression line through garnet yields an aberrant value of 722 ±
430 Ma (MSWD = 4·6) and is interpreted to have no age significance.
Instead, the large scatter of garnet and apatite trace lead, the large
variation in Th/Ucalc, and the anomalous high 206Pb/238U age of some
garnet samples are interpreted to reflect initial isotopic heterogeneity
of lead and contrasting availability of Th and U during reaction
progress and growth of garnet and apatite. (For discussion see text.)
apatite was heterogeneous. This second possibility is
also compatible with the lead systematics in the 206Pb/
204
Pb–207Pb/204Pb and 206Pb/204Pb–208Pb/204Pb diagrams
(excess scatter; Fig. 4b and c, Table 2), which reflects a
broad range of apparent Th/U after crystallization.
2021
JOURNAL OF PETROLOGY
VOLUME 42
Fig. 5. Rb–Sr isochron diagram for alkali feldspar and biotite from
the retrogressed granulite G97-2. Data from Table 3.
Retrogressed felsic granulite (G97-2)
Fine-grained green and red–brown biotite and alkali
feldspar were separated from this sample for Rb–Sr
geochronology. Both green and red–brown biotite are
retrograde and formed from the breakdown of garnet.
Green and brown biotite formed at temperatures higher
than the closure temperature for the Rb–Sr system of
biotite, which is commonly thought to be >350°C (e.g.
Armstrong et al., 1966), although there is an increasing
number of arguments that this temperature estimate is
too low (see Villa, 1998; Kühn et al., 2000). The two
biotite samples had low initial strontium contents (4·96
and 4·71 ppm, respectively) and high Rb contents (1015
and 981 ppm, respectively). Therefore, they developed
highly radiogenic Sr isotope ratios (Table 3). The two
biotite samples and the alkali feldspar fall on a common
isochron that corresponds to an age at 323·0 ± 2·3 Ma
(2; MSWD = 0·066; Fig. 5). Because of the highly
radiogenic nature of Sr in biotite, possible heterogeneities
in the isotopic composition of alkali feldspar and biotite
at the time the ambient temperature of the granulite had
fallen below the closure temperature of biotite do not
have an effect on the calculated Rb–Sr age. The initial
composition of strontium at Sri = 0·7191 is highly
radiogenic and indicates that the protoliths of the granulite had a long crustal residence before granulite-facies
metamorphism.
Garnet–clinopyroxene rock (G97-3)
Four samples of titanite from this rock were analysed.
All four samples had intermediate 206Pb/204Pb values that
demand a good knowledge of the initial lead isotopic
composition to define a precise titanite age. The initial
lead isotopic composition was estimated using diopside
from the same sample and alkali feldspar from sample
NUMBER 11
NOVEMBER 2001
G97-1. Two samples of diopside were analysed (Table
2). Their lead isotopic compositions are slightly radiogenic
and differ between the two samples. Thus, the lead
isotopic composition of diopside seems to have been
affected by in situ lead growth, resulting in minimum
values for the 206Pb/238U and 207Pb/235U ages of titanite.
The diopside and titanite samples define a secondary
lead isochron that corresponds to an age at 341·9 ±
3·8 Ma (2; MSWD = 1·15) in the 206Pb/204Pb–207Pb/
204
Pb diagram (Fig. 6). For an undisturbed system, the
initial lead isotopic composition of titanite lies on the
secondary lead line. Alkali feldspar from sample G97-1
falls on this line and possibly represents the best estimate
for the initial lead isotope ratios of titanite. Data reduction
using the lead isotopic composition of alkali feldspar
yields concordant ages (Fig. 6; Table 1) that agree with
the 207Pb/206Pb age of the secondary lead isochron (341·7
± 4·8 Ma, 2, MSWD = 1·79). The age of the lead
line agrees within error limits with the 206Pb/238U age of
the individual titanite samples (see Fig. 6), whose ages
range from 338·8 to 341·1 Ma if the diopside lead is used
for the common lead correction and from 341·4 to
342·4 Ma if the alkali feldspar lead is used for the common
lead correction. The weighted mean 206Pb/238U age of
the titanite samples is 340·6 ± 0·8 Ma (2; MSWD =
1·49; diopside) and 342·0 ± 0·8 Ma (2; MSWD =
0·219, Fig. 6; alkali feldspar), respectively. It should be
noted that 206Pb/238U ages are more precise than 207Pb/
206
Pb ages for Phanerozoic samples, and that the 206Pb/
238
U age at 340·6 ± 0·8 Ma represents a minimum age.
The 206Pb/238U age at 342·0 ± 0·8 Ma is considered
here to be the best age estimate for the titanite from
sample G97-3 (see Fig. 6, inset).
DISCUSSION
Closure temperature of minerals
Ionic diffusion in the crystal structure may result in the
loss of mobile ions from minerals. If the mobile ion is
the daughter isotope of a geochronological system, its
loss will cause the reduction of the apparent isotopic age
of the mineral. The widely held assumption that this
diffusion and loss from the crystal structure are dependent
on the ambient temperature and the cooling rate of the
mineral eventually resulted in the definition of the closing
temperature of different geochronological systems for a
wide variety of minerals and cooling rates (e.g. Dodson,
1973; Jäger, 1973; Copeland et al., 1988; Mezger et al.,
1991; Cherniak, 1995, 2000). Ionic mobility, however,
is less dependent on temperature than on the distribution
and density of crystal defects, availability and composition
of fluids, deformational microstructures and metamorphic
history (e.g. Lasaga, 1981; Chakraborty, 1997). Therefore, it has been argued that these factors may affect the
2022
ROMER AND RÖTZLER
UHT GRANULITES IN SAXONY: GEOCHRONOLOGY
Fig. 6. (a) U–Pb systematics of titanite (data from Table 1). It should
be noted that trace-lead of diopside (Table 2) is slightly radiogenic
and, therefore, the age data represent minimum estimates. The isotopic
composition of alkali feldspar (Table 2) represents the most primitive
lead estimate, yet it is not from sample G97-3. U–Pb data derived
using diopside for the common lead correction are shown in dashedline ellipses, whereas those using alkali feldspar are shown in continuousline shaded ellipses. (b) Pb–Pb systematics of titanite (data from Table
2).
geochronological system of a mineral in a much more
profound way than temperature does and that many
estimates of the closure temperature are too low (e.g.
Dahl, 1997; Kamber et al., 1998; Villa, 1998).
Estimates of the closure temperature for the U–Pb
system of zircon, monazite and titanite are based on field
data, i.e. the presence of inherited zircon, monazite and
titanite in magmatic systems (e.g. Copeland et al., 1988;
Zhang & Schärer, 1996), comparison among several
geochronometers in the same suite or region (e.g. Mezger
et al., 1991) and limited experimental studies (e.g. Cherniak et al., 1991; Cherniak, 1995, 2000). Some of these
studies, and to an even larger extent confirmations of
earlier estimates, involve circular arguments, whereas the
petrological basis of other estimates has become obsolete
[for examples and a discussion, see Villa (1998)]. From
these studies, one would expect that the closing temperature for the U–Pb system under dry conditions is
zircon > monazite [ titanite. U–Pb age data of granulites
from the SGM, however, give an age sequence titanite
> zircon > monazite (little or no excess of 206Pb in
monazite) or titanite > zircon > monazite (significant
206
Pb excess in monazite), which indicates that the closing
temperature for the U–Pb system under dry conditions
is in the sequence titanite > zircon > monazite or
titanite > zircon > monazite. Furthermore, the closure
temperature of titanite, and probably monazite, is considerably higher than previously thought. In either case,
the observed age distribution is not compatible with
earlier estimates of closure temperatures for these minerals. It should be noted that coincident ages for zircon,
titanite and monazite could be obtained even for highly
contrasting temperatures of isotopic closure for these
minerals, as known from the literature, if the Saxon
granulites cooled extremely rapidly. This alternative,
however, would imply initial cooling rates in excess
of 250–350°C/my (depending on the chosen literature
values), which appears unlikely for rocks that are transferred from lower- to middle-crustal levels (see also below).
The contrast of our results with earlier estimates of
closure temperatures may be due to the type of sample
used. Samples with low apparent closure temperatures
may originate from deformed and dynamically recrystallized rocks or ‘wet’ systems, i.e. rocks with a high
activity of H2O (aH2O). The granulite samples from Waldheim used for U–Pb dating represent ‘dry’ systems.
Sample G97-3, however, shows locally minor secondary
muscovite. With ‘dry’, we refer here to systems with low
aH2O, rather than the absence of fluids. In this context, it
is important to note that aH2O depends strongly on pressure
(e.g. Aranovich & Newton, 1996, 1997). During decompression, the same fluid may thus pass through a
wide range of aH2O and may change its character at lower
pressure. The same fluid that at high pressure is unable
to drive hydration reactions may at low pressure drive
the formation of hydrous phases. Thus, secondary muscovite in sample G97-3 does not necessarily imply fluid
influx as long as the other ions are ‘locally’ available.
The formation of muscovite in G97-3, however, requires
mobility of K over distances larger than the size of the
investigated sample, i.e. decimetre scale or larger. The
U–Pb age of titanite, which coincides with that of zircon
and possibly is higher than that of monazite, implies that
the closure temperature of the U–Pb system of titanite
in systems with low aH2O is similar to or higher than that
of monazite. The apparently unaffected U–Pb systematics
of titanite may reflect the spatial separation of muscovite
and titanite in the sample and not necessarily demonstrate
its insensitivity to increases in aH2O.
Age of metamorphic peak
The minimum age for the granulite-facies metamorphism
is given by the highest U–Pb age, i.e. the titanite age at
342·0 ± 0·8 Ma (2; Fig. 6) and the zircon age at 341·5
2023
JOURNAL OF PETROLOGY
VOLUME 42
± 0·8 Ma (2; Fig. 3). If all ages represent the time at
which the ambient temperature of the rock had fallen
below the closure temperature of titanite, zircon and
monazite, respectively, then this age would represent a
minimum age for both the pressure and temperature
peak of metamorphism. For instance, if the temperature
of isotopic closure for zircon is 800–900°C (e.g. Dahl,
1997; Mezger & Krogstad, 1997), the age data would
contain no information about the high-temperature and
high-pressure exhumation history of the SGM, because
at such low temperatures the SGM already would have
reached a middle-crustal level (Ζ8 kbar; Fig. 2). In this
example, both the titanite and zircon age would not be
related to the phases used to constrain the P–T conditions.
We consider such a low temperature for isotopic closure,
however, as unlikely, especially because of the occurrence
of inherited zircon crystals in mantle rocks and ultrahightemperature rocks. These inherited crystals suggest that
the closure temperature of zircon in dry systems far
exceeds 1000°C (e.g. Gebauer, 1990; Kröner et al., 1998).
The coincidence of the age of zircon with the age of
titanite indicates that the closure temperature of titanite
should be in the same range as that of zircon under ‘dry’
conditions.
Alternatively, the U–Pb ages of titanite, zircon and
monazite represent formation ages. All investigated zircon
crystals are of the poly-faceted type commonly found in
high-grade metamorphic rocks. No inherited zircon was
observed in sample G97-1. Rare inclusions of metamorphic zircon in garnet indicate that zircon formed at
the same time as or earlier than garnet, which is part of
the peak-pressure assemblage. Thus, the U–Pb zircon
age should be related to the pressure maximum. This
conclusion is supported by the following argument. Zircon growth is controlled by the availability of zirconium,
which essentially becomes available through the breakdown of major phases that contain significant amounts
of zirconium (e.g. clinopyroxene, amphibole, biotite, Feoxides) and the dissolution of old zircon grains. For
instance, ilmenite, magnetite and biotite contain 150 to
>550 ppm, 20–320 ppm and 17–50 ppm zirconium,
respectively (e.g. Brooks, 1969; McKay et al., 1986; Ewart
& Griffin, 1994). The consumption of these phases during
prograde metamorphism and close to metamorphic peak
conditions should release zirconium and allow the crystallization of metamorphic zircon. Although the growth
of zircon cannot be uniquely related to a distinct P–T
window, it seems likely that it is related to major phases
that have grown close to Pmax. Textural evidence shows
that titanite (G97-3) is part of the peak metamorphic
assemblage (Rötzler & Romer, 2001). It should be noted
that the present U–Pb age data of zircon, monazite and
titanite—in agreement with Nasdala et al. (1996) and
Kröner et al. (1998)—are incompatible with earlier reported U–Pb zircon (SHRIMP) and monazite ages in
NUMBER 11
NOVEMBER 2001
the range 320–315 Ma (Baumann et al., 1997; Vavra et
al., 1998).
Cooling and exhumation history
Numerical modelling demonstrates that the orogeninternal temperature distribution and variation with time
strongly depend on the chosen boundary conditions, the
most critical of which seems to be heat flux at the bottom
of the modelled lithosphere and the exhumation rate
(e.g. Stüwe & Sandiford, 1995; Grasemann et al., 1998).
Assuming constant depth–constant heat flux as boundary
condition (e.g. England & Thompson, 1984) not only
implies lithospheric delamination, but also results in a
temperature rise during exhumation (Stüwe & Sandiford,
1995). Such a temperature rise is not observed for the
Saxon granulites (Rötzler & Romer, 2001, fig. 2). Assuming alternatively a constant depth–constant temperature boundary condition implies variable heat flow
at the base of the lithosphere over time and does not
require lithospheric delamination (Stüwe & Sandiford,
1995). This results in P–T paths that strongly depend on
the exhumation rate (Grasemann et al., 1998): slowly
exhumed rocks have plenty of time to lose their heat by
conduction, and thus will cool distinctly during exhumation. In contrast, fast exhumation of high-pressure
rocks will show little change in temperature along their
P–T path for segments of fast exhumation. Fast exhumation rates and fast cooling rates seem little compatible with each other.
The inferred cooling history of the SGM strongly
depends on the closure temperature of the various dated
minerals, which among other factors also depends on the
cooling rate. Most temperature values for isotopic closure
are supposed to apply for scenarios of moderate to slow
cooling, and therefore, may be too low for settings of
fast cooling. Furthermore, the closing temperature of
some minerals is also under debate because of the poorly
known influence of fluids, deformation, distribution of
crystal defects and recrystallization (see previous sections).
The exhumation history of the SGM depends on the
reliability of pressure estimates and their linking with the
age data. All pressure estimates used for the calculation
of exhumation rates were derived directly from the P–T
path of dated samples (Figs 2 and 7), for which detailed
petrological data exist (Rötzler & Romer, 2001). This
avoids problems associated with spatially and temporally
highly variable geothermal gradients in orogenically
thickened crust.
Cooling and exhumation rates are calculated for discrete temperature values (for crystallization or cooling
ages), the corresponding pressure being read from the
P–T path (see Rötzler & Romer, 2001; Figs 2 and 7).
For cooling ages, the assumed cooling temperature was
2024
ROMER AND RÖTZLER
UHT GRANULITES IN SAXONY: GEOCHRONOLOGY
Fig. 7. Cooling and exhumation rates for the SGM using zircon, titanite, monazite and biotite. Symbol width reflects the age uncertainty.
Rates are calculated for distinct values of closure temperature (e.g. Jäger, 1973; Copeland et al., 1988) for each mineral. To better reflect the
effect of different temperatures of isotopic closure, rates are calculated for several temperature values. The pressure data necessary for the
calculation of exhumation rates are derived from the P–T path of the dated granulite samples (Fig. 2). Models 1 and 2 represent extreme cases
using the following assumptions: Model 1—titanite and zircon ages represent crystallization ages, and monazite and biotite yield cooling ages;
Model 2—all minerals yield cooling ages only. (For details see text.)
used to derive the appropriate pressure from the P–T
path (see Rötzler & Romer, 2001; Fig. 7). All rates are
calculated taking into account the uncertainties of the
age determinations. Although 1 uncertainties for pressure and temperature estimates were given by Rötzler &
Romer (2001), they are not used for the calculation of
the cooling and exhumation rates. Taking them into
consideration would only slightly enhance the range of
cooling and exhumation rates, but would not result in a
qualitatively different solution. The extreme range in
rates in the high-temperature segment of the exhumation
path of the Saxon granulites is entirely due to the small
difference between the ages of zircon/titanite and monazite, which allows even small age uncertainties to have
a drastic effect on the derived rates. Cooling and exhumation rates are calculated for two extreme models
(Fig. 7).
Model 1. The U–Pb ages of titanite and zircon are
formation ages. Textural evidence indicates that they
formed close to peak pressure conditions. Their age,
therefore, reflects the pressure peak. Monazite, which on
textural grounds is considered to have grown during peak
metamorphism, is interpreted to yield a cooling age.
Biotite yields a cooling age.
Model 2. Monazite, titanite and zircon U–Pb ages
represent cooling ages. Any petrological argumentation
to link the crystallization of these trace phases with the
major phases, and thereby with P–T conditions, is fruitless
as the age of the mineral is not related to the time of
crystallization. The inferred post-peak cooling history
depends strongly on the chosen values for the closure
temperature of these minerals, a subject that in part is
disputed (e.g. Mezger et al., 1989, 1991; Santos Zalduegi
et al., 1996; Dahl, 1997; Mezger & Krogstad, 1997;
Kamber et al., 1998; Villa, 1998). Age information about
the metamorphic peak is not contained in the analysed
systems and can be estimated only indirectly from the
geological context.
Cooling history
From the cooling and exhumation rates estimated from
the simple Models 1 and 2, it becomes clear that most
combinations of closing-temperature estimates indicate
geologically fast rates (Fig. 7). An age difference of 2–4 my
between zircon and monazite results in cooling rates of
25–50°C/my for Model 1 and 75–150 to 25–50°C/my
for Model 2, depending on the chosen values for the
closure temperature of monazite and zircon (see Fig. 7).
It should be noted that a significant contribution of excess
206
Pb in monazite raises the monazite age, and thus would
2025
JOURNAL OF PETROLOGY
VOLUME 42
increase the derived average cooling rate (or would
require a higher temperature of isotopic closure for
monazite). The age difference between monazite and
biotite, in combination with a range of closure temperatures for both minerals, yields average cooling rates
ranging from 40 to 20°C/my (Fig. 7). This range, however, represents a minimum estimate, as the temperature
of isotopic closure of biotite may be considerably higher
than commonly thought [for an example, see Kühn et
al. (2000)].
Exhumation history
The exhumation history is intimately related to the
cooling history and the chosen values for isotopic closure
of the various geochronometers. The high-pressure segment of the exhumation path yields geologically fast
average exhumation rates (Fig. 7). For instance, an age
difference of 2–4 my between zircon and monazite results
in exhumation rates of 9–18 mm/yr for Model 1 and
14–28 to 2–5 mm/yr for Model 2, depending on the
chosen values for the closure temperature of monazite
and zircon (see Fig. 7). It should be noted that a significant
contribution of excess 206Pb in monazite raises the monazite age, and thus would increase the derived exhumation rate, or alternatively would indicate that the
temperatures used here, 750°C and 950°C for isotopic
closure of monazite, are distinctly too low. Fast early
exhumation also is indicated by a U–Pb zircon age of
340 Ma (SHRIMP, no uncertainties stated, Vavra et al.,
1999) from an anatectic lens in the Cordierite Gneiss
Unit (Fig. 1). Cordierite gneisses occur between the
Granulite Complex and the Schist Cover. They form
part of the metamorphic zonation that is mainly due to
thermal overprint from the hot Granulite Complex (e.g.
Rötzler, 1992; Reinhardt & Kleemann, 1994). Their
thermal peak was reached when the Cordierite Gneiss
Unit, and thus the Granulite Complex, was at a middlecrustal level (4 kbar, Rötzler, 1992). Although it may not
be possible to compare directly the thermal evolution of
rocks from the interior of the granulite massif with rocks
at its margin, the essentially indistinguishable ages of
titanite and zircon from the peak assemblage of the
granulite samples and the zircon age from the Cordierite
Gneiss Unit require a very fast exhumation of the hot
Saxon granulites to at least a middle-crustal level. For
instance, if the granulite in the vicinity of the dated
Cordierite Gneiss Unit had a P–T–t path comparable
with that of the samples from Waldheim, the inferred
exhumation and cooling rates are far in excess of 20 mm/
yr and 100°C/my, respectively. The age difference between monazite and biotite, in combination with a range
of closure temperatures for both minerals, yields exhumation rates ranging from 2 to <0·2 mm/yr (Fig. 7).
NUMBER 11
NOVEMBER 2001
This range is little dependent on the temperature of
isotopic closure of biotite. Thus, once the granulites have
reached the middle crust, independent of which model
is chosen to interpret the data, the inferred exhumation
rates invariably are moderate to low.
The two models thus constrain the exhumation of the
Saxon granulites to have been fast during its initial phase
and then markedly slower once the rocks had reached
middle-crustal level. Such a slow-down of exhumation is
also known from other areas with high-pressure rocks,
such as, for instance, the Alps (Duchêne et al., 1997), the
Gföhl area in the Bohemian Massif (O’Brien, 1997) and
the Red River Shear Zone (Nam et al., 1998), and reflects
the decrease of the driving force for exhumation with
time. Independent of the chosen values for the temperature of isotopic closure of zircon, titanite and monazite, exhumation rates of the SGM are high (Fig. 7).
They fall in the range known from other areas. For
instance, exhumation rates as high as 15–39 mm/yr are
inferred for the ultrahigh-pressure rocks from Dora Maira
(Gebauer, 1997) and eclogites from Papua New Guinea
(Hill & Baldwin, 1993). Exhumation rates in excess of
10 mm/yr have also been suggested for parts of the
Bohemian Massif, high-grade rocks of the Alps and
eclogites occurring along the Red River Shear Zone (e.g.
Duchêne et al., 1997; Nam et al., 1998).
Comparison with thermal models
The exhumation and cooling rates do not conflict with
rates known from other high-grade metamorphic areas.
Little dependent on the chosen values for the temperature
of isotopic closure of monazite, the obtained exhumation
rates are high. In contrast, the obtained cooling rates
vary strongly and become extremely high for closure
temperatures as low as those commonly considered to
be typical for monazite (e.g. Copeland et al., 1988; Zhang
& Schärer, 1996) and biotite (e.g. Armstrong et al., 1966;
Jäger, 1973). Fast average rates for the early phases of
exhumation that are paralleled by fast average rates of
cooling, however, seem little compatible with results from
modelling (e.g. Grasemann et al., 1998). Instead, during
initial rapid exhumation, there should be little cooling,
as (1) the low thermal conductivity would not allow the
loss of large amounts of heat within a short time and (2)
the thermal contrast between the hot granulite and its
wall rock would become large only after a significant
amount of exhumation had occurred, i.e. the hot granulite
had been placed in contact with rocks of the middle and
upper crust. The thermal contrast between the granulite
and its wall rocks, however, is the driving force for the
cooling of the granulite. The apparent conflict between
the estimated cooling and exhumation rates and the
results of modelling may be resolved if either of the
2026
ROMER AND RÖTZLER
UHT GRANULITES IN SAXONY: GEOCHRONOLOGY
following two explanation applies. (1) In dry undeformed
systems, the temperature of isotopic closure of monazite
is distinctly higher than 750°C and possibly even 950°C.
Such an explanation requires significantly lower rates of
cooling during the initial stages of exhumation, which
remains fast. (2) Thermal conduction was not the dominant process of cooling. Instead, there were alternative
processes of cooling. The thermal contrast to the wall
rock may have induced in the wall-rock dehydration
reactions and possibly even partial melting. Both processes require large amounts of heat and, therefore, act
as sinks (e.g. Fyfe et al., 1978; Walther & Orville, 1982;
Haack & Zimmermann, 1996). Especially the presence
of fluids, and, to a lesser extent, of melts, would allow
for additional rapid heat loss through convection (e.g.
Fyfe et al., 1978). Furthermore, fluids and melts reduce
the rock strength, which is a prerequisite for models that
suggest the Granulite Massif was hydraulically expelled
and intruded into the NW foreland of the Variscan
orogen (e.g. Henk, 1999; Franke & Stein, 2000).
Effect of reaction history on the initial
isotopic composition of geochronometers
The U–Pb system of garnet gives a broad range of
apparent ages, some of which are considerably older
than those of zircon, monazite and titanite (see Figs.
3, 4 and 6) despite textural evidence of a common
crystallization history and age. Such a discrepancy has
been argued elsewhere to be due to inheritance of garnet
from earlier metamorphism (e.g. Erambert & Austrheim,
1993), the presence of inherited zircon or monazite (e.g.
Vance & Holland, 1993; Zhou & Hensen, 1995), or to
reflect the pressure peak (e.g. Chen et al., 1998), whereby
in the last interpretation the younger ages of other
minerals are thought to be associated with the thermal
peak. Textural and mineral-chemical evidence from
sample G97-1 is not compatible with the presence of
inherited garnet from an earlier high-grade metamorphic
event (Rötzler & Romer, 2001). Garnet, however, shows
a distinct compositional variation with higher Ca contents
in its core (see Rötzler & Romer, 2001). An interpretation
that the higher apparent age is related to the pressure
peak of metamorphism is not compatible with the P–T
history of the area and the regional tectonic scenario (e.g.
Franke & Stein, 2000). Inherited zircon could significantly
affect the U–Pb age of garnet if it originates from an
earlier event (e.g. Vance & Holland, 1993; Zhou &
Hensen, 1995). Although large zircon inclusions have
been observed in garnet, there is no evidence for the
presence of submicroscopic zircon inclusions in garnet.
Therefore, the anomalously high U–Pb ages do not
represent a memory from the early geological history of
the investigated granulites. A wide range of U–Pb ages,
as well as anomalously high ages, however, may also be
due to initial isotopic heterogeneities originating from
the reaction history. Garnet has grown over a wide range
of pressure and temperature at the expense of various
phases, such as biotite, aluminium silicates, plagioclase
and ilmenite. During growth, the composition of garnet
as well as the composition and relative contribution of
the consumed phases change. Lead incorporated into
garnet represents the weighted average (or a fraction
thereof ) of the lead made available from the consumed
phases. All these phases may contain trace amounts of
uranium and lead. Most importantly, the U/Pb concentration ratio will differ among the various phases.
Thus, even if all consumed phases originally had the
same lead isotopic composition, they all have developed
individual and contrasting lead isotope compositions by
the time of consumption through the formation of garnet.
The diversity of lead composition thereby is a function
of the range in U/Pb and the time elapsed between
formation and consumption of the individual phases.
Such a dependence on the reaction history of the initial
isotopic composition of garnet has so far not been documented for lead, but is well known for the Sm–Nd system
of garnet, for which—under unfavourable circumstances—it will yield grossly incorrect ages (e.g.
Jagoutz, 1995; Romer & Smeds, 1996). The crucial point
is (analogous to the example of incorrect Sm–Nd ages)
that the source of initial lead in garnet varies with time,
commonly is poorly known, and generally is not accessible
for lead isotope analysis (as these minerals were consumed
during garnet formation). The effect of heterogeneous
initial lead becomes obvious only in samples with low
parent/daughter ratio (P/D), i.e. those samples that even
after a long time show little radiogenic lead. Depending
on reaction history, age of the consumed phases and U/
Pb of the consumed phases, heterogeneous initial lead
may result in an age diversity of >100 my (see Fig. 4) or
only a few million years. Depending on the variation of
the initial lead isotopic composition, apparent ages for
core and rim of garnet may differ. Thereby, it is possible
that the core appears younger than the rim, just as there
are cases where the core appears older than the rim. In
the latter case, the age difference may be used improperly
to deduce growth rates.
This problem of heterogeneous initial lead is also
illustrated by the Th/U systematics of garnet. Calculated
Th/U of garnet range from 0·5 to 6·0 (see Fig. 4b).
Such a wide range cannot be obtained by changes in
distribution coefficient for these two elements. Instead,
it has to be due to contrasting availability of Th and U
during garnet growth. The heterogeneous Th/U reflects
the contrasting nature of reaction partners available for
consumption during garnet formation, and thus indirectly
argues for heterogeneous initial lead.
2027
JOURNAL OF PETROLOGY
VOLUME 42
In a similar manner as for garnet, the scatter of the
lead isotope data, the range in apparent Th/U and the
range in 206Pb/238U age of rutile and apatite may be
entirely due to heterogeneities in the initial lead isotope
signatures of these minerals. For instance, attributing
each rutile fraction an individual initial lead would result
in concordant, internally consistent ages for all three
samples without requiring extreme values for the initial
lead isotope ratios. However, the resulting rutile age can
be ‘adjusted’ (by choice of a suitable initial lead) to any
value between the 342 Ma maximum age given by titanite
and zircon (which would imply that rutile has a closure
temperature for Pb that lies in the same range as that of
zircon) and 323 Ma, i.e. the Rb–Sr age of biotite (which
would imply that rutile remains an open system with
respect to lead until the ambient temperature has fallen
below the closure temperature of biotite). Similarly, there
is textural evidence for two generations of apatite in
sample G97-1. During crystallization, apatite incorporated lead from its precursors and, thus, inherited
their isotopic signature. Although apatite is prone to lose
radiogenic lead at high temperature, it is likely that
initial lead and radiogenic lead behave differently. The
radiogenic lead will occur in the crystal structure on sites
that are damaged by the radioactive decay. The migration
of lead from these sites will need less energy than migration of initial lead that occurs on undamaged structural
sites suited for lead. Thus, it might be speculated that
apatite retains a partial memory of its initial lead, i.e.
the lead isotopic composition of several generations of
apatite that cooled together below the closure temperature of apatite will not necessarily be homogeneous.
This heterogeneity, which will also undoubtedly be present in minerals such as zircon, monazite and xenotime,
will have an insignificant effect on the age of minerals
with high P/D ratios, as the radiogenic lead contribution
will overwhelm any initial heterogeneity given enough
time. In contrast, for minerals that have low P/D ratios,
the contribution of radiogenic lead will remain modest
and the initial heterogeneities will remain apparent.
Age constraints for tectonic models
Early tectonic models for the formation of the Saxon
granulites (e.g. Weber & Behr, 1983; Franke, 1993) discuss
the high-temperature granulite-facies metamorphism in
an Ordovician extensional setting (heat source through
upwelling mantle) and subsequent exhumation as a metamorphic core complex in an extensional setting. These
models rely heavily on (1) the wide range of age data
obtained on granulites, whereby most minerals started
to retain their radiogenic isotopes not before
>340–350 Ma, and (2) the necessity of a mantle-derived
heat source, which could become available in an
NUMBER 11
NOVEMBER 2001
extensional setting, to obtain the high temperature of
granulite-facies metamorphism. However, we find no
evidence for two metamorphic events or slow cooling
from an Ordovician UHT event to a Variscan granulitefacies metamorphism. Instead, there is only evidence for
one UHT event that lasted only a few million years, i.e.
hardly longer than the geochronological resolution.
There are two types of garnet, relict Ca-rich garnet
cores and re-equilibrated Ca-poor garnet. The chemical
range between the two garnets reflects release of Ca in
response to decompression (Rötzler & Romer, 2001).
The high-pressure peak conditions in sample G97-1 are
given by the assemblage garnet + kyanite + ternary
feldspar + quartz, whereby the Ca-rich garnet is part
of this assemblage. Zircon also is part of this assemblage.
Furthermore, titanite from the garnet–clinopyroxene rock
(G97-3) is part of the peak metamorphic assemblage and
yields the same Variscan age as zircon in sample G971. Thus, there is no indication for a preserved Ordovician
metamorphic history in the investigated granulite
samples.
U–Pb zircon ages from the Saxon granulites fall in a
small age range (e.g. von Quadt, 1993; Nasdala et al.,
1996; Kröner et al., 1997, 1998; this paper) and do not
require a long or complex metamorphic history. The
large range in age data mainly originates from Sm–Nd
mineral isochrons (470–340 Ma). As seen in the previous
section, and argued by Jagoutz (1995), the initial Nd
isotopic composition of the various metamorphic phases
depends on the metamorphic reaction history and does
not necessarily have to be the same for all metamorphic
minerals. As a consequence, an ‘isochron’ defined by
these phases initially may have a positive or negative
slope (e.g. Jagoutz, 1995; Romer & Smeds, 1996) that
translates into ages that are too old and young, respectively. Thus, the range in ages attributed to the UHT
metamorphism possibly originates to a significant part
from unfavourably suited samples. A comparison of age
data from the UHT Saxon granulites with other Variscan
granulites in the Bohemian Massif shows that U–Pb
zircon age data fall in a small range [e.g. Gföhl assemblage: 337–345 Ma (van Breemen et al., 1982; Schenk
& Todt, 1983; Friedl et al., 1994)], whereas age data
obtained by other methods show a considerably larger
spread (e.g. Beard et al., 1992; Becker, 1993; von Quadt,
1993). Again, we interpret this spread in Sm–Nd ages as
due to the lack of initial isotopic homogeneity among the
phases used for mineral isochrons. Thus, the anomalous
Sm–Nd ages in the Saxon granulites and the other
Variscan granulites of the Bohemian massif should not
be interpreted in terms of a prolonged metamorphic
history, memory of earlier stages of metamorphism, or
low-temperature mobility of Sm and Nd (for the ages
that are too young). Instead, these anomalous ages should
be seen as what they are, the unfortunate analytical results
2028
ROMER AND RÖTZLER
UHT GRANULITES IN SAXONY: GEOCHRONOLOGY
from samples that do not fulfil the initial requirements for
an isochron, i.e. the same initial isotopic composition at
the same time for all phases used to define the isochron.
Petrological and geochronological data demonstrate
that there was only one UHT event, and that the UHT
rocks were exhumed quickly after 340 Ma. In contrast,
sedimentological studies have shown a rather undisturbed
sedimentary record in the orogenic foreland until 334 Ma,
which implies that there was no significant change in
topographic relief until 334 Ma (see Franke & Stein,
2000). This apparent conflict was resolved in a series of
models that have in common fast later transport with
subsequent diapiric rise of the Saxon granulites (e.g.
Henk, 1999; DEKORP Working Group, 1999), but
differed in the source of the protoliths. As the interpretation of the Saxon granulites as resurfaced material
from the subducted Rhenohercynian plate does not work
because of isotope geochemical reasons ( Jaeckel et al.,
1999), the model favoured at present suggests a derivation
of the Saxon granulites from the Saxothuringian orogenic
root to the SE of its present position by ‘hydraulic
expulsion’ and subsequent diapiric rise (Henk, 1999;
DEKORP Working Group, 1999; Franke & Stein, 2000).
The Saxon granulites are not the only Variscan UHT
rocks within the Bohemian Massif. Furthermore, HT
and UHT rocks within the Bohemian Massif do not
represent small isolated, individual occurrences, but encompass huge volumes of rock, all of which are characterized by fast rates of exhumation to a middle- and
upper-crustal level. Reliable U–Pb age data from these
massifs fall in a narrow age range from 345 to 337 Ma
for the HT and UHT metamorphism (van Breemen et
al., 1982; Schenk & Todt, 1983; Friedl et al., 1994).
Tectonic models for the evolution of the Saxon granulites,
therefore, not only have to explain the fast exhumation
history of this massif at the northern border of the
Bohemian Massif, but also the occurrence and exhumation of coeval HT and UHT metamorphic rocks
throughout the Bohemian massif.
SUMMARY
Granulite-facies rocks in the structurally lower part of
the Saxon Granulite Massif, Germany, experienced
UHT–HP metamorphism during the Variscan orogeny.
We sampled a sapphirine-bearing granulite (G97-1), a
retrogressed felsic granulite (G97-2) and a garnet–
clinopyroxene rock (G97-3), all collected within 1 km
along a railway track near Waldheim, to reconstruct the
P–T path and to constrain the age of the metamorphism
and exhumation of this granulite complex.
P–T data derived from mineral assemblages of two
samples in accordance with earlier estimates demonstrate
that metamorphism in the Saxon Granulite Massif culminated in UHT–HP conditions of 1010–1060°C and
>22 kbar (Rötzler & Romer, 2001). Mineral assemblages
related to the UHT–HP metamorphism and retrograde
assemblages related to the exhumation of the Granulite
Complex define a clockwise P–T loop, where UHT
conditions persisted even after a significant pressure drop.
Retrograde hydrous phases are characteristic once the
rocks have reached low pressure.
The U–Pb age of concordant zircon (G97-1) at 341·5
± 0·8 Ma (2) and concordant titanite (G97-3) at 342·0
± 0·8 Ma (2) are interpreted as formation ages. As
titanite in sample G97-3 is part of the mineral assemblage
defining metamorphic peak conditions, this age corresponds to the metamorphic pressure peak. U–Pb monazite data (G97-1) are slightly discordant and yield a
weighted 207Pb/206Pb minimum age at 338·0 ± 0·5 Ma
(2). The U–Pb ages of zircon, titanite and monazite
demonstrate (1) fast exhumation of the Granulite Complex during the first 2–4 my after the pressure peak at
an average rate of 9–18 mm/yr and fast cooling at an
average rate of 25–50°C/my and (2) that the temperature
for isotopic closure of titanite in systems of low aH2O is in
the same range as that of zircon and higher than that of
monazite.
The Rb–Sr biotite age (G97-2) at 323·0 ± 2·3 Ma
(2) demonstrates that the average exhumation and
cooling rates of the Granulite Complex dropped
significantly for the segment bracketed by the age of
monazite and biotite. Depending on the values chosen
for isotopic closure exhumation rates range from
2 to <0·2 mm/y and cooling rates range from 40 to
20°C/my.
Rutile, garnet and apatite (all G97-1) have little radiogenic lead and yield a broad range in apparent 206Pb/
238
U ages. This age range is a characteristic feature of
metamorphic minerals with low parent/daughter ratio
and is explained as being due to initial isotopic heterogeneity of these minerals. The initial isotopic heterogeneity is the result of the reaction history of the sample,
may cause anomalously high or low ages, and eventually
precludes the use of low-P/D minerals as precise geochronometers.
ACKNOWLEDGEMENTS
We thank M. Boche and J. Müller for help with the
mineral separation, and M. Dziggel (GFZ Potsdam) for
drawing the final version of the geological map. R.L.R.
thanks Ralf Hetzel (GFZ) for discussion and constructive
comments on the manuscript. We gratefully acknowledge
constructive reviews by W. Franke, N. Machado and A.
von Quadt, as well as thoughtful editorial handling by
P. Kempton. Sampling was financially supported by
2029
JOURNAL OF PETROLOGY
VOLUME 42
DFG-Grant KE 552/2-3. Analytical work was performed
at GeoForschungsZentrum Potsdam.
REFERENCES
Aranovich, L. Ya. & Newton, R. C. (1996). H2O activity in concentrated
NaCl solutions at high pressures and temperatures measured by the
brucite–periclase equilibrium. Contributions to Mineralogy and Petrology
125, 200–212.
Aranovich, L. Ya. & Newton, R. C. (1997). H2O activity in concentrated
KCl solutions at high pressures and temperatures measured by the
brucite–periclase equilibrium. Contributions to Mineralogy and Petrology
127, 261–271.
Armstrong, R. L., Jäger, E. & Eberhardt, P. (1966). A comparison of
K–Ar and Rb–Sr ages on Alpine biotites. Earth and Planetary Science
Letters 1, 13–19.
Baumann, N., Pilot, J., Werner, C.-D. & Todt, W. (1997). Zur Geochronologie und Isotopengeochemie des Sächsischen Granulitgebirges. Terra Nostra 97(5), 19–22.
Beard, B. L., Medaris, L. G., Jr, Johnson, C. M., Bruecker, H. K. &
Misar, Z. (1992). Petrogenesis of Variscan high-temperature Group
A eclogites from the Moldanubian Zone of the Bohemian Massif,
Czechoslovakia. Contributions to Mineralogy and Petrology 111, 468–483.
Becker, H. (1993). Contrasting origin of Variscan high-P granulites
and high-T peridotites (Bohemian Massif ): evidence from Sm–Nd
garnet ages. Terra Abstracts 5, 380.
Brooks, C. K. (1969). On the distribution of zirconium and hafnium
in the Skaergaard Intrusion, East Greenland. Geochimica et Cosmochimica Acta 33, 357–374.
Chakraborty, S. (1997). Rates and mechanisms of Fe–Mg interdiffusion
in olivine at 980 degrees–1300 degrees C. Journal of Geophysical
Research B102, 12317–12331.
Chakraborty, S. & Ganguly, J. (1990). Compositional zoning and cation
diffusion in aluminosilicate garnets. In: Ganguly, J. (ed.) Diffusion,
Atomic Ordering and Mass Transfer. Advances in Physical Geochemistry, 8.
Heidelberg: Springer, pp. 120–175.
Chen, F., Hegner, E. & Todt, W. (1998). Garnet dating of granulites
from the Variscan foldbelt in Central Europe; evidence for early and
pre-Variscan high grade metamorphism. Acta Universitatis Carolinae,
Geologica 42, 221–222.
Cherniak, D. (1995). Lead diffusion in titanite and preliminary results
on the effects of radiation damage on Pb transport. Chemical Geology
110, 177–194.
Cherniak, D. (2000). Pb diffusion in rutile. Contributions to Mineralogy and
Petrology 139, 198–207.
Cherniak, D., Lanford, W. A. & Ryerson, F. J. (1991). Lead diffusion
in apatite and zircon using ion implantation and Rutherford backscattering techniques. Geochimica et Cosmochimica Acta 55, 1663–1673.
Copeland, P., Parrish, R. R. & Harrison, T. M. (1988). Identification
of inherited radiogenic Pb in monazite and implications for U–Pb
systematics. Nature 333, 760–763.
Dahl, P. S. (1997). A crystal-chemical basis for Pb retention and fissiontrack annealing systematics in U-bearing minerals, with implications
for geochronology. Earth and Planetary Science Letters 150, 277–290.
DEKORP Working Group (1999). Structure of the Saxonian granulites:
geological and geophysical constraints on the exhumation of highpressure/high-temperature rocks in the mid-European Variscan belt.
Tectonics 18, 756–773.
Dodson, H. M. (1973). Closure temperature in cooling geochronological
and petrological systems. Contributions to Mineralogy and Petrology 40,
259–274.
NUMBER 11
NOVEMBER 2001
Duchêne, S., Lardeaux, J.-M. & Albarède, F. (1997). Exhumation of
eclogites: insights from depth–time path analysis. Tectonophysics 280,
125–140.
England, P. C. & Thompson, A. B. (1984). Pressure–temperature–time
paths of regional metamorphism. I. Heat transfer during the evolution
of regions of thickened continental crust. Journal of Petrology 25,
894–928.
Erambert, M. & Austrheim, H. (1993). The effect of fluid and deformation on zoning and inclusion patterns in poly-metamorphic
garnets. Contributions to Mineralogy and Petrology 115, 204–214.
Ewart, A. & Griffin, W. L. (1994). Application of proton-microprobe
data to trace-element partitioning in volcanic rocks. Chemical Geology
117, 251–284.
Franke, W. (1993). The Saxonian Granulites: a metamorphic core
complex? Geologische Rundschau 82, 505–515.
Franke, W. & Stein, E. (2000). Exhumation of high-grade rocks in
the Saxo-Thuringian belt: geological constraints and geodynamic
concepts. In: Franke, W., Haak, V., Oncken, O. & Tanner, D. (eds)
Orogenic Processes: Quantification and Modelling in the Variscan Belt. Geological
Society, London, Special Publications 179, 337–354.
Friedl, G., von Quadt, A. & Finger, F. (1994). 340 Ma U/Pb Monazitalter aus dem niederösterreichischen Moldanubikum und ihre
geologische Bedeutung. Terra Nostra 94(3), 43–46.
Fyfe, W. S., Price, N. J. & Thompson, A. B. (1978). Fluids in the Earth’s
Crust. Amsterdam: Elsevier.
Gebauer, D. (1990). Isotopic systems—geochronology of eclogites. In:
Carswell, D. A. (ed.) Eclogite Facies Rocks. New York: Blackie, pp.
141–158.
Gebauer, D. (1997). 35 Ma old ultrahigh-pressure metamorphism and
evidence for very rapid exhumation in the Dora Maira Massif,
Western Alps. Lithos 41, 5–24.
Grasemann, B., Ratschbacher, L. & Hacker, B. R. (1998). Exhumation
of ultrahigh-pressure rocks: thermal boundary conditions and cooling
history. In: Hacker, B. R. & Liou, J. G. (eds) When Continents Collide:
Geodynamics and Geochemistry of Ultrahigh-Pressure Rocks. Dordrecht:
Kluwer Academic, pp. 117–139.
Grew, E. S. (1986). Petrogenesis of kornerupine at Waldheim (Sachsen),
German Democratic Republic. Zeitschrift für Geologische Wissenschaften
14, 525–558.
Grew, E. S. (1989). A second occurrence of kornerupine in Waldheim,
Saxony, German Democratic Republic. Zeitschrift für Geologische Wissenschaften 17, 67–76.
Haack, U.K. & Zimmermann, H. D. (1996). Retrograde mineral
reactions: a heat source in the continental crust? Geologische Rundschau
85, 130–137.
Hagen, B., Hoernes, S. & Rötzler, J. (1995). Consistent ultra-high
temperatures in the Saxonian granulite massif as deduced from
cation exchange and O-isotope thermometry. Terra Abstracts 7, 340.
Henk, A. (1999). Modelling lower crustal extrusion in the Saxothuringian belt. Terra Nostra 99(1), 100.
Hill, E. J. & Baldwin, S. L. (1993). Exhumation of high-pressure
metamorphic rocks during crustal extension in the D’Entrecasteaux
region, Papua New Guinea. Journal of Metamorphic Geology 11, 261–277.
Hofmann, A. W. & Giletti, B. J. (1970). Diffusion of geochronological
important nuclides in minerals under hydrothermal conditions. Eclogae Geologicae Helvetiae 63, 141–150.
Jaeckel, P., Anthes, G., Molzahn, M., Oncken, O. & Reischmann, T.
(1999). Pb isotopic systematics of the central Variscan belt. Terra
Nostra 99(1), 111–112.
Jaffey, A. H., Flynn, K. F., Glendenin, L. E., Bentley, W. C. & Essling,
A. M. (1971). Precision measurement of half-lives and specific
activities of 235U and 238U. Physics Review C4, 1889–1906.
2030
ROMER AND RÖTZLER
UHT GRANULITES IN SAXONY: GEOCHRONOLOGY
Jäger, E. (1973). Die alpine Orogenese im Lichte der radiometrischen
Altersbestimmung. Eclogae Geologicae Helvetiae 66, 11–21.
Jagoutz, E. (1995). Isotopic constraints on garnet equilibration. Terra
Abstracts 7(1), 339.
Kamber, B. S., Frei, R. & Gibb, A. J. (1998). Pitfalls and new approaches
in granulite chronometry—an example from the Limpopo Belt,
Zimbabwe. Precambrian Research 91, 269–285.
Krogh, T. (1973). A low-contamination method for hydrothermal
decomposition of zircon and extraction of U and Pb for isotopic
age determinations. Geochimica et Cosmochimica Acta 37, 485–494.
Kroner, U. (1995). Postkollisionale Extension am Nordrand der Böhmischen Masse: Die Exhumierung des Sächsischen Granulitgebirges.
Freiberger Forschungshefte C457, 1–114.
Kröner, A., O’Brien, P. J. & Pidgeon, R. J. (1997). Carboniferous high,
medium and low pressure metamorphism in granulites from the
South Bohemia confirmed by SHRIMP zircon ages. Terra Nova
(Abstract Supplement 1) 9, 495.
Kröner, A., Jaeckel, P., Reischmann, T. & Kroner, U. (1998). Further
evidence for an early Carboniferous (>340 Ma) age of high-grade
metamorphism in the Saxonian granulite complex. Geologische Rundschau 86, 751–766.
Kühn, A., Glodny, J., Iden, K. & Austrheim, H. (2000). Retention of
Precambrian Rb/Sr phlogopite ages through Caledonian eclogite
facies metamorphism, Bergen Arc Complex, W-Norway. Lithos 51,
305–330.
Lasaga, A. C. (1981). The atomistic basis of kinetics: defects in minerals.
In: Lasaga, A. C. & Kirkpatrick, R. J. (eds) Kinetics of Geochemical
Processes. Mineralogical Society of America, Reviews in Mineralogy 8, 261–319.
Ludwig, K. R. (1994). ISOPLOT 2.71: a plotting and regression
program for radiogenic-isotope data. US Geological Survey Open-File
Report 91-445, 44 pp.
Manhès, G., Minster, J. F. & Allègre, C. J. (1978). Comparative
uranium–thorium–lead and rubidium–strontium study of the Saint
Séverin amphibolite: consequences for early solar system chronology.
Earth and Planetary Science Letters 39, 14–24.
Mattinson, J. M. (1973). Anomalous isotopic composition of lead in
young zircons. Carnegie Institution of Washington Yearbook 72, 613–616.
McKay, G. A., Wagstaff, J. & Yang, S.-R. (1986). Zirconium, hafnium,
and rare earth element partition coefficients for ilmenite and other
minerals in high-Ti lunar mare basalts: an experimental study.
Proceedings of the 16th Lunar and Planetary Science Conference. Journal of
Geophysical Research Supplement 97, D226–D237.
Mezger, K. & Krogstad, E. J. (1997). Interpretation of discordant U–Pb
zircon ages: an evaluation. Journal of Metamorphic Geology 15, 127–140.
Mezger, K., Hanson, G. N. & Bohlen, S. R. (1989). High-precision
U–Pb ages of metamorphic rutile: application to the cooling history
of high-grade terranes. Earth and Planetary Science Letters 96, 106–118.
Mezger, K., Rawnsley, C. M., Bohlen, S. R. & Hanson, G. N. (1991).
U–Pb garnet, sphene, monazite, and rutile ages: implications for
the duration of high-grade metamorphism and cooling histories,
Adirondacks Mts., New York. Journal of Geology 99, 415–428.
Nam, T. N., Toriumi, M. & Itaya, T. (1998). P–T–t paths and postmetamorphic exhumation of the Day Nui Con Voi shear zone in
Vietnam. Tectonophysics 290, 299–318.
Nasdala, L., Gruner, T., Nemchin, A. A., Pidgeon, R. T. & Tichomirowa, M. (1996). New SHRIMP ion microprobe measurements
on zircons from Saxonian magmatic and metamorphic rocks. Freiberger Isotopenkolloquium 1996, Proceedings. Freiberg: Freiberg University
of Mining and Technology. pp. 205–214.
Nasdala, L., Wenzel, M., Vavra, G., Irmer, G., Wenzel, T. & Kober,
B. (2001). Metamictisation of natural zircon: accumulation versus
thermal annealing of radioactivity-induced damage. Contributions to
Mineralogy and Petrology 141, 125–144.
O’Brien, P. J. (1997). Garnet zoning and reaction textures in overprinted
eclogites, Bohemian Massif, European Variscides; a record of their
thermal history during exhumation. Lithos 41, 119–133.
Parrish, R. R. (1990). U–Pb dating of monazite and its application to
geological problems. Canadian Journal of Earth Sciences 27, 1431–1450.
Reinhardt, J. & Kleemann, U. (1994). Extensional unroofing of granulitic lower crust and related low-pressure, high-temperature metamorphism in the Saxonian Granulite Massif, Germany. Tectonophysics
238, 71–94.
Reinhardt, J. & Vavra, G. (1997). Petrological and geochronological
constraints on the tectonometamorphic history of the Saxonian
Granulite Massif. Terra Nostra 97(5), 137–139.
Romer, R. L. (1996). U–Pb systematics of stilbite-bearing low-temperature mineral assemblages from the Malmberget iron ore, northern Sweden. Geochimica et Cosmochimica Acta 60, 1951–1961.
Romer, R. L. & Smeds, S.-A. (1996). U–Pb columbite ages of pegmatites
from Sveconorwegian terranes in southwestern Sweden. Precambrian
Research 76, 15–30.
Rötzler, J. (1992). On the petrogenesis in the Saxon granulite massif
(in German, with English abstract). Geotektonische Forschungen 77,
1–100.
Rötzler, J. & Romer, R. L. (2001). P–T–t evolution of ultrahightemperature granulites from the Saxon Granulite Massif, Germany.
Part I: Petrology. Journal of Petrology 42, 1995–2013.
Rötzler, J., Budzinski, H. & Budzinski, G. (1994). Evidence for Early
Variscan very high temperature (>1000°C)–high pressure metamorphism of garnet–clinopyroxene granulites in the Saxon granulite
massif, Germany. European Journal of Mineralogy 6, Supplement 1,
234.
Santos Zalduegi, J. F., Schärer, U., Ibarguchi, J. I. G. & Girardeau,
J. (1996). Origin and evolution of the Paleozoic Cabo Ortegal
ultramafic–mafic complex (NW Spain): U–Pb, Rb–Sr and Pb–Pb
isotope data. Chemical Geology 129, 281–304.
Schärer, U. (1984). The effect of initial 230Th disequilibrium on young
U–Pb ages: the Makalu case, Himalaya. Earth and Planetary Science
Letters 67, 191–204.
Schenk, V. & Todt, W. (1983). U–Pb Datierungen an Zirkon und
Monazit der Granulite im Moldanubikum Niederösterreichs (Waldviertel). Forschritte der Mineralogie 61, Beiheft 1, 190–191.
Smith, H. A. & Giletti, B. J. (1997). Lead diffusion in monazite.
Geochimica et Cosmochimica Acta 61, 1047–1055.
Steiger, R. H. & Jäger, E. (1977). Subcommission of geochronology:
convention on the use of decay constants in geo- and cosmochronology. Earth and Planetary Science Letters 36, 359–362.
Stüwe, K. & Sandiford, M. (1995). Mantle–lithospheric deformation
and crustal metamorphism with some speculations on the thermal
and mechanical significance of the Tauern Event, Eastern Alps.
Tectonophysics 242, 115–132.
Tilton, G. R. (1973). Isotopic lead ages of chondritic meteorites. Earth
and Planetary Science Letters 19, 321–329.
van Breemen, O., Aftalion, M., Bowes, D. R., Dudek, A., Misar, Z.,
Povondra, P. & Vrana, S. (1982). Geochronological studies of the
Bohemian Massif, Czechoslovakia, and their significance in the
evolution of Central Europe. Transactions of the Royal Society of Edinburgh,
Earth Sciences 73, 89–108.
Vance, D. & Holland, T. B. H. (1993). A detailed isotopic and
petrological study of a single garnet from the Gassetts Schist,
Vermont. Contributions to Mineralogy and Petrology 114, 101–118.
Vavra, G., Gebauer, D. & Schmid, R. (1994). Zircon growth and
recrystallization during granulite facies metamorphism in the Ivrea
Zone (Southern Alps): a combined cathodoluminescence and ion
microprobe study. Journal of the Czech Geological Society 39(1), 114–116.
2031
JOURNAL OF PETROLOGY
VOLUME 42
Vavra, G., Reinhardt, J., Todt, W. & Pidgeon, R. T. (1998). Dating of
exhumation of a hot core complex (Saxonian Granulite Massif )—old
prejudices and new perspectives of U–Pb dating of zircons and
monazite. Freiberger Forschungshefte C471, 226–228.
Vavra, G., Reinhardt, J. & Pidgeon, R. T. (1999). Lower Carboniferous
(340 Ma) HP/HT-metamorphism and rapid exhumation of the
Saxonian Granulite Massif. Terra Nostra 99(1), 203.
Villa, I. M. (1998). Isotopic closure. Terra Nova 10, 42–47.
von Quadt, A. (1993). The Saxonian Granulite Massif: new aspects
from geochronological studies. Geologische Rundschau 82, 516–530.
Walther, J. V. & Orville, P. M. (1982). Volatile production and transport
in regional metamorphism. Contributions to Mineralogy and Petrology 79,
252–257.
NUMBER 11
NOVEMBER 2001
Watson, E. B., Harrison, T. M. & Ryerson, F. J. (1985). Diffusion of
Sm, Sr, and Pb in fluorapatite. Geochimica et Cosmochimica Acta 49,
813–823.
Weber, K. & Behr, H.-J. (1983). Geodynamic interpretation of the
Mid-European Variscides. In: Martin, H. & Eder, F. W. (eds)
Intracontinental Fold Belts. Berlin: Springer, pp. 427–469.
Zhang, L.-S. & Schärer, U. (1996). Inherited Pb components in
magmatic titanite and their consequence for the interpretation of
U–Pb ages. Earth and Planetary Science Letters 138, 57–65.
Zhou, B. & Hensen, B. J. (1995). Inherited Sm/Nd isotope components
preserved in monazite inclusions within garnets in leucogneiss from
East Antarctica and implications for closure temperature studies.
Chemical Geology 121, 317–326.
2032