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MGSi

Mg2Si, commonly referred to as magnesium silicide, is a binary inorganic compound formed from magnesium and silicon. It is produced and studied for its semiconductor properties and potential applications in thermoelectrics. The shorthand MGSi is sometimes used in informal discussions, but the conventional formula is Mg2Si.

Structure and synthesis: Mg2Si crystallizes in the antifluorite structure, with silicon atoms forming a face-centered cubic

Properties: Mg2Si is a gray crystalline solid with high thermal stability and a melting point around the

Reactions and handling: On hydrolysis, Mg2Si can produce magnesium hydroxide and silane (SiH4), releasing flammable gas.

Applications and research: Mg2Si has been investigated as a thermoelectric material for mid-temperature applications, with ongoing

lattice
and
magnesium
atoms
occupying
the
tetrahedral
sites.
The
compound
is
typically
prepared
by
direct
reaction
of
magnesium
metal
with
silicon
at
elevated
temperatures
under
inert
atmosphere,
or
by
other
high-temperature
synthesis
routes
followed
by
purification.
low
thousands
of
degrees
Celsius.
It
is
a
narrow-bandgap
semiconductor,
which
has
made
it
a
subject
of
interest
in
thermoelectric
research.
Its
electrical
behavior
can
be
influenced
by
doping
and
stoichiometry,
allowing
exploration
of
p-type
and
n-type
conduction
through
appropriate
dopants
or
processing
conditions.
Mg2Si
is
relatively
reactive
in
air
and
water,
particularly
in
powder
form,
and
surfaces
often
require
protection.
It
also
reacts
with
acids
to
generate
hydrogen
gas
and
silicate
species.
Because
of
its
reactivity,
handling
is
typically
done
under
inert
atmosphere
or
with
protective
coatings,
and
powders
are
stored
away
from
moisture
and
air.
work
to
enhance
performance
through
doping,
nanostructuring,
and
composite
approaches.
It
is
primarily
of
interest
to
researchers,
rather
than
as
a
consumer
material,
and
is
used
as
a
model
system
for
studying
silicide
chemistry
and
thermoelectric
behavior.