GRMS or Graphical Representation of Model Spaces: Vol. 1 BasicsThe purpose of these notes is to give some simple tools and pictures to physicists and ' chemists working on the many-body problem. Abstract thinking and seeing have much in common - we say "I see" meaning "I understand" , for example. Most of us prefer to have a picture of an abstract object. The remarkable popularity of the Feynman diagrams, and other diagrammatic approaches to many-body problem derived thereof, may be partially due to this preference. Yet, paradoxically, the concept of a linear space, as fundamental to quantum physics as it is, has never been cast in a graphical form. We know that is a high-order contribution to a two-particle scattering process (this one invented by Cvitanovic(1984)) corresponding to a complicated matrix element. The lines in such diagrams are labeled by indices of single-particle states. When things get complicated at this level it should be good to take a global view from the perspective of the whole many-particle space. But how to visualize the space of all many-particle states ? Methods of such visualization or graphical representation of the ,spaces of interest to physicists and chemists are the main topic of this work. |
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GRMS or Graphical Representation of Model Spaces: Vol. 1 Basics Wlodzislaw Duch Limited preview - 2012 |
Common terms and phrases
antisymmetric atomic basis branching diagram calculation of matrix coefficients complete active space configuration interaction corresponding cycles cyclic permutation D-part density matrix Diophantine equations doubly excited doubly occupied orbital Duch and Karwowski eigenfunctions electrons elementary loops example fagot graph formula four-segment loops four-slope graph full space Gelfand gives graph of Fig graph theory graphical representation group theory β Karwowski 1985 labeling M-diagram m₁ many-particle matrix elements methods model space non-fagot graphs non-zero elements number of particles number of paths obtained one-particle orbital configurations orbital orderings Paldus permutation point group symmetry problem represented reversed lexical ordering Ŝ² Ŝ2-adapted segment values Shavitt shift operators shown in Fig simple singly occupied arcs slopes spin eigenfunctions spin functions spin orbitals spin path subgraph subspaces symmetric group symmetry Table three-slope graph transposition two-particle operator two-segment loops unitary group approach vertex vertices