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Synthetic magnetic fabrics in a plasticene medium
Tectonophysics,
164 (1989) 73-78
1Letter Section 1
Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands
Synthetic magnetic fabrics in a plasticene medium G.J. BORRADAILE Department
ofGeology, Lakehead
and M.A. PUUMALA
University,
Thunder Bay, Ont. P7B SE1 (Canada)
(Accepted March 30,1989)
Abstract Borradaile, G.J. and Puumala, M.A., 1989. Synthetic magnetic fabrics in a plasticene medium. Tectonophysics,
164:
73-78. Mixtures of fenimagnetic
grains with a supporting medium of paramagnetic
plasticene permit hypotheses
concerning the interpretation of assemblages of different minerals to be confirmed. The deformation of such plasticene mixtures in pure shear, transpression and simple shear emphasize the dominance of the initial anisotropy over the end-result for low strains (< 25% shortening in pure shear). For minor amounts of multidomainal ferrimagnetic grains the deformation experiments indicate that the magnetic lineation rotates rapidly into the maximum extension direction for the three strain histories tested. Although the magnetic fabric directions are reliable kinematic indicators after modest strain, in simple shear the symmetry of the fabric is not a plane-strain fabric. Great discrepancies occur in the case of assemblages single-domain ferrimagnetic grams in plasticene. In pure shear these produce “inverse” fabrics in which the magnetic lineation spins towards parallelism with the maximum shortening
Introduction Recent work on the anisotropy of magnetic susceptibility (“am,” or “magnetic fabric”) of metamorphic
and deformed
rocks has followed
two interesting directions. Firstly, it has been shown by various methods that there may be several different minerals contributing to the ams of a rock (e.g., Coward and Whalley, 1979; Rochette and Vialon, 1984; Borradaile, 1988). Thus, Henry (1983) considered the effects of different mixtures of minerals on the resultant magnetic fabric. In practice this is very difficult to verify and hitherto the effects have been considered in theoretical models. Practical difficulties arise because real rocks are not homogeneous, nor uniform in mineralogy so that the interfering contributions of variation in mineralogy and variation in intensity of fabric (preferred orientation) cannot be distinguished. 0040-1951/89/$03.50
0 1989 Elsevier Science Publishers B.V.
direction.
Secondly, attention is being paid increasingly to the deformation processes responsible for the development of ams. An early conceptual model, the March model (e.g., see Hrouda,
1987),
has
been used frequently. In this, the rigid-body rotation of non-impinging
magnetic grains in a zero-
viscosity medium is taken as the simplest model of development of preferred orientation in a real tectonite. Owens (1974) emphasized that the actual strain-response model should embody a variety of processes (e.g., Borradaile 1988) to account for the rock fabric which in turn, is (at least partly) expressed in a magnetic fabric. Moreover, strain control may not be the appropriate factor. Stress induced orientation of newly crystallizing phases may be more influential in controlling the magnetic fabric of some metamorphic rocks. For example, traces of metamorphic pyrrhotite (Rochette, 1987a) or matrix-forming metamorphic products such as chlorite (Borradaile et
al., 1986) may appear during syntectonic morphism and dominate the ams. Experimental
deformation,
ture, of synthetic
aggregates
some
information
fabrics
on
(Borradaile these
simulations
at least
an order
than in nature, laboratory changes dent
to produce
strain-rates. in magnetic
(over
at room
tempera-
X ==5.8 Sl/unit
provides
maghemite
magnetic
U.1 microns
and Alford,
stresses,
1987, 1988). Nevrequire
high
of magnitude ductile
flow higher
deformation
Although fabrics
a period
the
at
Induced
are not time-depen-
of 2 years)
the high
flow
stresses probably could have the structure of ferrimagnetic
internal effects on grains which com-
plicate the effects rotation.
attributed
otherwise
Mineral grains used include magnctirc hami uith a grain NIX <)f 1. 0.149 mm. (suxxptibiht~
of minerals
strain-induced
ertheless,
meta-
to grain
mass).
grains
Sljunit
cene and to deform these aggregates in pure shear, simple shear and transpressional shear without stressing
the mineral
grains involved.
The materiab
Our plasticene was a colourless obtained from Mid-Canada Games
(grey) variety Ltd. * Its sus-
ceptibility is 650 X 10e6 SI/unit volume and its density is 1.764 g/cm2. The chief magnetic constituent is montmorillonite with a susceptibility of 2271 X low6 SI/unit mass after it has been degreased with hexane solvents and dried. The bulk of
the
plasticene
is
taken
up
by
portlandite
(Ca(OH),), calcite and oils (taken up by the clay) which have a C: H : N ratio of 28.23 : 3.45 : 0.02. The constituents
other
than montmorillonite
con-
tribute negligibly to the susceptibility. We do not know how variable these parameters are for the various brands of plasticene as the manufacturers would not supply us with information. However, our data are quite consistent for
f‘rom magnetI< solvent
pIat\ long x audio
orthochlorophr-
of the maghemitc
I> (J..Jhl
mabs.
We shall not these materials and feldspar)
report (and
all our experiments
others
using chlorite.
but the reader
these experiments
the above information. tion coil instrument This is a low-field
that
reproduced
Our measurements
are made with a Sapphire
with quartz
will appreciate
can be simply
Mixing experiments
ferent susceptibilities and different ams. This has allowed us to mix such mineral grains with plasti-
derived
nol. The susceptibilitv
medium
grains with dif-
0.5 micron>
thick)
strength
mineral
single-domam.
tapes using the dangerous
We have attempted to illuminate both these subjects by using plasticene as a deformable that can support
and
(measuring
instruments
using of ams
Sl-2 induc-
coupled with an IBM PC. * instrument with a r.m.s. field
of 0.6 Oe operating
at 750 HT.
Henry’s hypothesis (1983) hold that susceptibility contributions from different minerals may be simply added so that slight variations in mineralogy in rocks with the same uniform, fabric intensities produce simple linear plots on a k, (i = 1. 2, 3) versus k (average k-value) graph. Plasticene, being a model for a paramagnetic rock matrix, is mixed with different amounts of the magnetite. Ams measurements were made after kneading each sample in the same fashion. Despite the crude attempts to produce a “similar” fabric each time the results were remarkably successful (Fig. 1). Clearly, the three lines (two of which coincide) for the k, values of the specimens are very well defined,
and
they
do intersect
close
to k, = k.
Similarly successful mix-experiments were performed using chlorite grains and Ottawa sand and chlorite-magnetite mixtures. Those experiments confirm relationships inferred from less well-defined information in real rocks concerning the correlations between degree of anisotropy and bulk susceptibility (see Hrouda, 1987, fig. 3) and be-
the batch that we obtained.
* Sapphire * Mid-Canada
Games
Ltd., Downsview.
Ont. M3J 2P5.
2Go.
Instruments.
PO Box 385,
Ruthven.
Ont.
NOP
The impregnated plasticene three different strain histories:
Ki 6.0
shear), rolling shear). into
2 cm x 2 cm segments (carefully
standard
film is used
and prevent
/Vol.)
material
Plastic
the specimens
of the sample-holder.
After one magnetic
measurement
ment of deformation
is applied
is repeated
yet another
to obtain
into the
holder.
to encase
contamination
cut
these can be
orientation)
sample
(simple
is then
so that
preserving
2 cm-cubical
food-wrap
SI
and shearing
The layer of worked
stacked
( units are 10v2
(transpression)
is deformed by flattening (pure
a further
incre-
and the procedure experiment.
Fig. 1. Experiments with varying amounts of magnetite in a plasticene matrix. The principal susceptibilities (k,, i = 1, 2, 3) lie on straight lines (correlation coefficients given) - that intersect at a value corresponding to a theoretical isotropic fabric. k max and kint values coincide because the fabric is nearly perfectly oblate.
tween the proportion and bulk susceptibility
a)
of paramagnetic material (see Rochette 1987b, fig.
3). Deformation
experiments
Deformation experiments were performed on numerous mixtures of plasticene with mutidomainal magnetite sand grains and with single-domain (SD) maghemite grains. The latter is of interest because Rochette (1988, p. 185) and Potter and Stephenson (1988) predict that unusual “inverse” fabrics may develop using SD particles as the dominant source of ams. The ferrimagnetic grains increase the suceptibility of the samples at least a thousand-fold, so that
Flattening magnetite
deformation
kint
=A
in plasticene
kmin
= m
b) I.0
,
I n
n
’
’
the contribution of the montmorillonite-plasticene matrix to the ams can be ignored for practical
purposes.
However,
experiments
on
pure
plasticene produce very similar results to those shown here, due to the alignments imposed upon the paramagnetic montmorillonite. The main difference is that the fabrics are not quite so well defined. In all the experiments shown below the data points on the lower hemisphere, equal area stereonets have 95% confidence limits around the minimum susceptibility directions of the order of 2 or 3O in diameter. On the P’-T, fabric diagrams the error bars are smaller than the symbols used to plot the points.
-1.01
’
I.06
’
’ I-18
’
’ I .30
’
’ I.42
’
I.54
J I.66
P’ Fig. 2. Pure shear deformation of plasticene containing a trace of magnetite sand (grain size < 0.149 mm). (All stereonets are lower hemisphere, equal area.) Successive data points correspond to the.initial fabric and fabrics produced after 25%, 50% and 75% shortening. k_
axes congregate around the shorten-
ing direction (a) and ellipsoid shapes move to oblate forms as the degree of anisotropy (P') increases (b).
76
Pure shear experiments
represents the symmetrv shapes, are represented
These were the most difficult to perform as the of shortening are least accurate in
measurements this
strain
history.
The
agrams for flattening approximately results
data
points
refer, respectively, magnetite
cate that principal
susceptibilities
that kmin becomes
parallel
tion. The magnetic
fabric
these properties ventional
Flinn
to 0% and
diagrams
are compared
The
(Fig. 2) indispin rapidly
so
The results indicate strain.
However,
direc-
son predicted,
ellipsoid
moves
which
far into the field of flattening.
This is shown on a
P’- T diagram (Fig. 2b) in which P’ represents the degree of anisotropy quite separately from T which
GBSDO
-
rapidly
the
diagram
distinguishes than
of structural
the con-
geology. The
by Borradaile
for SD maghemite
(1988 ).
flakes
stmilarly
of the ams ellipsoid
as Rochette, “inverse”
maximum
toward
diagram
successfully
a rapid rotation
to the flattening swiftly
This
more
on the di-
25%, 50% and 75% shortening.
for multidomainal
by 0 < T-C I
shapes
of the ams ellipsoid. Rod by .- 1 -c T-c 0 and disc
with
Potter and Stephen-
fabrics
are produced
susceptibility
(k,,,)
parallelism
with
the
in
spins
shortening
axis (Fig. 3a). Note that this occurs with less than 2.5% shortening despite the unfavourable orientation of the initial susceptibility ellipsoid. Consequently the axial symmetry requires that the ams ellipsoid is rod-shaped although the deformation ellipsoid is disc-shaped (Fig. 3b).
GBSD3
a)
Rolling (“transpressionul”)
experiments
The plasticene-mineral mixtures were rolled with a domestic rolling-pin, to predetermined thicknesses
corresponding
to successive
shorten-
ings of approximately 25%, 50% and 75%. Ams measurements were then made in the manner outsingle - domoin moghemite flottening
deformotion
kmox
=
kint
.A
kmm
=
l n
b, I.0 I
lined previously. The rolling action was hypothesized to produce k max lineations perpendicular to the direction of rolling. However, this is not the case. The magnetic lineation is found repeatedly to lie parallel to the direction of rolling, i.e. the direction of shearing (Fig. 4a). This is taken to indicate the important, perhaps dominant, transpressional component of the shearing action produced during rolling. Again, the principal susceptibilities spin rapidly,
-,.,I
I.02
I.04
I.06
I.06
P’ Fig. 3. Pure shear deformation of plasticene containing a trace
in this case so that k,,,
lies perpendicular
to the shearing/ rolling plane. The fabrics produced are progressively more flattened as deformation proceeds, moving away from the initially unfavourable, neutral fabric shape for the example shown in Fig. 4b.
of single-domain size ( ~1 micron) fenimagnetic grains. k,, axes rapidly spin to align with the shortening direction giving an inverse fabric (a). Successive data points correspond
Simple shear experiments
to
approximately 0%. 25%, 50% and 75% shortening. The initial shape of the fabric is neutral (b) but moves rapidly into the prolate field.
These are more precise experiments since there is better control on the amount of strain. The
77
R.D.
the shear plane in a sense kinematically
e
a)
compati-
ble with an S-fabric (Fig. 5).
PI
One might have hypothesized that the ultimate fabric in a shear zone would be a plane-strain (neutral ellipsoid) fabric showing neither flattening nor constriction. close to plane
Although the initial fabric is
strain,
only the first increment
moves the fabric towards constriction.
Thereafter,
the fabric becomes progressively more flat-shaped. Thus
the magnetic
fabric
simple interpretation
does not reflect
the
that it should be congruent
with plane-strain. ” Rolling
pin”
deformation
kint
.A
kmin
=
n
shear
a) 4T
direction
GBPLO
-
7
fi
0.
- 0.5
-
t
-1.01
’
’
’
I.08
’ II6
’
’ 1.24
’
’ I.32
’
’
’
I.40
P’ Fig. 4. Transpressional deformation produced by a rolling-pin
simple
on plasticene with traces of magnetite sand. Successive data points correspond to OS, 25%, 50% and 75% thinning of the plasticene sample. k,,
aligns strongly with the rolling direc-
shear
for 8 = 0
to 2.8
increments
of
in
0.4
kint
=A
kmin
=
n
tion (R.D.) see (a). The ams fabric becomes oblate.
plasticene-magnetite mixture is shaped into a 2 cm cube. After an initial measurement of ams the specimen is sheared with a shear strain of 0.4 in a shear box. The material is then carefully cut and the parts reassembled to re-form a 2 cm cube, being careful to preserve the orientation of the parts. A further ams measurement is then taken and the experiment required.
repeated as many times as
The k,, axis spins progressively to a position inclined away from the shear direction and at a high angle to the plane of shear. Thus the magnetic fabric plane k,, - kint becomes inclined to
-
I
I.0 I.10
/ I.20
I
i
I.30
P’ Fig. 5. Simple shear deformation of plasticene with a trace of magnetite sand. Successive data points correspond to the initial fabric and increments of shear strain of 0.4 in a shear-box, to a maximum shear strain of 2.8. The principal directions spin so that k,,
defines a direction that is kinematically compatible
with simple shear (a). However, the ams ellipsoid shape is oblate rather than neutral in shape as one might expect.
7x
Conclusions
References
(1) Hem-y’s hypothesis susceptibility
that different
sources of
give rise to characteristic
k, versus k
plots is confirmed. multi-domainal
ferrimagnetic
“ inverse”
rod-shaped in nature
that
matic indicators. (3) In a rolling-type,
foland
fabrics
combinations
of SD
lead to mag-
be misleading
as kinedeforma-
tion the magnetic lineation develops parallel to the rolling direction. The ellipsoids are disc-shaped. (4) In simple shear, the magnetic fabric rapidly spins to an S-fabric orientation (using the S-C notation of structural geologists). Although the deformation is plane strain, the magnetic fabrics are disc-shaped. (5) In all of the above experiments, although limited in analogy to natural the importance of the initial
rock deformation, magnetic fabric is
clearly seen at low strains. For shear of less than 25% shortening cipal
susceptibility
material
directions
that are somewhat
of strain directions. strains, tibilities
in
this
unreliable
pure prin-
artificial indicators
Borradaile,
G.J. G.J..
Planet. Coward,
Western
axes.
Acknowledgments Graham Borradaile acknowledges the support of NSERC grant no. A6861 and the constructive criticism of Mel Friedman.
J. Strut.
cxpen-
Expenmental Geol.,
J.. ‘Tarling.
Whalley,
shear
10: X95--904.
D. and
m a slate.
J.S..
the Kishorn
Scotland.
susceptibilite
Alford, Phv\.
J. Struct.
physics,
near
Geol..
C.,
Earth. fabnc
de I’anisotropie
Tectonophysics, model
anisotropv
and
Kyle of Lochalsh,
1: 259-273.
quantitative
F.. lY87. Mathematical
the paramagnetic
1979. Texture
nappe,
magnetique.
relationshtp
and strain
de
91: 165.-177. between
in slates. Tectono-
142: 323- 327
W.H..
affecting
1974. Mathematical the
magnetic
Tectonophysics.
model
anisotropy
studies
of
on factors
deformed
rocks.
24: 115 - 131.
Potter, D.K. and Stephenson, in rocks and magnetic
A., 1988. Single domain
fabric analysis.
Geophys.
particles Res. Lett..
1.5: 1097-1100. Rochette,
P., 1987a. Metamorphic
control
black shales in the Swiss Alps: toward isograds”. Rochette, related
Earth Planet. to magnetic
of the mineralogy
of
the use of “ magnetic
Sci. Lett., 84: 446-456.
P.. 1987b. Magnetic
susceptibility
fabric
studies.
of the rock matrix J. Struct.
Geol..
9:
1015-1020. Rochette,
P.. 1988.
La susceptibilitC
faiblement
magnktiques-orogines
University
of Grenoble.
Rochette,
P. and Vialon,
studied
with strain
between
in laboratory
C.‘.. 1988.
fabrics.
B., 1983. Interpretation
Owens,
stram
of susceptibility
and
tested, there suscep-
Alford,
Mothersill.
across
for each of the strain histories
of principal
C‘., 1’187. RelationshIp and
Inter., 48: I61 - 166. M.P.
studies Henry,
petrofahnc,
I -20.
133: 12 I 135.
and
1986. Sources
linear fabrics
alignments
Alford.
cones and magnetic
such modest
strong
and
usceptibility,
156:
susceptibility
beyond
developed
However,
example, produces
Magnetic
ments. Tectonophysu,
Hrouda,
transpressional
1988.
Tectonophysica,
G.J.
magnetic
Borradaile,
markers
to the flattening
traces could
would
of
manner.
magnetic
perpendicular
Clearly,
fabrics
minerals
of orientation
(SD) sized ferrimagnetic
and MD ferrimagnetic netic
rotation
shape in a qualitative
with their lineation direction.
physical
predictions
Single-domain produce
simple
(MD)
March-type
fabric ellipsoid
G.J..
and strain. Borradaile.
(2) In pure shear lows
Borradaile,
des roches
of planar
shales and slates (French
amsotropy
Geol.. 6: 33-38.
Thesis,
211 pp.
P., 1984. Development
in Dauphinois
by magnetic
trol. J. Struct.
Grenoble,
anisotrope
et applications.
and its mineralogical
and Alps) con-
164 (1989) 73-78
1Letter Section 1
Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands
Synthetic magnetic fabrics in a plasticene medium G.J. BORRADAILE Department
ofGeology, Lakehead
and M.A. PUUMALA
University,
Thunder Bay, Ont. P7B SE1 (Canada)
(Accepted March 30,1989)
Abstract Borradaile, G.J. and Puumala, M.A., 1989. Synthetic magnetic fabrics in a plasticene medium. Tectonophysics,
164:
73-78. Mixtures of fenimagnetic
grains with a supporting medium of paramagnetic
plasticene permit hypotheses
concerning the interpretation of assemblages of different minerals to be confirmed. The deformation of such plasticene mixtures in pure shear, transpression and simple shear emphasize the dominance of the initial anisotropy over the end-result for low strains (< 25% shortening in pure shear). For minor amounts of multidomainal ferrimagnetic grains the deformation experiments indicate that the magnetic lineation rotates rapidly into the maximum extension direction for the three strain histories tested. Although the magnetic fabric directions are reliable kinematic indicators after modest strain, in simple shear the symmetry of the fabric is not a plane-strain fabric. Great discrepancies occur in the case of assemblages single-domain ferrimagnetic grams in plasticene. In pure shear these produce “inverse” fabrics in which the magnetic lineation spins towards parallelism with the maximum shortening
Introduction Recent work on the anisotropy of magnetic susceptibility (“am,” or “magnetic fabric”) of metamorphic
and deformed
rocks has followed
two interesting directions. Firstly, it has been shown by various methods that there may be several different minerals contributing to the ams of a rock (e.g., Coward and Whalley, 1979; Rochette and Vialon, 1984; Borradaile, 1988). Thus, Henry (1983) considered the effects of different mixtures of minerals on the resultant magnetic fabric. In practice this is very difficult to verify and hitherto the effects have been considered in theoretical models. Practical difficulties arise because real rocks are not homogeneous, nor uniform in mineralogy so that the interfering contributions of variation in mineralogy and variation in intensity of fabric (preferred orientation) cannot be distinguished. 0040-1951/89/$03.50
0 1989 Elsevier Science Publishers B.V.
direction.
Secondly, attention is being paid increasingly to the deformation processes responsible for the development of ams. An early conceptual model, the March model (e.g., see Hrouda,
1987),
has
been used frequently. In this, the rigid-body rotation of non-impinging
magnetic grains in a zero-
viscosity medium is taken as the simplest model of development of preferred orientation in a real tectonite. Owens (1974) emphasized that the actual strain-response model should embody a variety of processes (e.g., Borradaile 1988) to account for the rock fabric which in turn, is (at least partly) expressed in a magnetic fabric. Moreover, strain control may not be the appropriate factor. Stress induced orientation of newly crystallizing phases may be more influential in controlling the magnetic fabric of some metamorphic rocks. For example, traces of metamorphic pyrrhotite (Rochette, 1987a) or matrix-forming metamorphic products such as chlorite (Borradaile et
al., 1986) may appear during syntectonic morphism and dominate the ams. Experimental
deformation,
ture, of synthetic
aggregates
some
information
fabrics
on
(Borradaile these
simulations
at least
an order
than in nature, laboratory changes dent
to produce
strain-rates. in magnetic
(over
at room
tempera-
X ==5.8 Sl/unit
provides
maghemite
magnetic
U.1 microns
and Alford,
stresses,
1987, 1988). Nevrequire
high
of magnitude ductile
flow higher
deformation
Although fabrics
a period
the
at
Induced
are not time-depen-
of 2 years)
the high
flow
stresses probably could have the structure of ferrimagnetic
internal effects on grains which com-
plicate the effects rotation.
attributed
otherwise
Mineral grains used include magnctirc hami uith a grain NIX <)f 1. 0.149 mm. (suxxptibiht~
of minerals
strain-induced
ertheless,
meta-
to grain
mass).
grains
Sljunit
cene and to deform these aggregates in pure shear, simple shear and transpressional shear without stressing
the mineral
grains involved.
The materiab
Our plasticene was a colourless obtained from Mid-Canada Games
(grey) variety Ltd. * Its sus-
ceptibility is 650 X 10e6 SI/unit volume and its density is 1.764 g/cm2. The chief magnetic constituent is montmorillonite with a susceptibility of 2271 X low6 SI/unit mass after it has been degreased with hexane solvents and dried. The bulk of
the
plasticene
is
taken
up
by
portlandite
(Ca(OH),), calcite and oils (taken up by the clay) which have a C: H : N ratio of 28.23 : 3.45 : 0.02. The constituents
other
than montmorillonite
con-
tribute negligibly to the susceptibility. We do not know how variable these parameters are for the various brands of plasticene as the manufacturers would not supply us with information. However, our data are quite consistent for
f‘rom magnetI< solvent
pIat\ long x audio
orthochlorophr-
of the maghemitc
I> (J..Jhl
mabs.
We shall not these materials and feldspar)
report (and
all our experiments
others
using chlorite.
but the reader
these experiments
the above information. tion coil instrument This is a low-field
that
reproduced
Our measurements
are made with a Sapphire
with quartz
will appreciate
can be simply
Mixing experiments
ferent susceptibilities and different ams. This has allowed us to mix such mineral grains with plasti-
derived
nol. The susceptibilitv
medium
grains with dif-
0.5 micron>
thick)
strength
mineral
single-domam.
tapes using the dangerous
We have attempted to illuminate both these subjects by using plasticene as a deformable that can support
and
(measuring
instruments
using of ams
Sl-2 induc-
coupled with an IBM PC. * instrument with a r.m.s. field
of 0.6 Oe operating
at 750 HT.
Henry’s hypothesis (1983) hold that susceptibility contributions from different minerals may be simply added so that slight variations in mineralogy in rocks with the same uniform, fabric intensities produce simple linear plots on a k, (i = 1. 2, 3) versus k (average k-value) graph. Plasticene, being a model for a paramagnetic rock matrix, is mixed with different amounts of the magnetite. Ams measurements were made after kneading each sample in the same fashion. Despite the crude attempts to produce a “similar” fabric each time the results were remarkably successful (Fig. 1). Clearly, the three lines (two of which coincide) for the k, values of the specimens are very well defined,
and
they
do intersect
close
to k, = k.
Similarly successful mix-experiments were performed using chlorite grains and Ottawa sand and chlorite-magnetite mixtures. Those experiments confirm relationships inferred from less well-defined information in real rocks concerning the correlations between degree of anisotropy and bulk susceptibility (see Hrouda, 1987, fig. 3) and be-
the batch that we obtained.
* Sapphire * Mid-Canada
Games
Ltd., Downsview.
Ont. M3J 2P5.
2Go.
Instruments.
PO Box 385,
Ruthven.
Ont.
NOP
The impregnated plasticene three different strain histories:
Ki 6.0
shear), rolling shear). into
2 cm x 2 cm segments (carefully
standard
film is used
and prevent
/Vol.)
material
Plastic
the specimens
of the sample-holder.
After one magnetic
measurement
ment of deformation
is applied
is repeated
yet another
to obtain
into the
holder.
to encase
contamination
cut
these can be
orientation)
sample
(simple
is then
so that
preserving
2 cm-cubical
food-wrap
SI
and shearing
The layer of worked
stacked
( units are 10v2
(transpression)
is deformed by flattening (pure
a further
incre-
and the procedure experiment.
Fig. 1. Experiments with varying amounts of magnetite in a plasticene matrix. The principal susceptibilities (k,, i = 1, 2, 3) lie on straight lines (correlation coefficients given) - that intersect at a value corresponding to a theoretical isotropic fabric. k max and kint values coincide because the fabric is nearly perfectly oblate.
tween the proportion and bulk susceptibility
a)
of paramagnetic material (see Rochette 1987b, fig.
3). Deformation
experiments
Deformation experiments were performed on numerous mixtures of plasticene with mutidomainal magnetite sand grains and with single-domain (SD) maghemite grains. The latter is of interest because Rochette (1988, p. 185) and Potter and Stephenson (1988) predict that unusual “inverse” fabrics may develop using SD particles as the dominant source of ams. The ferrimagnetic grains increase the suceptibility of the samples at least a thousand-fold, so that
Flattening magnetite
deformation
kint
=A
in plasticene
kmin
= m
b) I.0
,
I n
n
’
’
the contribution of the montmorillonite-plasticene matrix to the ams can be ignored for practical
purposes.
However,
experiments
on
pure
plasticene produce very similar results to those shown here, due to the alignments imposed upon the paramagnetic montmorillonite. The main difference is that the fabrics are not quite so well defined. In all the experiments shown below the data points on the lower hemisphere, equal area stereonets have 95% confidence limits around the minimum susceptibility directions of the order of 2 or 3O in diameter. On the P’-T, fabric diagrams the error bars are smaller than the symbols used to plot the points.
-1.01
’
I.06
’
’ I-18
’
’ I .30
’
’ I.42
’
I.54
J I.66
P’ Fig. 2. Pure shear deformation of plasticene containing a trace of magnetite sand (grain size < 0.149 mm). (All stereonets are lower hemisphere, equal area.) Successive data points correspond to the.initial fabric and fabrics produced after 25%, 50% and 75% shortening. k_
axes congregate around the shorten-
ing direction (a) and ellipsoid shapes move to oblate forms as the degree of anisotropy (P') increases (b).
76
Pure shear experiments
represents the symmetrv shapes, are represented
These were the most difficult to perform as the of shortening are least accurate in
measurements this
strain
history.
The
agrams for flattening approximately results
data
points
refer, respectively, magnetite
cate that principal
susceptibilities
that kmin becomes
parallel
tion. The magnetic
fabric
these properties ventional
Flinn
to 0% and
diagrams
are compared
The
(Fig. 2) indispin rapidly
so
The results indicate strain.
However,
direc-
son predicted,
ellipsoid
moves
which
far into the field of flattening.
This is shown on a
P’- T diagram (Fig. 2b) in which P’ represents the degree of anisotropy quite separately from T which
GBSDO
-
rapidly
the
diagram
distinguishes than
of structural
the con-
geology. The
by Borradaile
for SD maghemite
(1988 ).
flakes
stmilarly
of the ams ellipsoid
as Rochette, “inverse”
maximum
toward
diagram
successfully
a rapid rotation
to the flattening swiftly
This
more
on the di-
25%, 50% and 75% shortening.
for multidomainal
by 0 < T-C I
shapes
of the ams ellipsoid. Rod by .- 1 -c T-c 0 and disc
with
Potter and Stephen-
fabrics
are produced
susceptibility
(k,,,)
parallelism
with
the
in
spins
shortening
axis (Fig. 3a). Note that this occurs with less than 2.5% shortening despite the unfavourable orientation of the initial susceptibility ellipsoid. Consequently the axial symmetry requires that the ams ellipsoid is rod-shaped although the deformation ellipsoid is disc-shaped (Fig. 3b).
GBSD3
a)
Rolling (“transpressionul”)
experiments
The plasticene-mineral mixtures were rolled with a domestic rolling-pin, to predetermined thicknesses
corresponding
to successive
shorten-
ings of approximately 25%, 50% and 75%. Ams measurements were then made in the manner outsingle - domoin moghemite flottening
deformotion
kmox
=
kint
.A
kmm
=
l n
b, I.0 I
lined previously. The rolling action was hypothesized to produce k max lineations perpendicular to the direction of rolling. However, this is not the case. The magnetic lineation is found repeatedly to lie parallel to the direction of rolling, i.e. the direction of shearing (Fig. 4a). This is taken to indicate the important, perhaps dominant, transpressional component of the shearing action produced during rolling. Again, the principal susceptibilities spin rapidly,
-,.,I
I.02
I.04
I.06
I.06
P’ Fig. 3. Pure shear deformation of plasticene containing a trace
in this case so that k,,,
lies perpendicular
to the shearing/ rolling plane. The fabrics produced are progressively more flattened as deformation proceeds, moving away from the initially unfavourable, neutral fabric shape for the example shown in Fig. 4b.
of single-domain size ( ~1 micron) fenimagnetic grains. k,, axes rapidly spin to align with the shortening direction giving an inverse fabric (a). Successive data points correspond
Simple shear experiments
to
approximately 0%. 25%, 50% and 75% shortening. The initial shape of the fabric is neutral (b) but moves rapidly into the prolate field.
These are more precise experiments since there is better control on the amount of strain. The
77
R.D.
the shear plane in a sense kinematically
e
a)
compati-
ble with an S-fabric (Fig. 5).
PI
One might have hypothesized that the ultimate fabric in a shear zone would be a plane-strain (neutral ellipsoid) fabric showing neither flattening nor constriction. close to plane
Although the initial fabric is
strain,
only the first increment
moves the fabric towards constriction.
Thereafter,
the fabric becomes progressively more flat-shaped. Thus
the magnetic
fabric
simple interpretation
does not reflect
the
that it should be congruent
with plane-strain. ” Rolling
pin”
deformation
kint
.A
kmin
=
n
shear
a) 4T
direction
GBPLO
-
7
fi
0.
- 0.5
-
t
-1.01
’
’
’
I.08
’ II6
’
’ 1.24
’
’ I.32
’
’
’
I.40
P’ Fig. 4. Transpressional deformation produced by a rolling-pin
simple
on plasticene with traces of magnetite sand. Successive data points correspond to OS, 25%, 50% and 75% thinning of the plasticene sample. k,,
aligns strongly with the rolling direc-
shear
for 8 = 0
to 2.8
increments
of
in
0.4
kint
=A
kmin
=
n
tion (R.D.) see (a). The ams fabric becomes oblate.
plasticene-magnetite mixture is shaped into a 2 cm cube. After an initial measurement of ams the specimen is sheared with a shear strain of 0.4 in a shear box. The material is then carefully cut and the parts reassembled to re-form a 2 cm cube, being careful to preserve the orientation of the parts. A further ams measurement is then taken and the experiment required.
repeated as many times as
The k,, axis spins progressively to a position inclined away from the shear direction and at a high angle to the plane of shear. Thus the magnetic fabric plane k,, - kint becomes inclined to
-
I
I.0 I.10
/ I.20
I
i
I.30
P’ Fig. 5. Simple shear deformation of plasticene with a trace of magnetite sand. Successive data points correspond to the initial fabric and increments of shear strain of 0.4 in a shear-box, to a maximum shear strain of 2.8. The principal directions spin so that k,,
defines a direction that is kinematically compatible
with simple shear (a). However, the ams ellipsoid shape is oblate rather than neutral in shape as one might expect.
7x
Conclusions
References
(1) Hem-y’s hypothesis susceptibility
that different
sources of
give rise to characteristic
k, versus k
plots is confirmed. multi-domainal
ferrimagnetic
“ inverse”
rod-shaped in nature
that
matic indicators. (3) In a rolling-type,
foland
fabrics
combinations
of SD
lead to mag-
be misleading
as kinedeforma-
tion the magnetic lineation develops parallel to the rolling direction. The ellipsoids are disc-shaped. (4) In simple shear, the magnetic fabric rapidly spins to an S-fabric orientation (using the S-C notation of structural geologists). Although the deformation is plane strain, the magnetic fabrics are disc-shaped. (5) In all of the above experiments, although limited in analogy to natural the importance of the initial
rock deformation, magnetic fabric is
clearly seen at low strains. For shear of less than 25% shortening cipal
susceptibility
material
directions
that are somewhat
of strain directions. strains, tibilities
in
this
unreliable
pure prin-
artificial indicators
Borradaile,
G.J. G.J..
Planet. Coward,
Western
axes.
Acknowledgments Graham Borradaile acknowledges the support of NSERC grant no. A6861 and the constructive criticism of Mel Friedman.
J. Strut.
cxpen-
Expenmental Geol.,
J.. ‘Tarling.
Whalley,
shear
10: X95--904.
D. and
m a slate.
J.S..
the Kishorn
Scotland.
susceptibilite
Alford, Phv\.
J. Struct.
physics,
near
Geol..
C.,
Earth. fabnc
de I’anisotropie
Tectonophysics, model
anisotropv
and
Kyle of Lochalsh,
1: 259-273.
quantitative
F.. lY87. Mathematical
the paramagnetic
1979. Texture
nappe,
magnetique.
relationshtp
and strain
de
91: 165.-177. between
in slates. Tectono-
142: 323- 327
W.H..
affecting
1974. Mathematical the
magnetic
Tectonophysics.
model
anisotropy
studies
of
on factors
deformed
rocks.
24: 115 - 131.
Potter, D.K. and Stephenson, in rocks and magnetic
A., 1988. Single domain
fabric analysis.
Geophys.
particles Res. Lett..
1.5: 1097-1100. Rochette,
P., 1987a. Metamorphic
control
black shales in the Swiss Alps: toward isograds”. Rochette, related
Earth Planet. to magnetic
of the mineralogy
of
the use of “ magnetic
Sci. Lett., 84: 446-456.
P.. 1987b. Magnetic
susceptibility
fabric
studies.
of the rock matrix J. Struct.
Geol..
9:
1015-1020. Rochette,
P.. 1988.
La susceptibilitC
faiblement
magnktiques-orogines
University
of Grenoble.
Rochette,
P. and Vialon,
studied
with strain
between
in laboratory
C.‘.. 1988.
fabrics.
B., 1983. Interpretation
Owens,
stram
of susceptibility
and
tested, there suscep-
Alford,
Mothersill.
across
for each of the strain histories
of principal
C‘., 1’187. RelationshIp and
Inter., 48: I61 - 166. M.P.
studies Henry,
petrofahnc,
I -20.
133: 12 I 135.
and
1986. Sources
linear fabrics
alignments
Alford.
cones and magnetic
such modest
strong
and
usceptibility,
156:
susceptibility
beyond
developed
However,
example, produces
Magnetic
ments. Tectonophysu,
Hrouda,
transpressional
1988.
Tectonophysica,
G.J.
magnetic
Borradaile,
markers
to the flattening
traces could
would
of
manner.
magnetic
perpendicular
Clearly,
fabrics
minerals
of orientation
(SD) sized ferrimagnetic
and MD ferrimagnetic netic
rotation
shape in a qualitative
with their lineation direction.
physical
predictions
Single-domain produce
simple
(MD)
March-type
fabric ellipsoid
G.J..
and strain. Borradaile.
(2) In pure shear lows
Borradaile,
des roches
of planar
shales and slates (French
amsotropy
Geol.. 6: 33-38.
Thesis,
211 pp.
P., 1984. Development
in Dauphinois
by magnetic
trol. J. Struct.
Grenoble,
anisotrope
et applications.
and its mineralogical
and Alps) con-