The Kato theorem, or Kato's cusp condition (after Japanese mathematician Tosio Kato), is used in computational quantum physics.[1][2] It states that for generalized Coulomb potentials, the electron density has a cusp at the position of the nuclei, where it satisfies
For a Coulombic system one can thus, in principle, read off all information necessary for completely specifying the Hamiltonian directly from examining the density distribution. This is also known as E. Bright Wilson's argument within the framework of density functional theory (DFT). The electron density of the ground state of a molecular system contains cusps at the location of the nuclei, and by identifying these from the total electron density of the system, the positions are thus established. From Kato's theorem, one also obtains the nuclear charge of the nuclei, and thus the external potential is fully defined. Finally, integrating the electron density over space gives the number of electrons, and the (electronic) Hamiltonian is defined. This is valid in a non-relativistic treatment within the Born–Oppenheimer approximation, and assuming point-like nuclei.
ReferencesEdit
^Kato, Tosio (1957). "On the eigenfunctions of many-particle systems in quantum mechanics". Communications on Pure and Applied Mathematics. 10 (2): 151–177. doi:10.1002/cpa.3160100201.
^March, N. H. (1986). "Spatially dependent generalization of Kato's theorem for atomic closed shells in a bare Coulomb field". Phys. Rev. A. 33 (1): 88–89. Bibcode:1986PhRvA..33...88M. doi:10.1103/PhysRevA.33.88. PMID 9896587.
This quantum mechanics-related article is a stub. You can help Wikipedia by expanding it.
kato, theorem, kato, cusp, condition, after, japanese, mathematician, tosio, kato, used, computational, quantum, physics, states, that, generalized, coulomb, potentials, electron, density, cusp, position, nuclei, where, satisfies, displaystyle, frac, mathbf, f. The Kato theorem or Kato s cusp condition after Japanese mathematician Tosio Kato is used in computational quantum physics 1 2 It states that for generalized Coulomb potentials the electron density has a cusp at the position of the nuclei where it satisfies Z k a o 2 n r d n r d r r R k displaystyle Z k frac a o 2n mathbf r frac dn mathbf r dr r rightarrow mathbf R k Here R k displaystyle mathbf R k denotes the positions of the nuclei Z k displaystyle Z k their atomic number and a o displaystyle a o is the Bohr radius For a Coulombic system one can thus in principle read off all information necessary for completely specifying the Hamiltonian directly from examining the density distribution This is also known as E Bright Wilson s argument within the framework of density functional theory DFT The electron density of the ground state of a molecular system contains cusps at the location of the nuclei and by identifying these from the total electron density of the system the positions are thus established From Kato s theorem one also obtains the nuclear charge of the nuclei and thus the external potential is fully defined Finally integrating the electron density over space gives the number of electrons and the electronic Hamiltonian is defined This is valid in a non relativistic treatment within the Born Oppenheimer approximation and assuming point like nuclei References Edit Kato Tosio 1957 On the eigenfunctions of many particle systems in quantum mechanics Communications on Pure and Applied Mathematics 10 2 151 177 doi 10 1002 cpa 3160100201 March N H 1986 Spatially dependent generalization of Kato s theorem for atomic closed shells in a bare Coulomb field Phys Rev A 33 1 88 89 Bibcode 1986PhRvA 33 88M doi 10 1103 PhysRevA 33 88 PMID 9896587 This quantum mechanics related article is a stub You can help Wikipedia by expanding it vte Retrieved from https en wikipedia org w index php title Kato theorem amp oldid 1101077163, wikipedia, wiki, book, books, library,
