The quantum structure of matter grand challenge project: large-scale 3-D solutions in relativistic quantum dynamics

The quantum structure of matter grand challenge project: large-scale 3-D solutions in relativistic quantum dynamics

The numerical methods used to solve the time-dependent Dirac equation on a three-dimensional Cartesian lattice are described. Efficient algorithms are required for computationally intensive studies of nonperturbative relativistic quantum dynamics. Discretization is achieved through the lattice basis...

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Bibliographische Detailangaben
Hauptverfasser: Wells, J. C., Oberacker, V. E., Umar, A. S., Bottcher, C., Strayer, M. R., Drake, J., Flanery, R.
Format: Tagungsbericht
Sprache:eng
Schlagworte:
Applied computing > Physical sciences and engineering > Physics
Computer systems organization > Architectures > Parallel architectures > Multiple instruction, multiple data
Electrons
Equations
Laboratories
Large-scale systems
Lattices
Mathematics of computing > Mathematical analysis > Numerical analysis
Mathematics of computing > Mathematical analysis > Numerical analysis > Computations on matrices
Mathematics of computing > Mathematical analysis > Numerical analysis > Numerical differentiation
Mesons
Physics
Production
Quantum computing
Space technology
Theory of computation > Design and analysis of algorithms
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Beschreibung
Zusammenfassung:The numerical methods used to solve the time-dependent Dirac equation on a three-dimensional Cartesian lattice are described. Efficient algorithms are required for computationally intensive studies of nonperturbative relativistic quantum dynamics. Discretization is achieved through the lattice basis-spline collocation method, in which quantum-state vectors and coordinate-space operators are expressed in terms of basis-spline functions on a spatial lattice. All numerical procedures reduce to a series of matrix-vector operations which are performed on the Intel iPSC/860 hypercube, making full use of parallelism. Solutions to the problems of limited node memory and node-to-node communication overhead inherent in using distributed-memory, multiple-instruction, multiple-data stream parallel computers are discussed.
ISSN:1063-9535
DOI:10.1145/169627.169647