362 Free energy calculations
fromx=−atox= 0, i.e., the value ofyremains fixed in each ensemble
member during this process. The work performed on each system inthe
ensemble is related to the change in potential energy in this processbyW=U(0,y)−U(−a,y)(see eqn. (1.4.2)). By performing the average ofW over the initial en-
semble, that is, an ensemble in whichx=−afor each member of the
ensemble, show that〈W〉>∆A.c. Now perform the average of exp(−βW) for the work in part b using the
same initial ensemble and show that the Jarzynski equality〈exp(−βW)〉=
exp(−β∆A) holds.8.7. Calculate the unbiasing (Z(r)) and curvature (G(r)) factors (see eqns. (8.7.20)
and (8.7.31)) in the blue moon ensemble method for the following constraints:
a. a distance between two positionsr 1 andr 2 ;b. the difference of distances betweenr 1 andr 2 andr 1 andr 3 , i.e.,σ=
|r 1 −r 2 |−|r 1 −r 3 |;c. the bend angle between the three positionsr 1 ,r 2 , andr 3. Treatr 1 as the
central position;
∗d. the dihedral angle involving the four positionsr 1 ,r 2 ,r 3 , andr 4.8.8. For the enzyme–inhibitor binding free energy calculation illustrated in Fig. 8.1,
describe, in detail, the algorithm that would be needed to perform the calcu-
lation along the indirect path. What are the potential energy functions that
would be needed to describe each endpoint?∗ 8 .9. a. Write a program to perform an adiabatic free energy dynamicscalcu-
lation of the free energy profileA(x) corresponding to the potential in
problem 8.6. Using the following values in your program:a= 1,U 0 = 5,
kTy= 1,kTx= 5,my= 1,mx= 1000,λ= 2.878. Use separate Nos ́e–
Hoover chains to control thexandytemperatures.b. Use your program to perform the histogram test of Section 8.12. Does
your histogram peak atp= 1/2?8.10. Write adiabatic dynamics and thermodynamic integration codesto generate
theλfree energy profile of Fig. 8.2 using the switchesf(λ) = (λ^2 −1)^4 and
g(λ) = ((λ−1)^2 −1)^4. In your adiabatic dynamics code, usekTλ= 0.3,
kT = 1,mλ= 250,m= 1. For the remaining parameters, takeωx= 1,
ωy= 2, andκ= 1.∗8.11. Derive eqns. (8.10.13).