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Mechanisms of fracture propagation in experimentally extended Sioux quartzite
259
Tectonophysics, 182 (1990) 259-218
Elsevier Science Publishers B.V.. Amsterdam
Mechanisms of fracture propagation in experimentally Sioux quartzite
extended
Duncan Mardon *, Andreas K. Kronenberg, John Handin, Melvin Friedman and James E. Russell Centerfor Tectonophysics, Texas A&M University, College Station, TX 77843 (U.S.A.) (Received November 30,1989; accepted February 14,199O)
ABSTRACT Mardon, B., Kronenberg, A.K., Handin, .I., Friedman, M. and Russell, J.E., 1990. Mechanisms of fracture propagation in experimentally extended Sioux quartzite. Tectonophysics, 182: 259-278. Notched samples of Sioux quart&e have been extended to faihtre at temperatures 7’ between 25 o and 710 o C, strain rates i from 5.2 x 1Om6 to 6.7 x 10W4 s-i, and 100 MPa confining pressure, and fracture morphologies examined by optical and scanning electron microscopy. In all the extension tests performed, sample failure occurred by the formation of a tensile fracture in or near the notch mid-plane. Differential stress magnitudes at failure are insensitive to variations in T and < and calculated tensile strengths are comparable to previously reported values for unconfined tests at room temperature. Force-displacement records show a change in mechanical response, from linear elastic behavior at temperatures between 2S0 and 412*C to significant yielding in compression prior to failure in the 500° to 71O*C tests. In all cases, fractures consist almost entirely of intragranular cracks (IGC) which exhibit characteristic surface features which can be used to infer local crack propagation directions. In one test in which fracturing was initiated at an edge flaw, IGC propagation directions show no overall trend. The observations indicate that the mechanism of fracture propagation involves nucleation, growth and coalescence of IGC which are themselves propagating in all directions in the plane of the main fracture. The onset of inelastic yielding prior to failure at elevated temperatures is attributed to the formation of thermally induced GBC which act as nucleation sites for IGC during extension.
Introduction The rich variety of features developed on the surfaces of fractures in brittle solids provides a record of the variations in stress and velocity at the tips of propagating cracks. Detailed observation and interpretation of such features is thus a potentially powerful tool for studying the fracture process, especially when combined with information on bulk mechanical behavior. Microscopic features observed on fracture surfaces have been used to infer the locations and dimensions of fracture-initiating flaws, the direction and velocity of crack propagation and details of the mechanisms of crack nucleation and growth in metals,
* Now at Exxon Production Research Company, P.O. Box 2189, Houston, TX 77252, U.S.A. HO-1951/90/$03.50
0 1990 - Elsevier Science Publishers B.V.
glass, ceramics and polymers (e.g., Strauss and Cullen, 1978) and has served to guide theoretical work on fracturing in these materials (e.g., Broek, 1974; Lawn and Wilshaw, 1975). Although significant advances have been made towards understanding fracturing in rocks and minerals (e.g., Atkinson, 1984) relatively few studies have reported detailed observations of fracture surface features. Ryan and Sammis (1978) studied the mechanics of columnar jointing of basalt, driven by thermal stresses during cooling from a melt. Combining evidence from seismic surveys of crystallizing basalt flows with an analogy to fracture surface features produced in cyclic-loading experiments in alu~num and polymers, they interpreted the parallel, evenly spaced markings on joint surfaces as fatigue striations, each corresponding to a discrete episode of crack extension. Smooth and rough bands within each striation
260
D. MARDON
were associated tion,
with elastic and inelastic
respectively,
deforma-
of the host rock at crack
Using similar surface features,
DeGraff
(1987) were able to infer directions
tips.
and Aydin
of joint growth
a canonical are
ensemble
disposed
mediately
upon
gion has been named ing the mirror
plumose joints
Engelder
markings
cutting
episodic
(1984)
on the surfaces
interbedded
siltstones
attributed
logic materials
which report
mineral
as
a
rockforming
and its similarity
ing has been studied
in geo-
and
roscopic
of fine radial
with to its
intensity including tions
industrial
In fact, fracture
as hackle,
crack branching
A variety
observations
to glass in which fractur-
extensively.
mirror.
Border-
roughening,
as mist. This in turn gives way to a zone of larger
of fracture surfaces have been conducted quartz single crystals. This is due mainly importance
the fracture
re-
usually
of fracturing detailed
featureless.
of cross-fold
scale ridges known studies
Im-
this smooth
is a zone of incipient
consisting
origin.
and shales to
crack growth.
Most experimental
and almost
its high reflectivity,
larly,
and
regions which
the
the site of crack nucleation,
are smooth
and determine the sequence of fracture events leading to polygonization of cooling basalts. SimiBahat
about
surrounding
crack surfaces Based
of four textural
radially
ET AL.
beyond
is observed
of factors
may influence
of development microstructure,
in macroscopic
ridges, referred
to
which macto occur. the relative
of these textural zones, specimen size and variastresses.
For
example,
all
four zones are often well developed and mutually distinct on fracture surfaces in glass, owing to its
surface features produced in tensile tests on quartz are highly similar to those in glass (Norton and
homogeneity and ceramics, however,
Atkinson, 1981). Unlike glass, however, quartz has a weak cleavage on its rhombohedral planes which
or even absent,
isotropy. In polycrystalline some zones may be indistinct
especially
in coarse-grained
porous
contributes to the formation of stepped fracture surfaces (Martin and Durham, 1975; Ball and
materials. The development of zones of increasing surface roughness in the direction of crack propagation is
Payne, 1976) the form of which provides further information on the details of fracture behavior.
a dynamic effect in which breakdown crack front into numerous secondary
The primary purpose of this study has been to investigate the mechanism of tensile fracture prop-
curs (e.g., Shand,
1954; Mecholsky
The mirror
corresponds
agation bulk
in polycrystalline mechanical
behavior
quartz
by examining
the
and
morphologies
of
fractures produced in extension experiments performed on Sioux quartzite. The fractures in our experimental samples show many of the characteristic surface features seen on fractures in quartz single crystals. Detailed observations and mapping of crack propagation directions inferred from these surface features provides substantial insight into the fracture propagation process quartzite constitution responsible yielding elevated
prior to failure temperatures.
and changes in for the onset of
in samples
extended
at
Fracture surface features Glass and ceramics Experimental work on tensile crack propagation in glass and ceramics (e.g., Henderson, 1975; Rice, 1984) has established the existence of
region
of a single, from
primary
the initiating
crack
of a single cracks ocet al., 1978).
to the propagation
that
accelerates
flaw. As the velocity
away of the
crack tip nears the terminal velocity for crack propagation of the medium, sufficient energy becomes available to nucleate secondary microcracks about
the primary
propagation ing in the Rayleigh upper
surface
bound
crack tip, but not for extensive
of these secondary cracks, thus resultformation of mist. The velocity of waves
is usually
for the terminal
taken
crack velocity
as an (e.g.
Field, 1971) and velocities of 0.6 u, are typically observed in experiments where v, is the shear wave velocity
(Mecholsky
et al., 1978). The larger
energy release rate associated with a longer overall crack cannot effect further acceleration of the primary crack but instead produces increasingly extensive propagation of secondary cracks leading to hackle formation and, ultimately, crack branching. The presence of flaws in polycrystals tends to hasten the onset of breakdown of the accelerating primary crack front.
FRACTURE
PROPAGATION
Several
IN EXPERIMENTALLY
characteristic
have been identified
fracture
ceramics
whose
of crack propagation.
form
can
cate crack growth parallel this configuration area, change patterns vidual trolled. gation
and
therefore
The
gence of cleavage
to a line bisecting
toward
The concavity
the fracture
origin,
the angle of
of cleavage
especially
suggests
that their formation
teraction
with elastic stress waves (McColm,
the increase associated
with
surface.
steps (Friedel,
a
by in1983).
of crack
Experimental
methods
River of indi-
is cleavage-con-
in the direction
is influenced
in surface
on the surfaces
direction
steps
those on m,
to the step lines because
in which fracturing inferred
was parallel
step intersection.
steps indi-
of the fracture
is down-stream,
the
261
QUARTZITE
gation
features
to infer
Straight
energy,
are often formed
SIOUX
with glass and
be used
minimizes
in elevation grains
surface
in experiments
direction
EXTENDED
propa-
of conver-
1964).
The fractures duced
examined
in this study were pro-
in a suite of extension
dry (no pore pressure)
tests on nominally
Sioux quartzite
at tempera-
tures T from 25 o to 710 o C and strain
rates i of
5.2 X 10m6 to 6.7 x 10e4 s-‘. A lateral confining pressure PC of 100 MPa was applied in all the
Quartz single crystals
experiments.
Essentially all the fracture surface features described above have been produced in tensile frac-
Starting
ture experiments on quartz single crystals, in addition to features associated with its cleavage on the rhombohedral planes r{lOil} and z{Olil}
The texture and composition of Sioux quartzite makes it well suited to the purposes of this study.
(Ball and Payne, 1976; Norton and Atkinson, 1981). A mirror region is generally present about the fracture-initiating flaw. However, for most crystallographic orientations, mist and hackle features are replaced by cleavage steps which are concave toward the fracture origin and increase in size in the direction of crack propagation. Macroscopic crack branching occurs on r and z. Ball and Payne (1976) made a comprehensive study of tensile crack growth in quartz from an edge slit in thin, single crystal slabs of five different orientations in a variety of chemical environments and at temperatures ranging from 77 to 800 K. Arcuate cleavage steps were produced on fracture surfaces of all orientations except for fracture on the (ll!?O) plane in the [liOO] direction. This last orientation exhibited mirror and hackle zones similar to glass. Norton and Atkinson (1981) studied crack propagation from a surface flaw in synthetic and natural Brazilian quartz crystal rods in bending and found that arcuate cleavage steps on basal fracture surfaces exhibited angular, saw-tooth profiles with characteristic hexagonal symmetry. Two intersecting sets of arcuate steps with a gentler, low-amplitude form were produced on m-fractures. In both cases the direction of crack propa-
material
and sample preparation
It is a well indurated, sedimentary orthoquartzite consisting of 99% equigranular quartz and minor amounts of hematite, magnetite, zircon and rutile. The mean quartz grain size, determined by the linear intercept method, is 160 pm. The bulk density
of Sioux
quartzite
is 2.64 g/cm3,
com-
pared to 2.651 g/cm3 for crystalline alpha-quartz (Sosman, 1965), indicating it has extremely low porosity. Krech et al. (1974) have reported a variety of physical properties for Sioux quartzite, including unconfined
tensile
at room temperature.
and compressive Critical
tors for mode I crack propagation zite have been .determined (1982).
strengths
stress intensity
fac-
in Sioux quart-
by Peck and
Gordon
The sample geometry used in the extension tests is shown in Fig. 1. Cylindrical samples with diameters of 18.30( +0.05) mm were cored from a single block of Sioux quartzite. Each core was then cut and ground perpendicular to its axis to a length of 39.8( f 0.9) mm. A circular notch with a radius of curvature of 11.07( + 0.04) mm was machined midway along the length of each core to generate a stress concentration in the sample during extension and thereby localize fracturing. The circular notches were fabricated by turning the samples on a lathe against a cylindrical diamond grinding tool that was held in a controlled feed
D. MARDON
load piston. determined perature
Based using
on axial a hollow
accuracy
ET AL
temperature
profiles
test sample,
the tem-
was taken to be +5”C.
Raw load records (e.g., Fig. 3) show an initial rise as confining pressure is increased, followed by measurements
of
constant-load
packing
segment
friction,
corresponding
and
LOADIN
Fig. 1. Geometry cular
notch
mid-way
Sioux quartzite
of 11.07( +0.04)
along the sample length.
the notch shown
of notched
with a radius is 15.45( +0.05)
with Cu jacket
while jacket
mm.
samples.
sample
-SPECIMEN
sample
Sq-8 is shown
area a at Sq-24
is
with
its
RESISTANCE
removed.
’ Cu
and turned on an axis oriented normal to that of the sample. The diameter of each sample at the notch
mid-plane
was machined
IG PISTON
mm is machined
The cross-sectional Extended
A cir-
a
to free-travel
-
OR
Pb
LUCALOX
FURNACE
JACKET
SPACER
to 15.45( kO.05)
mm. EXTENSION
FITTING
Test apparatus The design of the sample column used are illustrated
assembly and loading in Fig. 2. Notched
samples of Sioux quartzite were sealed in Cu and Pb jackets and extended by retracting an axial loading piston while maintaining a lateral (argon) confining pressure PC of 100 MPa. The loading column incorporates a gun-lock fitting between the lower piston
and closure
of the pressure
vessel OSURE
which allows an interval of free-travel displacement. This permits packing friction to be measured for each test, prior to extending the sample, by measuring the load while advancing and retracting the load piston. Axial loads were measured using a BLH load cell calibrated against a 133 kN (30,000 lb) Tinius Olsen proving ring and confining pressures were read on a Heise gauge. Given the sample dimensions, axial and lateral stresses applied to the sample are resolvable to within kO.7 MPa. An internal resistance furnace with nichrome wire windings was used to achieve elevated temperatures which were monitored using a chromel-alumel thermocouple entering the pressure vessel through a port along the axis of the top
50 mm Fig. 2. Sample
and piston
used for extension were prepared ends.
The
hardened fitting, assembly
with
lower
circular
piston
steel tube allowed
assembly
tests at pressure. notches
assembly,
threaded
of triaxial mid-way
to the endplug
friction
prior to loading
the sample.
their
of a hollow, and a bayonet
piston
measurements
samples
between
consisting
for free travel of the upper
so that packing
gas apparatus
Sioux quartrite
and sample
could be made
FRACTURE
PROPAGATION
IN EXPERIMENTALLY
EXTENDED
SIOUX
sq-2 T = 25’C
263
QUARTZITE
corrected
for the effects of packing
strength,
and for the stress concentration
ated with the notch. conveniently
made
tests on precut
samples
axial force supported mid-plane
measured
load
total
the results as follows.
by an intact at failure
a simple
are
of extension Let F, be the sample
across
and let Fp’ be the
for a precut
displacement.
positive,
jacket associ-
The first two corrections using
the notch
friction,
sample
at the same
Taking
compression
force balance
yields:
to
F,=F,-P,(A-a)+C
IO
05 DISPLACEMENT
Fig.
3. Raw
load-displacement
Following
pressurization
advanced
and then retracted
friction ment
(measured
was then performed
constant
displacement
15
for experiment
in order
to measure
= 2f).
by retracting
corresponds
to the lower
hollow
steel tube.
portion
of the sample
Nominally
A is the cross-sectional
tensile
are obtained
deflection stresses
at a
in the force
engaging
with
the
at the notched
at a load Pc(A - CI) where
area of the load piston
cross-sectional
experi-
the load piston
piston
was
the packing
The extension
rate. The negative
record
Sq-2.
to PC = 100 MPa, the load piston
load difference
and
n is the
area at the notch.
displacement. Once the gun-lock fitting has engaged and contact with the sample is made, the measured deviator+
load drops reflecting stress to the sample.
(1)
where A and a are the cross-sectional areas of the piston and notch mid-plane, respectively, and C is the correction for packing friction and jacket
(mm1
record
be
the application
of
Extension tests on samples containing a precut through the notch were performed at conditions identical to those used in the tests on intact samples to determine jacket strength corrections. Pb
strength. For a precut sample, which can support no tensile axial force, we have: O=Fp’-P,(A-a)+C
(2)
Assuming C is a constant perature, displacement rate, F, is found
by subtracting
age axial stress at failure
for a particular temand jacket material,
(2) from (1). The avera,, is then given by:
u, = F,/a The correction for the stress concentration sociated with the notch is made using an propriate extension, developed
(3) asap-
concentration factor K. During an annular zone of tensile stress is first at the periphery of the notch and then
Stress
expands radially inward, displacing the zone of compression, toward the axis of the sample. The maximum periphery %l,X =
tensile stress a,,,,,, which occurs at the of the notch at failure, is given by:
KU,,
jackets, used only in room temperature tests, were significantly weaker and have smaller strains to failure than Cu jackets. In some tests in which Pb jackets were used, Pb appears to have entered microcracks in the specimen surface, suggesting
our sample geometry. As expected, relatively weak stress concentrator.
these samples could have failed by hydraulic fracture and that the results obtained using Cu jackets
Here, the maximum compressive stress u, is equal to the confining pressure P,; the minimum
may be more
compressive displacements
reliable.
However,
after
correcting
for jacket strength, the load supported by samples extended at the same conditions are the same for both jacket materials, within measurement error. Analysis
of mechanical
data
To determine the failure stress for each test specimen, the measured load at failure Fp must be
(4)
and is taken as the failure stress. Based on results given by Peterson (1974, we estimate K = 1.27 for
stress and
the notch
u3 is the axial nominal strains,
initial sample lengths, were corrected distortions of the apparatus. Observational
is a
stress. Axial dividing by for elastic
methods
Fracture traces were studied in thin sections under plane light and crossed polarizing filters in
D. MAROON
264
......== ’ 4====....._
ET AL
FRACTURE
PROPAGATION
experimentally
IN EXPERIMENTALLY
extended
sure-impregnated surfaces
were
quently
examined
samples
with coated
blue
epoxy.
with
SIOUX
carbon
going, tensile fracture
35 scanning
a narrow
subse-
The measured
Results
tensile Table
TABLE
occurred
stresses
at failure
behavior
In all the extension failure
zone about
tests
performed,
by the formation
the main fracture
differential
stresses
1. In ten of the eighteen samples
within (Fig. 4). of high
u, - a,, axial
a, and amax, and nominal
ple to be discussed
of a through-
in orientations
for all the extension
on notched
sample
consist of
the notch mid-plane
Few cracks are observed resolved shear stress.
elec-
(SEM).
Bulk mechanical
(Fig. 1). Fractures
many cracks that parallel
Fracture and
265
QUARTZITE
that were pres-
using a JEOL
tron microscope
EXTENDED
strains
tests are given extension
tests run
(one test on a modified later),
the average
Comments
c in
sam-
axial stress
1
Sioux quartzite
extension
tests *
T
.
PCa
0,
(“C)
;s-t)
(MPa)
(MPa)
b
-03
Jacket
0” ’
mate-
(MPa)
d enlmax (MPa)
rial
Strain at
W ’
Exp.
failure
(J)
No.
e (W)
25
5.4 x 10-6
100
116.2
cu
-0.3
-0.4
0.42
25
5.4 x 10-6
100
119.1
cu
- 3.2
-4.1
0.35
25
1.2 x 10-s
100
93.1
Pb
_
25
5.5 x 1om5
100
124.5
cu
- 8.6
25
5.6
1O-5
100
112.8
Pb
- 12.2
25
5.7 x 10-s
100
105.6
Pb
- 5.0
25
6.0 x 1O-4
100
96.4
Pb
Sq-4 sq-5
0.31
0.08 _
- 10.9
0.35
0.21
sq-1
- 15.5
0.35
0.34
sq-2
-6.4
0.26
_
0.43
0.12 _
Sq-6
sq-13
Shallow sawcut at notch used to initiate
x
fracture
sq-3 Apparently
did not enter
tensile field 25
6.7
x
1O-4
79.2
100
0.23
Pb
Sq-8
Apparently
did not enter
tensile field 412
1.7 x 10-s
100
500
5.2 x 1O-6
100
108
CU
77.9
-6.1
-7.7
cu
0.42 0.32
0.10 _
sq-15 sq-22
Apparently
did not enter
tensile field 500
8.7 x 1O-6
100
108.0
cu
500
1.1 x 10-5
100
89.2
cu
-3.9 _
-5.0
0.84 0.95
0.78 _
sq-24 sq-23
Apparently
did not enter
tensile field 500
1.7 x 10-s
100
107.5
cu
- 3.4
-4.3
0.75
1.36
Sq-16
500
1.7 x 10-s
100
107.9
cu
- 3.8
-4.8
0.67
0.94
sq-17
500
1.7 x 10-s
100
101.9
cu
-0
-0
0.53
Sq-18
8.4 x 1O-6
100
105.5
cu
-0
-0
0.78
sq-30
251
from
25 o to 500’ C and back to
500/ 25 600
Cycled at pressure
25 o C prior to extension 6.8 x 10-6
99.8
100
cu
0.74
Sq-28
Apparently
did not enter
tensile field 600
8.1 x 1O-6
80.9
100
cu
-
0.43
sq-27
Apparently
did not enter
tensile field 710
6.6 x 10-6
100
104.0
T = temperature;
i = extensional
stress
a,,,
at failure;
no. = experiment
cu
strain
= maximum
PC= confining
rate;
tensile
- 2.0
stress
-2.5 pressure;
at failure;
compressive
Nominal
value at notch (uncorrected
Nominal
value at notch corrected
Corrected
for stress concentration
See text for method
stress). for jacket for friction
of determination.
at notch,
strength). and jacket
friction,
strength.
and jacket
strength.
0.76
(I, - us = differential
W= estimate
number.
PC= q (the maximum
0.68
of mechanical
Sq-26 stress at failure; work
o, = average
in extension
to failure;
tensile Exp.
266
D. MARDON
was tensile
when sample
failure
tests, a,, was approximately six tests, failure
while axial stresses
However,
fractures
these tests have the same location as those
produced
In two
in tests
as tensile
fractures
generated failure
perature,
unrelated
1). As discussed
above,
material
tensile
stresses
temperature
1). This
Given tensile
to variations
room
average
- 11 MPa) reported
ocinter-
stress a,,,
in the tem-
within
used (Table
1). However,
the loading
column
and flaws in the sample
increase
such
tensile
tic behavior
could
stress
deformed
Samples
was generally
con-
insensi-
and strain investigated
rate, (Table
difference
be-
records
at low and high tempera-
extended (Figs.
is in
the maximum
the form of the load-displacement
tures.
at
(- 10 to
is apparently
there is a significant
25 o and 412’ C exhibit
substantially
strengths
in temperature
Bending
of
- 10.9 MPa,
tensile
in the data,
for samples
due to small misalignments
strength
value,
at failure
ated in the sample at the periphery of the notch before the average axial stress becomes tensile. moments
tensile
we esti-
the three largest values
the range of conditions
tween
are gener-
Thus,
by Krech et al. (1974).
the scatter
tive to variations
axial stress at failure
strain rate or jacket
for Sioux quartzite.
the range of unconfined
and orientation
in which
the
(Table
in
as well.
The sign of the measured is apparently
mate
stress
PC= 100 MPa by averaging
were
curred in the tensile field; they are therefore preted
fracture
zero and in the other
occurred
still compressive.
occurred.
ET AL.
at temperatures nearly
5a and
marked
between
perfect
linear
5b). Specimen
by a peak
elasfailure
in differential
centrations and thereby induce fracturing prior to achieving a net tensile stress. Because such imper-
stress and a small, inaudible stress drop to values supported by the metal jacket. In contrast, sam-
fections
ples extended at temperatures undergo significant inelastic
all act
to reduce
stress magnitude (most negative)
the measured
tensile
at failure, we regard the largest values as closest to the “true”
failure
(Fig.
5~). The onset
of 500’ yielding of yielding
0.2
06
04
DISPLACEMENT
P,(=u,
AXIAL
T = 25 o C in Cu and Pb jackets, exhibiting
a similar
mechanical
T = 500 ’ C. d. Sample
(shown
response
as samples
deformed
at T = 25 o C following
correspond
to changes
at
I%)
DISPLACEMENT
Sioux
with arbitrary
Sq-2 deformed
, I0
05 STRAIN
(mm)
for extended
respectively
Sq-30 extended
Displacements
records
TESTS
)=lCOMPo
0
DISPLACEMENT
(mm)
OUARTZITE
EXTENSION
stress-displacement
at
06
04
DISPLACEMENT
(mm) SIOUX
Fig. 5. Differential
occurs
b
cl 02
to 710°C prior to
quartzite
specimens.
offset in displacement). at room
temperature.
heat treatment
lmml
a. Samples b. Sample c. Samples
Sq-1 and
Sq-15 extended Sq-16
at T = 500 o C at hydrostatic
in length of entire samples,
corrected
for apparatus
and
Sq-17
pressure distortion,
at T = 412 o C, extended
at
PC= 100 MPa.
FRACTURE
PROPAGATION
differential sure.
IN EXPERIMENTALLY
stresses well below the confining
Nominal
strains
at failure
temperatures.
mechanical tween 412”
100 MPa (Sosman, Inelastic
nonlinear
behavior
to
the areas
under
at in
static conditions.
which occurs somewhere
be-
this
500 o to 710” C extension
to an elastic
was tensile.
temperatures
similar
and
by finding
subtracting return
in Table
For
between
the
to hydro-
1 for all the
tests for which the measured
at failure
1965).
yielding
determined
for W are given
Values extension
which occurs near 600 o C at
were
their curves
change
twice those obtained
and 500” C, is not due to the alpha-
beta quartz transition
267
QUARTZITE
pres-
in the 500”
Evidently,
behavior,
SIOUX
area corresponding
710° C tests are typically lower
EXTENDED
samples
axial stress extended
25O and 412”C,
at
W varies
in the
from 0.08 to 0.34 J and has a mean value of 0.17 J.
tests (e.g., Fig. 5c) was
For the 500 o to 710 o C tests, W ranges from 0.76
to that observed
also seen in one test (Sq-30) in which the sample
to 1.36 J, with
was extended hydrostatically This indicates
approximately five times larger than that for the lower temperature tests. This effect is illustrated in
at 25’C after first being annealed at 500 ’ C and 100 MPa (Fig. 5d). that the change in mechanical be-
mated
the mechanical
W is approximated under each curve.
and contain
where F, and AL are the force drop and change in axial length at failure, respectively. Values of W for samples which exhibited yielding followed by
low-relief
steps of widely varying
20
-J" QO 5 J
;
IO ..
k!E k u. 0
:
W=O.94
J
0 -R-;
0
DISPLACEMENT
Fig. 6. Estimates respectively.
of inelastic
Substantial
work
differences
of nonlinear
in W are apparent,
behavior
0.6
02
(mm)
W done in extension and increased
re-
I
I3
i 0.4
sizes
"C
A
0.2
area
mist and hackle
sq-2 25'C
w = 0.34
(Sq-17).
the shaded
Thin section examination shows that fractures occupy a narrow zone, generally less than two grain-diameters wide, about the notch mid-plane (e.g., Fig. 4). Fractures consist of many smaller cracks, most of which are linked, that parallel the
(5)
T=
is
fracture surfaces protests are relatively flat
and shapes. Distinct mirror, gions are not developed.
that the sample
“O7
as one-half
Macroscopically, the duced in all the extension
in mechanical we have esti-
w = ;F,AL
J, that
Fracture surface morphology
work W done in extending
the samples to failure. Assuming behaves as a linear elastic solid:
0.96
sion test (Sq-2) and a test run at 500°C
some permanent constituat elevated temperature. In the paper, we argue that thermally-induced micro-
To further illustrate this change behavior at elevated temperatures,
value,
Fig. 6 which shows differential load versus displacement records for a room temperature exten-
havior, from a linear elastic response at low temperature to significant inelastic yielding at high temperatures, is due to tive change that occurs subsequent sections of this change is due to cracking.
a mean
DISPLACEMENT
for experiments associated
0.4 (mm)
Sq-2 (a) and Sq-17 (b) performed
with the lack of yielding
strain to failure exhibited
0.6
at T= 25’
and 5OO”C,
prior to failure at T = 25 o C and the onset
by Sioux quartzite
at T = 500 o C.
D. MARDON
268
Fig. 7. Optical Fracture those
of fractures developed photc nnicrographs co1nsist largely of IGC at all conditions
in samples
surfaces developed
at low temperatures.
c. Fracture
step
ET AL.
Sq-5 (a) and Sq-18 (b) at T = 25 o C and T = iOO”C, rc:spectively. as ctre not as smooth fractures formed at high temperatures
tested. However, at grain
micrographs
boundary
in sample
taken in plane light).
Sq-18
shown
at hig h magnifi cation
(all
FRACTURE
PROPAGATION
main fracture.
IN EXPERIMENTALLY
Individual
one grain diameter
EXTENDED
crack lengths
SIOUX
range from
of fractures
to more than 10 mm. Fractures
formed at all temperatures
consist mainly
which
grains
269
QUARTZITE
412°C quartz
of cracks
grains
4 and 7)
boundaries
i.e., intragranular cracks (IGC). In all cases, grain boundary cracks (GBC) make up a small fraction
to 710°C commonly
of the fracture
7~). Thus,
cut through
quartz
surface.
In thin sections,
Fig. 8. SEM micrographs
of fracture
primarily
and stepped
of IGC (smooth
used to nucleate exhibits
fracture
a river pattern
(Figs.
surface
of sample
surfaces)
in this sample of coalescing
the traces
and promote
cleavage
Sq-13 extended
with isolated fracture
propagation
with respect
its growth
surface
at temperatures typically
without
cutting
of 25’
and
across many
deflections
(Fig. 7a). Fractures
at
produced
grain at 500”
have more jagged traces (Fig. 7b) and show steps at grain boundaries (Fig. IGC
at T= 25’C
GBC (pitted
steps from which
formed
are straight,
which
and i = 1.2
make
x
in top right corner).
from left to right. direction
to each other by 90 o ).
10V5 s-‘. Shallow
b. At higher
has been inferred
up these
a. Fracture
consists
saw cut (at left) was
magnification,
(images
fractures
an IGC
a and b are rotated
D. MARDON
270
SEM examination reveals the form and 1~ )cation of individual IGC and GBC. GBC are irn :gular in shape and appear as pitted patches on the fracture surface with widely ranging orientati !ons relative to the fracture plane (e.g., Figs. 8a and 9a). IGC surfaces are much smoother and are oriented sub-parallel to the main fracture surl!ace (Figs. 8, 9 and 10). Some IGC surfaces are feat1ure-
have a wider range of orientations than those form Led at lower temperatures. In plane polarized light , grain boundaries throughout the samples show a exter rded at the higher temperatures notic ;eably higher relief than in the lower temperature specimens. This suggests that pervasive cracking (2f grain boundaries has occurred at elevated temr jeratures.
Fig. 9. SEM micrographs
of fracture
from GBC step. b. Two well-developed
surface
(sample
Sq-13).
sets of intersecting
ET AL.
a. Arcuate
arcuate
propagation
cleavage
steps of IGC suggest
steps on IGC provide direction.
a high-confidence
crack
growth
indicator
directio n out of local crack
FRACTURE
PROPAGATION
IN EXPERIMENTALLY
EXTENDED
SIOUX
less or show broad undulations. However, many IGC exhibit diagnostic surface features, like those seen on crack surfaces in experimentally deformed quartz single crystals, which can be used to infer IGC propagation directions. Examples include river patterns (Fig. 8) and concentric, arcuate cleavage steps (Fig. 9a). In some cases, intersect-
Fig. 10. SEM micrographs parallel
cleavage
possibly
across a subgrain
of complex
steps to coalescing
within a single quartz these features
cleavage
wall. b. Multiple
grain (small arrows). within individual
ing sets of arcuate cleavage steps are observed (Fig. 9h). Often, the direction of IGC propagation inferred from these features is away from an adjacent GBC (Figs. 8 and 9a). This suggests GBC form pre-existing flaws which act as nucleation sites for IGC. The inferred direction of IGC propagation is often different for adjacent quartz grains
steps on IGC surfaces
river pattern
within
sets of arcuate Patterns
suggest
of fracture
an individual cleavage multiple
grains yield low-confidence
271
QUARTZITE
in sample
IGC suggesting
Sq-13. a. Transition a change
in growth
steps indicating
strongly
crack nucleation
sites along grain boundaries.
indicators
varying
of crack propagation
direction
directions
from closely-spaced direction
by
- 45O,
of crack propagation Visual averages
(large arrows).
of
272
D. MARDON
and, in some cases, varies within individual grains (Figs. 10a and lob). In the example shown in Fig. lob, IGC appear to have nucleated at several places on a single quartz grain boundary. These observations indicate that the grain-scale mechanism of fracture formation is complex, involving simultaneous propagation of many cracks in different directions within the fracture plane.
Fig. 11. SEM micrographs
of fracture
exhibit many of the features
observed
patterns.
b. In addition
surface
of sample
for IGC of fractures
to these features,
fracture
surfaces
Fractures in samples extended at 500 o to 710” C show the same surface features as those developed in the lower temperature tests, induding river patterns and arcuate cleavage steps (Fig. lla). In addition, the surfaces of these frac:tures show traces of IGC, intersecting the main fralcture at high angles (Fig. lla). This observation indicates that IGC formed in samples extendced at
Sq-26 extended generated
at T= 710°C
at room temperature,
of high temperature
small flake-like
ET AL.
steps.
samples
and
(= 6.6
including
X
10m6 s-i.
arcuate
a. IGC s urfaces
cleavage
show IGC which intersect
steps an id river at high ang les and
FRACTURE
PROPAGATION
elevated
temperatures
orientations, from
IN EXPERIMENTALLY
thin
have
consistent section
EXTENDED
a broader
observations.
Unique
fractures produced at high temperatures flake-like steps, up to a few micrometers ter (Fig. lib).
range
with the conclusions
The origin
SIOUX
of
the saw cut. Together,
drawn
the direction
to the
from the saw cut.
are small in diame-
of these features
is not
known. Crack propagation
213
QUARTZITE
where en echelon
cracks overlap
The variability inferred
served
in SEM,
in the directions from
IGC
suggests
of crack propa-
surface that
the
features direction
obof
motion of a macroscopic fracture front may have little or no influence on the propagation direction of individual cracks nucleating within the fracture tip process
zone.
To test for a relationship
be-
tween crack (grain-scale) and fracture (macroscopic) propagation directions, an extension test was performed at room temperature using a modified notched sample (Sq-13) in which a shallow saw cut was placed in one side of the notch mid-plane to initiate fracturing. Surface features on the fracture produced in this test were mapped at two scales of observation, on a close-up photo-
that
was away
(Fig. 12b). Nearly
all steps
on the fracture
surface
vergence.
On the close-up
photograph
crack
tips just
Viewed
along
below
have
the same (Fig. 12a),
in color than the surround-
ing surface due to scattering gation,
indicate
propagation
Fractures consist of en echelon cracks, most of which are linked. Steps on fracture surfaces occur
these steps are lighter
directions
these features
of fracture
of light by en echelon
the main
the fracture
fracture
plane,
surface.
away from
the
saw cut, these steps would appear as en echelon cracks rotated clockwise relative to the main fracture plane. Presumably, these are secondary cracks which formed by breakdown of the primary crack front as it accelerated away from the saw-cut. Directions of crack propagation at the grainscale were inferred from surface features mapped on IGC surfaces in a traverse of contiguous SEM photographs taken along a chord oriented normal to the saw cut (Figs. 12b and 13). Like the fractures produced in tests using standard notched samples, the fracture surface of Sq-13 consists
graph and in a traverse of SEM photographs. Based on the radius of curvature of the tip of the
almost entirely of IGC, oriented sub-parallel to the fracture plane, linked by GBC, at high angles to the fracture plane, which form steps in the
saw cut, about 0.2 mm, the stress concentration the deepest part of the saw cut is estimated
the total fracture
have
been
about
ten
times
stronger
than
at to that
associated with the notch. As expected, the nominal stress across the notch at failure was small and did not appear to reach the tensile field (Table 1). In a close-up photograph (Fig. 12a), the fracture surface can be separated into two regions of distinctly different surface roughnesses. Surrounding the saw cut is a relatively smooth zone containing a few small steps that is interpreted as a fracture mirror. The remainder of the fracture surface contains steps interpreted
much larger and more numerous as hackle. The boundary between
these regions is symmetric and concave toward the saw cut. The distance between this boundary and the leading edge saw cut measured along a diameter bisecting the saw cut is 3.2 mm (Fig. 12b), about one fifth the diameter of the notch midplane. Many steps on the fracture surface have raised, straight edges that trend nearly normal to
fracture
surface.
GBC comprise surface.
tion, there is no roughness between
a small fraction
of
At this scale of observa-
marked difference in surface the mirror and hackle regions,
Determinations of local crack propagation direction were assigned either high-confidence (solid arrow, Fig. 13) or low-confidence (open arrows) ratings. These ratings were subjective and reflect possible ambiguity in inferring crack propagation directions. High-confidence ratings were reserved for those features judged tors of local propagation tinct
river
patterns
and
as unambiguous indicadirection, including disarcuate
cleavage
steps
(Figs. 8 and 9), whereas low-confidence ratings were awarded in situations where an interpretation other than the one given was possible (Fig. 10) but still less likely. No determination of crack propagation was made in cases where two or more alternative interpretations appeared equally likely. In contrast to the direction of fracture growth, i.e., away from the saw cut, indicated by macro-
D. MARDON
274
I........&A -4,..m..............e.....w.....v
%. ... ... ...L&&p? . . . . . .
I
. . . . . . . . . . .
p’.]
ET AL.
from SEM traverse across sample Sq-13. Grain boundaries are shown as solid lines and GBC at the surface are shown stippled. Local
P_= lOOMPa
Tz25C
crack propagation directions are indicated for IGC, based upon cleavage steps and river patterns. The overall fracture extension direction is vertical, away from the saw cut.
Fig. 13. Map of fracture surface constructed
iJ
SQ-13
High Confidence LOW Condidence
I
Local Crack Propagation Direction
Grain Boundary
400pm
276
scopic surface features (Fig. 12), there is no overall trend in local crack propagation directions indicated by IGC surface features (Fig. 13). This indicates that microstructural heterogeneities, especially grain boundaries and cleavage, are the dominant controls on the direction of crack propagation at the grain-scale. Figure 8 shows a striking illustration of this effect. In this example, a prominent river pattern provides a ‘high-confidence indicator of IGC propagation direction (large arrow, Fig. X), away from an adjacent GBC, that is at least 100” oblique (clockwise) to the overall direction of fracture propagation (small arrow, Fig. 8). Note that this location is less than 0.5 mm away from the saw cut at which the fracture initiated and that the GBC is oriented parallel to the fracture plane. Opening displacements across the GBC in this example apparently resulted in tensile stress concentrations along its perimeter that were substantially stronger than that associated with the nearby saw cut and thereby initiated crack growth in the adjacent quartz grain. Discussion
Detailed examination of the fractures produced in our experiments has established that, over the range of conditions investigated, failure of Sioux quartzite occurs by tensile fracturing. Fractures consist almost entirely of ICC which exhibit characteristic surface features like those seen on fractures in quartz single crystals extended under conditions which ensured brittle behavior (Ball and Payne, 1976; Norton and Atkinson, 1981). In addition, our results indicate that catastrophic fracturing of quartzite involves localized nucleation, propagation, and coalescence of microcracks about the primary fracture front. This is essentially the same mechanism that has been inferred for stable fracture growth in quartz-bearing crystalline rocks from both field (e.g., Segall and Pollard, 1983) and experimentai studies (Hoagland et al., 1973; Peck and Gordon, 1982). While a consistent direction of fracture propagation at the macroscopic scale can sometimes be identified, crack propagation at the grain-scale has no such preferred direction. This implies that the tip of a propagating fracture
Il. MARDON
ET AL,
consists of a zone of microcracks which are themselves propagating in various directions in the plane of the main fracture. Evidently, the macroscopic stress field associated with the main fracture confines IGC formation within a narrow zone, up to a few grain-diameters wide, about the fracture plane while heterogeneities in stress intensity at the grain-scale, associated with the rock grain structure, control IGC nucleation and propagation. Because sample failure occurred by brittle fracturing in all the extension tests performed, the transition in mechanical behavior, from a linear elastic response at low temperature to significant inelastic yielding prior to failure at high temperatures, cannot be due to a change in deformation mechanism. Instead, this transition, which occurs between 412” and 500°C appears to be due to thermally induced microcracking of quartzite grain boundaries which act to increase the density of critical flaws for IGC nucleation during extension. This interpretation is supported by the mechanical response observed in extension test Sq-13, run at 25” C after first annealing the sample at 500°C which shows inelastic yielding like that observed in the extension tests run at 500 o to 710 o C. Thin section observations suggest that grain boundaries in samples heated to at least 500” C may be extensively cracked. However, many of these samples have non-zero tensile strengths, indicating that not all grain boundaries are cracked. Thin section and SEM observations also indicate that IGC in test specimens which exhibited yielding prior to failure have a broader range of orientations than in specimens for which such yielding was not observed. A microcrack population having a broad range of orientations could accommodate the bulk shear deformation associated with yielding in compression prior to failure. Thermally induced microcracking of Sioux quartzite subjected to slow, uniform heating has been investigated by several methods, including measurements of acoustic emissions and P-wave velocities (Johnson et al., 1978). and by pointcounting in thin sections (Friedman and Johnson, 1978). Johnson et al. (1978) found that the onset of microcracking associated with the thermal expansion anisotropy of quartz in unconfined speci-
FRACTURE
PROPAGATION
IN EXPERIMENTALLY
EXTENDED
SIOUX
OUARTZITE
211
the thermal aa
coefficients
(Y, - (Y,, varies
from 0.6 X 10e5 to 1 X 10m5 “C’
in the temper-
ature range 20” to 500 o C (Birch, 1966; Skinner, 1966). Using these values and assuming a tensile
E =;+uAT
strength
Et = E2
ture dl
z
(Y= 10 MPa yields
for microcracking
ture change quartz interface
grains
thermal
expansion
AT at confining of similar
dimension
(c, = e2). Expansion
ferences in expansion
anisotropy
neighboring
(d, = d2), bonded
anisotropy
coefficients
for tempera-
PC between
pressure
depends
a and Young’s
the a and c crystallographic
at their upon
moduli
a threshold
tempera-
PC= 100 MPa in the
at
range 304” to 490 o C. Given the highly idealized nature of the bi-crystal model and assumptions
d2
involved, Fig. 14. Maximum
expansion
dif-
atures
the range of estimated
is in surprisingly
temperature experiments cracking
interval
412”
indicate
has begun
threshold
good agreement
temperwith the
to 500 o C in which our
thermally
induced
micro-
to occur.
E for
axes.
Conclusions (1) Notched samples tended at temperatures
of
Sioux quartzite between 25”
exand
mens occurs at a threshold temperature of 200°C and that thermal cracking continues as the temperature is increased beyond 200” C. This threshold temperature can be expected to increase with increasing confining pressure. To estimate the temperature increase AT re-
710°C strain rates i from 5.2 X 10e6 to 6.7 x lop4 s-l, and 100 MPa confining pressure fail by brittle, tensile fracturing. Failure occurs at differential stresses that are insensitive to variations
quired
in T and
for thermal
cracking
of quartzite
at 100
i and
calculated
tensile
strains model,
(2) The fractures produced in all extension tests consist mainly of intragranular cracks (IGC) which closely parallel the main fracture. Grain boundary
sions are bonded across a planar interface. The a and c crystallographic axes in one of the crystals are, respectively, parallel and normal to this interface; in the other crystal these orientations are reversed. Because the principal directions of thermal expansion anisotropy in the adjoining crystals are orthogonal, this model yields a minimum estimate for AT. Assuming the strains in both halves of the bi-crystal are equal, we find: AT=
a[l+
E,/E,.] +2P, E,(a,-a,.)
for un-
tests at room temperature.
cracks (GBC) make up a small fracture surface area in all cases.
fraction
of the
(3) IGC exhibit characteristic surface features, like those developed on experimentally produced tensile fractures in quartz single crystals, which can be used to infer IGC propagation directions. (4) Two scales of crack propagation are defined. At the sample scale, fracture propagation is directional, whereas microcracks at the grain scale grow in all directions within the fracture plane. This conclusion suggests that the tip of a propa-
(6)
where E, and EC are the effective Young’s
values
are
MPa confining pressure, we have used a simple model for linear, one-dimensional thermoelastic in a quartz bi-crystal (Fig. 14). In this a pair of quartz crystals of equal dimen-
reported
strengths
comparable confined
to previously
T
moduli
in the a and c directions, (Y, and (Y, are the corresponding coefficients of thermal expansion, and (Yis the uniaxial tensile strength of quartz. At temperatures below the alpha-beta transition, the elastic moduli for quartz are insensitive to variations in the temperature (Johnson et al., 1978) so we have used the room temperature values E, = 78 GPa and EC = 103 GPa. The difference between
gating fracture consists of a zone of microcracks. The macroscopic stress field associated with the main fracture restricts IGC formation within a narrow zone about the fracture plane while microstructural heterogeneities, principally grain boundaries and cleavage, are the dominant controls on IGC nucleation and propagation. The mechanism of catastrophic fracture propagation in Sioux quartzite thus involves localized nucleation,
D. MARDON
278
growth,
and
essentially
coalescence
the same
of microcracks
as that
and
for stable
is
Friedman,
M. and Johnson,
fined Sioux quartzite.
fracture
B., 1978. Thermal
ET AL.
cracks in uncon-
Proc. 19th Symp.
Rock Mech., 423-
430.
growth.
Hendersen,
(5) The change linear
elastic
in mechanical
behavior
temperatures
yielding
to 710°C
tests,
quartzite
in extension
between
cant inelastic
from
tests run
at
R.,
1975.
SEM/TEM
Metals and Ceramics Hoagland,
R.G.,
Hahn,
fluence
prior to failure
boundaries.
GBC act as nucleation
in the 500 o cracking
Thermally
of
induced
sites for IGC during
Johnson,
of microstructure B.. Gangi,
Krech,
Cambridge Martin,
for their
study,
fabricating
forming
invaluable
extension
and R. Gott-
contributions
to this
specimens
and per-
pressure
(of more
the notched tests under
than one form). Many thanks are extended to B. Johnson for helpful discussions and to J. Ehrman for his assistance with the scanning electron microscope.
We thank
preparation
C. Littleton
of multiple
for her flawless
manuscripts
in varying
forms of revision. Support from the U.S. Department of Energy (grant DE-FGO584ER13228) is gratefully
in rock.
temperature
F.A. and Hjelmstad,
crackchanges.
acknowledged.
R.J.
McColm,
T.R., 1975. Fracture
University III, and
crack growth
Durham,
W.B.,
of Brittle Solids,
1975.
J. Geophys.
I.J., 1983. Ceramic
Mecholsky,
U.S. Bur.
Press, Cambridge.
in quartz.
gists. Leonard
K.E., 1974. A
research,
7865.
Lawn, B.R. and Wilshaw,
Acknowledgements
schalk
propagation
rock suite for rapid excavation
Mines, Rep. Invest.,
J. Magouirk
1973. In-
J., 1978. Thermal
to slow, uniform
W.W., Henderson,
standard
B. Turk,
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A.R.,
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exten-
sion.
We thank
on fracture
A.F. and Handin,
ing of rock subjected
Handbook.
Batelle. Columbus,
G.T. and Rosenfield,
Rock Mech., 5: 77-106.
to thermal
Fractography
Info. Center,
25 o and 412 o C to signifi-
is due
grain
response,
Science
Mechanisms
of
Res.. 80: 4837-4844. for Material
Technolo-
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J.J., Frieman,
S.W. and Rice, R.W., 1978. Fracto-
graphic
analysis
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Cullen
(Editors),
Fractography
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and
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W.H. ASTM
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M.G. and Atkinson
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Tectonophysics,
B.K., 1981. Stress-dependent
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mor-
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Peck, L. and Gordon,
R.B., 1982. The effect
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energy
of compressive
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Res. Lett., 9: 186-189. Peterson,
R.E.,
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Mechanisms of fracture propagation in experimentally Sioux quartzite
extended
Duncan Mardon *, Andreas K. Kronenberg, John Handin, Melvin Friedman and James E. Russell Centerfor Tectonophysics, Texas A&M University, College Station, TX 77843 (U.S.A.) (Received November 30,1989; accepted February 14,199O)
ABSTRACT Mardon, B., Kronenberg, A.K., Handin, .I., Friedman, M. and Russell, J.E., 1990. Mechanisms of fracture propagation in experimentally extended Sioux quartzite. Tectonophysics, 182: 259-278. Notched samples of Sioux quart&e have been extended to faihtre at temperatures 7’ between 25 o and 710 o C, strain rates i from 5.2 x 1Om6 to 6.7 x 10W4 s-i, and 100 MPa confining pressure, and fracture morphologies examined by optical and scanning electron microscopy. In all the extension tests performed, sample failure occurred by the formation of a tensile fracture in or near the notch mid-plane. Differential stress magnitudes at failure are insensitive to variations in T and < and calculated tensile strengths are comparable to previously reported values for unconfined tests at room temperature. Force-displacement records show a change in mechanical response, from linear elastic behavior at temperatures between 2S0 and 412*C to significant yielding in compression prior to failure in the 500° to 71O*C tests. In all cases, fractures consist almost entirely of intragranular cracks (IGC) which exhibit characteristic surface features which can be used to infer local crack propagation directions. In one test in which fracturing was initiated at an edge flaw, IGC propagation directions show no overall trend. The observations indicate that the mechanism of fracture propagation involves nucleation, growth and coalescence of IGC which are themselves propagating in all directions in the plane of the main fracture. The onset of inelastic yielding prior to failure at elevated temperatures is attributed to the formation of thermally induced GBC which act as nucleation sites for IGC during extension.
Introduction The rich variety of features developed on the surfaces of fractures in brittle solids provides a record of the variations in stress and velocity at the tips of propagating cracks. Detailed observation and interpretation of such features is thus a potentially powerful tool for studying the fracture process, especially when combined with information on bulk mechanical behavior. Microscopic features observed on fracture surfaces have been used to infer the locations and dimensions of fracture-initiating flaws, the direction and velocity of crack propagation and details of the mechanisms of crack nucleation and growth in metals,
* Now at Exxon Production Research Company, P.O. Box 2189, Houston, TX 77252, U.S.A. HO-1951/90/$03.50
0 1990 - Elsevier Science Publishers B.V.
glass, ceramics and polymers (e.g., Strauss and Cullen, 1978) and has served to guide theoretical work on fracturing in these materials (e.g., Broek, 1974; Lawn and Wilshaw, 1975). Although significant advances have been made towards understanding fracturing in rocks and minerals (e.g., Atkinson, 1984) relatively few studies have reported detailed observations of fracture surface features. Ryan and Sammis (1978) studied the mechanics of columnar jointing of basalt, driven by thermal stresses during cooling from a melt. Combining evidence from seismic surveys of crystallizing basalt flows with an analogy to fracture surface features produced in cyclic-loading experiments in alu~num and polymers, they interpreted the parallel, evenly spaced markings on joint surfaces as fatigue striations, each corresponding to a discrete episode of crack extension. Smooth and rough bands within each striation
260
D. MARDON
were associated tion,
with elastic and inelastic
respectively,
deforma-
of the host rock at crack
Using similar surface features,
DeGraff
(1987) were able to infer directions
tips.
and Aydin
of joint growth
a canonical are
ensemble
disposed
mediately
upon
gion has been named ing the mirror
plumose joints
Engelder
markings
cutting
episodic
(1984)
on the surfaces
interbedded
siltstones
attributed
logic materials
which report
mineral
as
a
rockforming
and its similarity
ing has been studied
in geo-
and
roscopic
of fine radial
with to its
intensity including tions
industrial
In fact, fracture
as hackle,
crack branching
A variety
observations
to glass in which fractur-
extensively.
mirror.
Border-
roughening,
as mist. This in turn gives way to a zone of larger
of fracture surfaces have been conducted quartz single crystals. This is due mainly importance
the fracture
re-
usually
of fracturing detailed
featureless.
of cross-fold
scale ridges known studies
Im-
this smooth
is a zone of incipient
consisting
origin.
and shales to
crack growth.
Most experimental
and almost
its high reflectivity,
larly,
and
regions which
the
the site of crack nucleation,
are smooth
and determine the sequence of fracture events leading to polygonization of cooling basalts. SimiBahat
about
surrounding
crack surfaces Based
of four textural
radially
ET AL.
beyond
is observed
of factors
may influence
of development microstructure,
in macroscopic
ridges, referred
to
which macto occur. the relative
of these textural zones, specimen size and variastresses.
For
example,
all
four zones are often well developed and mutually distinct on fracture surfaces in glass, owing to its
surface features produced in tensile tests on quartz are highly similar to those in glass (Norton and
homogeneity and ceramics, however,
Atkinson, 1981). Unlike glass, however, quartz has a weak cleavage on its rhombohedral planes which
or even absent,
isotropy. In polycrystalline some zones may be indistinct
especially
in coarse-grained
porous
contributes to the formation of stepped fracture surfaces (Martin and Durham, 1975; Ball and
materials. The development of zones of increasing surface roughness in the direction of crack propagation is
Payne, 1976) the form of which provides further information on the details of fracture behavior.
a dynamic effect in which breakdown crack front into numerous secondary
The primary purpose of this study has been to investigate the mechanism of tensile fracture prop-
curs (e.g., Shand,
1954; Mecholsky
The mirror
corresponds
agation bulk
in polycrystalline mechanical
behavior
quartz
by examining
the
and
morphologies
of
fractures produced in extension experiments performed on Sioux quartzite. The fractures in our experimental samples show many of the characteristic surface features seen on fractures in quartz single crystals. Detailed observations and mapping of crack propagation directions inferred from these surface features provides substantial insight into the fracture propagation process quartzite constitution responsible yielding elevated
prior to failure temperatures.
and changes in for the onset of
in samples
extended
at
Fracture surface features Glass and ceramics Experimental work on tensile crack propagation in glass and ceramics (e.g., Henderson, 1975; Rice, 1984) has established the existence of
region
of a single, from
primary
the initiating
crack
of a single cracks ocet al., 1978).
to the propagation
that
accelerates
flaw. As the velocity
away of the
crack tip nears the terminal velocity for crack propagation of the medium, sufficient energy becomes available to nucleate secondary microcracks about
the primary
propagation ing in the Rayleigh upper
surface
bound
crack tip, but not for extensive
of these secondary cracks, thus resultformation of mist. The velocity of waves
is usually
for the terminal
taken
crack velocity
as an (e.g.
Field, 1971) and velocities of 0.6 u, are typically observed in experiments where v, is the shear wave velocity
(Mecholsky
et al., 1978). The larger
energy release rate associated with a longer overall crack cannot effect further acceleration of the primary crack but instead produces increasingly extensive propagation of secondary cracks leading to hackle formation and, ultimately, crack branching. The presence of flaws in polycrystals tends to hasten the onset of breakdown of the accelerating primary crack front.
FRACTURE
PROPAGATION
Several
IN EXPERIMENTALLY
characteristic
have been identified
fracture
ceramics
whose
of crack propagation.
form
can
cate crack growth parallel this configuration area, change patterns vidual trolled. gation
and
therefore
The
gence of cleavage
to a line bisecting
toward
The concavity
the fracture
origin,
the angle of
of cleavage
especially
suggests
that their formation
teraction
with elastic stress waves (McColm,
the increase associated
with
surface.
steps (Friedel,
a
by in1983).
of crack
Experimental
methods
River of indi-
is cleavage-con-
in the direction
is influenced
in surface
on the surfaces
direction
steps
those on m,
to the step lines because
in which fracturing inferred
was parallel
step intersection.
steps indi-
of the fracture
is down-stream,
the
261
QUARTZITE
gation
features
to infer
Straight
energy,
are often formed
SIOUX
with glass and
be used
minimizes
in elevation grains
surface
in experiments
direction
EXTENDED
propa-
of conver-
1964).
The fractures duced
examined
in this study were pro-
in a suite of extension
dry (no pore pressure)
tests on nominally
Sioux quartzite
at tempera-
tures T from 25 o to 710 o C and strain
rates i of
5.2 X 10m6 to 6.7 x 10e4 s-‘. A lateral confining pressure PC of 100 MPa was applied in all the
Quartz single crystals
experiments.
Essentially all the fracture surface features described above have been produced in tensile frac-
Starting
ture experiments on quartz single crystals, in addition to features associated with its cleavage on the rhombohedral planes r{lOil} and z{Olil}
The texture and composition of Sioux quartzite makes it well suited to the purposes of this study.
(Ball and Payne, 1976; Norton and Atkinson, 1981). A mirror region is generally present about the fracture-initiating flaw. However, for most crystallographic orientations, mist and hackle features are replaced by cleavage steps which are concave toward the fracture origin and increase in size in the direction of crack propagation. Macroscopic crack branching occurs on r and z. Ball and Payne (1976) made a comprehensive study of tensile crack growth in quartz from an edge slit in thin, single crystal slabs of five different orientations in a variety of chemical environments and at temperatures ranging from 77 to 800 K. Arcuate cleavage steps were produced on fracture surfaces of all orientations except for fracture on the (ll!?O) plane in the [liOO] direction. This last orientation exhibited mirror and hackle zones similar to glass. Norton and Atkinson (1981) studied crack propagation from a surface flaw in synthetic and natural Brazilian quartz crystal rods in bending and found that arcuate cleavage steps on basal fracture surfaces exhibited angular, saw-tooth profiles with characteristic hexagonal symmetry. Two intersecting sets of arcuate steps with a gentler, low-amplitude form were produced on m-fractures. In both cases the direction of crack propa-
material
and sample preparation
It is a well indurated, sedimentary orthoquartzite consisting of 99% equigranular quartz and minor amounts of hematite, magnetite, zircon and rutile. The mean quartz grain size, determined by the linear intercept method, is 160 pm. The bulk density
of Sioux
quartzite
is 2.64 g/cm3,
com-
pared to 2.651 g/cm3 for crystalline alpha-quartz (Sosman, 1965), indicating it has extremely low porosity. Krech et al. (1974) have reported a variety of physical properties for Sioux quartzite, including unconfined
tensile
at room temperature.
and compressive Critical
tors for mode I crack propagation zite have been .determined (1982).
strengths
stress intensity
fac-
in Sioux quart-
by Peck and
Gordon
The sample geometry used in the extension tests is shown in Fig. 1. Cylindrical samples with diameters of 18.30( +0.05) mm were cored from a single block of Sioux quartzite. Each core was then cut and ground perpendicular to its axis to a length of 39.8( f 0.9) mm. A circular notch with a radius of curvature of 11.07( + 0.04) mm was machined midway along the length of each core to generate a stress concentration in the sample during extension and thereby localize fracturing. The circular notches were fabricated by turning the samples on a lathe against a cylindrical diamond grinding tool that was held in a controlled feed
D. MARDON
load piston. determined perature
Based using
on axial a hollow
accuracy
ET AL
temperature
profiles
test sample,
the tem-
was taken to be +5”C.
Raw load records (e.g., Fig. 3) show an initial rise as confining pressure is increased, followed by measurements
of
constant-load
packing
segment
friction,
corresponding
and
LOADIN
Fig. 1. Geometry cular
notch
mid-way
Sioux quartzite
of 11.07( +0.04)
along the sample length.
the notch shown
of notched
with a radius is 15.45( +0.05)
with Cu jacket
while jacket
mm.
samples.
sample
-SPECIMEN
sample
Sq-8 is shown
area a at Sq-24
is
with
its
RESISTANCE
removed.
’ Cu
and turned on an axis oriented normal to that of the sample. The diameter of each sample at the notch
mid-plane
was machined
IG PISTON
mm is machined
The cross-sectional Extended
A cir-
a
to free-travel
-
OR
Pb
LUCALOX
FURNACE
JACKET
SPACER
to 15.45( kO.05)
mm. EXTENSION
FITTING
Test apparatus The design of the sample column used are illustrated
assembly and loading in Fig. 2. Notched
samples of Sioux quartzite were sealed in Cu and Pb jackets and extended by retracting an axial loading piston while maintaining a lateral (argon) confining pressure PC of 100 MPa. The loading column incorporates a gun-lock fitting between the lower piston
and closure
of the pressure
vessel OSURE
which allows an interval of free-travel displacement. This permits packing friction to be measured for each test, prior to extending the sample, by measuring the load while advancing and retracting the load piston. Axial loads were measured using a BLH load cell calibrated against a 133 kN (30,000 lb) Tinius Olsen proving ring and confining pressures were read on a Heise gauge. Given the sample dimensions, axial and lateral stresses applied to the sample are resolvable to within kO.7 MPa. An internal resistance furnace with nichrome wire windings was used to achieve elevated temperatures which were monitored using a chromel-alumel thermocouple entering the pressure vessel through a port along the axis of the top
50 mm Fig. 2. Sample
and piston
used for extension were prepared ends.
The
hardened fitting, assembly
with
lower
circular
piston
steel tube allowed
assembly
tests at pressure. notches
assembly,
threaded
of triaxial mid-way
to the endplug
friction
prior to loading
the sample.
their
of a hollow, and a bayonet
piston
measurements
samples
between
consisting
for free travel of the upper
so that packing
gas apparatus
Sioux quartrite
and sample
could be made
FRACTURE
PROPAGATION
IN EXPERIMENTALLY
EXTENDED
SIOUX
sq-2 T = 25’C
263
QUARTZITE
corrected
for the effects of packing
strength,
and for the stress concentration
ated with the notch. conveniently
made
tests on precut
samples
axial force supported mid-plane
measured
load
total
the results as follows.
by an intact at failure
a simple
are
of extension Let F, be the sample
across
and let Fp’ be the
for a precut
displacement.
positive,
jacket associ-
The first two corrections using
the notch
friction,
sample
at the same
Taking
compression
force balance
yields:
to
F,=F,-P,(A-a)+C
IO
05 DISPLACEMENT
Fig.
3. Raw
load-displacement
Following
pressurization
advanced
and then retracted
friction ment
(measured
was then performed
constant
displacement
15
for experiment
in order
to measure
= 2f).
by retracting
corresponds
to the lower
hollow
steel tube.
portion
of the sample
Nominally
A is the cross-sectional
tensile
are obtained
deflection stresses
at a
in the force
engaging
with
the
at the notched
at a load Pc(A - CI) where
area of the load piston
cross-sectional
experi-
the load piston
piston
was
the packing
The extension
rate. The negative
record
Sq-2.
to PC = 100 MPa, the load piston
load difference
and
n is the
area at the notch.
displacement. Once the gun-lock fitting has engaged and contact with the sample is made, the measured deviator+
load drops reflecting stress to the sample.
(1)
where A and a are the cross-sectional areas of the piston and notch mid-plane, respectively, and C is the correction for packing friction and jacket
(mm1
record
be
the application
of
Extension tests on samples containing a precut through the notch were performed at conditions identical to those used in the tests on intact samples to determine jacket strength corrections. Pb
strength. For a precut sample, which can support no tensile axial force, we have: O=Fp’-P,(A-a)+C
(2)
Assuming C is a constant perature, displacement rate, F, is found
by subtracting
age axial stress at failure
for a particular temand jacket material,
(2) from (1). The avera,, is then given by:
u, = F,/a The correction for the stress concentration sociated with the notch is made using an propriate extension, developed
(3) asap-
concentration factor K. During an annular zone of tensile stress is first at the periphery of the notch and then
Stress
expands radially inward, displacing the zone of compression, toward the axis of the sample. The maximum periphery %l,X =
tensile stress a,,,,,, which occurs at the of the notch at failure, is given by:
KU,,
jackets, used only in room temperature tests, were significantly weaker and have smaller strains to failure than Cu jackets. In some tests in which Pb jackets were used, Pb appears to have entered microcracks in the specimen surface, suggesting
our sample geometry. As expected, relatively weak stress concentrator.
these samples could have failed by hydraulic fracture and that the results obtained using Cu jackets
Here, the maximum compressive stress u, is equal to the confining pressure P,; the minimum
may be more
compressive displacements
reliable.
However,
after
correcting
for jacket strength, the load supported by samples extended at the same conditions are the same for both jacket materials, within measurement error. Analysis
of mechanical
data
To determine the failure stress for each test specimen, the measured load at failure Fp must be
(4)
and is taken as the failure stress. Based on results given by Peterson (1974, we estimate K = 1.27 for
stress and
the notch
u3 is the axial nominal strains,
initial sample lengths, were corrected distortions of the apparatus. Observational
is a
stress. Axial dividing by for elastic
methods
Fracture traces were studied in thin sections under plane light and crossed polarizing filters in
D. MAROON
264
......== ’ 4====....._
ET AL
FRACTURE
PROPAGATION
experimentally
IN EXPERIMENTALLY
extended
sure-impregnated surfaces
were
quently
examined
samples
with coated
blue
epoxy.
with
SIOUX
carbon
going, tensile fracture
35 scanning
a narrow
subse-
The measured
Results
tensile Table
TABLE
occurred
stresses
at failure
behavior
In all the extension failure
zone about
tests
performed,
by the formation
the main fracture
differential
stresses
1. In ten of the eighteen samples
within (Fig. 4). of high
u, - a,, axial
a, and amax, and nominal
ple to be discussed
of a through-
in orientations
for all the extension
on notched
sample
consist of
the notch mid-plane
Few cracks are observed resolved shear stress.
elec-
(SEM).
Bulk mechanical
(Fig. 1). Fractures
many cracks that parallel
Fracture and
265
QUARTZITE
that were pres-
using a JEOL
tron microscope
EXTENDED
strains
tests are given extension
tests run
(one test on a modified later),
the average
Comments
c in
sam-
axial stress
1
Sioux quartzite
extension
tests *
T
.
PCa
0,
(“C)
;s-t)
(MPa)
(MPa)
b
-03
Jacket
0” ’
mate-
(MPa)
d enlmax (MPa)
rial
Strain at
W ’
Exp.
failure
(J)
No.
e (W)
25
5.4 x 10-6
100
116.2
cu
-0.3
-0.4
0.42
25
5.4 x 10-6
100
119.1
cu
- 3.2
-4.1
0.35
25
1.2 x 10-s
100
93.1
Pb
_
25
5.5 x 1om5
100
124.5
cu
- 8.6
25
5.6
1O-5
100
112.8
Pb
- 12.2
25
5.7 x 10-s
100
105.6
Pb
- 5.0
25
6.0 x 1O-4
100
96.4
Pb
Sq-4 sq-5
0.31
0.08 _
- 10.9
0.35
0.21
sq-1
- 15.5
0.35
0.34
sq-2
-6.4
0.26
_
0.43
0.12 _
Sq-6
sq-13
Shallow sawcut at notch used to initiate
x
fracture
sq-3 Apparently
did not enter
tensile field 25
6.7
x
1O-4
79.2
100
0.23
Pb
Sq-8
Apparently
did not enter
tensile field 412
1.7 x 10-s
100
500
5.2 x 1O-6
100
108
CU
77.9
-6.1
-7.7
cu
0.42 0.32
0.10 _
sq-15 sq-22
Apparently
did not enter
tensile field 500
8.7 x 1O-6
100
108.0
cu
500
1.1 x 10-5
100
89.2
cu
-3.9 _
-5.0
0.84 0.95
0.78 _
sq-24 sq-23
Apparently
did not enter
tensile field 500
1.7 x 10-s
100
107.5
cu
- 3.4
-4.3
0.75
1.36
Sq-16
500
1.7 x 10-s
100
107.9
cu
- 3.8
-4.8
0.67
0.94
sq-17
500
1.7 x 10-s
100
101.9
cu
-0
-0
0.53
Sq-18
8.4 x 1O-6
100
105.5
cu
-0
-0
0.78
sq-30
251
from
25 o to 500’ C and back to
500/ 25 600
Cycled at pressure
25 o C prior to extension 6.8 x 10-6
99.8
100
cu
0.74
Sq-28
Apparently
did not enter
tensile field 600
8.1 x 1O-6
80.9
100
cu
-
0.43
sq-27
Apparently
did not enter
tensile field 710
6.6 x 10-6
100
104.0
T = temperature;
i = extensional
stress
a,,,
at failure;
no. = experiment
cu
strain
= maximum
PC= confining
rate;
tensile
- 2.0
stress
-2.5 pressure;
at failure;
compressive
Nominal
value at notch (uncorrected
Nominal
value at notch corrected
Corrected
for stress concentration
See text for method
stress). for jacket for friction
of determination.
at notch,
strength). and jacket
friction,
strength.
and jacket
strength.
0.76
(I, - us = differential
W= estimate
number.
PC= q (the maximum
0.68
of mechanical
Sq-26 stress at failure; work
o, = average
in extension
to failure;
tensile Exp.
266
D. MARDON
was tensile
when sample
failure
tests, a,, was approximately six tests, failure
while axial stresses
However,
fractures
these tests have the same location as those
produced
In two
in tests
as tensile
fractures
generated failure
perature,
unrelated
1). As discussed
above,
material
tensile
stresses
temperature
1). This
Given tensile
to variations
room
average
- 11 MPa) reported
ocinter-
stress a,,,
in the tem-
within
used (Table
1). However,
the loading
column
and flaws in the sample
increase
such
tensile
tic behavior
could
stress
deformed
Samples
was generally
con-
insensi-
and strain investigated
rate, (Table
difference
be-
records
at low and high tempera-
extended (Figs.
is in
the maximum
the form of the load-displacement
tures.
at
(- 10 to
is apparently
there is a significant
25 o and 412’ C exhibit
substantially
strengths
in temperature
Bending
of
- 10.9 MPa,
tensile
in the data,
for samples
due to small misalignments
strength
value,
at failure
ated in the sample at the periphery of the notch before the average axial stress becomes tensile. moments
tensile
we esti-
the three largest values
the range of conditions
tween
are gener-
Thus,
by Krech et al. (1974).
the scatter
tive to variations
axial stress at failure
strain rate or jacket
for Sioux quartzite.
the range of unconfined
and orientation
in which
the
(Table
in
as well.
The sign of the measured is apparently
mate
stress
PC= 100 MPa by averaging
were
curred in the tensile field; they are therefore preted
fracture
zero and in the other
occurred
still compressive.
occurred.
ET AL.
at temperatures nearly
5a and
marked
between
perfect
linear
5b). Specimen
by a peak
elasfailure
in differential
centrations and thereby induce fracturing prior to achieving a net tensile stress. Because such imper-
stress and a small, inaudible stress drop to values supported by the metal jacket. In contrast, sam-
fections
ples extended at temperatures undergo significant inelastic
all act
to reduce
stress magnitude (most negative)
the measured
tensile
at failure, we regard the largest values as closest to the “true”
failure
(Fig.
5~). The onset
of 500’ yielding of yielding
0.2
06
04
DISPLACEMENT
P,(=u,
AXIAL
T = 25 o C in Cu and Pb jackets, exhibiting
a similar
mechanical
T = 500 ’ C. d. Sample
(shown
response
as samples
deformed
at T = 25 o C following
correspond
to changes
at
I%)
DISPLACEMENT
Sioux
with arbitrary
Sq-2 deformed
, I0
05 STRAIN
(mm)
for extended
respectively
Sq-30 extended
Displacements
records
TESTS
)=lCOMPo
0
DISPLACEMENT
(mm)
OUARTZITE
EXTENSION
stress-displacement
at
06
04
DISPLACEMENT
(mm) SIOUX
Fig. 5. Differential
occurs
b
cl 02
to 710°C prior to
quartzite
specimens.
offset in displacement). at room
temperature.
heat treatment
lmml
a. Samples b. Sample c. Samples
Sq-1 and
Sq-15 extended Sq-16
at T = 500 o C at hydrostatic
in length of entire samples,
corrected
for apparatus
and
Sq-17
pressure distortion,
at T = 412 o C, extended
at
PC= 100 MPa.
FRACTURE
PROPAGATION
differential sure.
IN EXPERIMENTALLY
stresses well below the confining
Nominal
strains
at failure
temperatures.
mechanical tween 412”
100 MPa (Sosman, Inelastic
nonlinear
behavior
to
the areas
under
at in
static conditions.
which occurs somewhere
be-
this
500 o to 710” C extension
to an elastic
was tensile.
temperatures
similar
and
by finding
subtracting return
in Table
For
between
the
to hydro-
1 for all the
tests for which the measured
at failure
1965).
yielding
determined
for W are given
Values extension
which occurs near 600 o C at
were
their curves
change
twice those obtained
and 500” C, is not due to the alpha-
beta quartz transition
267
QUARTZITE
pres-
in the 500”
Evidently,
behavior,
SIOUX
area corresponding
710° C tests are typically lower
EXTENDED
samples
axial stress extended
25O and 412”C,
at
W varies
in the
from 0.08 to 0.34 J and has a mean value of 0.17 J.
tests (e.g., Fig. 5c) was
For the 500 o to 710 o C tests, W ranges from 0.76
to that observed
also seen in one test (Sq-30) in which the sample
to 1.36 J, with
was extended hydrostatically This indicates
approximately five times larger than that for the lower temperature tests. This effect is illustrated in
at 25’C after first being annealed at 500 ’ C and 100 MPa (Fig. 5d). that the change in mechanical be-
mated
the mechanical
W is approximated under each curve.
and contain
where F, and AL are the force drop and change in axial length at failure, respectively. Values of W for samples which exhibited yielding followed by
low-relief
steps of widely varying
20
-J" QO 5 J
;
IO ..
k!E k u. 0
:
W=O.94
J
0 -R-;
0
DISPLACEMENT
Fig. 6. Estimates respectively.
of inelastic
Substantial
work
differences
of nonlinear
in W are apparent,
behavior
0.6
02
(mm)
W done in extension and increased
re-
I
I3
i 0.4
sizes
"C
A
0.2
area
mist and hackle
sq-2 25'C
w = 0.34
(Sq-17).
the shaded
Thin section examination shows that fractures occupy a narrow zone, generally less than two grain-diameters wide, about the notch mid-plane (e.g., Fig. 4). Fractures consist of many smaller cracks, most of which are linked, that parallel the
(5)
T=
is
fracture surfaces protests are relatively flat
and shapes. Distinct mirror, gions are not developed.
that the sample
“O7
as one-half
Macroscopically, the duced in all the extension
in mechanical we have esti-
w = ;F,AL
J, that
Fracture surface morphology
work W done in extending
the samples to failure. Assuming behaves as a linear elastic solid:
0.96
sion test (Sq-2) and a test run at 500°C
some permanent constituat elevated temperature. In the paper, we argue that thermally-induced micro-
To further illustrate this change behavior at elevated temperatures,
value,
Fig. 6 which shows differential load versus displacement records for a room temperature exten-
havior, from a linear elastic response at low temperature to significant inelastic yielding at high temperatures, is due to tive change that occurs subsequent sections of this change is due to cracking.
a mean
DISPLACEMENT
for experiments associated
0.4 (mm)
Sq-2 (a) and Sq-17 (b) performed
with the lack of yielding
strain to failure exhibited
0.6
at T= 25’
and 5OO”C,
prior to failure at T = 25 o C and the onset
by Sioux quartzite
at T = 500 o C.
D. MARDON
268
Fig. 7. Optical Fracture those
of fractures developed photc nnicrographs co1nsist largely of IGC at all conditions
in samples
surfaces developed
at low temperatures.
c. Fracture
step
ET AL.
Sq-5 (a) and Sq-18 (b) at T = 25 o C and T = iOO”C, rc:spectively. as ctre not as smooth fractures formed at high temperatures
tested. However, at grain
micrographs
boundary
in sample
taken in plane light).
Sq-18
shown
at hig h magnifi cation
(all
FRACTURE
PROPAGATION
main fracture.
IN EXPERIMENTALLY
Individual
one grain diameter
EXTENDED
crack lengths
SIOUX
range from
of fractures
to more than 10 mm. Fractures
formed at all temperatures
consist mainly
which
grains
269
QUARTZITE
412°C quartz
of cracks
grains
4 and 7)
boundaries
i.e., intragranular cracks (IGC). In all cases, grain boundary cracks (GBC) make up a small fraction
to 710°C commonly
of the fracture
7~). Thus,
cut through
quartz
surface.
In thin sections,
Fig. 8. SEM micrographs
of fracture
primarily
and stepped
of IGC (smooth
used to nucleate exhibits
fracture
a river pattern
(Figs.
surface
of sample
surfaces)
in this sample of coalescing
the traces
and promote
cleavage
Sq-13 extended
with isolated fracture
propagation
with respect
its growth
surface
at temperatures typically
without
cutting
of 25’
and
across many
deflections
(Fig. 7a). Fractures
at
produced
grain at 500”
have more jagged traces (Fig. 7b) and show steps at grain boundaries (Fig. IGC
at T= 25’C
GBC (pitted
steps from which
formed
are straight,
which
and i = 1.2
make
x
in top right corner).
from left to right. direction
to each other by 90 o ).
10V5 s-‘. Shallow
b. At higher
has been inferred
up these
a. Fracture
consists
saw cut (at left) was
magnification,
(images
fractures
an IGC
a and b are rotated
D. MARDON
270
SEM examination reveals the form and 1~ )cation of individual IGC and GBC. GBC are irn :gular in shape and appear as pitted patches on the fracture surface with widely ranging orientati !ons relative to the fracture plane (e.g., Figs. 8a and 9a). IGC surfaces are much smoother and are oriented sub-parallel to the main fracture surl!ace (Figs. 8, 9 and 10). Some IGC surfaces are feat1ure-
have a wider range of orientations than those form Led at lower temperatures. In plane polarized light , grain boundaries throughout the samples show a exter rded at the higher temperatures notic ;eably higher relief than in the lower temperature specimens. This suggests that pervasive cracking (2f grain boundaries has occurred at elevated temr jeratures.
Fig. 9. SEM micrographs
of fracture
from GBC step. b. Two well-developed
surface
(sample
Sq-13).
sets of intersecting
ET AL.
a. Arcuate
arcuate
propagation
cleavage
steps of IGC suggest
steps on IGC provide direction.
a high-confidence
crack
growth
indicator
directio n out of local crack
FRACTURE
PROPAGATION
IN EXPERIMENTALLY
EXTENDED
SIOUX
less or show broad undulations. However, many IGC exhibit diagnostic surface features, like those seen on crack surfaces in experimentally deformed quartz single crystals, which can be used to infer IGC propagation directions. Examples include river patterns (Fig. 8) and concentric, arcuate cleavage steps (Fig. 9a). In some cases, intersect-
Fig. 10. SEM micrographs parallel
cleavage
possibly
across a subgrain
of complex
steps to coalescing
within a single quartz these features
cleavage
wall. b. Multiple
grain (small arrows). within individual
ing sets of arcuate cleavage steps are observed (Fig. 9h). Often, the direction of IGC propagation inferred from these features is away from an adjacent GBC (Figs. 8 and 9a). This suggests GBC form pre-existing flaws which act as nucleation sites for IGC. The inferred direction of IGC propagation is often different for adjacent quartz grains
steps on IGC surfaces
river pattern
within
sets of arcuate Patterns
suggest
of fracture
an individual cleavage multiple
grains yield low-confidence
271
QUARTZITE
in sample
IGC suggesting
Sq-13. a. Transition a change
in growth
steps indicating
strongly
crack nucleation
sites along grain boundaries.
indicators
varying
of crack propagation
direction
directions
from closely-spaced direction
by
- 45O,
of crack propagation Visual averages
(large arrows).
of
272
D. MARDON
and, in some cases, varies within individual grains (Figs. 10a and lob). In the example shown in Fig. lob, IGC appear to have nucleated at several places on a single quartz grain boundary. These observations indicate that the grain-scale mechanism of fracture formation is complex, involving simultaneous propagation of many cracks in different directions within the fracture plane.
Fig. 11. SEM micrographs
of fracture
exhibit many of the features
observed
patterns.
b. In addition
surface
of sample
for IGC of fractures
to these features,
fracture
surfaces
Fractures in samples extended at 500 o to 710” C show the same surface features as those developed in the lower temperature tests, induding river patterns and arcuate cleavage steps (Fig. lla). In addition, the surfaces of these frac:tures show traces of IGC, intersecting the main fralcture at high angles (Fig. lla). This observation indicates that IGC formed in samples extendced at
Sq-26 extended generated
at T= 710°C
at room temperature,
of high temperature
small flake-like
ET AL.
steps.
samples
and
(= 6.6
including
X
10m6 s-i.
arcuate
a. IGC s urfaces
cleavage
show IGC which intersect
steps an id river at high ang les and
FRACTURE
PROPAGATION
elevated
temperatures
orientations, from
IN EXPERIMENTALLY
thin
have
consistent section
EXTENDED
a broader
observations.
Unique
fractures produced at high temperatures flake-like steps, up to a few micrometers ter (Fig. lib).
range
with the conclusions
The origin
SIOUX
of
the saw cut. Together,
drawn
the direction
to the
from the saw cut.
are small in diame-
of these features
is not
known. Crack propagation
213
QUARTZITE
where en echelon
cracks overlap
The variability inferred
served
in SEM,
in the directions from
IGC
suggests
of crack propa-
surface that
the
features direction
obof
motion of a macroscopic fracture front may have little or no influence on the propagation direction of individual cracks nucleating within the fracture tip process
zone.
To test for a relationship
be-
tween crack (grain-scale) and fracture (macroscopic) propagation directions, an extension test was performed at room temperature using a modified notched sample (Sq-13) in which a shallow saw cut was placed in one side of the notch mid-plane to initiate fracturing. Surface features on the fracture produced in this test were mapped at two scales of observation, on a close-up photo-
that
was away
(Fig. 12b). Nearly
all steps
on the fracture
surface
vergence.
On the close-up
photograph
crack
tips just
Viewed
along
below
have
the same (Fig. 12a),
in color than the surround-
ing surface due to scattering gation,
indicate
propagation
Fractures consist of en echelon cracks, most of which are linked. Steps on fracture surfaces occur
these steps are lighter
directions
these features
of fracture
of light by en echelon
the main
the fracture
fracture
plane,
surface.
away from
the
saw cut, these steps would appear as en echelon cracks rotated clockwise relative to the main fracture plane. Presumably, these are secondary cracks which formed by breakdown of the primary crack front as it accelerated away from the saw-cut. Directions of crack propagation at the grainscale were inferred from surface features mapped on IGC surfaces in a traverse of contiguous SEM photographs taken along a chord oriented normal to the saw cut (Figs. 12b and 13). Like the fractures produced in tests using standard notched samples, the fracture surface of Sq-13 consists
graph and in a traverse of SEM photographs. Based on the radius of curvature of the tip of the
almost entirely of IGC, oriented sub-parallel to the fracture plane, linked by GBC, at high angles to the fracture plane, which form steps in the
saw cut, about 0.2 mm, the stress concentration the deepest part of the saw cut is estimated
the total fracture
have
been
about
ten
times
stronger
than
at to that
associated with the notch. As expected, the nominal stress across the notch at failure was small and did not appear to reach the tensile field (Table 1). In a close-up photograph (Fig. 12a), the fracture surface can be separated into two regions of distinctly different surface roughnesses. Surrounding the saw cut is a relatively smooth zone containing a few small steps that is interpreted as a fracture mirror. The remainder of the fracture surface contains steps interpreted
much larger and more numerous as hackle. The boundary between
these regions is symmetric and concave toward the saw cut. The distance between this boundary and the leading edge saw cut measured along a diameter bisecting the saw cut is 3.2 mm (Fig. 12b), about one fifth the diameter of the notch midplane. Many steps on the fracture surface have raised, straight edges that trend nearly normal to
fracture
surface.
GBC comprise surface.
tion, there is no roughness between
a small fraction
of
At this scale of observa-
marked difference in surface the mirror and hackle regions,
Determinations of local crack propagation direction were assigned either high-confidence (solid arrow, Fig. 13) or low-confidence (open arrows) ratings. These ratings were subjective and reflect possible ambiguity in inferring crack propagation directions. High-confidence ratings were reserved for those features judged tors of local propagation tinct
river
patterns
and
as unambiguous indicadirection, including disarcuate
cleavage
steps
(Figs. 8 and 9), whereas low-confidence ratings were awarded in situations where an interpretation other than the one given was possible (Fig. 10) but still less likely. No determination of crack propagation was made in cases where two or more alternative interpretations appeared equally likely. In contrast to the direction of fracture growth, i.e., away from the saw cut, indicated by macro-
D. MARDON
274
I........&A -4,..m..............e.....w.....v
%. ... ... ...L&&p? . . . . . .
I
. . . . . . . . . . .
p’.]
ET AL.
from SEM traverse across sample Sq-13. Grain boundaries are shown as solid lines and GBC at the surface are shown stippled. Local
P_= lOOMPa
Tz25C
crack propagation directions are indicated for IGC, based upon cleavage steps and river patterns. The overall fracture extension direction is vertical, away from the saw cut.
Fig. 13. Map of fracture surface constructed
iJ
SQ-13
High Confidence LOW Condidence
I
Local Crack Propagation Direction
Grain Boundary
400pm
276
scopic surface features (Fig. 12), there is no overall trend in local crack propagation directions indicated by IGC surface features (Fig. 13). This indicates that microstructural heterogeneities, especially grain boundaries and cleavage, are the dominant controls on the direction of crack propagation at the grain-scale. Figure 8 shows a striking illustration of this effect. In this example, a prominent river pattern provides a ‘high-confidence indicator of IGC propagation direction (large arrow, Fig. X), away from an adjacent GBC, that is at least 100” oblique (clockwise) to the overall direction of fracture propagation (small arrow, Fig. 8). Note that this location is less than 0.5 mm away from the saw cut at which the fracture initiated and that the GBC is oriented parallel to the fracture plane. Opening displacements across the GBC in this example apparently resulted in tensile stress concentrations along its perimeter that were substantially stronger than that associated with the nearby saw cut and thereby initiated crack growth in the adjacent quartz grain. Discussion
Detailed examination of the fractures produced in our experiments has established that, over the range of conditions investigated, failure of Sioux quartzite occurs by tensile fracturing. Fractures consist almost entirely of ICC which exhibit characteristic surface features like those seen on fractures in quartz single crystals extended under conditions which ensured brittle behavior (Ball and Payne, 1976; Norton and Atkinson, 1981). In addition, our results indicate that catastrophic fracturing of quartzite involves localized nucleation, propagation, and coalescence of microcracks about the primary fracture front. This is essentially the same mechanism that has been inferred for stable fracture growth in quartz-bearing crystalline rocks from both field (e.g., Segall and Pollard, 1983) and experimentai studies (Hoagland et al., 1973; Peck and Gordon, 1982). While a consistent direction of fracture propagation at the macroscopic scale can sometimes be identified, crack propagation at the grain-scale has no such preferred direction. This implies that the tip of a propagating fracture
Il. MARDON
ET AL,
consists of a zone of microcracks which are themselves propagating in various directions in the plane of the main fracture. Evidently, the macroscopic stress field associated with the main fracture confines IGC formation within a narrow zone, up to a few grain-diameters wide, about the fracture plane while heterogeneities in stress intensity at the grain-scale, associated with the rock grain structure, control IGC nucleation and propagation. Because sample failure occurred by brittle fracturing in all the extension tests performed, the transition in mechanical behavior, from a linear elastic response at low temperature to significant inelastic yielding prior to failure at high temperatures, cannot be due to a change in deformation mechanism. Instead, this transition, which occurs between 412” and 500°C appears to be due to thermally induced microcracking of quartzite grain boundaries which act to increase the density of critical flaws for IGC nucleation during extension. This interpretation is supported by the mechanical response observed in extension test Sq-13, run at 25” C after first annealing the sample at 500°C which shows inelastic yielding like that observed in the extension tests run at 500 o to 710 o C. Thin section observations suggest that grain boundaries in samples heated to at least 500” C may be extensively cracked. However, many of these samples have non-zero tensile strengths, indicating that not all grain boundaries are cracked. Thin section and SEM observations also indicate that IGC in test specimens which exhibited yielding prior to failure have a broader range of orientations than in specimens for which such yielding was not observed. A microcrack population having a broad range of orientations could accommodate the bulk shear deformation associated with yielding in compression prior to failure. Thermally induced microcracking of Sioux quartzite subjected to slow, uniform heating has been investigated by several methods, including measurements of acoustic emissions and P-wave velocities (Johnson et al., 1978). and by pointcounting in thin sections (Friedman and Johnson, 1978). Johnson et al. (1978) found that the onset of microcracking associated with the thermal expansion anisotropy of quartz in unconfined speci-
FRACTURE
PROPAGATION
IN EXPERIMENTALLY
EXTENDED
SIOUX
OUARTZITE
211
the thermal aa
coefficients
(Y, - (Y,, varies
from 0.6 X 10e5 to 1 X 10m5 “C’
in the temper-
ature range 20” to 500 o C (Birch, 1966; Skinner, 1966). Using these values and assuming a tensile
E =;+uAT
strength
Et = E2
ture dl
z
(Y= 10 MPa yields
for microcracking
ture change quartz interface
grains
thermal
expansion
AT at confining of similar
dimension
(c, = e2). Expansion
ferences in expansion
anisotropy
neighboring
(d, = d2), bonded
anisotropy
coefficients
for tempera-
PC between
pressure
depends
a and Young’s
the a and c crystallographic
at their upon
moduli
a threshold
tempera-
PC= 100 MPa in the
at
range 304” to 490 o C. Given the highly idealized nature of the bi-crystal model and assumptions
d2
involved, Fig. 14. Maximum
expansion
dif-
atures
the range of estimated
is in surprisingly
temperature experiments cracking
interval
412”
indicate
has begun
threshold
good agreement
temperwith the
to 500 o C in which our
thermally
induced
micro-
to occur.
E for
axes.
Conclusions (1) Notched samples tended at temperatures
of
Sioux quartzite between 25”
exand
mens occurs at a threshold temperature of 200°C and that thermal cracking continues as the temperature is increased beyond 200” C. This threshold temperature can be expected to increase with increasing confining pressure. To estimate the temperature increase AT re-
710°C strain rates i from 5.2 X 10e6 to 6.7 x lop4 s-l, and 100 MPa confining pressure fail by brittle, tensile fracturing. Failure occurs at differential stresses that are insensitive to variations
quired
in T and
for thermal
cracking
of quartzite
at 100
i and
calculated
tensile
strains model,
(2) The fractures produced in all extension tests consist mainly of intragranular cracks (IGC) which closely parallel the main fracture. Grain boundary
sions are bonded across a planar interface. The a and c crystallographic axes in one of the crystals are, respectively, parallel and normal to this interface; in the other crystal these orientations are reversed. Because the principal directions of thermal expansion anisotropy in the adjoining crystals are orthogonal, this model yields a minimum estimate for AT. Assuming the strains in both halves of the bi-crystal are equal, we find: AT=
a[l+
E,/E,.] +2P, E,(a,-a,.)
for un-
tests at room temperature.
cracks (GBC) make up a small fracture surface area in all cases.
fraction
of the
(3) IGC exhibit characteristic surface features, like those developed on experimentally produced tensile fractures in quartz single crystals, which can be used to infer IGC propagation directions. (4) Two scales of crack propagation are defined. At the sample scale, fracture propagation is directional, whereas microcracks at the grain scale grow in all directions within the fracture plane. This conclusion suggests that the tip of a propa-
(6)
where E, and EC are the effective Young’s
values
are
MPa confining pressure, we have used a simple model for linear, one-dimensional thermoelastic in a quartz bi-crystal (Fig. 14). In this a pair of quartz crystals of equal dimen-
reported
strengths
comparable confined
to previously
T
moduli
in the a and c directions, (Y, and (Y, are the corresponding coefficients of thermal expansion, and (Yis the uniaxial tensile strength of quartz. At temperatures below the alpha-beta transition, the elastic moduli for quartz are insensitive to variations in the temperature (Johnson et al., 1978) so we have used the room temperature values E, = 78 GPa and EC = 103 GPa. The difference between
gating fracture consists of a zone of microcracks. The macroscopic stress field associated with the main fracture restricts IGC formation within a narrow zone about the fracture plane while microstructural heterogeneities, principally grain boundaries and cleavage, are the dominant controls on IGC nucleation and propagation. The mechanism of catastrophic fracture propagation in Sioux quartzite thus involves localized nucleation,
D. MARDON
278
growth,
and
essentially
coalescence
the same
of microcracks
as that
and
for stable
is
Friedman,
M. and Johnson,
fined Sioux quartzite.
fracture
B., 1978. Thermal
ET AL.
cracks in uncon-
Proc. 19th Symp.
Rock Mech., 423-
430.
growth.
Hendersen,
(5) The change linear
elastic
in mechanical
behavior
temperatures
yielding
to 710°C
tests,
quartzite
in extension
between
cant inelastic
from
tests run
at
R.,
1975.
SEM/TEM
Metals and Ceramics Hoagland,
R.G.,
Hahn,
fluence
prior to failure
boundaries.
GBC act as nucleation
in the 500 o cracking
Thermally
of
induced
sites for IGC during
Johnson,
of microstructure B.. Gangi,
Krech,
Cambridge Martin,
for their
study,
fabricating
forming
invaluable
extension
and R. Gott-
contributions
to this
specimens
and per-
pressure
(of more
the notched tests under
than one form). Many thanks are extended to B. Johnson for helpful discussions and to J. Ehrman for his assistance with the scanning electron microscope.
We thank
preparation
C. Littleton
of multiple
for her flawless
manuscripts
in varying
forms of revision. Support from the U.S. Department of Energy (grant DE-FGO584ER13228) is gratefully
in rock.
temperature
F.A. and Hjelmstad,
crackchanges.
acknowledged.
R.J.
McColm,
T.R., 1975. Fracture
University III, and
crack growth
Durham,
W.B.,
of Brittle Solids,
1975.
J. Geophys.
I.J., 1983. Ceramic
Mecholsky,
U.S. Bur.
Press, Cambridge.
in quartz.
gists. Leonard
K.E., 1974. A
research,
7865.
Lawn, B.R. and Wilshaw,
Acknowledgements
schalk
propagation
rock suite for rapid excavation
Mines, Rep. Invest.,
J. Magouirk
1973. In-
J., 1978. Thermal
to slow, uniform
W.W., Henderson,
standard
B. Turk,
Ohio.
A.R.,
Proc. 19th Symp. Rock Mech., 259-267.
exten-
sion.
We thank
on fracture
A.F. and Handin,
ing of rock subjected
Handbook.
Batelle. Columbus,
G.T. and Rosenfield,
Rock Mech., 5: 77-106.
to thermal
Fractography
Info. Center,
25 o and 412 o C to signifi-
is due
grain
response,
Science
Mechanisms
of
Res.. 80: 4837-4844. for Material
Technolo-
Hill, Glasgow.
J.J., Frieman,
S.W. and Rice, R.W., 1978. Fracto-
graphic
analysis
of ceramics.
Cullen
(Editors),
Fractography
In: B.M. Strauss in Failure
and
Analysis.
W.H. ASTM
STP 645: 363-379. Norton,
M.G. and Atkinson
phological
features
Tectonophysics,
B.K., 1981. Stress-dependent
on fracture
surfaces
of quartz
mor-
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77: 283-295.
Peck, L. and Gordon,
R.B., 1982. The effect
stress on the fracture
energy
of compressive
of Sioux quartzite.
Geophys.
Res. Lett., 9: 186-189. Peterson,
R.E.,
1974.
Stress
Concentration
Factors.
Wiley,
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