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pdV

pdV refers to the pressure-volume work term in thermodynamics. It represents the infinitesimal amount of work done when the volume of a system changes by an infinitesimal amount dV at pressure p. In a quasi-static, reversible process, the differential work done by the system on its surroundings is δW = p dV, and the total work over a process is W = ∫ p dV.

Sign conventions for pdV can vary. Many physics texts use δW = p dV to denote work done

Relation to the first law of thermodynamics is given by dU = δQ − δW for a reversible

Examples help illustrate pdV. For an isothermal ideal-gas expansion with p = nRT / V, the work is

In a pressure–volume diagram, the work done during a process equals the area under the p–V curve

by
the
system,
while
some
chemistry
sources
adopt
δW
=
-p
dV
to
denote
work
done
on
the
system.
Because
W
is
path
dependent,
δ
and
the
sign
are
important
in
energy
accounting.
path,
so
with
δW
=
p
dV
one
has
dU
=
δQ
−
p
dV.
This
underlies
many
energy
balance
calculations
for
simple
compressible
systems.
W
=
∫
V1^V2
(nRT
/
V)
dV
=
nRT
ln(V2/V1).
For
a
reversible
adiabatic
process
with
p
V^γ
=
constant,
the
work
is
W
=
(p2
V2
−
p1
V1)
/
(1
−
γ)
(or
equivalently
W
=
(p1
V1
−
p2
V2)
/
(γ
−
1))
depending
on
sign
convention.
between
the
initial
and
final
volumes.
The
pdV
term
thus
provides
a
concise
way
to
express
the
mechanical
work
exchanged
with
the
surroundings
in
many
thermodynamic
problems.