1549380323-Statistical Mechanics Theory and Molecular Simulation

(jair2018) #1

248 Isobaric ensembles


Ri=

∑n
∑α=1mi,αri,α
n
α=1mi,α

. (5.11.2)


We saw in Section 1.11 that the center-of-mass motion of each molecule can be sep-
arated from internal motion relative to a body-fixed frame. Thus,if the derivation
leading up to eqn. (4.6.57) is repeated using the transformation in eqn. (5.11.1), the
following pressure estimator is obtained:


Pmol(P,R) =

1


dV

∑N


i=1

[


P^2 i
Mi
+Ri·Fi

]


, (5.11.3)


whereMiis the mass of theith molecule, andPiis the momentum of its center of
mass:


Pi=

∑n

α=1

pi,α, (5.11.4)

andFiis the force on the center of mass


Fi=

∑n

α=1

Fi,α. (5.11.5)

The virial term appearing in eqn. (5.11.3)


∑N

i=1

Ri·Fi

is known as themolecular virial.
Given the molecular virial, it is straightforward to derive a molecular dynamics
algorithm for the isoenthalpic-isobaric ensemble that uses a molecular virial. The key
feature of this algorithm is that the barostat coupling acts only on the center-of-mass
positions and momenta. Assuming three spatial dimensions and no constraints between
the molecules, the equations of motion take the form


r ̇i,α=
pi,α
mi,α

+



W

Ri

p ̇i,α=Fi,α−

(


1 +


1


N


)



W

mi,α
Mi
Pi

V ̇=dV pǫ
W

p ̇ǫ=dV(Pmol−P) +

1


N


∑N


i=1

P^2 i
Mi

. (5.11.6)


These equations have the conserved energy


H′=



i,α

p^2 i,α
2 mi,α
+U(r) +

p^2 ǫ
2 W

+PV, (5.11.7)


where therinU(r) denotes the full set of atomic positions. The proof that these
equations generate the correct isobaric-isoenthalpic ensemble is left as an exercise

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