Add to ORKGIn any quantum dynamics method that approximates wave functions as a linearly combined basis set, non-orthogonality can be is a problem. It has been proven in previous studies that, by using the most standard form of Matching Pursuit in combination with a Gaussian wave packet ansatz, exact quantum-mechanical correspondence can be obtained for particle tunneling in one and two dimensions. This study is an attempt to prove that this approach can be generally applicable to systems of arbitrary dimension propagating with an an-harmonic potential, and that adaptive initial state sampling can be used to make the method even more computationally efficient
The behavior of particles at the atomic level is dictated by quantum theory and must satisfy the Sch...
Abstract We generalize the string method, originally designed for the study of thermally activated r...
We examine an extension to the theory of Gaussian wave packet dynamics on a potential surface by mea...
Propagating a multi–dimensional wavepacket using the time–dependent Schr ̈odinger Equation is a comp...
Gaussian wavepacket methods are an attractive way to solve the time-dependent Schrödinger equation (...
Gaussian wavepacket methods are an attractive way to solve the time-dependent Schrödinger equation (...
Gaussian wavepacket methods are an attractive way to solve the time-dependent Schrödinger equation (...
Gaussian wavepacket methods are an attractive way to solve the time-dependent Schrödinger equation (...
Methods for solving the time-dependent Schrödinger equation via basis set expansion of the wave fun...
We introduce a rigorous method for simulations of quantum dynamics by implementing a simple concaten...
We introduce a rigorous method for simulations of quantum dynamics by implementing a simple concaten...
In this paper, we examine whether a quantum computer can efficiently simulate quantum processes such...
Abstract: In a recent publication, we introduced a computational approach to treat the simultaneous ...
A review of methods that propagate quantum wave functions with the help of trajectory guided Gaussia...
We present an extension of our earlier work on adaptive quantum wavepacket dynamic
The behavior of particles at the atomic level is dictated by quantum theory and must satisfy the Sch...
Abstract We generalize the string method, originally designed for the study of thermally activated r...
We examine an extension to the theory of Gaussian wave packet dynamics on a potential surface by mea...
Propagating a multi–dimensional wavepacket using the time–dependent Schr ̈odinger Equation is a comp...
Gaussian wavepacket methods are an attractive way to solve the time-dependent Schrödinger equation (...
Gaussian wavepacket methods are an attractive way to solve the time-dependent Schrödinger equation (...
Gaussian wavepacket methods are an attractive way to solve the time-dependent Schrödinger equation (...
Gaussian wavepacket methods are an attractive way to solve the time-dependent Schrödinger equation (...
Methods for solving the time-dependent Schrödinger equation via basis set expansion of the wave fun...
We introduce a rigorous method for simulations of quantum dynamics by implementing a simple concaten...
We introduce a rigorous method for simulations of quantum dynamics by implementing a simple concaten...
In this paper, we examine whether a quantum computer can efficiently simulate quantum processes such...
Abstract: In a recent publication, we introduced a computational approach to treat the simultaneous ...
A review of methods that propagate quantum wave functions with the help of trajectory guided Gaussia...
We present an extension of our earlier work on adaptive quantum wavepacket dynamic
The behavior of particles at the atomic level is dictated by quantum theory and must satisfy the Sch...
Abstract We generalize the string method, originally designed for the study of thermally activated r...
We examine an extension to the theory of Gaussian wave packet dynamics on a potential surface by mea...