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microfracturing

Microfracturing is the initiation and growth of small fractures, or microcracks, within a solid under stress. These features are usually submillimeter to a few millimeters long and can occur in rocks, concrete, ceramics, and metals as precursors to larger fractures. Microfracturing reduces strength and stiffness and can increase deformability; in porous rocks it also alters porosity and permeability.

Causes include mechanical loading beyond the elastic limit, thermal cycling that creates differential expansion, chemical weakening

Detection and study rely on imaging and monitoring techniques such as optical microscopy, scanning electron microscopy,

Geologically, networks of microfractures influence rock stiffness, strength, seismic velocities, and, crucially, porosity and permeability. They

The term microfracturing is related to microcracking and is used variably across disciplines; some authors reserve

by
fluids,
and
cyclic
fatigue.
Microfractures
often
start
at
defects,
grain
boundaries,
or
mineral
interfaces
and
propagate
where
stress
concentration
or
fluid
pressure
are
sufficient.
X-ray
or
micro-CT
tomography,
and
acoustic
emission
or
microseismic
monitoring.
Laboratory
tests
on
rock
or
concrete
samples
under
controlled
loading,
combined
with
imaging,
are
common
ways
to
examine
microfracture
development.
affect
hydrocarbon
reservoirs,
groundwater
flow,
and
the
evolution
of
fracture
systems
during
tectonic
or
diagenetic
processes.
In
engineering,
microfracturing
signals
damage
accumulation
and
can
herald
macroscopic
failure,
influencing
the
durability
and
fatigue
life
of
structures
like
concrete,
tunnels,
and
pressure
vessels.
In
hydraulic
fracturing,
induced
microfractures
help
form
interconnected
fracture
networks
that
enhance
fluid
flow;
models
often
incorporate
microcrack
growth
within
the
evolving
stress
field.
microfracturing
for
damage
at
the
microscale.