Home

thermoacoustics

Thermoacoustics is the study of the interaction between thermal and acoustic processes in fluids, focusing on how temperature variations, heat transfer, and sound waves influence one another and how acoustic energy can be generated, amplified, or converted into thermal energy and vice versa.

A central principle is the Rayleigh criterion: when heat is added to a gas in phase with

Devices in thermoacoustics include engines that convert heat into acoustic power and refrigerators that use acoustic

History and status: theoretical foundations were laid by Lord Rayleigh in the 19th century, with modern experimental

the
pressure
fluctuations
of
an
acoustic
wave,
work
is
done
on
the
gas
and
the
wave
grows.
Conversely,
heat
removal
in
phase
with
the
pressure
fluctuations
damps
the
wave.
In
thermoacoustic
devices
a
temperature
gradient
along
a
porous
medium,
such
as
a
stack
or
regenerator,
interacts
with
the
oscillating
flow
to
produce
net
energy
transfer
between
heat
and
sound.
power
to
move
heat.
Configurations
are
typically
standing-wave
or
traveling-wave
resonators,
with
a
hot
end
and
a
cold
end
and
a
porous
stack
to
enable
thermoacoustic
heat
pumping.
The
same
physical
principles
underpin
both
energy
generation
and
heat
transport
in
these
systems.
and
practical
development
advancing
in
the
late
20th
century
and
onward.
Current
research
spans
theory,
materials,
and
applications
such
as
waste-heat
recovery,
low-emission
power
generation,
and
solid-state
cooling.
Challenges
include
efficiency
limits,
material
losses,
and
control
of
instabilities,
but
thermoacoustic
devices
offer
robustness
and
simplicity
due
to
their
lack
of
moving
mechanical
parts.