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Kinks in mica: Role of dislocations and (001) cleavage
49
‘I~ctonoph_vsics. 127 (1986) 49-65 Eisevier
Science
Publishers
B.V.. Amsterdam
- Printed
in The Netherlands
KINKS IN MICA: ROLE OF DISLOCATIONS
(Received
June 24, 1985; revised version accepted
December
AND (001) CLEAVAGE
13, 1985)
ABSTRACT Bell. I.A.. Wilson, C.J.L., McLaren, and (001) cleavage. Kinking
in natural
transmission kink band
electron
(KBBs).
Gentle
where (001) planes
between
active slip planes together
dilation
occur
observed
deformed
biotite
and
(TEM). It is found that complex
process;
parallel
M.A., 1986. Kinks in mica: Role of dislocations
127: 49-65.
and experimentally microscopy
boundaries
A.C. and Etheridge,
Tectonophysirs,
bending
of (001) planes
are bent several degrees,
plays
KBBs which may be applicable
and
the KBB. A model
to other crystalline
has been
in complex
wails
to (001). Microfracturing
and
is presented
materials
by
role in the kinking
are observed
parallel
investigated
exist in the vicinity of
an important
edge dislocations
with broad bands of dislocations
to (001) planes
muscovite
mjcrostructures
to explain
the origin
of
with only one active slip plane.
INTRODUCTION
The purpose in the bending
of this paper is to examine and
kinking
of natural
the role of dislocations and experimentally
and (001) cleavage
deformed
biotite
and
muscovite, using trans~ssion electron microscope (TEM) observations. The samples examined in this study originated from large single crystals of biotite obtained from schists
adjacent
to the pegmatites
that occur at Mica Creek,
Mount
Isa, Australia
(Wilson, 1972). Kinking in micas is believed to be a result of slip parallel to (001). Slip directions parallel to [lOO] and (110) were predicted from “percussion” or “pressure” figures on (001) by Miigge (1898). The studies of Borg and Handin (1966) and Etheridge et al. (19’73), confirmed the slip directions to be [loo] and (110), assuming that kinking was caused by slip and that the direction of slip was normal to the kink axis. Crystallographic models to account for the angular characteristics of kink bands
* Present address:
Research
School of Earth Sciences, Australian
2600. Australia.
BOO-19~1/86/~03.50
8 1986 Elsevier Science Publishers
B.V.
National
University,
Canberra.
A.C.T.
50
(KBs)
micas
in
have been
(1983). These models ships across a sharp that sharp continuous
band
to deformation understood.
kink band boundary
(McLaren
mechanisms,
(1968) and
and involve
(KBB).
Baronnet
and
near coincidence
However,
Olives
relation-
our investigations
scale may be characterised
by a more
show gradual.
on the TEM scale and may be referred to as a and Etheridge, 1980). Despite its obvious importance the detailed structure of KBBs in micas is poorly
OBSERVATIONS
The as-collected are bounded
Fig;1.
by Starkey
ideal geometry
KBBs on the optical change in orientation
deformation
OPTICAL
proposed
assume
by regions
0pd& -graphs
Experimentally experimentally
natural
deformed deformed
by TEM. For explanation
micas contain
isolated
a few millimeters
of KBs cut normal biotite
sample
see text.
to (001). The KBBs
wide over which the (001) cleavage
to the KBB and (001) planes.
compressed
biotite single crystal,
KBBs normal
parallel
A. Natural
to [310]. C. Muscovite
planes
biotite.
inclusion
sample 830. Areas 1, 2 and 3 have been examined
B.
in an in detail
51
are curved range
boundary from
through
from
4-6”
10 to 40”.
and additional
undeformed
deformed 3kbar
areas
in the apparatus
and strain
microstructure
(Fig. The
1A). The angles largest
planar
rotation
boundaries
within
single
described
of rotation of (~1)
(Fig. 1B) was examined
across
occur at a. Cylindrical
biotite
crystals
by Paterson
rates of approximately
of (001) across
occurs
lop4
s-’
by
cores were taken
Etheridge
(1971)
(1970) at confining to produce
in detail by Etheridge
KBBs
the central and
pressures
of
kinks. The resulting
et al. (1973).
Plate-like muscovite inclusions intergrown with the natural biotite are common. The muscovite inclusion in an experimentally deformed sample (Fig. 1C) shows optically continuous bending at BI and a KBB the surrounding biotite. Bl is an anticlockwise anticlockwise bending (area 2), whereas KB2 surrounded by anticlockwise bending (area 3).
at KB2, mimicking the structure in (area 1) bend of (001) bounded by is a clockwise kink (26”) of (001) Bending of (001) near Bl tends to
broaden this boundary, whereas at KB2 the kinking and bending are in the opposite sense and there is a reduction of the width. In order to correlate the crystal defects of Bl
and
KB2 with
ion-beam
thinned
the optical
observations,
and re-examined
the sample
in the electron
has been
progressively
microscope.
TEM OBSERVATIONS
Three samples showing well-developed KBBs were selected and examined by TEM at 200 kV: a natural biotite and two experimental samples, 830 (shortened 20% parallel to (310) at 3OO’C) and 839 (shortened 20% parallel to (001) at 600°C). Muscovite inclusions have been found in the deformed sample 830 (Fig, 1C). Radiation damage in the electron beam occurs in both biotite and muscovite. However, it is significantly less in the muscovite and this has made it possible examine the crystal defects associated with the KBBs in this mineral.
to
Natural biotite The natural biotite has a 2M, structure and has been cut so that the few naturally induced KBBs were normal to the specimen foil. Several (001) foils were also prepared and observed in the electron microscope; to minimise generation of dislocations
during
preparation
of samples
by cleavage
techniques,
very thick foils
f - 100 pm) were cleaved and then ion-beam thinned. Rapid radiation damage in the microscope of the biotites precludes informative bright field (BF) or dark field (DF) micrographs
and most of the results have been deduced
from diffraction
photos
or
observations of shapes and sizes of KBBs. Similar microstructures exist both within and outside a kink band. There was a low to medium density (approximately 15 pm-‘) of stacking faults on (001) with the fault vectors: R 1.4 = i f]OIOl;
R,., = & 6[310] or R,,
= t- +[3iO]
Fig. 2. BF micrographs
of natural
section
dislocations.
showing
parallel
biotite.
A. An area within
a KB. B. KBB at h (Fig. 1A). C. A (001)
53
(Bell and
Wilson,
1977, 1981). No twins
occur outside
the KB, whereas within
were common
(Fig. 2A).
were observed.
the KBs dislocation
Occasional densities
dislocations
of p = 10’ cm-’
KBBs that are sharp on the scale of an optical micrograph (area b Fig. 1A) have a marked curvature of (001) on the TEM scale (Fig. 2B). The biotite has been divided into slabs (less than 0.3 pm wide) by cleavage along (001). Within of about curvature
the KBB, rotation
40” takes place across a region up to 0.2 pm wide, within which the is fairly constant. These regions of (001) rotation are V-shaped, with each
thin slab apparently having deformed and other areas are missing. Observations
of (001) sections
independently.
Parts of the KBB have cracked
(Fig. 2C) show two sets of pnrailel,
equally
spaced
(0.8 pm), dislocation images (p = 10’ cme2). Rapid degradation of the contrast by radiation damage made a Burgers vector analysis impossible. The majority of these dislocation
images are parallel
to the trace of the KBB which is [310]. that is, parallel
to the rotation axis of the kink. Assuming these dislocations are pure edge and are causing the bending of (001) adjacent to the KB shown in Fig. 1A. their Burgers vector is [llO]. The dislocations and may contribute
of the second
to the asymmetric
rotation
In areas between KBBs low densities of together with occasional partial ( p in Fig. 3A) similar to that in the as-collected biotites. bending or other deformation features in areas
set are approximately
15” from [310]
of (001) across a KBB.
stacking faults are found (Fig, 3A). and unit dislocations. Fault density is There are no dislocation networks, between KBs (Fig. 38).
BF micrographs (Fig. 3B, 4) of the KBBs generally show a gentle curvature of the (001) planes and V or Y-shaped areas. Diffraction patterns at KBBs (Figs. 3C-E) show intermediate orientations between the two extremes. Intermediate orientations are as small as 1’. They are closer to the KB orientation and
may not be observed
continuous
curvature
in the BF micrograph.
than the host orientation
Streaking
of the arcs is due to
of (001).
At most KBBs, tilting experiments show that the rotation axis of the kink boundary is contained in the (001) plane and is normal to the original compression direction. Occasionally, the kink is not a simple rotation of (001): as well as the rotation, a small (usually less than 5”) twist of (001) has occurred. Cleavage of (001) planes is associated with all KBBs (Fig. 4). This
cleavage
divides the biotite into curved slabs (of the order of 0.1 pm wide) and creates boomerang-shaped openings (Fig. 4A). These openings are commonly not symmetrical about the KBB and their curvature is not always continuous. In Fig. 4B, there are lineations at a high angle to (001) and stacking faults on either side of the KBB. These lineations may be walls of edge dislocations viewed edge-on. Fractures also occur parallel to KBBs (Fig. 4C) and are in part responsible for the Y-shaped
A
F
0.5 urn
Fig. 4. BF micrographs biotite.
of some common
A. (001) cleavage.
B. Lineations
features
normal
associated
with KBBs in experimentally
deformed
to (001) in the lower sectton of B. C. Cracking
parallel
to
the KBB.
(Fig. 4B). There is the possibility that some cleavage and fracturing occurred the sample preparation. Even so, these cleavages and fractures still highlight
regions
during
areas of crystal
weakness.
Experimentally deformed ~~~cou~~einclusions
These inclusions have the polytype structure (2M,) and the crystallographic orientation of the host biotite. The most common defects in the muscovites are dislocations, in association with stacking faults (Fig. 5) and cracks on (001) cleavage planes. Dark-field images and diffraction patterns (Fig. 5A-.D) recorded with increasing
tilt from the muscovite
inclusion
(Fig. 1C) show that the stacking
faults
and dislocations lie on the (001) plane (Fig. 5B-D). A series of micrographs taken under weak-beam conditions (Fig. 6) correspond with the features illustrated in Fig. 1C and are described
below.
Fig. 3. TEM microstructures within
associated
with experimentally
deformed
a KB. B. BF of KBBs (Bl and B2) with radii of curvature
patterns
from the host orientation
rows of 001 reflections, (corresponding
to the most
mediate
orientation
discrete
reflections,
reflections distinguished
spread
(H) and kink boundaries
indicating
three discrete
widely
is 19O from
an angle
due to streaking.
reflections)
exist between
In D, there are three
these are the host and
and an intermediate
KB orientations
orientation. respectively.
in the rest of the arc,
the host and KB orientations
area
Diffraction
The interIn E, many
the host and KB. These are approximatety
of 15”. However,
The angle between
A. DF of a typical
Bl and B2 respectively.
orientations;
the host and 4O from the KB orientations,
hence orientations, through
separated
biotite.
of less than 2 pm. C-E.
no reflections is 20’.
ten 008 can
he
hhl: ZM,
A
Fig. 5. DF micrographs muscovite.
Using
diffraction
patterns.
image widths
and diffraction
at various
tilts (T)
of an experimentally
are O”, l.S”, 6.5” and 23.5”, respectively.
A with inset of C. shows that the tilt axis is aligned parallel
for dislocations.
the same position
patterns
,q = 111 the tilts in A-D planar
defects
and faults increase
for increasing
in C and D. B. C and D have the same magnification.
deformed
A comparison
of
to the trace of (001). The tilt. Note that X indicates
5
S~~struc~~res in area 1 of Fig.
uniformly
distributed
6B there appear
IC.
Figure
6A shows
across the field of view, with a density
to have been individual
dislocations of 1
(001) planes containing
x
relatively
lo9 crne2. In Fig.
an active dislocation
source. On the active slip plane (S) the spacing between adjacent dislocations reasonably constant, suggesting that the dislocations cannot be piled up against object
outside
the field of view. In the active
slip plane
(X),
the dislocations
is an are
approximately parallel to the foil surface and are interacting strongly. The interaction can be seen as zig-zags of the dislocation Iine images and a network has developed.
This network,
Fig. 7. DF micrographs indicates
of dislocation
the same dislocation
some parallel
although
to U? = (310).
highly
structures
tilted,
is similar
in area 2 (see Fig. 1C). A. g=lll.
in B and C. Most of the dislocations A-C
and D-E
in appearance
are parallel
have the same magnification.
B-E,
to those
g = 331. Z
to U, = [IlO] but there are
59
networks
developed
slip planes slip planes, spacing
on (001) in cleaved samples
are separated
by 1 to 3 pm. Between
there is a dislocation
of dislocations
less well-defined 2 x 10” cm-‘.
In a nearby
1961). The active
the two most widely spaced
active
wall (W’,) at a high angle to (001) in which the
is approximately
dislocation
(Silk and Barnes,
wall (W,).
0.25 pm. About Dislocation
2 pm to the right there is a
density
in this micrograph
area closer to Bl (Fig. 6C) most of the dislocations
is are
associated with low-angle dislocation boundaries. A comparison of these micrographs clearly shows a transition from uniformly distributed dislocations to a more ordered dislocation structure comprising walls and active slip planes as the KBB is approached. Substructures at Bl and area 2 at Fig. IC. Figure 6D shows the dislocation structures found at the optically observed 10” bend boundary (Bl). The dislocation walls are well developed, but are no longer simple low-angle boundaries. For example, the walls labelled X are quite complex in that the dislocations pile-up against the wall. Most of the dislocations are either confined in walls or broad bands running normal to the walls, that is, parallel to (001). Figure 6E shows a broad KB containing
a high density
Further low-angle
across boundaries
of uniformly
the bend
(Fig. 7A-C)
distributed
dislocations.
the dislocation
and an increase
Fig. 8. A is a composite
of DF micrographs
There is a 9” rotation
walls
in dislocation
again
form
density
typical
is observed
cl
c
8
area& indicated.
boundary
of the Bl boundary.
B-D
of (001) across this boundary.
are diffraction
patterns
from the
60
between
the walls. Active
from the planar
faults are in contrast
wall (Fig. 7A). Figures but
at slightly
different
Fig. 9. A BF micrograph has cracked
(001) slip planes
are common.
Fringes
and can be seen to bend across the dislocation
7B and C are of the same area (note the disIocations tilts of the specimen.
of the KB 2 boundary
and the diffraction
1 to 2 pm apart
pattern
indicates
with
The dislocation
its corresponding
diffraction
that there are several discrete,
images
pattern. intermediate
at 2). at T are
The boundary orientations.
61
probably
parallel
to (310).
Just adjacent
tend to form walls (Figs. 7D-E). Figs. 6 and 7 indicate the reflecting
planes
axis is approximately
to KB 2, in area 2. the dislocations
The contrast
a misorientatioil
changes
across the dislocation
of the reflecting
are g = hhf where 1 varies between parallel
planes.
In these micrographs,
+ 3 and
to the trace of (001). The change
< 10’. Figure 8 is a mosaic across the bend boundary.
again walls in
- 3. Thus, the tilt of orientation
is
Bl. There are five well-devel-
oped dislocation walls giving rise to obvious contrast changes. The inset diffraction patterns are from the areas indicated and show that there is a 9” rotation of (001)
Fig. 10. A and B are DF micrographs u = (110).
of area 3. The dislocations
are scattered
and few dislocations
have
across the field of view (8 pm). Each dislocation about
2’. Similar boundaries
surrounding
biotite
grains.
wall produces
a misorientation
have been traced from the muscovite However,
no information
into the
on the dislocations
in the
biotites could be obtained due to rapid radiation damage. ~ubstru~tu~~ in KK? and area 3 uf Fig. t C. KB 2, which
is a distinct
boundary
is a 24” orientation
in the optical
study,
is illustrated
of
inclusion
in Fig. 9. There
planar
change of (001) and several discrete intermediate orientations in the corresponding diffraction pattern. The boundary is not planar but is off-set across cracks that are paraliel to the KBB and cleavages. Note the staggering of the lower part of the boundary. The associated diffraction patterns indicate a small twist of (001) has occurred at KB 2. Away from KB 2, in area 3, the dislocations tend to form walls (Fig. 10A). Dislocation images are only approximately parallel to [llO]. Some stacking
faults
and isolated
dislocations
are found
further
away from KB 2 (Fig.
10B). DISCUSSION
A general theory of kinking in crystalline material was developed by Frank and Stroh (1952) on the basis that a pair of KBBs is composed of simple walls of dislocations of opposite sign. Neither the natural nor experimental KBBs observed in the micas are simple dislocation walls or single arrays of dislocations as suggested by Starkey (1968). Nor do the KBBs involve simple coincidence lattice relationships as required by the model of Baronnet and Olives (1983). Instead, they are complex boundaries governed by varying (001) configurations and associated microfractures in a finite zone, which Etheridge et al. (1973) determined, from optical measurements,
to have widths of the order of 1 to 2 pm. Their observations
this TEM study. Other features (1) discrete
intermediate
(2) complex
dislocation
active slip planes containing
observed
orientations
are confirmed
by
include: within
walls of irregular
the KBs;
spacing
(Figs. 6-7)
between
which are
dislocations;
(3) higher dislocation densities within a KB than outside (Fig. 2A); (4) Y and boomerang-shaped openings between (001) planes produced cleavage; (5) regions of gentle (001) plane curvature related to the distribution cation walls and cracks subnormal to (001); (6) asymmetry of KBs related to the distribution of dislocations.
by (001) of dislo-
On the basis of these observations a model for the evolution of deformation bands or KBs in mica is suggested (Fig. 11). Initial bending of the lattice appears to involve slip solely on (001) with the generation of dislocations that are capable of producing dislocation walls. At low strains, relatively few slip planes are active and walls are rare, presumably due to the inhibition of climb in material with such a low stacking fault energy (Etheridge and Hobbs, 1974). The active slip planes divide the
63
1-I
l------K8
Fig. 11. A model
to explain
(001).
bending
A. Elastic
dislocation
density
dislocation
and
the origin
formation
walls and secondary
D. Creation
of dilatation
of TEM microstructures
of an elongated
crystal
of dislocation
parallel walls
that
associated to active
with shortening
slip plane
become
(001).
KB 1. C. Creation
KBs (KB 2) within the region of lattice misorientation
openings
along (001) cleavage
planes
parallel
that bound
to
B. increased of further
confined
to KB 1.
slabs with a constant
width
(d).
crystal
into
increases,
slabs
and
relieve
stress in the immediately
the elastic limit of material
between
adjacent
the slip planes is approached,
a necessity for more active slip planes and giving rise to dislocation Further bending is accommodated by creating more complicated walls between
areas.
the first formed walls that define the original
As strain creating
walls (Fig. 11 B). and additional
zone of lattice bending
(Fig. 11C). Arrays of active slip planes and tilt walls divide the crystal into blocks. As the relative rotation between these blocks increases, dislocation densities in the arrays increases. Eventually cleavages along (001) and, to a lesser extent, along KBBs will be energetically favoured over a further increase in dislocation density. This creates the boomerang-shaped dilatation openings at KBBs. It is clear from this study that what may be considered a simple KBB on an optical scale is in fact quite complex. These observations in mica are compatible with results described from other minerals where kinking is a consequence of slip on one glide plane. For instance, McLaren and Etheridge (1980) have demonstrated that optically distinct KBBs in orthopyroxene are also complex dislocation arrays. The presence of microfracturing in association with kinking has also been described in ice by Wilson et al. (1986), in other micas by Wilson and Bell (1979) and its occurrence
in orthopyroxene
is suggested
by the secondary
alteration
along
KBBs
64
(McLaren metals
and Etheridge,
(Fraser
1980). Where secondary
et al., 1973)
KBBs are produced
glide planes without
are activated,
e.g. in
the need to fracture
the
material. CONCLUSIONS
TEN observations of kinking in 2M, micas suggest that KBB morphologies do not conform to simple tilt boundaries involving the pile-up of dislocations belonging to a simple slip system, as in the models of McLaren and Etheridge (1980). nor do they fit the ideal geometrical models of Starkey (1968) or Baronnet and Ohves (1983). Instead, the KBB regions in these micas consist of a complex combination of (001) plane curvature, small highly deformed regions containing many dislocations and sometimes high stacking fault density, together with dilation by (001) cleavage. Fractures subparallel to KBBs also occur. Stacking faults are common in biotite, but few dislocation networks were observed. However, in the muscovites dislocation arrays occur in active slip planes and form tilt (with minor twist) walls. This confirms the conclusion of Bell and Wilson (1981) that there are significant differences in the way the two micas deform. Slip is restricted to (001) in both micas, but radiation damage prevents the direct observation of dislocations in the experimentally deformed biotite. In muscovite broad regions of bending (observed optically) consist of dislocation vvalls normal to the trace of (001) planes, with individual walls rotating (001) by up to 2”. Dislocation arrays also occur in active slip planes, where they range from widely-spaced, non-interacting configurations to well-developed networks. ACKNOWLEDGEMENTS
We wish to thank M.S. Paterson
for many stimulating
discussions
on the origin of
kinks. REFERENCES Baronnet,
A. and Ohves,
graphic
J., 1983. The geometry
model. Tectonophysics,
Bell. 1.A. and
of micas around
kink band boundaries
1. A crystallo-
91: 359-373.
Wilson,
C.J.L.,
1977. Growth
defects
Bell, LA. and Wilson,
C.J.L.,
1981. Deformation
in metamorphic
biotite.
Phys.
Chem.
Miner.,
2:
153-169. deformation Borg,
1.Y. and
model. Tectonophysics, Handin,
of biotite
and muscovite:
TEM
microstructure
deformation
of crystalline
rocks.
Tectonophysics,
and
78: 201-228.
J., 1966. Experimental
3:
249-368. Etheridge, foliated Etheridge, Contrib.
M.A., 1971. Experimental
investigations
rocks. Ph.D. Thesis, Australian M.A. and Hobbs,
Mineral
Petrol..
B.E., 1974. Chemical 43, 111-124.
of the mechanisms
National
University,
of mica preferred
Canberra,
and deformational
controls
orientation
in
A.C.T. (unpubt). on recrystallisation
of mica.
65
Etheridge,
M.A., Hobbs,
biotite.
Contrib.
B.E. and Paterson,
Mineral.
Petrol.,
MS.,
1973. Experimental
Frank,
F.C. and Stroh, A.N., 1952. On the theory
of kinking.
Fraser,
H.L., Smallman,
1973. The plastic
between
300°K
McLaren.
A.C.
deformed
R.E. and Loretto,
and 1050°K,
and
M.A.,
Paterson,
MS..
M.H..
1980.
II: Mechanisms
Miigge, 0.. 1898. LJber Translationen Geol. Palaontol..
of single crystals
of
Phys. Sot. Proc. Ser. B. 65: 811-821. deformation
of NiAl single crystals
I and II. Philos. Msg.. 28: 651-677.
Etheridge,
orthopyroxene.
deformation
38: 21-36.
A transmission of kinking.
und verwandte
electron
Bull. Mineral.,
Erscheinungen
microscope
study
of naturally
103: 558-563.
in Krystallen.
Neues Jahrb.
Mineral.
1: 71-158.
1970. A high-pressure,
high-temperature
apparatus
for rock deformation.
Int. J. Rock
in mica. Acta Metall..
9: 55X-562.
Mech. Min., Sci.. 7: 5177526. Silk, E.C.H. Starkey,
and Barnes,
RX.
1961. The observation
J.. 1968. The geometry
of dislocations
of kink bands in crystals-A
simple model. Contrib.
Mineral.
Petrol..
19:
133-141. Wilson.
C.J.L..
igneous Wilson,
1972. The stratigraphic
intrusions.
C.J.L.
and
Tectonophysics, Wilson,
C.J.L.,
Tectonophysics.
Proc. Australas. Bell, I.A.,
1979.
and metamorphic
sequence
west of Mount
Isa. and associated
Inst. Min. Metall. 243: 27-42. Deformation
of biotite
and
muscovite:
Optical
microstructure.
58: 179-200. Burg.
J.P.
and
127: 27-48.
Mitchell,
J.C.,
1986.
The
origin
of
kinks
in polycrystalline
ice.
‘I~ctonoph_vsics. 127 (1986) 49-65 Eisevier
Science
Publishers
B.V.. Amsterdam
- Printed
in The Netherlands
KINKS IN MICA: ROLE OF DISLOCATIONS
(Received
June 24, 1985; revised version accepted
December
AND (001) CLEAVAGE
13, 1985)
ABSTRACT Bell. I.A.. Wilson, C.J.L., McLaren, and (001) cleavage. Kinking
in natural
transmission kink band
electron
(KBBs).
Gentle
where (001) planes
between
active slip planes together
dilation
occur
observed
deformed
biotite
and
(TEM). It is found that complex
process;
parallel
M.A., 1986. Kinks in mica: Role of dislocations
127: 49-65.
and experimentally microscopy
boundaries
A.C. and Etheridge,
Tectonophysirs,
bending
of (001) planes
are bent several degrees,
plays
KBBs which may be applicable
and
the KBB. A model
to other crystalline
has been
in complex
wails
to (001). Microfracturing
and
is presented
materials
by
role in the kinking
are observed
parallel
investigated
exist in the vicinity of
an important
edge dislocations
with broad bands of dislocations
to (001) planes
muscovite
mjcrostructures
to explain
the origin
of
with only one active slip plane.
INTRODUCTION
The purpose in the bending
of this paper is to examine and
kinking
of natural
the role of dislocations and experimentally
and (001) cleavage
deformed
biotite
and
muscovite, using trans~ssion electron microscope (TEM) observations. The samples examined in this study originated from large single crystals of biotite obtained from schists
adjacent
to the pegmatites
that occur at Mica Creek,
Mount
Isa, Australia
(Wilson, 1972). Kinking in micas is believed to be a result of slip parallel to (001). Slip directions parallel to [lOO] and (110) were predicted from “percussion” or “pressure” figures on (001) by Miigge (1898). The studies of Borg and Handin (1966) and Etheridge et al. (19’73), confirmed the slip directions to be [loo] and (110), assuming that kinking was caused by slip and that the direction of slip was normal to the kink axis. Crystallographic models to account for the angular characteristics of kink bands
* Present address:
Research
School of Earth Sciences, Australian
2600. Australia.
BOO-19~1/86/~03.50
8 1986 Elsevier Science Publishers
B.V.
National
University,
Canberra.
A.C.T.
50
(KBs)
micas
in
have been
(1983). These models ships across a sharp that sharp continuous
band
to deformation understood.
kink band boundary
(McLaren
mechanisms,
(1968) and
and involve
(KBB).
Baronnet
and
near coincidence
However,
Olives
relation-
our investigations
scale may be characterised
by a more
show gradual.
on the TEM scale and may be referred to as a and Etheridge, 1980). Despite its obvious importance the detailed structure of KBBs in micas is poorly
OBSERVATIONS
The as-collected are bounded
Fig;1.
by Starkey
ideal geometry
KBBs on the optical change in orientation
deformation
OPTICAL
proposed
assume
by regions
0pd& -graphs
Experimentally experimentally
natural
deformed deformed
by TEM. For explanation
micas contain
isolated
a few millimeters
of KBs cut normal biotite
sample
see text.
to (001). The KBBs
wide over which the (001) cleavage
to the KBB and (001) planes.
compressed
biotite single crystal,
KBBs normal
parallel
A. Natural
to [310]. C. Muscovite
planes
biotite.
inclusion
sample 830. Areas 1, 2 and 3 have been examined
B.
in an in detail
51
are curved range
boundary from
through
from
4-6”
10 to 40”.
and additional
undeformed
deformed 3kbar
areas
in the apparatus
and strain
microstructure
(Fig. The
1A). The angles largest
planar
rotation
boundaries
within
single
described
of rotation of (~1)
(Fig. 1B) was examined
across
occur at a. Cylindrical
biotite
crystals
by Paterson
rates of approximately
of (001) across
occurs
lop4
s-’
by
cores were taken
Etheridge
(1971)
(1970) at confining to produce
in detail by Etheridge
KBBs
the central and
pressures
of
kinks. The resulting
et al. (1973).
Plate-like muscovite inclusions intergrown with the natural biotite are common. The muscovite inclusion in an experimentally deformed sample (Fig. 1C) shows optically continuous bending at BI and a KBB the surrounding biotite. Bl is an anticlockwise anticlockwise bending (area 2), whereas KB2 surrounded by anticlockwise bending (area 3).
at KB2, mimicking the structure in (area 1) bend of (001) bounded by is a clockwise kink (26”) of (001) Bending of (001) near Bl tends to
broaden this boundary, whereas at KB2 the kinking and bending are in the opposite sense and there is a reduction of the width. In order to correlate the crystal defects of Bl
and
KB2 with
ion-beam
thinned
the optical
observations,
and re-examined
the sample
in the electron
has been
progressively
microscope.
TEM OBSERVATIONS
Three samples showing well-developed KBBs were selected and examined by TEM at 200 kV: a natural biotite and two experimental samples, 830 (shortened 20% parallel to (310) at 3OO’C) and 839 (shortened 20% parallel to (001) at 600°C). Muscovite inclusions have been found in the deformed sample 830 (Fig, 1C). Radiation damage in the electron beam occurs in both biotite and muscovite. However, it is significantly less in the muscovite and this has made it possible examine the crystal defects associated with the KBBs in this mineral.
to
Natural biotite The natural biotite has a 2M, structure and has been cut so that the few naturally induced KBBs were normal to the specimen foil. Several (001) foils were also prepared and observed in the electron microscope; to minimise generation of dislocations
during
preparation
of samples
by cleavage
techniques,
very thick foils
f - 100 pm) were cleaved and then ion-beam thinned. Rapid radiation damage in the microscope of the biotites precludes informative bright field (BF) or dark field (DF) micrographs
and most of the results have been deduced
from diffraction
photos
or
observations of shapes and sizes of KBBs. Similar microstructures exist both within and outside a kink band. There was a low to medium density (approximately 15 pm-‘) of stacking faults on (001) with the fault vectors: R 1.4 = i f]OIOl;
R,., = & 6[310] or R,,
= t- +[3iO]
Fig. 2. BF micrographs
of natural
section
dislocations.
showing
parallel
biotite.
A. An area within
a KB. B. KBB at h (Fig. 1A). C. A (001)
53
(Bell and
Wilson,
1977, 1981). No twins
occur outside
the KB, whereas within
were common
(Fig. 2A).
were observed.
the KBs dislocation
Occasional densities
dislocations
of p = 10’ cm-’
KBBs that are sharp on the scale of an optical micrograph (area b Fig. 1A) have a marked curvature of (001) on the TEM scale (Fig. 2B). The biotite has been divided into slabs (less than 0.3 pm wide) by cleavage along (001). Within of about curvature
the KBB, rotation
40” takes place across a region up to 0.2 pm wide, within which the is fairly constant. These regions of (001) rotation are V-shaped, with each
thin slab apparently having deformed and other areas are missing. Observations
of (001) sections
independently.
Parts of the KBB have cracked
(Fig. 2C) show two sets of pnrailel,
equally
spaced
(0.8 pm), dislocation images (p = 10’ cme2). Rapid degradation of the contrast by radiation damage made a Burgers vector analysis impossible. The majority of these dislocation
images are parallel
to the trace of the KBB which is [310]. that is, parallel
to the rotation axis of the kink. Assuming these dislocations are pure edge and are causing the bending of (001) adjacent to the KB shown in Fig. 1A. their Burgers vector is [llO]. The dislocations and may contribute
of the second
to the asymmetric
rotation
In areas between KBBs low densities of together with occasional partial ( p in Fig. 3A) similar to that in the as-collected biotites. bending or other deformation features in areas
set are approximately
15” from [310]
of (001) across a KBB.
stacking faults are found (Fig, 3A). and unit dislocations. Fault density is There are no dislocation networks, between KBs (Fig. 38).
BF micrographs (Fig. 3B, 4) of the KBBs generally show a gentle curvature of the (001) planes and V or Y-shaped areas. Diffraction patterns at KBBs (Figs. 3C-E) show intermediate orientations between the two extremes. Intermediate orientations are as small as 1’. They are closer to the KB orientation and
may not be observed
continuous
curvature
in the BF micrograph.
than the host orientation
Streaking
of the arcs is due to
of (001).
At most KBBs, tilting experiments show that the rotation axis of the kink boundary is contained in the (001) plane and is normal to the original compression direction. Occasionally, the kink is not a simple rotation of (001): as well as the rotation, a small (usually less than 5”) twist of (001) has occurred. Cleavage of (001) planes is associated with all KBBs (Fig. 4). This
cleavage
divides the biotite into curved slabs (of the order of 0.1 pm wide) and creates boomerang-shaped openings (Fig. 4A). These openings are commonly not symmetrical about the KBB and their curvature is not always continuous. In Fig. 4B, there are lineations at a high angle to (001) and stacking faults on either side of the KBB. These lineations may be walls of edge dislocations viewed edge-on. Fractures also occur parallel to KBBs (Fig. 4C) and are in part responsible for the Y-shaped
A
F
0.5 urn
Fig. 4. BF micrographs biotite.
of some common
A. (001) cleavage.
B. Lineations
features
normal
associated
with KBBs in experimentally
deformed
to (001) in the lower sectton of B. C. Cracking
parallel
to
the KBB.
(Fig. 4B). There is the possibility that some cleavage and fracturing occurred the sample preparation. Even so, these cleavages and fractures still highlight
regions
during
areas of crystal
weakness.
Experimentally deformed ~~~cou~~einclusions
These inclusions have the polytype structure (2M,) and the crystallographic orientation of the host biotite. The most common defects in the muscovites are dislocations, in association with stacking faults (Fig. 5) and cracks on (001) cleavage planes. Dark-field images and diffraction patterns (Fig. 5A-.D) recorded with increasing
tilt from the muscovite
inclusion
(Fig. 1C) show that the stacking
faults
and dislocations lie on the (001) plane (Fig. 5B-D). A series of micrographs taken under weak-beam conditions (Fig. 6) correspond with the features illustrated in Fig. 1C and are described
below.
Fig. 3. TEM microstructures within
associated
with experimentally
deformed
a KB. B. BF of KBBs (Bl and B2) with radii of curvature
patterns
from the host orientation
rows of 001 reflections, (corresponding
to the most
mediate
orientation
discrete
reflections,
reflections distinguished
spread
(H) and kink boundaries
indicating
three discrete
widely
is 19O from
an angle
due to streaking.
reflections)
exist between
In D, there are three
these are the host and
and an intermediate
KB orientations
orientation. respectively.
in the rest of the arc,
the host and KB orientations
area
Diffraction
The interIn E, many
the host and KB. These are approximatety
of 15”. However,
The angle between
A. DF of a typical
Bl and B2 respectively.
orientations;
the host and 4O from the KB orientations,
hence orientations, through
separated
biotite.
of less than 2 pm. C-E.
no reflections is 20’.
ten 008 can
he
hhl: ZM,
A
Fig. 5. DF micrographs muscovite.
Using
diffraction
patterns.
image widths
and diffraction
at various
tilts (T)
of an experimentally
are O”, l.S”, 6.5” and 23.5”, respectively.
A with inset of C. shows that the tilt axis is aligned parallel
for dislocations.
the same position
patterns
,q = 111 the tilts in A-D planar
defects
and faults increase
for increasing
in C and D. B. C and D have the same magnification.
deformed
A comparison
of
to the trace of (001). The tilt. Note that X indicates
5
S~~struc~~res in area 1 of Fig.
uniformly
distributed
6B there appear
IC.
Figure
6A shows
across the field of view, with a density
to have been individual
dislocations of 1
(001) planes containing
x
relatively
lo9 crne2. In Fig.
an active dislocation
source. On the active slip plane (S) the spacing between adjacent dislocations reasonably constant, suggesting that the dislocations cannot be piled up against object
outside
the field of view. In the active
slip plane
(X),
the dislocations
is an are
approximately parallel to the foil surface and are interacting strongly. The interaction can be seen as zig-zags of the dislocation Iine images and a network has developed.
This network,
Fig. 7. DF micrographs indicates
of dislocation
the same dislocation
some parallel
although
to U? = (310).
highly
structures
tilted,
is similar
in area 2 (see Fig. 1C). A. g=lll.
in B and C. Most of the dislocations A-C
and D-E
in appearance
are parallel
have the same magnification.
B-E,
to those
g = 331. Z
to U, = [IlO] but there are
59
networks
developed
slip planes slip planes, spacing
on (001) in cleaved samples
are separated
by 1 to 3 pm. Between
there is a dislocation
of dislocations
less well-defined 2 x 10” cm-‘.
In a nearby
1961). The active
the two most widely spaced
active
wall (W’,) at a high angle to (001) in which the
is approximately
dislocation
(Silk and Barnes,
wall (W,).
0.25 pm. About Dislocation
2 pm to the right there is a
density
in this micrograph
area closer to Bl (Fig. 6C) most of the dislocations
is are
associated with low-angle dislocation boundaries. A comparison of these micrographs clearly shows a transition from uniformly distributed dislocations to a more ordered dislocation structure comprising walls and active slip planes as the KBB is approached. Substructures at Bl and area 2 at Fig. IC. Figure 6D shows the dislocation structures found at the optically observed 10” bend boundary (Bl). The dislocation walls are well developed, but are no longer simple low-angle boundaries. For example, the walls labelled X are quite complex in that the dislocations pile-up against the wall. Most of the dislocations are either confined in walls or broad bands running normal to the walls, that is, parallel to (001). Figure 6E shows a broad KB containing
a high density
Further low-angle
across boundaries
of uniformly
the bend
(Fig. 7A-C)
distributed
dislocations.
the dislocation
and an increase
Fig. 8. A is a composite
of DF micrographs
There is a 9” rotation
walls
in dislocation
again
form
density
typical
is observed
cl
c
8
area& indicated.
boundary
of the Bl boundary.
B-D
of (001) across this boundary.
are diffraction
patterns
from the
60
between
the walls. Active
from the planar
faults are in contrast
wall (Fig. 7A). Figures but
at slightly
different
Fig. 9. A BF micrograph has cracked
(001) slip planes
are common.
Fringes
and can be seen to bend across the dislocation
7B and C are of the same area (note the disIocations tilts of the specimen.
of the KB 2 boundary
and the diffraction
1 to 2 pm apart
pattern
indicates
with
The dislocation
its corresponding
diffraction
that there are several discrete,
images
pattern. intermediate
at 2). at T are
The boundary orientations.
61
probably
parallel
to (310).
Just adjacent
tend to form walls (Figs. 7D-E). Figs. 6 and 7 indicate the reflecting
planes
axis is approximately
to KB 2, in area 2. the dislocations
The contrast
a misorientatioil
changes
across the dislocation
of the reflecting
are g = hhf where 1 varies between parallel
planes.
In these micrographs,
+ 3 and
to the trace of (001). The change
< 10’. Figure 8 is a mosaic across the bend boundary.
again walls in
- 3. Thus, the tilt of orientation
is
Bl. There are five well-devel-
oped dislocation walls giving rise to obvious contrast changes. The inset diffraction patterns are from the areas indicated and show that there is a 9” rotation of (001)
Fig. 10. A and B are DF micrographs u = (110).
of area 3. The dislocations
are scattered
and few dislocations
have
across the field of view (8 pm). Each dislocation about
2’. Similar boundaries
surrounding
biotite
grains.
wall produces
a misorientation
have been traced from the muscovite However,
no information
into the
on the dislocations
in the
biotites could be obtained due to rapid radiation damage. ~ubstru~tu~~ in KK? and area 3 uf Fig. t C. KB 2, which
is a distinct
boundary
is a 24” orientation
in the optical
study,
is illustrated
of
inclusion
in Fig. 9. There
planar
change of (001) and several discrete intermediate orientations in the corresponding diffraction pattern. The boundary is not planar but is off-set across cracks that are paraliel to the KBB and cleavages. Note the staggering of the lower part of the boundary. The associated diffraction patterns indicate a small twist of (001) has occurred at KB 2. Away from KB 2, in area 3, the dislocations tend to form walls (Fig. 10A). Dislocation images are only approximately parallel to [llO]. Some stacking
faults
and isolated
dislocations
are found
further
away from KB 2 (Fig.
10B). DISCUSSION
A general theory of kinking in crystalline material was developed by Frank and Stroh (1952) on the basis that a pair of KBBs is composed of simple walls of dislocations of opposite sign. Neither the natural nor experimental KBBs observed in the micas are simple dislocation walls or single arrays of dislocations as suggested by Starkey (1968). Nor do the KBBs involve simple coincidence lattice relationships as required by the model of Baronnet and Olives (1983). Instead, they are complex boundaries governed by varying (001) configurations and associated microfractures in a finite zone, which Etheridge et al. (1973) determined, from optical measurements,
to have widths of the order of 1 to 2 pm. Their observations
this TEM study. Other features (1) discrete
intermediate
(2) complex
dislocation
active slip planes containing
observed
orientations
are confirmed
by
include: within
walls of irregular
the KBs;
spacing
(Figs. 6-7)
between
which are
dislocations;
(3) higher dislocation densities within a KB than outside (Fig. 2A); (4) Y and boomerang-shaped openings between (001) planes produced cleavage; (5) regions of gentle (001) plane curvature related to the distribution cation walls and cracks subnormal to (001); (6) asymmetry of KBs related to the distribution of dislocations.
by (001) of dislo-
On the basis of these observations a model for the evolution of deformation bands or KBs in mica is suggested (Fig. 11). Initial bending of the lattice appears to involve slip solely on (001) with the generation of dislocations that are capable of producing dislocation walls. At low strains, relatively few slip planes are active and walls are rare, presumably due to the inhibition of climb in material with such a low stacking fault energy (Etheridge and Hobbs, 1974). The active slip planes divide the
63
1-I
l------K8
Fig. 11. A model
to explain
(001).
bending
A. Elastic
dislocation
density
dislocation
and
the origin
formation
walls and secondary
D. Creation
of dilatation
of TEM microstructures
of an elongated
crystal
of dislocation
parallel walls
that
associated to active
with shortening
slip plane
become
(001).
KB 1. C. Creation
KBs (KB 2) within the region of lattice misorientation
openings
along (001) cleavage
planes
parallel
that bound
to
B. increased of further
confined
to KB 1.
slabs with a constant
width
(d).
crystal
into
increases,
slabs
and
relieve
stress in the immediately
the elastic limit of material
between
adjacent
the slip planes is approached,
a necessity for more active slip planes and giving rise to dislocation Further bending is accommodated by creating more complicated walls between
areas.
the first formed walls that define the original
As strain creating
walls (Fig. 11 B). and additional
zone of lattice bending
(Fig. 11C). Arrays of active slip planes and tilt walls divide the crystal into blocks. As the relative rotation between these blocks increases, dislocation densities in the arrays increases. Eventually cleavages along (001) and, to a lesser extent, along KBBs will be energetically favoured over a further increase in dislocation density. This creates the boomerang-shaped dilatation openings at KBBs. It is clear from this study that what may be considered a simple KBB on an optical scale is in fact quite complex. These observations in mica are compatible with results described from other minerals where kinking is a consequence of slip on one glide plane. For instance, McLaren and Etheridge (1980) have demonstrated that optically distinct KBBs in orthopyroxene are also complex dislocation arrays. The presence of microfracturing in association with kinking has also been described in ice by Wilson et al. (1986), in other micas by Wilson and Bell (1979) and its occurrence
in orthopyroxene
is suggested
by the secondary
alteration
along
KBBs
64
(McLaren metals
and Etheridge,
(Fraser
1980). Where secondary
et al., 1973)
KBBs are produced
glide planes without
are activated,
e.g. in
the need to fracture
the
material. CONCLUSIONS
TEN observations of kinking in 2M, micas suggest that KBB morphologies do not conform to simple tilt boundaries involving the pile-up of dislocations belonging to a simple slip system, as in the models of McLaren and Etheridge (1980). nor do they fit the ideal geometrical models of Starkey (1968) or Baronnet and Ohves (1983). Instead, the KBB regions in these micas consist of a complex combination of (001) plane curvature, small highly deformed regions containing many dislocations and sometimes high stacking fault density, together with dilation by (001) cleavage. Fractures subparallel to KBBs also occur. Stacking faults are common in biotite, but few dislocation networks were observed. However, in the muscovites dislocation arrays occur in active slip planes and form tilt (with minor twist) walls. This confirms the conclusion of Bell and Wilson (1981) that there are significant differences in the way the two micas deform. Slip is restricted to (001) in both micas, but radiation damage prevents the direct observation of dislocations in the experimentally deformed biotite. In muscovite broad regions of bending (observed optically) consist of dislocation vvalls normal to the trace of (001) planes, with individual walls rotating (001) by up to 2”. Dislocation arrays also occur in active slip planes, where they range from widely-spaced, non-interacting configurations to well-developed networks. ACKNOWLEDGEMENTS
We wish to thank M.S. Paterson
for many stimulating
discussions
on the origin of
kinks. REFERENCES Baronnet,
A. and Ohves,
graphic
J., 1983. The geometry
model. Tectonophysics,
Bell. 1.A. and
of micas around
kink band boundaries
1. A crystallo-
91: 359-373.
Wilson,
C.J.L.,
1977. Growth
defects
Bell, LA. and Wilson,
C.J.L.,
1981. Deformation
in metamorphic
biotite.
Phys.
Chem.
Miner.,
2:
153-169. deformation Borg,
1.Y. and
model. Tectonophysics, Handin,
of biotite
and muscovite:
TEM
microstructure
deformation
of crystalline
rocks.
Tectonophysics,
and
78: 201-228.
J., 1966. Experimental
3:
249-368. Etheridge, foliated Etheridge, Contrib.
M.A., 1971. Experimental
investigations
rocks. Ph.D. Thesis, Australian M.A. and Hobbs,
Mineral
Petrol..
B.E., 1974. Chemical 43, 111-124.
of the mechanisms
National
University,
of mica preferred
Canberra,
and deformational
controls
orientation
in
A.C.T. (unpubt). on recrystallisation
of mica.
65
Etheridge,
M.A., Hobbs,
biotite.
Contrib.
B.E. and Paterson,
Mineral.
Petrol.,
MS.,
1973. Experimental
Frank,
F.C. and Stroh, A.N., 1952. On the theory
of kinking.
Fraser,
H.L., Smallman,
1973. The plastic
between
300°K
McLaren.
A.C.
deformed
R.E. and Loretto,
and 1050°K,
and
M.A.,
Paterson,
MS..
M.H..
1980.
II: Mechanisms
Miigge, 0.. 1898. LJber Translationen Geol. Palaontol..
of single crystals
of
Phys. Sot. Proc. Ser. B. 65: 811-821. deformation
of NiAl single crystals
I and II. Philos. Msg.. 28: 651-677.
Etheridge,
orthopyroxene.
deformation
38: 21-36.
A transmission of kinking.
und verwandte
electron
Bull. Mineral.,
Erscheinungen
microscope
study
of naturally
103: 558-563.
in Krystallen.
Neues Jahrb.
Mineral.
1: 71-158.
1970. A high-pressure,
high-temperature
apparatus
for rock deformation.
Int. J. Rock
in mica. Acta Metall..
9: 55X-562.
Mech. Min., Sci.. 7: 5177526. Silk, E.C.H. Starkey,
and Barnes,
RX.
1961. The observation
J.. 1968. The geometry
of dislocations
of kink bands in crystals-A
simple model. Contrib.
Mineral.
Petrol..
19:
133-141. Wilson.
C.J.L..
igneous Wilson,
1972. The stratigraphic
intrusions.
C.J.L.
and
Tectonophysics, Wilson,
C.J.L.,
Tectonophysics.
Proc. Australas. Bell, I.A.,
1979.
and metamorphic
sequence
west of Mount
Isa. and associated
Inst. Min. Metall. 243: 27-42. Deformation
of biotite
and
muscovite:
Optical
microstructure.
58: 179-200. Burg.
J.P.
and
127: 27-48.
Mitchell,
J.C.,
1986.
The
origin
of
kinks
in polycrystalline
ice.