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mesoporosity

Mesoporosity is a characteristic of porous materials whose pore diameters fall within the mesopore range defined by IUPAC (2 to 50 nanometers). Materials with mesoporosity feature networks of interconnected pores that are larger than micropores but smaller than macropores, providing high surface areas and enhanced accessibility for larger molecules.

Common mesoporous materials include silica forms such as MCM-41 and SBA-15, as well as mesoporous carbons, metal

Characterization relies on gas adsorption techniques, notably nitrogen adsorption-desorption isotherms to obtain surface area (BET) and

Properties of mesoporous materials include high surface area, tunable pore size, and good accessibility of internal

Applications span catalysis, adsorption and separation, drug delivery, energy storage, and sensing. In catalysis, mesopores enable

Challenges include achieving reproducible pore structures at scale, maintaining stability under operating conditions, and functionalizing pore

oxides,
and
some
polymer
networks.
Mesoporosity
is
typically
introduced
through
templating
strategies
during
synthesis:
soft
templating
uses
surfactants
or
block
copolymers
that
assemble
into
regular
mesostructures,
while
hard
templating
uses
a
solid
sacrificial
template
that
is
removed
after
the
framework
is
formed.
pore
size
distributions
(BJH
or
NLDFT).
Transmission
electron
microscopy
and
small-angle
X-ray
scattering
can
reveal
pore
ordering
and
structure.
surfaces.
The
pore
architecture
influences
diffusion
of
molecules
in
catalysis
and
adsorption
processes.
The
stability
depends
on
composition
and
synthesis
conditions;
silica-based
systems
are
common
but
can
be
susceptible
to
hydrothermal
degradation,
while
carbon
and
some
oxides
may
offer
better
conductivity
or
redox
activity.
diffusion
of
bulky
reactants
to
active
sites.
In
drug
delivery,
mesoporous
carriers
can
load
and
release
therapeutic
molecules.
In
energy
devices,
mesoporous
materials
serve
as
electrodes
or
electrolytic
hosts.
surfaces
for
specific
interactions.
Ongoing
research
seeks
to
broaden
material
types,
improve
thermal
and
chemical
resilience,
and
integrate
mesoporous
components
into
composite
systems.