Home

crystallinity

Crystallinity is the degree to which a solid exhibits long-range, periodic atomic or molecular order. In crystalline materials, atoms or molecules are arranged in a repeating lattice over large distances; in amorphous materials, order is limited to short ranges. Many materials show a spectrum between these extremes, with semi-crystalline materials containing both crystalline and amorphous regions. In polymers, crystallinity specifically refers to the fraction of chains organized into ordered, tightly packed regions (crystalline lamellae) within a largely disordered matrix.

Quantifying crystallinity typically yields a crystallinity degree (Xc) between 0 and 1 (or 0% and 100%). Common

Factors that influence crystallinity include cooling rate, annealing, molecular weight and tacticity (in polymers), impurities, and

Effects of crystallinity are widespread: higher crystallinity typically raises melting temperature, stiffness, and chemical resistance, while

measurement
methods
include
differential
scanning
calorimetry
(DSC),
which
estimates
Xc
from
the
heat
of
fusion
relative
to
the
heat
of
fusion
for
a
fully
crystalline
reference;
X-ray
diffraction
(XRD),
which
separates
sharp
crystalline
peaks
from
broad
amorphous
halos;
and
density
or
solid-state
NMR
techniques.
In
metals
and
ceramics,
crystallinity
is
often
referred
to
as
crystalline
fraction
and
can
influence
properties
such
as
strength,
toughness,
and
diffusion.
processing
conditions.
Slower
cooling
or
post-processing
annealing
generally
increases
crystallinity
by
allowing
molecules
to
rearrange
into
ordered
structures,
while
rapid
cooling
can
trap
an
amorphous
state.
reducing
impact
strength
and
solubility.
It
also
affects
optical
properties
and
barrier
performance
in
polymers.
Common
semi-crystalline
polymers
include
polyethylene
and
polypropylene;
highly
crystalline
materials
often
exhibit
distinct
spherulitic
morphologies
and
higher
rigidity.