Comparison of the propagation of semiclassical frozen Gaussian wave functions with quantum propagation for a highly excited anharmonic oscillator

Abstract: Quantum and semiclassical description of a triply degenerate anharmonic oscillatorThe propagation of an initially highly excited localized wave packet in an anharmonic oscillator potenti~ is stu~ied within th~ frozen Gaussian approximation. Comparison is made to quantum mec.h~lcal basIS set ~alc~lat1ons. The frozen Gaussian approximation involves the expansion of the ID1t1al wave function 10 terms of an overcomplete Gaussian basis set. The wave function evolution is ~v.aluated by allowing eac~ Gaussian to trav… Show more

“…Beginning with the work of Heller [3], FG wave packets have a long history of use in quantum and semiclassical simulations. CS provide a very convenient analog of the classical phase space point, following classical trajectory motion, and ensembles of CS have been extensively used within the semiclassical Herman-Kluk propagator formulation [4,5] (see for example the reviews [6][7][8][9][10]). Recently a number of quantum methods have emerged, such as multiple spawning (MS) by Martinez [11][12][13][14] and Coupled Coherent States (CCS)…”

Gaussian-based techniques for quantum propagation from the time-dependent variational principle: Formulation in terms of trajectories of coupled classical and quantum variables

“…Beginning with the work of Heller [3], FG wave packets have a long history of use in quantum and semiclassical simulations. CS provide a very convenient analog of the classical phase space point, following classical trajectory motion, and ensembles of CS have been extensively used within the semiclassical Herman-Kluk propagator formulation [4,5] (see for example the reviews [6][7][8][9][10]). Recently a number of quantum methods have emerged, such as multiple spawning (MS) by Martinez [11][12][13][14] and Coupled Coherent States (CCS)…”

Gaussian-based techniques for quantum propagation from the time-dependent variational principle: Formulation in terms of trajectories of coupled classical and quantum variables

“…(9) is done numerically by the Monte Carlo integration procedure described in Ref. [16]. To test the numerical performance of the different methods we chose two different nonlinear potentials which we now introduce.…”

Long-time and unitary properties of semiclassical initial value representations

“…[1][2][3][4][5] In brief, this method is a stationary phase approximation of the quantum coherent state propagator evaluated in an uniformized initial value representation. When applied to finding autocorrelations and from the perspective of phase space, every timestep requires the calculation of the overlap of a swarm of "frozen" Gaussians, often selected by Monte Carlo-based sampling dependent on the initial state.…”

Communication: HK propagator uniformized along a one-dimensional manifold in weakly anharmonic systems