12.2 The variational Monte Carlo method 381
probability 1− 2 α. This is clearly a Markov process as described inSection 10.3.
We are interested in the probabilityρ(x,t)to find the walker at sitex=naat
timet=mh, wherenandmare both integer. This probability satisfies the master
equation of the Markov process:ρ(x,t+h)−ρ(x,t)=α[ρ(x+a,t)+ρ(x−a,t)− 2 ρ(x,t)]≈αa^2∂^2 ρ(x,t)
∂x^2.
(12.22)
For smallh, the left hand side can be written ash(∂ρ/∂t), and definingγ=a^2 α/h,
we can write the continuum form of the master equation (for smalla)as
∂ρ(x,t)
∂t=γ∂^2 ρ(x,t)
∂x^2. (12.23)
This equation is called thediffusion equation: it describes how the probability
distribution of a walker evolves in time. It may equivalently be interpreted as the
density distribution for a large collection of independent walkers.
Consider the following function:G(x,y;t)=1
√
4 πγte−(x−y)(^2) /( 4 γt)
. (12.24)
This function has the following properties:- Considered as a function ofyandt, keepingxfixed, it is a solution of the
diffusion equation fort>0. - Fort→0,Greduces to a delta-function:
G(x,y;t)→δ(x−y)fort→0. (12.25)Gis called theGreen’s functionof the diffusion equation. This function can be
used to write the time evolution of any initial distributionρ(x,0)of this equation
in integral form:
ρ(y,t)=∫
dxG(x,y;t)ρ(x,0), (12.26)which can easily be checked using the properties ofG. Inspection of the Green’s
function shows that it is normalised, that is,∫
dyG(x,y;t)=1, independent ofx
andt.
The Green’s function can be interpreted as the probability distribution of a single
walker which starts off at positionxatt=0. We can useGto construct a new
Markov process corresponding to the diffusion equation. We discretise the time in
steps t. We start with a walker localised atxatt=0. Then we move this walker
to a new positionyat time twith probability distributionG(x,y; t). From this,