TY - JOUR
T1 - Monte Carlo evaluation of real-time Feynman path integrals for quantal many-body dynamics
T2 - Distributed approximating functions and Gaussian sampling
AU - Kouri, Donald J.
AU - Zhu, Wei
AU - Ma, Xin
AU - Pettitt, B. Montgomery
AU - Hoffman, David K.
PY - 1992
Y1 - 1992
N2 - In this paper we report the initial steps in the development of a Monte Carlo method for evaluation of real-time Feynman path integrals for many-particle dynamics. The approach leads to Gaussian importance sampling for real-time dynamics in which the sampling function is short ranged due to the occurrence of Gaussian factors. These Gaussian factors result from the use of a generalization of our new discrete distributed approximating functions (DDAFs) to continuous distributed approximating functions (CDAFs) so as to replace the exact coordinate representation free-particle propagator by a "CDAF-class, free-particle propagator" which is highly banded. The envelope of the CDAF-class free propagator is the product of a "bare Gaussian", exp[-(x′ - x)2σ2(0)/(2σ4(0) + ℏ2τ2/m2)], with a "shape polynomial" in (x′ - x)2, where σ(0) is a width parameter at zero time (associated with the description of the wavepacket in terms of Hermite functions), τ is the time step (τ = t/N, where t is the total propagation time), and x and x′ are any two configurations of the system. The bare Gaussians are used for Monte Carlo integration of a path integral for the survival probability of a Gaussian wavepacket in a Morse potential. The approach appears promising for real-time quantum Monte Carlo studies based on the time-dependent Schrödinger equation, the time-dependent von Neumann equation, and related equations.
AB - In this paper we report the initial steps in the development of a Monte Carlo method for evaluation of real-time Feynman path integrals for many-particle dynamics. The approach leads to Gaussian importance sampling for real-time dynamics in which the sampling function is short ranged due to the occurrence of Gaussian factors. These Gaussian factors result from the use of a generalization of our new discrete distributed approximating functions (DDAFs) to continuous distributed approximating functions (CDAFs) so as to replace the exact coordinate representation free-particle propagator by a "CDAF-class, free-particle propagator" which is highly banded. The envelope of the CDAF-class free propagator is the product of a "bare Gaussian", exp[-(x′ - x)2σ2(0)/(2σ4(0) + ℏ2τ2/m2)], with a "shape polynomial" in (x′ - x)2, where σ(0) is a width parameter at zero time (associated with the description of the wavepacket in terms of Hermite functions), τ is the time step (τ = t/N, where t is the total propagation time), and x and x′ are any two configurations of the system. The bare Gaussians are used for Monte Carlo integration of a path integral for the survival probability of a Gaussian wavepacket in a Morse potential. The approach appears promising for real-time quantum Monte Carlo studies based on the time-dependent Schrödinger equation, the time-dependent von Neumann equation, and related equations.
UR - http://www.scopus.com/inward/record.url?scp=0001259668&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=0001259668&partnerID=8YFLogxK
U2 - 10.1021/j100203a013
DO - 10.1021/j100203a013
M3 - Article
AN - SCOPUS:0001259668
SN - 0022-3654
VL - 96
SP - 9622
EP - 9630
JO - Journal of physical chemistry
JF - Journal of physical chemistry
IS - 24
ER -