Formulas that Represent Cauchy Problem Solution for Momentum and Position Schrödinger Equation

被引:0
作者
Ivan D. Remizov
机构
[1] National Research University Higher School of Economics,
来源
Potential Analysis | 2020年 / 52卷
关键词
Schrödinger equation; Cauchy problem; solution representation; Chernoff theorem; 81Q05; 47D08; 35C15; 35J10;
D O I
暂无
中图分类号
学科分类号
摘要
In the paper we derive two formulas representing solutions of Cauchy problem for two Schrödinger equations: one-dimensional momentum space equation with polynomial potential, and multidimensional position space equation with locally square integrable potential. The first equation is a constant coefficients particular case of an evolution equation with derivatives of arbitrary high order and variable coefficients that do not change over time, this general equation is solved in the paper. We construct a family of translation operators in the space of square integrable functions and then use methods of functional analysis based on Chernoff product formula to prove that this family approximates the solution-giving semigroup. This leads us to some formulas that express the solution for Cauchy problem in terms of initial condition and coefficients of the equations studied.
引用
收藏
页码:339 / 370
页数:31
相关论文
共 88 条
  • [1] Mazzucchi S(2018)Infinite dimensional oscillatory integrals with polynomial phase and applications to higher-order heat-type equations Potential Anal. 49 209-223
  • [2] Bonaccorsi S(2015)High order heat-type equations and random walks on the complex plane Stochastic Processes Appl. 125 797-818
  • [3] Mazzucchi S(2012)Feynman integrals of functionals of exponential form with a polynomial exponent Mosc. Univ. Math. Bull. 67 233-235
  • [4] Kravtseva AK(2016)Asymptotic expansions of Feynman integrals of exponentials with polynomial exponent Russ. J. Math. Phys. 23 491-509
  • [5] Kravtseva AK(2011)Functional-integral solution for the Schrödinger equation with polynomial potential: a white noise approach Infin. Dimens. Anal. Quantum. Probab. Relat. Top. 14 675-648
  • [6] Smolyanov OG(1932)On one-parameter unitary groups in Hilbert Space Ann. Math. 33 643-4557
  • [7] Shavgulidze ET(2016)Quasi-Feynman formulas – a method of obtaining the evolution operator for the Schrödinger equation J. Funct. Anal. 270 4540-523
  • [8] Mazucchi S(2005)The Schrödinger propagator for scattering metrics Ann. Math. 162 487-1309
  • [9] Stone MH(2009)Wave front set for solutions to Schrödinger equations J. Funct. Anal. 256 1299-1121
  • [10] Remizov ID(1996)The Schrödinger and diffusion propagators coexisting on a lattice J. Phys. A Math. Gen. 5 29-37
123456789