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The influence of the low-high quartz transformation on recrystallization and grain growth during contact metamorphism (Traversella intrusion, North Italy)
Tectonophysics,
120 (1985) 107-117
Elsevier Science Publishers
THE INFLUENCE
107
B.V., Amsterdam
- Printed
in The Netherlands
OF THE LOW-HIGH
RECRYSTALLIZATION METAMORPHISM
QUARTZ
TRANSFORMATION
ON
AND GRAIN GROWTH DURING CONTACT
(TRAVERSELLA
INTRUSION,
NORTH ITALY)
R. WIRTH Mmeralogisches (Received
Institut der Lkersitiit
August
zu Kijln, Ziilprcherstr.
30, 1984; revised version
accepted
- I (West-Germany)
49, 5000 Kijln
February
25, 1985)
ABSTRACT Wirth,
R., 1985. The influence
growth
during
contact
of the low-high
metamorphism
quartz
transformation
(Traversella
intrusion,
on recrystallization
North
Italy).
and grain
Tectonophysics,
120:
107-117. Recrystallization recrystallization at about
and gram
transformation low-high
recrystallization
by
disordered
of atoms
transformation. the atomic
structure during
which
The remarkable and grain
displacement
the low-high
are transferred
migration
This limit of
of 620 f 20°C. which coincidence
growth
becomes
from
quartz
with the
mechanism
of the grain boundary
to the other grain. A lowering
results such that grain boundary
temperature
of recrystallization
of the SiO, tetrahedra
of the number
35 m of the contact.
maximum
quartz
is explained
The already
and from the grain boundary migration
only within
for the beginning
of quartz
by the fluctuations
occur
with an inferred
for the low-high
620°C
transformation.
in an increase
boundary, boundary
temperature
quartz
more distorted
of about
of quartz
coincides
6-7 km is the temperature
of the temperature
results
growth
and grain growth
of the
becomes
transformation,
one grain
of the activation
even This
into the grain energy
the most important
for grain
process
for
and grain growth.
INTRODUCTION
The Sesia-Lanzo Zone is one of the main structural units of the internal Western Alps. It comprises polymetamorphic and some monometamorphic rocks and is part of the Austro-alpine continental crust. During an Early Alpine event the Sesia unit was overprinted by high-pressure low-temperature metamorphism owing to a subduction process. The Sesia-Lanzo zone is characterized mainly by widespread jadeitic pyroxene-garnet-quartz assemblages in paraschists and metagranitoids (Compagnoni et al., 1977). These rocks were affected by the Late Alpine and post-tectonic Traversella Intrusion. Most of the country rocks are glaucophane-mica schists (Reinsch, 1979). The quartz crystals in these mica schists have been deformed during subduction .and uplift of the Sesia unit. Contact heating of the intrusion initiated processes like recovery, recrystallization and grain growth of formerly
0040-1951/85/$03.30
0 1985 Elsevier Science Publishers
B.V.
108
strained
crystals.
Generally,
recovery
and point defect agglomerates, annihilation loops
of dislocations
of opposed
(Haessner,
1978). The
more favourable
configurations migration is continued
migrate
the average
grain
from the magnitude
specific smaller
further diameter.
of dislocations of point
are the basic processes after the completion
through
the recrystallized
The driving
of point
of dislocation
forming
energetically
defects and dislocations
of recrystallization
(Haessner,
of recrystallization, structure,
force for grain
defects
of these defects, and the
sign as well as the shrinking
and the absorption
1978). If annealing
by reactions
the annihilation
rearrangement
by grain-boundary boundaries
is characterized
in particular
growth
the grain
thereby
increasing
(coarsening)
stems
boundary energy of the grains; it is about three orders of than that of recrystallization. Consequently, grain growth phe-
nomena proceed much more slowly (Haessner, 1978). Voll(l960) has pointed out the relevance of these processes for the grain-boundary distribution of naturally deformed rocks. Recovery, recrystallization, and grain growth are supposed to be thermally activated processes (Haasen, 1972; Haessner, 1978). For contact metamorphic heating of quartzites at the Ballachulish granitic intrusion-Scottish Highland Voll (1968) derived a threshold temperature of 59O’C for the beginning of grain growth of quartz.
He pointed
out a possible
relationship
between
the threshold
temperature
for grain growth of quartz in a contact aureole and the low-high quartz transformation temperature (Voll, 1968). This idea is supported by a recent paper of Joesten (1983) which reports a temperature quartz in a contact aureole.
of 600°C
for the beginning
of grain growth
of
In this paper a model is proposed, which shows, how recrystallization and grain growth are affected by the atomic transformation mechanism of the low-high quartz transformation. This model is based on investigations of recrystallization and grain growth of quartz in the contact aureole of the Traversella Intrusion. METHODS AND MATERIAL STUDIED
Microscopic investigations concerning recrystallization and grain growth of quartz in the contact aureole of the Traversella Intrusion have been carried out by polarized light analysis. The investigated rocks in the contact containing up to 47% quartz by volume.
aureole are glaucophane-mica The quartz grains in these
schists rocks are
arranged in clusters of several hundred grains. These clusters contain only occasionally micas or feldspars. The grain size of the quartz was determined by measuring the smallest and the largest diameter of each quartz grain, and calculating the mean value. About 450 grains from different clusters were measured in every thin section. Then the mean value of 450 grains and the standard deviation were calculated. Grains not completely surrounded by other quartz grains (quartz-mica, quartz-feldspar phase boundaries) were not measured. Also omitted were deformed
109
i.e., those containing
grains,
these measurements microscope. The total amount Early
Alpine
Dauphin6 electron studies,
of quartz,
deformation,
were determined ture (Comer,
undulant
were carried
and
the amount
low-angle
of newly
of Dauphin6
thin sections
schists. Suitable
and mounted
mm and the thickness
areas of quartz
on copper
about
All
using a light
grains
deformed
recrystallized
through
the inversion
twins was confirmed
microscopy (TEM), and scanning electron samples of quartz clusters were prepared
glaucophaneemica
grown
boundaries.
ocular
by
quartz
by means of a Swift pointcounter.
in quartz by cooling
1972). The existence
grain
of a calibrated
of the host quartz
the amount
from thin sections
twins are produced
extinction,
out by means
microscopy by cutting clusters
grids. The diameter
0.03 mm. The samples
tempera-
by transmission
(SEM). For TEM thin sections from
were extracted of the samples
were thinned
from the is about
3
for TEM by ion
beam milling (argon 99.999/5 kV-80 PA), and coated with carbon. Electron microscopy was performed in a Jeol JEM 200 CX microscope with side entry goniometer. The microscope was operated at 200 kV. For SEM studies thin sections with a polished surface were etched by hydrofluoric acid vapor (HF 40%) for 35 min. The samples were coated with carbon, and additionally with chromium tilting the samples at about 45”. Scanning electron microscopy was performed in a Cambridge SEM, operated
at 30 kV.
RESULTS
The Traversella km has a vertical estimated intrusions
Intrusion, outcrop
a quartz diorite with horizontal of about
dimensions
1200 m. The temperature
of 4.5 x 1.5
of the intrusion
is
in the range of 800”-900°C referring to the data of Winkler for granitic (Winkler, 1962, 1967). The depth of the instrusion was derived from the
breakdown reaction of phengite, one of the most common minerals of the glaucophane-mica schists of the contact aureole (Wirth, 1984). At a distance of about
36 m to the intrusion
phengite
+ quartz + biotite
the following + sanidine
f cordierite
reaction
+ oligoclase
was observed: + andalusite/sillimanite
+ spine11 k corundum
+ H,O
At an interval of 36-16 m from the intrusion andalusite contact, sillimanite appears, and the amount of andalusite a distance
of about
10 m to the intrusion
only sillimanite
occurs. Approaching is strongly diminished. occurs.
the At
The breakdown
reaction of phengite with sanidine and cordierite indicates that at a distance of 36 m to the intrusion contact metamorphism has reached the alkalifeldspar-cordierite hornfels facies. That means temperatures of 580 + 20°C at a pressure of 0.5 kbar, or 630 + 20°C at a pressure of 2 kbar (Winkler, 1967). From the appearance of andalusite followed by sillimanite, a depth of the intrusion of less than 7 km ( -c 2 kbar) is derived, using the stability curves of Al,SiO, (Holdaway, 1971). and
110
muscovite pressure
+ quartz
The maximum
(622 + lO”C/2
temperature
ture of the intrusion for the intrusion,
(Winkler,
of the contact
kbar, Althaus
The breakdown
temperature
reaction
that a temperature
a temperature
at the contact
of 660”-690°C
range of 800°-900°C
rocks of about
150°C
(7
would be in the range of 630”-690°C.
at a distance at the contact
the maximum
and no andalusite.
to be 60% of the tempera-
of the surrounding
of phengite
80 m to the intrusion
et al., 1970). A confining
sillimanite
is estimated
1967). Assuming
and a temperature
km), the maximum
of about
reaction
of more than 2 kbar would have created
of 36 m to the intrusion is more reasonable.
temperature
indicates
At a distance
in the contact
aureole
has
reached 500”-52O’C. This value is derived from the sanidine-microcline transformation temperature (Laves, 1960). At an interval of 80 m to the contact the alkali-feldspar is sanidine. The distribution of the maximum temperatures in the contact aureole can be assumed to be 660”-690°C at the contact, about 630°C at 36 m, and 500-520°C at about 80 m. It is possible to report exact distances to the intrusion, contact
because
the contact
plane has an exposed
The temperature
Fig. 1. Quartz boundary, caused
crystal
plane
is vertical
vertical
dimension
of the low-high
with Dauphin6 damage.
At the outcrop
the
of 250 m.
transformation
twin (12 m from the intrusion).
visible with a (1011) reflection.
by radiation
quartz
at the outcrop.
is pressure
Fringe contrasts
dependent
distinguish
the twin
The small black dots on both sides of the twin boundary
are
117
(Buntebarth,
1980). At a pressure
625°C. Thus, the low-high of about
aggregates
the literature
P-quartz
transformation
36 m to the intrusion.
that the quartz From
quartz
of 2 kbar (7 km) the transformation
through
that Dauphine
the inversion
was reached
the stability
twinning
temperature
evidence
field of P-quartz.
can be produced
(Comer,
is
at a distance
there is some microstructural
from this area have reached
it is well known
by cooling
temperature
In addition,
temperature
from
1972). The twinned
parts are related by a rotation of 180” about the c-axis and are of the same hand. Dauphin6 twins cannot be detected by optical methods but are visible on suitably etched specimens. Dauphins microtwins can be identified by fringe patterns bonding the
twin,
microscope
visible
with
(Comer,
strong
and SEM at an interval which
did not
(1Oil)
reflections,
1972). Four different
reach
the inversion
temperature
Fig. 2. SEM
by hydrofluoric
and additionally
of quartz
line marks the Dauphin6
around
the c-axis.
two samples m). The TEM
acid (Fig. 2). Etch pits are to be seen on the surface
by the dashed
dashed
(54-80
electron by TEM
Dauphin5 twins on different electron by SEM studies from samples (36-O
micrograph showing a quartz crystal etched with hydrofluoric
The etch pits, separated
a transmission
have been investigated
of 36-O m to the intrusion,
studies from these four samples reveal many micrographs (Fig. 1). This result is supported m) etched
using
samples
line, show different
twin boundary.
orientations
The etch pits (triangles)
of
acid (25 m from the intrusion). (v left side; A right side). The are related by a rotation
of 180”
112
those quartz
grains which have their c-axis normal
etch pits are shaped arrangements to have
occasionally
the c-axis of the quartz reached
the P-quartz
Dauphine
The investigated
to the surface of the sample.
It is very common
of etch pits with different
of 180” about not
like triangles.
orientations. grain.
that in one grain They are related
In contrast,
temperature
by a rotation
the two samples
conditions
(54-80
The
there are inferred
m) show
only
twinning.
rocks are glaucophane-mica
schists containing
up to 47% quartz
by volume. 51 samples were collected at an interval of 317 m from the intrusion. At a distance of 317 m quartz appears as polycrystalline aggregates inside the glaucophane-mica schists. There are two different groups of quartz grains. Quartz. which have suffered following deviation tion,
Early Alpine
deformation,
are called host quartz
grains
in the
sections. The mean grain size of these host quartz is 328 pm (standard = 145 pm). The host quartz exhibit deformation lamellae, undulose extinc-
sutured
grain
boundaries,
incipient
polygonization
recrystallization
(formation
at grain
of
boundaries
low-angle (Fig.
grain
boundaries),
and
recrystallized
quartz grains have a mean grain size of 50 pm, and they are the second
3). These
group of quartz grains. The recrystallized quartz very often show undulose extinction, indicating that they have been deformed again or that they were formed by dynamic recrystallization. The undulose extinction makes them different from the statically recrystallized quartz, formed by the heating of the intrusion. At a distance
Fig. 3. Host undulose
quartz
extinction,
grains
which
sutured
grain boundaries.
have suffered
Early
Alpine
polygonization.
deformation. and incipient
The quartz recrystallization.
grains
exhibit
113
%
DEF WART2 RECRYST WART2
100
x loo
I% I ,
.*a.
.“.:
.
*. *.*..* .
.
10
1.. .
.. ‘.
..a..
.
.
.
.
.
.
.
.
i
l0.5
0.J
1
5
10
50 DISTANCE
Fig. 4. Percentage as a function
of deformed
of the distance
host quartz
TO
? 1000
1w THE
INTRUSION
grains and statically
[ml recrystallized
quartz
(by contact
heating)
to the intrusion.
of 40-317 m from the contact the volume percentage of host quartz grain to recrystallized quartz grains is high: 95575% and 5-25%, respectfully. In this range there is no significant change of the percentage. At a distance of 40-20 m to the contact the amount of host grains strongly decreases, and the amount of recrystallized quartz increases (Fig. 4). Quartz grains which have recrystallized by the heating of the intrusion
show no undulose
quartz grains increases At a distance grains decreases
towards
extinction.
the contact
The grain
size of the recrystallized
by grain growth (Fig. 5).
of 20-O m from the intrusion the percentage of the host quartz to 10% by volume, while the percentage of statically recrystallized
GRAIN SIZE bml T
L. 5
1
Fig. 5. Grain function
10
size of the quartz
of the distance
grains
to the intrusion.
50
100
DISTANCE
TO
which
th
40 THE
INTRUSION
have undergone
(error bar: standard
Iml
grain
growth
deviation).
(recrystallized
grains)
as a
Fig. 6. Coarsened
quartz
angles at triple points.
grains
near the intrusion
and without
undulose
(1.6 m) with straight
grain
boundaries.
equilibrium
extinction.
grains increases. From a distance of 40 m to the contact of the intrusion the grain size of the recrystallized grains increases from 50 pm to 260 pm by grain growth (Fig.
5). The coarsened
quartz
grains
are the result
of three
different
processes:
polygonization of the deformed host quartz, recrystallization and grain growth. The result is an arrangement of coarsened quartz grains with straight grain boundaries, equilibrium
angles at triple points and the absence of undulose
extinction
(Fig. 6).
The most important result is that recrystallization and grain growth are initiated by the heating bf the intrusion at a distance of about 35 m to the contact. As mentioned
above,
this distance
can be correlated
620 k 20°C. Referring to an intrusion depth ture for the low-high quartz transformation.
with a maximum
of about
temperature
of
5-7 km, this is the tempera-
DISCUSSION
Voll (1968) supposed that the beginning of grain growth during contact metamorphism may be initiated by the low-high quartz transformation. This assumption may be supported by the data of Joesten (1983) and the data presented in this paper. Recrystallization and grain growth are both explained by migrating high-angle grain boundaries. The migration of grain boundaries is suggested to occur the following way (Gleiter and Chalmers, 1972): Suppose, two grains are separated by a
115
grain
boundary
emission absorption model
of definite
of atoms
from
thickness.
the steps
of the same number
refers to metals.
SiO, tetrahedra
of atoms
The grain
area in the crystal lattice.
Grainboundary
on the surface
occurs
by
the
grain
and
by
at the steps of the growing
boundary
is assumed
It has not been proven
is involved
migration
of the shrinking
in the migration
grain.
to be a strongly
that the transfer
of grain
This
distorted
of single atoms or
boundaries
between
quartz
crystals. Assuming a transfer of single atoms, the strong Si-0 bond has to be broken. Grain boundary migration would then be correlated with a high activation energy.
This
migration
situation
of grain
hydrolysis,
is more
boundaries
and a transfer
favorable (Hobbs,
of single
if water
molecules
1968). The Si-0
atoms
are involved
bond
will be favored
in the
will be broken
(hydrolytic
by
weakening,
Griggs 1967). However, investigations to understand the nature and the behaviour of grain boundaries in silicates still have to be done. Experiments with metal alloys have shown that the mobility of grain boundaries depends on the energy of the grain boundary. That is, it depends on the disordered state of the crystal lattice in the grain boundary (Gleiter and Chalmers, 1972). An increase of the disordered state of the atoms in the grain boundary would result in a reduction of the activation energy for grain-boundary grain growth
migration.
should
In quartz
The threshold
temperature
for recrystallization
and
then decrease.
bearing
materials,
an
additional
distortion
of the grain-boundary
structure is caused by the low-high quartz transformation. The low quartz structure consists of a tetrahedral network in which tetrahedra are joined in a double spiral with two nonintersecting
threads
around
the trigonal
axis. The two states (Y, and (Ye
of low quartz of the same enatiomorph (left or right handed) are transformed into each other by a diad axis coinciding with the trigonal axis. These two states correspond to Dauphine twin domains which differ by tilt angles of opposite direction. Low-quartz, thus, consists of two equilibrium states (Y, and a*. An individual described Megaw
chain parallel to directions [loo], [OlO] or [llO] of the tetrahedra may be as a particle in a double minimum potential (Liebau and Bohm, 1982). (1973) suggested
temperature,
that in a temperature
the low-quartz
single crystal
These Dauphine
twin domains
of the domain
walls
transition states
temperature
were
having
observed
the chains
(Y, and CX*.These fluctuations
start
region
breaks
slightly
strongly
temperature
by Van
Tendeloo
to fluctuate
increase
below
the transition
up into small (r, and a2 domains. dependent et al. (1976).
between
fluctuations Near
the
the two permissible
when the temperature
is raised above
the transformation temperature T,. Below T, such fluctuations are correlated, yielding microdomains (Liebau and Bohm, 1982). Above T, the long-range correlation ceases. Each chain fluctuates independently between the two equivalent minimum states in a double minimum potential. The P-quartz structure can be concieved as both a geometrical and a time average of the two equilibrium positions. The most important point of the low-high quartz transformation mechanism is the fluctuation of the SiO, tetrahedra at the transformation temperature T,. These
116
fluctuations
are supposed
An increase
of the disordered
activation
to increase
energy needed
the disordered
state of a quartz grain-boundary.
state of the grain boundary
for grain-boundary
migration;
from the surface of one grain into the grain boundary, surface
of the growing
The
low-high
temperature
of the
of atoms
and from the boundary
to the
grain.
quartz
range
results in a lowering that is, the transfer
transformation
between
530”
and
shows 572°C
a volume (Taylor,
change
1972).
of 1.6% in a
This
results
in an
additional drfving force for grain-boundary migration. The quartz aggregates in the glaucophane-mica schists are enclosed by other minerals like phengite, feldspar. chlorite and biotite. An increase of the volume of quartz grains in the quartz aggregates causes a stress in the quartz, and of course in the surrounding minerals. However, stress on the quartz grains results in an additional driving force for grain boundary migration, thus, accelerating grain-boundary migration. Voll (1976) recrystallization
reported a threshold temperature of 290°C for the beginning of quartz in the Swiss Alps. These quartz were heated during
of the
Alpine orogeny. Voll has pointed out that the reason for the lower threshold temperature for recrystallization of quartz in regional metamorphic rocks is the great difference heating
in time during
time is supposed
the intrusion,
which the rock series were heated. to be lOOO-100,000
the depth
of the intrusion,
years, depending
and the dimension
In contact
aureoles
the
on the temperature
of
of the intrusive
body.
However, the heating time during regional metamorphism is up to four orders of magnitude higher. At the threshold temperature of 290°C for the recrystallization of quartz. only a few atoms will be transferred from one grain to the other grain in a short time, like the heating time of an intrusion. The only small transfer of atoms in a short time (1000 years) results in a nearly invisible displacement of the grain boundary. However, the threshold temperature for recrystallization is not only a function of the heating time, but it is also affected by the stored strain energy. The threshold
temperature
rocks from outside
decreases
quartz
as the rocks inside
stored
strain
recrystallization
energy
with increasing
the Traversella the contact
of the quartz
of quartz
contact aureole. grains
is really initiated
deformation
aureole
Therefore, does
(Haasen,
1974). The
show the same highly not
it can be assumed differ
by the low-high
very quartz
Knowing the depth of an intrusion, a low-high quartz transformation be derived by measuring the beginning of the quartz recrystallization aureole.
much,
strained that the and
the
transformation. isograde may in a contact
ACKNOWLEDGEMENTS
The author would like to thank Prof. Dr. G. Voll for the problem reported here, for critical reading the manuscript, and sions. Thanks are also due to Prof. Dr. H. Gleiter for use of the facilities in his institute. My thanks also go to Dr. S. Vogler and
introduction to the stimulating discuselectron microscopy H. Hofer for critical
117
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ihr
Berlin, 206 pp.
to the Leventina
Nappe,
Mitt., 56: 641-647. und vie1 Granit.
Beitr. Mineral.
8: 222-231.
H.G.F.,
1967. Die Genese
der metamorphen
Gesteine.
Springer,
Berlin-Heidelberg-New
York,
237 pp. Wirth, R., 1984. Dehydration Traversella
Intrusion.
and thermal
Neues Jahrb.
alteration
Mineral.
of white mica (phengite)
Monatsh.,
in press.
in the contact
aureole
of the
120 (1985) 107-117
Elsevier Science Publishers
THE INFLUENCE
107
B.V., Amsterdam
- Printed
in The Netherlands
OF THE LOW-HIGH
RECRYSTALLIZATION METAMORPHISM
QUARTZ
TRANSFORMATION
ON
AND GRAIN GROWTH DURING CONTACT
(TRAVERSELLA
INTRUSION,
NORTH ITALY)
R. WIRTH Mmeralogisches (Received
Institut der Lkersitiit
August
zu Kijln, Ziilprcherstr.
30, 1984; revised version
accepted
- I (West-Germany)
49, 5000 Kijln
February
25, 1985)
ABSTRACT Wirth,
R., 1985. The influence
growth
during
contact
of the low-high
metamorphism
quartz
transformation
(Traversella
intrusion,
on recrystallization
North
Italy).
and grain
Tectonophysics,
120:
107-117. Recrystallization recrystallization at about
and gram
transformation low-high
recrystallization
by
disordered
of atoms
transformation. the atomic
structure during
which
The remarkable and grain
displacement
the low-high
are transferred
migration
This limit of
of 620 f 20°C. which coincidence
growth
becomes
from
quartz
with the
mechanism
of the grain boundary
to the other grain. A lowering
results such that grain boundary
temperature
of recrystallization
of the SiO, tetrahedra
of the number
35 m of the contact.
maximum
quartz
is explained
The already
and from the grain boundary migration
only within
for the beginning
of quartz
by the fluctuations
occur
with an inferred
for the low-high
620°C
transformation.
in an increase
boundary, boundary
temperature
quartz
more distorted
of about
of quartz
coincides
6-7 km is the temperature
of the temperature
results
growth
and grain growth
of the
becomes
transformation,
one grain
of the activation
even This
into the grain energy
the most important
for grain
process
for
and grain growth.
INTRODUCTION
The Sesia-Lanzo Zone is one of the main structural units of the internal Western Alps. It comprises polymetamorphic and some monometamorphic rocks and is part of the Austro-alpine continental crust. During an Early Alpine event the Sesia unit was overprinted by high-pressure low-temperature metamorphism owing to a subduction process. The Sesia-Lanzo zone is characterized mainly by widespread jadeitic pyroxene-garnet-quartz assemblages in paraschists and metagranitoids (Compagnoni et al., 1977). These rocks were affected by the Late Alpine and post-tectonic Traversella Intrusion. Most of the country rocks are glaucophane-mica schists (Reinsch, 1979). The quartz crystals in these mica schists have been deformed during subduction .and uplift of the Sesia unit. Contact heating of the intrusion initiated processes like recovery, recrystallization and grain growth of formerly
0040-1951/85/$03.30
0 1985 Elsevier Science Publishers
B.V.
108
strained
crystals.
Generally,
recovery
and point defect agglomerates, annihilation loops
of dislocations
of opposed
(Haessner,
1978). The
more favourable
configurations migration is continued
migrate
the average
grain
from the magnitude
specific smaller
further diameter.
of dislocations of point
are the basic processes after the completion
through
the recrystallized
The driving
of point
of dislocation
forming
energetically
defects and dislocations
of recrystallization
(Haessner,
of recrystallization, structure,
force for grain
defects
of these defects, and the
sign as well as the shrinking
and the absorption
1978). If annealing
by reactions
the annihilation
rearrangement
by grain-boundary boundaries
is characterized
in particular
growth
the grain
thereby
increasing
(coarsening)
stems
boundary energy of the grains; it is about three orders of than that of recrystallization. Consequently, grain growth phe-
nomena proceed much more slowly (Haessner, 1978). Voll(l960) has pointed out the relevance of these processes for the grain-boundary distribution of naturally deformed rocks. Recovery, recrystallization, and grain growth are supposed to be thermally activated processes (Haasen, 1972; Haessner, 1978). For contact metamorphic heating of quartzites at the Ballachulish granitic intrusion-Scottish Highland Voll (1968) derived a threshold temperature of 59O’C for the beginning of grain growth of quartz.
He pointed
out a possible
relationship
between
the threshold
temperature
for grain growth of quartz in a contact aureole and the low-high quartz transformation temperature (Voll, 1968). This idea is supported by a recent paper of Joesten (1983) which reports a temperature quartz in a contact aureole.
of 600°C
for the beginning
of grain growth
of
In this paper a model is proposed, which shows, how recrystallization and grain growth are affected by the atomic transformation mechanism of the low-high quartz transformation. This model is based on investigations of recrystallization and grain growth of quartz in the contact aureole of the Traversella Intrusion. METHODS AND MATERIAL STUDIED
Microscopic investigations concerning recrystallization and grain growth of quartz in the contact aureole of the Traversella Intrusion have been carried out by polarized light analysis. The investigated rocks in the contact containing up to 47% quartz by volume.
aureole are glaucophane-mica The quartz grains in these
schists rocks are
arranged in clusters of several hundred grains. These clusters contain only occasionally micas or feldspars. The grain size of the quartz was determined by measuring the smallest and the largest diameter of each quartz grain, and calculating the mean value. About 450 grains from different clusters were measured in every thin section. Then the mean value of 450 grains and the standard deviation were calculated. Grains not completely surrounded by other quartz grains (quartz-mica, quartz-feldspar phase boundaries) were not measured. Also omitted were deformed
109
i.e., those containing
grains,
these measurements microscope. The total amount Early
Alpine
Dauphin6 electron studies,
of quartz,
deformation,
were determined ture (Comer,
undulant
were carried
and
the amount
low-angle
of newly
of Dauphin6
thin sections
schists. Suitable
and mounted
mm and the thickness
areas of quartz
on copper
about
All
using a light
grains
deformed
recrystallized
through
the inversion
twins was confirmed
microscopy (TEM), and scanning electron samples of quartz clusters were prepared
glaucophaneemica
grown
boundaries.
ocular
by
quartz
by means of a Swift pointcounter.
in quartz by cooling
1972). The existence
grain
of a calibrated
of the host quartz
the amount
from thin sections
twins are produced
extinction,
out by means
microscopy by cutting clusters
grids. The diameter
0.03 mm. The samples
tempera-
by transmission
(SEM). For TEM thin sections from
were extracted of the samples
were thinned
from the is about
3
for TEM by ion
beam milling (argon 99.999/5 kV-80 PA), and coated with carbon. Electron microscopy was performed in a Jeol JEM 200 CX microscope with side entry goniometer. The microscope was operated at 200 kV. For SEM studies thin sections with a polished surface were etched by hydrofluoric acid vapor (HF 40%) for 35 min. The samples were coated with carbon, and additionally with chromium tilting the samples at about 45”. Scanning electron microscopy was performed in a Cambridge SEM, operated
at 30 kV.
RESULTS
The Traversella km has a vertical estimated intrusions
Intrusion, outcrop
a quartz diorite with horizontal of about
dimensions
1200 m. The temperature
of 4.5 x 1.5
of the intrusion
is
in the range of 800”-900°C referring to the data of Winkler for granitic (Winkler, 1962, 1967). The depth of the instrusion was derived from the
breakdown reaction of phengite, one of the most common minerals of the glaucophane-mica schists of the contact aureole (Wirth, 1984). At a distance of about
36 m to the intrusion
phengite
+ quartz + biotite
the following + sanidine
f cordierite
reaction
+ oligoclase
was observed: + andalusite/sillimanite
+ spine11 k corundum
+ H,O
At an interval of 36-16 m from the intrusion andalusite contact, sillimanite appears, and the amount of andalusite a distance
of about
10 m to the intrusion
only sillimanite
occurs. Approaching is strongly diminished. occurs.
the At
The breakdown
reaction of phengite with sanidine and cordierite indicates that at a distance of 36 m to the intrusion contact metamorphism has reached the alkalifeldspar-cordierite hornfels facies. That means temperatures of 580 + 20°C at a pressure of 0.5 kbar, or 630 + 20°C at a pressure of 2 kbar (Winkler, 1967). From the appearance of andalusite followed by sillimanite, a depth of the intrusion of less than 7 km ( -c 2 kbar) is derived, using the stability curves of Al,SiO, (Holdaway, 1971). and
110
muscovite pressure
+ quartz
The maximum
(622 + lO”C/2
temperature
ture of the intrusion for the intrusion,
(Winkler,
of the contact
kbar, Althaus
The breakdown
temperature
reaction
that a temperature
a temperature
at the contact
of 660”-690°C
range of 800°-900°C
rocks of about
150°C
(7
would be in the range of 630”-690°C.
at a distance at the contact
the maximum
and no andalusite.
to be 60% of the tempera-
of the surrounding
of phengite
80 m to the intrusion
et al., 1970). A confining
sillimanite
is estimated
1967). Assuming
and a temperature
km), the maximum
of about
reaction
of more than 2 kbar would have created
of 36 m to the intrusion is more reasonable.
temperature
indicates
At a distance
in the contact
aureole
has
reached 500”-52O’C. This value is derived from the sanidine-microcline transformation temperature (Laves, 1960). At an interval of 80 m to the contact the alkali-feldspar is sanidine. The distribution of the maximum temperatures in the contact aureole can be assumed to be 660”-690°C at the contact, about 630°C at 36 m, and 500-520°C at about 80 m. It is possible to report exact distances to the intrusion, contact
because
the contact
plane has an exposed
The temperature
Fig. 1. Quartz boundary, caused
crystal
plane
is vertical
vertical
dimension
of the low-high
with Dauphin6 damage.
At the outcrop
the
of 250 m.
transformation
twin (12 m from the intrusion).
visible with a (1011) reflection.
by radiation
quartz
at the outcrop.
is pressure
Fringe contrasts
dependent
distinguish
the twin
The small black dots on both sides of the twin boundary
are
117
(Buntebarth,
1980). At a pressure
625°C. Thus, the low-high of about
aggregates
the literature
P-quartz
transformation
36 m to the intrusion.
that the quartz From
quartz
of 2 kbar (7 km) the transformation
through
that Dauphine
the inversion
was reached
the stability
twinning
temperature
evidence
field of P-quartz.
can be produced
(Comer,
is
at a distance
there is some microstructural
from this area have reached
it is well known
by cooling
temperature
In addition,
temperature
from
1972). The twinned
parts are related by a rotation of 180” about the c-axis and are of the same hand. Dauphin6 twins cannot be detected by optical methods but are visible on suitably etched specimens. Dauphins microtwins can be identified by fringe patterns bonding the
twin,
microscope
visible
with
(Comer,
strong
and SEM at an interval which
did not
(1Oil)
reflections,
1972). Four different
reach
the inversion
temperature
Fig. 2. SEM
by hydrofluoric
and additionally
of quartz
line marks the Dauphin6
around
the c-axis.
two samples m). The TEM
acid (Fig. 2). Etch pits are to be seen on the surface
by the dashed
dashed
(54-80
electron by TEM
Dauphin5 twins on different electron by SEM studies from samples (36-O
micrograph showing a quartz crystal etched with hydrofluoric
The etch pits, separated
a transmission
have been investigated
of 36-O m to the intrusion,
studies from these four samples reveal many micrographs (Fig. 1). This result is supported m) etched
using
samples
line, show different
twin boundary.
orientations
The etch pits (triangles)
of
acid (25 m from the intrusion). (v left side; A right side). The are related by a rotation
of 180”
112
those quartz
grains which have their c-axis normal
etch pits are shaped arrangements to have
occasionally
the c-axis of the quartz reached
the P-quartz
Dauphine
The investigated
to the surface of the sample.
It is very common
of etch pits with different
of 180” about not
like triangles.
orientations. grain.
that in one grain They are related
In contrast,
temperature
by a rotation
the two samples
conditions
(54-80
The
there are inferred
m) show
only
twinning.
rocks are glaucophane-mica
schists containing
up to 47% quartz
by volume. 51 samples were collected at an interval of 317 m from the intrusion. At a distance of 317 m quartz appears as polycrystalline aggregates inside the glaucophane-mica schists. There are two different groups of quartz grains. Quartz. which have suffered following deviation tion,
Early Alpine
deformation,
are called host quartz
grains
in the
sections. The mean grain size of these host quartz is 328 pm (standard = 145 pm). The host quartz exhibit deformation lamellae, undulose extinc-
sutured
grain
boundaries,
incipient
polygonization
recrystallization
(formation
at grain
of
boundaries
low-angle (Fig.
grain
boundaries),
and
recrystallized
quartz grains have a mean grain size of 50 pm, and they are the second
3). These
group of quartz grains. The recrystallized quartz very often show undulose extinction, indicating that they have been deformed again or that they were formed by dynamic recrystallization. The undulose extinction makes them different from the statically recrystallized quartz, formed by the heating of the intrusion. At a distance
Fig. 3. Host undulose
quartz
extinction,
grains
which
sutured
grain boundaries.
have suffered
Early
Alpine
polygonization.
deformation. and incipient
The quartz recrystallization.
grains
exhibit
113
%
DEF WART2 RECRYST WART2
100
x loo
I% I ,
.*a.
.“.:
.
*. *.*..* .
.
10
1.. .
.. ‘.
..a..
.
.
.
.
.
.
.
.
i
l0.5
0.J
1
5
10
50 DISTANCE
Fig. 4. Percentage as a function
of deformed
of the distance
host quartz
TO
? 1000
1w THE
INTRUSION
grains and statically
[ml recrystallized
quartz
(by contact
heating)
to the intrusion.
of 40-317 m from the contact the volume percentage of host quartz grain to recrystallized quartz grains is high: 95575% and 5-25%, respectfully. In this range there is no significant change of the percentage. At a distance of 40-20 m to the contact the amount of host grains strongly decreases, and the amount of recrystallized quartz increases (Fig. 4). Quartz grains which have recrystallized by the heating of the intrusion
show no undulose
quartz grains increases At a distance grains decreases
towards
extinction.
the contact
The grain
size of the recrystallized
by grain growth (Fig. 5).
of 20-O m from the intrusion the percentage of the host quartz to 10% by volume, while the percentage of statically recrystallized
GRAIN SIZE bml T
L. 5
1
Fig. 5. Grain function
10
size of the quartz
of the distance
grains
to the intrusion.
50
100
DISTANCE
TO
which
th
40 THE
INTRUSION
have undergone
(error bar: standard
Iml
grain
growth
deviation).
(recrystallized
grains)
as a
Fig. 6. Coarsened
quartz
angles at triple points.
grains
near the intrusion
and without
undulose
(1.6 m) with straight
grain
boundaries.
equilibrium
extinction.
grains increases. From a distance of 40 m to the contact of the intrusion the grain size of the recrystallized grains increases from 50 pm to 260 pm by grain growth (Fig.
5). The coarsened
quartz
grains
are the result
of three
different
processes:
polygonization of the deformed host quartz, recrystallization and grain growth. The result is an arrangement of coarsened quartz grains with straight grain boundaries, equilibrium
angles at triple points and the absence of undulose
extinction
(Fig. 6).
The most important result is that recrystallization and grain growth are initiated by the heating bf the intrusion at a distance of about 35 m to the contact. As mentioned
above,
this distance
can be correlated
620 k 20°C. Referring to an intrusion depth ture for the low-high quartz transformation.
with a maximum
of about
temperature
of
5-7 km, this is the tempera-
DISCUSSION
Voll (1968) supposed that the beginning of grain growth during contact metamorphism may be initiated by the low-high quartz transformation. This assumption may be supported by the data of Joesten (1983) and the data presented in this paper. Recrystallization and grain growth are both explained by migrating high-angle grain boundaries. The migration of grain boundaries is suggested to occur the following way (Gleiter and Chalmers, 1972): Suppose, two grains are separated by a
115
grain
boundary
emission absorption model
of definite
of atoms
from
thickness.
the steps
of the same number
refers to metals.
SiO, tetrahedra
of atoms
The grain
area in the crystal lattice.
Grainboundary
on the surface
occurs
by
the
grain
and
by
at the steps of the growing
boundary
is assumed
It has not been proven
is involved
migration
of the shrinking
in the migration
grain.
to be a strongly
that the transfer
of grain
This
distorted
of single atoms or
boundaries
between
quartz
crystals. Assuming a transfer of single atoms, the strong Si-0 bond has to be broken. Grain boundary migration would then be correlated with a high activation energy.
This
migration
situation
of grain
hydrolysis,
is more
boundaries
and a transfer
favorable (Hobbs,
of single
if water
molecules
1968). The Si-0
atoms
are involved
bond
will be favored
in the
will be broken
(hydrolytic
by
weakening,
Griggs 1967). However, investigations to understand the nature and the behaviour of grain boundaries in silicates still have to be done. Experiments with metal alloys have shown that the mobility of grain boundaries depends on the energy of the grain boundary. That is, it depends on the disordered state of the crystal lattice in the grain boundary (Gleiter and Chalmers, 1972). An increase of the disordered state of the atoms in the grain boundary would result in a reduction of the activation energy for grain-boundary grain growth
migration.
should
In quartz
The threshold
temperature
for recrystallization
and
then decrease.
bearing
materials,
an
additional
distortion
of the grain-boundary
structure is caused by the low-high quartz transformation. The low quartz structure consists of a tetrahedral network in which tetrahedra are joined in a double spiral with two nonintersecting
threads
around
the trigonal
axis. The two states (Y, and (Ye
of low quartz of the same enatiomorph (left or right handed) are transformed into each other by a diad axis coinciding with the trigonal axis. These two states correspond to Dauphine twin domains which differ by tilt angles of opposite direction. Low-quartz, thus, consists of two equilibrium states (Y, and a*. An individual described Megaw
chain parallel to directions [loo], [OlO] or [llO] of the tetrahedra may be as a particle in a double minimum potential (Liebau and Bohm, 1982). (1973) suggested
temperature,
that in a temperature
the low-quartz
single crystal
These Dauphine
twin domains
of the domain
walls
transition states
temperature
were
having
observed
the chains
(Y, and CX*.These fluctuations
start
region
breaks
slightly
strongly
temperature
by Van
Tendeloo
to fluctuate
increase
below
the transition
up into small (r, and a2 domains. dependent et al. (1976).
between
fluctuations Near
the
the two permissible
when the temperature
is raised above
the transformation temperature T,. Below T, such fluctuations are correlated, yielding microdomains (Liebau and Bohm, 1982). Above T, the long-range correlation ceases. Each chain fluctuates independently between the two equivalent minimum states in a double minimum potential. The P-quartz structure can be concieved as both a geometrical and a time average of the two equilibrium positions. The most important point of the low-high quartz transformation mechanism is the fluctuation of the SiO, tetrahedra at the transformation temperature T,. These
116
fluctuations
are supposed
An increase
of the disordered
activation
to increase
energy needed
the disordered
state of a quartz grain-boundary.
state of the grain boundary
for grain-boundary
migration;
from the surface of one grain into the grain boundary, surface
of the growing
The
low-high
temperature
of the
of atoms
and from the boundary
to the
grain.
quartz
range
results in a lowering that is, the transfer
transformation
between
530”
and
shows 572°C
a volume (Taylor,
change
1972).
of 1.6% in a
This
results
in an
additional drfving force for grain-boundary migration. The quartz aggregates in the glaucophane-mica schists are enclosed by other minerals like phengite, feldspar. chlorite and biotite. An increase of the volume of quartz grains in the quartz aggregates causes a stress in the quartz, and of course in the surrounding minerals. However, stress on the quartz grains results in an additional driving force for grain boundary migration, thus, accelerating grain-boundary migration. Voll (1976) recrystallization
reported a threshold temperature of 290°C for the beginning of quartz in the Swiss Alps. These quartz were heated during
of the
Alpine orogeny. Voll has pointed out that the reason for the lower threshold temperature for recrystallization of quartz in regional metamorphic rocks is the great difference heating
in time during
time is supposed
the intrusion,
which the rock series were heated. to be lOOO-100,000
the depth
of the intrusion,
years, depending
and the dimension
In contact
aureoles
the
on the temperature
of
of the intrusive
body.
However, the heating time during regional metamorphism is up to four orders of magnitude higher. At the threshold temperature of 290°C for the recrystallization of quartz. only a few atoms will be transferred from one grain to the other grain in a short time, like the heating time of an intrusion. The only small transfer of atoms in a short time (1000 years) results in a nearly invisible displacement of the grain boundary. However, the threshold temperature for recrystallization is not only a function of the heating time, but it is also affected by the stored strain energy. The threshold
temperature
rocks from outside
decreases
quartz
as the rocks inside
stored
strain
recrystallization
energy
with increasing
the Traversella the contact
of the quartz
of quartz
contact aureole. grains
is really initiated
deformation
aureole
Therefore, does
(Haasen,
1974). The
show the same highly not
it can be assumed differ
by the low-high
very quartz
Knowing the depth of an intrusion, a low-high quartz transformation be derived by measuring the beginning of the quartz recrystallization aureole.
much,
strained that the and
the
transformation. isograde may in a contact
ACKNOWLEDGEMENTS
The author would like to thank Prof. Dr. G. Voll for the problem reported here, for critical reading the manuscript, and sions. Thanks are also due to Prof. Dr. H. Gleiter for use of the facilities in his institute. My thanks also go to Dr. S. Vogler and
introduction to the stimulating discuselectron microscopy H. Hofer for critical
117
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