报告题目:FCI Truncation for Solving the Electronic and Nuclear Schrödinger Equations
报告人:James S. M. Anderson
Postdoctoral Associate of Computational Materials Science Research Team, RIKEN (Supervisor: Seiji Yunoki)
报告时间:7月6日, 10:00-11:00
报告地点:闵行校区生物药学楼4-200
联系人:魏冬青, 34204573; 徐沁, 34204348
Abstract
An important goal of contemporary electronic and nuclear structure is to be able obtain a desired accuracy from approximate solutions to the Schrödinger equation in the least time. The full configuration interaction (FCI) method provides the best possible wavefunction within a basis set. The approach prosed here involves selecting a subset of the solutions used in FCI (typically a subset of all possible Hartree-Fock solutions within a basis set). Results from Griebel and others [1-4] in the mathematics of complexity literature show that if the analytic solutions to a given Schrödinger equation have mixed bound derivatives then it is possible to obtain FCI accuracy with polynomial scaling (at least in the large basis set limit). The theorems from Griebel and others [1-4] indicate which solutions to include based on the number of nodes in each solution. We refer to this approach as the GK-CI method. This truncation of the FCI method does not require any physical intuition of orbitals (e.g. the Hartree-Fock solutions) and is not constructed from the typical excitation-hierarchy approach. In this presentation I will described the method as well as provide preliminary results from both electronic structure and nuclear structure calculations.[5]
[1] M. Griebel and S. Knapek, Constr. Approx. 16, 525 (2000).
[2] H. Bungartz and M. Griebel, Acta Numer. 13, 147 (2001).
[3] G. W. Wasilkowski and H. Wozniakowski, Found. Comput. Math. 5, 451 (2005).
[4] S. A. Smolyak, Dokl. Akad. Nauk, 4, 240 (1963).
[5] J. S. M. and P. W. Ayers, J. Chem. Phys. Submitted (2011).