The Coupled-Channel Method for Modelling Quantum Transmission of Composite Systems
DOI10.1007/978-3-319-51917-3_45zbMath1392.81093OpenAlexW2587796575MaRDI QIDQ4567994
S. I. Vinitskij, V. L. Derbov, O. Chuluunbaatar, Alexander Gusev, Andrzej Góźdź
Publication date: 20 June 2018
Published in: Communications in Computer and Information Science (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1007/978-3-319-51917-3_45
second-order ordinary differential equationsquantum tunnellingcoupled-channel methodfinite element method software
Particular ordinary differential operators (Dirac, one-dimensional Schrödinger, etc.) (34L40) Quantum computation (81P68) (2)-body potential quantum scattering theory (81U05) Finite element, Rayleigh-Ritz, Galerkin and collocation methods for ordinary differential equations (65L60) Channel models (including quantum) in information and communication theory (94A40) Quantum mechanics on special spaces: manifolds, fractals, graphs, lattices (81Q35)
Cites Work
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- KANTBP 3.0: new version of a program for computing energy levels, reflection and transmission matrices, and corresponding wave functions in the coupled-channel adiabatic approach
- Symbolic-Numeric Algorithm for Solving the Problem of Quantum Tunneling of a Diatomic Molecule through Repulsive Barriers
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- Symbolic-Numerical Algorithm for Generating Cluster Eigenfunctions: Tunneling of Clusters through Repulsive Barriers
- Calculation of a hydrogen atom photoionization in a strong magnetic field by using the angular oblate spheroidal functions
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