132 Microcanonical ensemble
as completely rigid, with internal bond lengthsdOHanddHH, so that the
constraints are:|rO−rH 1 |^2 −d^2 OH= 0
|rO−rH 2 |^2 −d^2 OH= 0
|rH 1 −rH 2 |^2 −d^2 HH= 0.a. Derive the constrained equations of motion for the three atomsin the
molecule in terms of undetermined Lagrange multipliers.
b. Assume that the equations of motion are integrated numerically using the
velocity Verlet algorithm. Derive a 3×3 matrix equation that can be used
to solve for the multipliers in the SHAKE step.
c. Devise an iterative procedure for solving your matrix equation based on
a linearization of the equation.
d. Derive a 3×3 matrix equation that can be used to solve for the multipliers
in RATTLE step. Show that this equation can be solved analytically
without iteration.3.4. A one-dimensional harmonic oscillator of massmand frequencyωis described
by the Hamiltonian
H=p^2
2 m+
1
2
mω^2 x^2.For the phase space function a(x,p) =p^2 , prove that the microcanonical
ensemble average〈a〉and the time averagēa=1
T
∫T
0dt a(x(t),p(t))are equal. Here,T= 2π/ωis one period of the motion.3.5. Consider a single particle moving in one dimension with a Hamiltonian ofthe
formH=p^2 / 2 m+U(x), and consider factorizing the propagator exp(iL∆t)
according to the following Trotter scheme:exp(iL∆t)≈exp(
∆t
2p
m∂
∂x)
exp(
∆tF(x)∂
∂p)
exp(
∆t
2p
m∂
∂x)
.
a. Derive the finite-difference equations determiningx(∆t) andp(∆t) for
this factorization. This algorithm is known as theposition Verletalgo-
rithm (Tuckermanet al., 1992).
b. From the matrix of partial derivativesJ =
∂x(∆t)
∂x(0)∂x(∆t)
∂p(0)
∂p(∆t)
∂x(0)∂p(∆t)
∂p(0)
,
show that the algorithm is measure-preserving and symplectic.