Geological Survey of Denmark and Greenland Bulletin 6, 67-76


67Geological Survey of Denmark and Greenland Bulletin 6, 67–76         © GEUS, 2004

Reconnaissance Pb-Pb dating of single mineral phases by
the step-leaching method: results from the Caledonides of
East Greenland

Kristine Thrane

Reconnaissance Pb-Pb step-leaching analyses have been carried out on garnet and kyanite from
the Krummedal supracrustal sequence in East Greenland, yielding respectively Neoproterozoic
and Caledonian ages. These data support previous analyses suggesting that the Krummedal
supracrustal sequence, widespread in southern parts of the East Greenland Caledonides, was
affected by both an early Neoproterozoic and a Caledonian thermal event. Titanite and apatite
fractions from the underlying crystalline basement rocks were analysed in order to obtain meta-
morphic ages, as a contrast and supplement to the numerous existing protolith ages on ortho-
gneisses. The titanite yielded a date of 486 ± 15 Ma which, if interpreted as a true age, is older
than the usual range of Caledonian ages in East Greenland. The significance of this date is
uncertain, but one possibility is that it reflects extension and subsidence taking place prior to
Caledonian collision. The apatite, in contrast, yielded a very young Caledonian date of 392 ± 24
Ma that may reflect the cooling of the basement gneisses to < 500°C subsequent to collision.

Keywords: Caledonian, East Greenland, geochronology, Neoproterozoic, step-leaching

Geological Survey of Denmark and Greenland, Øster Voldgade 10, DK-1350 Copenhagen K, Denmark. Present
address: Geological Institute, University of Copenhagen, Øster Voldgade 10, DK-1350 Copenhagen K, Denmark. E-
mail: Kthrane@geol.ku.dk

The Pb-Pb step-leaching (PbSL) method of Frei &
Kamber (1995) makes it possible to date a range of
rock-forming minerals that are normally difficult to
date due to the low parent to daughter isotope ratios.
Stepwise leaching of the mineral phases increases the
data spread in uranogenic (207Pb/204Pb – 206Pb/204Pb)
and thorogenic vs. uranogenic (208Pb/204Pb – 206Pb/
204Pb) diagrams, and as a consequence the precision
of Pb/Pb isochrons is improved (Frei et al. 1997).
Another advantage of the method is that the corre-
sponding uranogenic and thorogenic Pb ratios of the
different leach solutions can be observed, and a sig-
nature of Pb-containing microscopic mineral inclusions
revealed. Leach solutions that do not follow a linear
pattern in the 208Pb/204Pb vs. 206Pb/204Pb diagram re-
veal sources with different Th/U ratio from that of the
host mineral. If all the analyses fall on a linear trend

in the uranogenic diagram then the mineral inclusions
are in isotopic equilibrium with the host mineral.

Investigations by the PbSL method were undertaken
on selected samples collected during the 1997 and
1998 Geological Survey of Denmark and Greenland
expeditions to the Kong Oscar Fjord region (72°–75°N)
of the East Greenland Caledonides (Henriksen 1998,
1999). The study area (Fig. 1) is made up of major
Caledonian thrust sheets displaced westwards across
foreland windows (see also Higgins & Leslie 2004,
this volume; Thrane 2004, this volume). The thrust
sheets incorporate Archaean and Palaeoproterozoic
orthogneiss complexes overlain by a thick late Meso-
proterozoic – early Neoproterozoic metasedimentary
succession known as the Krummedal supracrustal se-
quence; the latter is structurally overlain by the Neo-
proterozoic Eleonore Bay Supergroup and Tillite

GEUS Bulletin 6.pmd 10-02-2005, 09:5467



68

Group, and Lower Palaeozoic rocks. These rock units
have been variably reworked during the Caledonian
orogeny.

Samples
In this study, PbSL analyses were carried out on gar-
net and kyanite from samples 426050 and 422766 of
the late Mesoproterozoic – early Neoproterozoic Krum-
medal supracrustal sequence (Kalsbeek et al. 2000),
with the objective of constraining the age of meta-
morphism which produced these minerals. In addi-
tion, PbSL analyses were undertaken on titanite from
a garnet amphibolite (426037) and a gabbroic gneiss
(426018), and on an apatite fraction from a tonalitic
basement gneiss (426008). The latter three samples all
derive from the crystalline basement complex under-

lying the Krummedal supracrustal sequence (Fig. 1),
and the aim was to determine metamorphic ages for
the mineral phases in the samples. Whole-rock Pb
analyses were also carried out on samples 426008,
426018 and 426050.

Zircon grains from the crystalline basement com-
plex in the study area analysed by ion microprobe
have hitherto only yielded Archaean and Palaeoprot-
erozoic magmatic ages. Although the rocks form parts
of Caledonian thrust sheets and have undergone ex-
tensive Caledonian deformation and metamorphism,
so far not a single Caledonian age has been obtained
from zircon (Thrane 2002). While Caledonian K-Ar
mineral ages have previously been recorded from all
rock types in the study area (e.g. Rex & Higgins 1985),
the spread in ages and uncertainties inherent in the
method is indicative only of a metamorphic overprint
of approximately Caledonian age.

27

27º

Nathorst LandCharcot
Land

Gletscher-
land

Suess Land

Andrée Land

C
A

LE
D

O
N

IA
N

 F
O

LD
 B

EL
T

Archaean mainly gneiss
complexes

Palaeoproterozoic mainly
gneiss complexes

Neoproterozoic (Eleonore
Bay Supergroup) to Ordovician

Caledonian granites

Post-Caledonian

Mesoproterozoic Krummedal
supracrustal sequence

72º

426008

426018

426050

422766

50 km

Extensional fault

Archaean–Palaeoproterozoic
boundary

Thrust

Detachment

456037

FF

Fig. 1. Simplified geological map of the study area in the East Greenland Caledonides, with sample localities discussed in the text.
Supracrustal rocks of Palaeoproterozoic age in Charcot Land are included with the Palaeoproterozoic gneiss complexes. FF, Forsblad
Fjord.

GEUS Bulletin 6.pmd 10-02-2005, 09:5468



69

Methods
For the samples analysed in the present study, a 200
mm sieve fraction of each mineral separate was puri-
fied by hand-picking. The samples were digested in a
series of steps using procedures documented in Table
1; the method used was modified after that of Berger
& Braun (1997) and Frei et al. (1997). The purified Pb
was loaded on Re filaments with silica gel and H

3
PO

4,

and the isotopic ratios analysed on the VG sector 54-
IT instrument at the University of Copenhagen. Most
analyses were performed using the Faraday multi-col-
lector; a few steps that contained very little Pb were
analysed with the single collector (ion counting Daly
detector). Fractionation of Pb was monitored by re-
peated analyses of the NBS 981 standard (values of
Todt et al. 1993) and amounted to 0.103 ± 0.016 %/
amu. The calculations of regression lines follow the
method of Ludwig (1999). Errors quoted are 2 F.

Five to seven acid-leach steps were undertaken on
each mineral separate. Whole-rock Pb and PbSL iso-
tope data are listed in Table 2 and plotted in Figs 2–5.

PbSL results

Krummedal supracrustal sequence
The late Mesoproterozoic – early Neoproterozoic
Krummedal supracrustal sequence is widely distribu-
ted in the southern part of the East Greenland Cale-
donides between 70° and 74°N (Fig. 1; Higgins 1988).

Sample 426050 was collected from the Krummedal
supracrustal sequence south of innermost Forsblad
Fjord, close to the faulted contact with the crystalline
basement complexes (Fig. 1). The general metamor-
phic grade of the Krummedal supracrustal sequence
is amphibolite facies, and the sample consists of quartz
+ plagioclase + K-feldspar + garnet + biotite + kyanite
+ sillimanite + amphibole + muscovite + titanite. The
garnet and biotite represent early phases, while kyanite
is a later phase that overgrows the deformation fabric
of the biotite. Kyanite and K-feldspar crystallised at
the same time, demonstrating that the rock has been
exposed to high P–T conditions; during cooling, silli-
manite, titanite and secondary biotite crystallised, and
part of the kyanite was consumed during formation
of muscovite.

Garnet and kyanite were analysed by PbSL (Fig. 2).
Seven steps were performed on the garnet; all the
steps, together with the whole-rock analysis, fall on a
linear array in the 207Pb/204Pb vs. 206Pb/204Pb diagram

Table 1. Sample data stepwise dissolution procedures

Mix = 1.5N HBr – 2N HCl 12:1 mixture. All steps except number 1 were left on the hotplate during the dissolution time.

 236 Mix 10 4.4N HBr 45 8.8N HBr 3 8.8N HBr 24 conc. HF 48 conc. HF 260 8.8N HBr 290

 97 Mix 10 4.4N HBr 45 8.8N HBr 3 8.8N HBr 24 conc. HF 48 conc. HF 260

 719 Mix 30 1.0N HBr 60 4.0N HBr 3 8.8N HBr 6 8.8N HBr 12 conc. HF 24 conc. HF 340

 195 Mix 10 4.4N HBr 45 8.8N HBr 3 8.8N HBr 24 conc. HF 48 conc. HF 260

 71 Mix 10 4.4N HBr 90 8.8N HBr 3 8.8N HBr 24 conc. HF 50 conc. HF 340

 139  10  60 1.0N HBr 3 1.5N HBr 3 8.8N HBr 3 7N HNO
3
 9

    

Sample Weight Step 1 Time Step 2 Time Step 3 Time Step 4 Time Step 5 Time Step 6 Time Step 7 Time
 mg  min.  min.  hrs  hrs  hrs  hrs  hrs 

426050
Garnet

426050
Kyanite

422766
Kyanite

426018
Titanite

426037
Titanite

426008 50% mix + 50% mix +
Apatite 50% H

2
O 50% H

2
O

GEUS Bulletin 6.pmd 10-02-2005, 09:5469



70

Table 2. Pb-Pb step leaching (PbSL) data

Sample Phase Step 206Pb/204Pb   ± 2 σ* 207Pb/204Pb ± 2 σ* 208Pb/204Pb ± 2 σ* r1 r2

426050 Wr  19.39 0.01 15.65 0.01 38.91 0.03 0.96 0.93
426008 Wr  14.32 0.01 14.61 0.01 38.51 0.03 0.93 0.92
426018 Wr  17.10 0.04 15.13 0.04 37.76 0.09 0.99 0.98

426050 Grt 1 23.34 0.64 16.01 0.44 39.09 1.08 1.00 1.00
426050 Grt 2 29.02 0.75 16.34 0.43 43.66 1.14 0.97 0.98
426050 Grt 3 69.99 1.99 18.74 0.53 116.25 3.30 1.00 1.00
426050 Grt 4 272.79 6.53 32.93 0.79 436.00 10.43 1.00 1.00
426050 Grt 5 99.56 1.31 20.49 0.27 44.90 0.59 1.00 1.00
426050 Grt 6 139.41 0.74 23.99 0.13 57.17 0.31 1.00 1.00
426050 Grt 7 152.05 4.39 24.48 0.71 87.67 2.53 1.00 1.00

426050 Ky 1 19.53 0.06 15.66 0.05 38.17 0.11 0.99 0.98
426050 Ky 2 20.45 0.14 15.70 0.11 38.52 0.27 0.99 1.00
426050 Ky 3 24.26 0.23 15.82 0.15 47.05 0.44 0.99 0.99
426050 Ky 4 34.83 0.16 16.42 0.08 65.68 0.31 0.99 0.99
426050 Ky 5 20.00 0.02 15.70 0.02 38.09 0.05 0.95 0.94
426050 Ky 6 33.13 0.19 16.49 0.10 38.81 0.22 0.99 0.99

422766 Ky 1 18.23 0.05 15.49 0.04 37.96 0.10 0.99 0.98
422766 Ky 2 19.92 0.16 15.64 0.12 40.81 0.32 0.99 1.00
422766 Ky 3 42.22 0.52 16.75 0.21 82.30 1.03 0.97 0.98
422766 Ky 4 171.43 19.09 24.12 2.69 326.96 36.41 1.00 1.00
422766 Ky 5 137.46 5.87 22.08 0.95 258.40 11.04 1.00 1.00
422766 Ky 6 20.59 0.04 15.70 0.03 38.60 0.07 0.98 0.97
422766 Ky 7 27.19 1.02 16.16 0.61 39.21 1.48 1.00 1.00

426018 Tit 1 16.50 0.02 15.09 0.02 37.40 0.04 0.95 0.95
426018 Tit 2 19.47 0.05 15.27 0.04 38.22 0.11 0.99 0.99
426018 Tit 3 104.74 1.13 20.29 0.22 56.20 0.61 1.00 1.00
426018 Tit 4 152.44 0.53 22.89 0.08 65.29 0.23 0.99 0.99
426018 Tit 5 120.05 0.35 20.97 0.06 56.99 0.17 0.99 0.99
426018 Tit 6 122.84 0.92 21.14 0.16 57.72 0.43 1.00 1.00

426037 Tit 1 16.53 0.22 15.11 0.20 37.11 0.50 1.00 1.00
426037 Tit 2 20.87 0.09 15.30 0.07 40.03 0.18 0.99 0.99
426037 Tit 3 76.66 1.92 18.21 0.46 46.56 1.17 1.00 1.00
426037 Tit 4 69.70 1.09 17.90 0.28 48.30 0.76 1.00 1.00
426037 Tit 5 36.53 0.18 16.15 0.08 41.79 0.21 0.99 0.99
426037 Tit 6 36.78 0.27 16.18 0.12 41.76 0.31 1.00 1.00

426008 Apa 1 27.93 0.06 15.36 0.04 40.96 0.09 0.99 0.99
426008 Apa 2 37.36 0.04 15.95 0.02 39.13 0.05 0.97 0.96
426008 Apa 3 38.28 0.03 15.91 0.01 38.70 0.04 0.93 0.85
426008 Apa 4 38.68 0.08 16.08 0.03 38.73 0.08 0.99 0.98
426008 Apa 5 64.84 0.94 21.41 0.31 35.92 0.52 1.00 1.00

Wr = whole-rock, Grt = garnet, Ky = kyanite,  Tit = titanite,  Apa = apatite.
r1 =

206Pb/204Pb vs.207Pb/204Pb error correlation (Ludwig 1988).
r2 =

206Pb/204Pb vs.208Pb/204Pb error correlation (Ludwig 1988).
               

* Errors are two standard deviations absolute (Ludwig 1988). 

GEUS Bulletin 6.pmd 10-02-2005, 09:5470



71

(3)

(2)
wr

(6) (7)

(1)

(1)

426050
Garnet

426050
Garnet

426050
Kyanite

426050
Kyanite

A

826 + 96 Ma
(MSWD = 0.14)

20
7 P

b 
/ 

20
4 P

b

(5)

0 100 200 300

C

20
7 P

b 
/ 

20
4 P

b

20
8 P

b 
/ 

20
4 P

b

(3)

2010 24 28 32 36 40

70

60

50

40

30

500

400

300

200

100

0

20
8 P

b 
/ 

20
4 P

b

all datapoints: 876 + 93 Ma (MSWD = 11.2)

(3)

(3)
(4)

426050
Monazite

426050
Monazite

E

20
7 P

b 
/ 

20
4 P

b

206Pb / 204Pb 206Pb / 204Pb

0 100 200 300

500

400

300

200

100

0

20
8 P

b 
/ 

20
4 P

b

34

38

26

30

22

14

18

10

17.0

16.2

16.6

15.8

15.4

15.0

36

28

32

24

16

20

12

(3)

(5)

(7)

(6)
(2)

(1)

B

0 100 200 300

(4)

(2)
(5)

(6)
(1)

D

(3)

(4)

(4)

(5)

(6)

▲ ▲ 
▲ ▲ 

▲ 

▲
▲

(2)

▲

▲

▲▲
▲

▲

▲
▲

▲
▲

▲

wr

Mo
na

zit
e t

ren
d

Garnet 
trend

Zircon trend

(3)

(4)
(3)

F

0 100 200 300

(4)

wr

▲wr

Garnet
Kyanite

(4)

(4)

2010 24 28 32 36 40

901 + 42 Ma
(MSWD = 1.86)

Fig. 2. Uranogenic (207Pb/204Pb – 206Pb /204Pb) and thorogenic vs. uranogenic (208Pb/204Pb – 206Pb /204Pb) Pb isotope diagrams with
PbSL data from step-leaching experiments on garnet (A, B) and kyanite (C, D), from mica schist sample 426050 (Krummedal
supracrustal sequence). E and F are steps representing monazite inclusions within the garnet and kyanite.

GEUS Bulletin 6.pmd 10-02-2005, 09:5471



72

(Fig. 2A) yielding a 207Pb/206Pb date of 876 ± 93 Ma
(MSWD = 11.2). The 208Pb/204Pb vs. 206Pb/204Pb diagram
(Fig. 2B) reveals the presence of mineral inclusions in
the garnet. The different Th/U ratios of the host min-
eral and the inclusions may explain the large MSWD
value of the errorchron. Steps 3 and 4 have very high
Th/U ratios, interpreted as representing monazite in-
clusions (Th/U > 3; DeWolf et al. 1996). All the mona-
zite is leached out in step 4, causing the observed
drop in the Th/U ratio. The very low Th/U ratio in
steps 5 and 6 is characteristic of zircon leach steps
(Th/U < 1; DeWolf et al. 1996). All the zircon is dis-
solved in step 6. Step 7 was undertaken because of
the red colour of the residue after step 6, showing
that garnet was still present.

The only leach steps dominated by garnet are the
two first, where all the most primitive Pb is extracted,

and step 7. These three steps together with the whole-
rock analysis yield an isochron date of 826 ± 96 Ma
(MSWD = 0.14). The large error of the date is due to
the low precision of step 7.

The same procedure was carried out on kyanite,
and again there is evidence for the presence of both
monazite and zircon inclusions (Fig. 2D). Steps 3 and
4 are dominated by monazite, and step 6 by zircon.
Three steps (1, 2 and 5) are interpreted as represent-
ing kyanite, but while the individual analyses are very
precise they do not form a sufficiently wide spread in
the Pb ratios to yield a precise date. The Pb whole-
rock analysis and the kyanite-dominated steps define
a slope which yields an isochron date of 1219 ± 790
Ma (MSWD = 0.24). Given the large uncertainty, this
date does not yield any useful chronological informa-
tion. The monazite-dominated steps from the garnet
(3 and 4) and the kyanite (3 and 4) plot on a linear
trend in both the 207Pb/204Pb vs. 206Pb/204Pb and 208Pb/
204Pb vs. 206Pb/204Pb diagrams (Fig. 2E, F). The four
monazite steps yield an isochron date of 901 ± 42 Ma
(MSWD = 1.86).

The monazite and garnet dates are in general ac-
cordance with the ion microprobe analyses of meta-
morphic zircon rims from the Krummedal supracru-
stal sequence that have yielded Neoproterozoic ages
around 940 Ma (Thrane et al. 1999a, b; Kalsbeek et al.
2000). The cores of detrital zircons from the same study
yielded ages ranging from c. 1100 to 1900 Ma, and it
therefore serves no practical purpose to calculate an
age from the zircon steps, as these will represent a
mixture of ages.

Sample 422766, also derived from the Krummedal
supracrustal sequence, was collected by J.C. Escher
and K.A. Jones in the southern part of Andrée Land,
very close to the contact with the structurally underly-
ing crystalline basement (Fig. 1). The sample contains
garnet and kyanite crystals up to 5 cm in diameter.

The kyanite was analysed by PbSL, while the gar-
net was considered too altered to justify analysis. Seven
steps were undertaken on the kyanite, and the analy-
ses represent an almost perfect leaching pattern (Fig.
3); all fall on a linear array in both the 207Pb/204Pb vs.
206Pb/204Pb and 208Pb/204Pb vs. 206Pb/204Pb diagrams,
except for step 7 which has a lower 208Pb/204Pb ratio
that probably indicates the presence of zircon inclu-
sions. A 207Pb/206Pb date of 437 ± 62 Ma (MSWD = 2.6)
is obtained using all the steps, while if step 7 is ex-
cluded a date of 445 ± 58 Ma (MSWD = 3.2) is ob-
tained. The large error is due to the analytical error of
steps 4 and 5.

(3)
(7)

(2)

(6)
(1)

(3)

(7)
(2)

(6)(1)

422766
Kyanite

28

24

20

16

12

A

 445 + 58 Ma
(MSWD = 3.2)

20
7 P

b 
/ 

20
4 P

b

(5)

(4)

0 40 80 120 160 200 240

422766
Kyanite

400

300

200

100

0

B

20
8 P

b 
/ 

20
4 P

b

(5)

(4)

0 40 80 120 160 200 240
206Pb / 204Pb

Fig. 3. Uranogenic (207Pb/204Pb – 206Pb /204Pb) and thorogenic
vs. uranogenic (208Pb/204Pb – 206Pb /204Pb) Pb isotope diagrams
with PbSL data from step-leaching experiments on kyanite, from
mica schist sample 422766 (Krummedal supracrustal sequence).

GEUS Bulletin 6.pmd 10-02-2005, 09:5472



73

Crystalline basement
The East Greenland Caledonian orogen is dominated
by major thrust sheets of reworked orthogneiss com-
plexes. The crystalline basement is divided into an
Archaean terrain to the south of 72°50′N and a Pal-
aeoproterozoic terrain to the north (Fig.1; Thrane
2002).

PbSL analyses on titanite from a metagabbroic gneiss
(426018) in the Archaean crystalline basement com-
plex west of innermost Forsblad Fjord (Fig. 1) were
undertaken. This gabbroic gneiss has yielded a Sm-
Nd model age (t

DM
) of 3.25 Ga (Thrane 2002). The

whole-rock analysis has the same Pb ratios as step 1,
indicating that the whole-rock and titanite are in equi-
librium. The six leach steps together with the whole-

rock analysis yield an isochron date of 504 ± 48 Ma
(MSWD = 1.81). However, the 208Pb/204Pb vs. 206Pb/
204Pb diagram (Fig. 4B) suggests that the titanite con-
tains small amounts of monazite inclusions, which
result in slightly elevated Th/U ratios for steps 3 and 4
compared with the titanite trend. If steps 3 and 4 are
excluded, an isochron date of 486 ± 15 Ma (MSWD =
0.16) is obtained (Fig. 4A).

Titanite from a sheared garnet amphibolite (426037)
cutting the basement gneisses of Nathorst Land (Fig.
1) was also analysed. All six data points define an
isochron date of 335 ± 140 Ma (MSWD = 0.11; Fig.
4C); the large error of the date is due to the limited
spread in the data points, as well as the large analyti-
cal errors of steps 3 and 4. In the 208Pb/204Pb vs. 206Pb/
204Pb diagram (Fig. 4D) the analyses show an unusual

(3)

(2)
(wr)

(6)

(1)

(1)

426018
Titanite

426037
Titanite

A

486 + 15 Ma
(MSWD = 0.16)

All steps:
335 + 140 Ma
(MSWD = 0.11)

20
7 P

b 
/ 

20
4 P

b

(5)

0 40 80 120 160 200

C

20
7 P

b 
/ 

20
4 P

b

206Pb / 204Pb 206Pb / 204Pb

20
8 P

b 
/ 

20
4 P

b

(3)

4010 50 70 90

50

46

42

33

34

70

60

50

40

30

20
8 P

b 
/ 

20
4 P

b

(4)23

25

19

21

17

15

13

19

20

17

18

16

15

14

0 20 40 60 80 100

(3)

(2)

wr

(6)

(1)

B

(5)

0 40 80 120 160 200

(4)

426018
Titanite

(3)

(2)

(6)

(1)

D

(5)

(4)

426037
Titanite

(4)

(5)
(6)

▲ ▲ 

▲

▲

▲
▲

▲
▲

(2)

▲

▲

▲

▲

Fig. 4. Uranogenic (207Pb/204Pb – 206Pb /204Pb) and thorogenic vs. uranogenic (208Pb/204Pb – 206Pb /204Pb) Pb isotope diagrams with
PbSL data from step-leaching experiments on titanite from a gabbroic gneiss in the basement (A, B; sample 426018) and a garnet
amphibolite (C, D; sample 426037).

GEUS Bulletin 6.pmd 10-02-2005, 09:5473



74

pattern: step 2 has an elevated Th/U ratio compared
to the general trend while step 3 has a lower Th/U
ratio. These features cannot be explained by the pres-
ence of monazite and zircon inclusions. If steps 2 and
3 are excluded from the isochron an even less precise
date of 309 ± 230 Ma (MSWD = 0.03) is obtained.

Apatite from a tonalitic basement gneiss (426008)
collected west of innermost Forsblad Fjord (Fig. 1)
was also analysed. Zircon crystals from this sample
have yielded U-Pb ages of c. 2800 Ma (Thrane 2002).
Apatite dissolves much more easily than silicate phases,
so a weaker acid and shorter leaching times were used
in this experiment. The analyses form a complex pat-
tern (Fig. 5). Step 1 is too thorogenic to derive from
apatite, and it is interpreted instead as influenced by
allanite since this is very easily dissolved and has a

higher Th/U ratio than apatite. Step 2 is less thorogenic
than step 1, but more so than step 3, and is therefore
interpreted as a mixture between allanite and apatite.
Step 3 is the only step dominated by apatite. The only
possible way to obtain a date is thus by combining
the whole-rock analysis and step 3, which yields a
date of 392 ± 24 Ma (Fig. 5A). Step 1 falls on the
isochron, while step 2 falls slightly above, demon-
strating that the two mineral phases were almost in
equilibrium, with the presumed allanite being slightly
older corresponding to its higher closure temperature.
In the 208Pb/204Pb vs. 206Pb/204Pb diagram it seems that
both steps 3 and 4 are apatite steps, but in the 207Pb/
204Pb vs. 206Pb/204Pb diagram it is clear that step 4 is
older and must be influenced by zircon inclusions
which were leached out in the strong acid of step 5.
The whole-rock analysis and step 5 yield a date of
2159 ± 46 Ma.

Summary and discussion
The analyses reported in this paper are the first PbSL
analyses reported on rocks from the Caledonian
orogen of East Greenland. All the samples have been
analysed only once. Several of the dates obtained are
not consistent with existing ages from the area, and
some of the new dates are also somewhat controver-
sial; replicate analyses should therefore be made for
all the samples, to confirm that the dates are consist-
ent, before any definite interpretations can be made.
Thus different interpretations are presented in the dis-
cussion that follows.

The reliability of the PbSL method is still an open
question. The main concern is the importance of the
micro-inclusions contained in the mineral being ana-
lysed, and whether it is possible to be certain which
combination of minerals is dissolved and affect the
individual steps. This important point has not yet been
resolved, and must be kept in mind when evaluating
the new dates.

Supracrustal rocks
The PbSL study demonstrates that Neoproterozoic
monazite and garnet are present in the Krummedal
supracrustal sequence; evidence of Caledonian mona-
zite has previously been reported (Kalsbeek et al.
2000). Zoned garnets have often been recorded
(Elvevold & Gilotti 1999; Thrane et al. 1999b), of which

23

23

19

17

15

13

A

426008
Apatite

 392 + 24 Ma

20
7 P

b 
/ 

20
4 P

b

42

40

38

36

34

B

426008
Apatite

20
8 P

b 
/ 

20
4 P

b

206Pb / 204Pb

(wr)

(wr)

(1)
(2)

(5)

(4)
(3)

(1)

(2)
(3) (4)

(5)

0 20 40 60 70

0 20 40 60 70

Fig. 5. Uranogenic (207Pb/204Pb – 206Pb /204Pb) and thorogenic
vs. uranogenic (208Pb/204Pb – 206Pb /204Pb) Pb isotope diagrams
with PbSL data from step-leaching experiments on apatite from
a tonalitic basement gneiss (sample 426008).

GEUS Bulletin 6.pmd 10-02-2005, 09:5474



75

the outer rims are interpreted to be Caledonian
whereas there has previously been doubt as to whether
the cores were Neoproterozoic or early Caledonian.
In contrast, the presence of Neoproterozoic kyanite
has not been demonstrated in this study. Petrograph-
ically it is often difficult to determine to which min-
eral paragenesis the kyanite belongs, and thus it can-
not be ruled out that some of the kyanite in parts of
the Krummedal supracrustal sequence may be Neo-
proterozoic (Elvevold & Spears 2000).

Evidence of early Caledonian metamorphism
in the crystalline basement?
The closure temperature for titanite is estimated by
Dahl (1997, and references therein) to be in the range
of 620–680°C, and by Cherniak (1993) in the range of
575–707°C, depending on the grain size. The titanite
date of 486 ± 15 Ma for sample 426018, together with
the date of the monazite inclusions, suggest that the
crystalline basement did experience Caledonian me-
dium to high-grade metamorphism.

No other ages of c. 486 Ma have yet been obtained
in East Greenland. The age of the Caledonian colli-
sion in East Greenland is usually referred to the inter-
val 430–425 Ma, on the basis of zircon ages from granite
intrusions and the time of migmatite formation in the
Krummedal supracrustal sequence (Watt et al. 2000;
Kalsbeek et al. 2000, 2001). No comparable zircon ages
have been recorded in the crystalline basement rocks
in the study area, where evidence of the Caledonian
overprint is restricted to imprecise lower concordia
intercept ages ranging from 467 ± 18 Ma to 443 ± 25
(Thrane et al. 1999a). It is not possible to determine
whether these lower intercept ages correspond to the
‘traditional’ East Greenland Caledonian range of events,
or to a potential earlier event. In North-East Green-
land Caledonian zircons have been recorded in some
Palaeoproterozoic gneisses (Kalsbeek et al. 1993),
which is in line with the assumption that the crystal-
line basement complexes of this northern region were
more strongly reworked during the Caledonian oro-
geny.

It might be speculated that the titanite date of 486
± 15 Ma is a cooling age, while the slightly older mona-
zite micro-inclusions in the titanites could represent
the peak of a collision event – comparable to the early
Caledonian event in Scandinavia (Mørk et al. 1988; An-
dréasson 1994, 2000). However, this is not possible in
East Greenland, since Ordovician carbonates were still

being deposited in the Iapetus-margin basin that lay
east of the Laurentian crystalline basement at this time;
there is no associated clastic input that would be ex-
pected if a collision had taken place nearby. The ex-
ceptionally thick Ordovician carbonate succession in
East Greenland (Smith 1991) is indicative of a signifi-
cant increase in the rate of subsidence, and it is pos-
sible that the c. 500 and 486 Ma dates are instead
related to extension. The c. 430 Ma ages are thus still
the best indication of the main Caledonian collision
phase in East Greenland. Apatite, yielding the young-
est Caledonian date of 392 ± 24, could be interpreted
to represent the time where the basement gneisses
cooled to < 500°C (Dahl 1997).

Acknowledgements
The isotope data described in this paper were acquired
at the Geological Institute, University of Copenhagen.
Robert Frei is thanked for introducing and guiding
me in the Pb-Pb step-leaching method. Jan C. Escher
and Kevin A. Jones kindly provided sample 422766.
Critical comments on the manuscript by Adam A.
Garde, A.K. Higgins and Feiko Kalsbeek are greatly
appreciated. This project was based on funding from
the Danish Natural Science Research Council. Minik
Rosing and Martin Whitehouse are thanked for re-
viewing the manuscript.

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