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monocrystals

Monocrystals, or single crystals, are solids in which the crystal lattice is continuous and unbroken throughout the entire sample, with no grain boundaries. This distinguishes them from polycrystals, which consist of many crystallites oriented differently, and from amorphous solids, which lack long-range order.

Because the atomic arrangement is continuous, many physical properties are anisotropic, meaning they vary with crystallographic

Common growth methods include the Czochralski process, where a seed crystal is rotated and pulled from a

Natural monocrystals occur in geology and are valued for hardness and optical properties (diamond, quartz, sapphire).

Quality is described by defect density, mosaic spread, and inclusion content. Large, defect-free crystals are challenging

direction.
Mechanical
strength,
thermal
expansion,
and
optical
indices
can
depend
on
orientation.
Impurities
and
defects
such
as
dislocations
reduce
crystal
perfection
and
performance.
melt
to
form
a
boule;
the
Bridgman-Stockbarger
technique,
which
cools
a
molten
sample
through
a
temperature
gradient
to
promote
single-crystal
solidification;
flux
growth,
which
uses
a
solvent
to
dissolve
the
material
and
promote
slow
crystallization;
and
hydrothermal
growth,
used
for
certain
oxides
at
high
pressure.
Epitaxial
methods
grow
thin
single-crystal
layers
on
a
substrate.
Synthetic
monocrystals
are
produced
for
technology,
including
silicon
wafers,
gallium
arsenide
for
electronics,
and
various
optical
crystals
such
as
lithium
niobate,
lithium
tantalate,
and
sapphire.
Applications
span
microelectronics,
photovoltaics,
LEDs,
lasers,
nonlinear
optics,
and
X-ray
instrumentation.
to
grow
and
costly,
which
limits
size
and
availability
for
some
applications.
The
orientation
of
the
seed
determines
the
crystal
directionality
and
is
important
for
device
performance.