dorsal/arxiv
View SchemaFactorizing the time evolution operator
| Authors | P. C. Garcia Quijas, L. M. Arevalo Aguilar |
|---|---|
| Categories | |
| ArXiv ID | quant-ph/0603253 |
| URL | https://arxiv.org/abs/quant-ph/0603253 |
| DOI | 10.1088/0031-8949/75/2/012 |
| Journal | Phys. Scr. 75 (2007) 185--194 |
Abstract
There is a widespread belief in the quantum physical community, and in textbooks used to teach Quantum Mechanics, that it is a difficult task to apply the time evolution operator Exp{-itH/h} on an initial wave function. That is to say, because the hamiltonian operator generally is the sum of two operators, then it is a difficult task to apply the time evolution operator on an initial wave function f(x,0), for it implies to apply terms operators like (a+b)^n. A possible solution of this problem is to factorize the time evolution operator and then apply successively the individual exponential operator on the initial wave function. However, the exponential operator does not directly factorize, i. e. Exp{a+b} is not equal to Exp{a}Exp{b}. In this work we present a useful procedure for factorizing the time evolution operator when the argument of the exponential is a sum of two operators, which obey specific commutation relations. Then, we apply the exponential operator as an evolution operator for the case of elementary unidimensional potentials, like the particle subject to a constant force and the harmonic oscillator. Also, we argue about an apparent paradox concerning the time evolution operator and non-spreading wave packets addressed previously in the literature.
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"abstract": "There is a widespread belief in the quantum physical community, and in\ntextbooks used to teach Quantum Mechanics, that it is a difficult task to apply\nthe time evolution operator Exp{-itH/h} on an initial wave function. That is to\nsay, because the hamiltonian operator generally is the sum of two operators,\nthen it is a difficult task to apply the time evolution operator on an initial\nwave function f(x,0), for it implies to apply terms operators like (a+b)^n. A\npossible solution of this problem is to factorize the time evolution operator\nand then apply successively the individual exponential operator on the initial\nwave function. However, the exponential operator does not directly factorize,\ni. e. Exp{a+b} is not equal to Exp{a}Exp{b}. In this work we present a useful\nprocedure for factorizing the time evolution operator when the argument of the\nexponential is a sum of two operators, which obey specific commutation\nrelations. Then, we apply the exponential operator as an evolution operator for\nthe case of elementary unidimensional potentials, like the particle subject to\na constant force and the harmonic oscillator. Also, we argue about an apparent\nparadox concerning the time evolution operator and non-spreading wave packets\naddressed previously in the literature.",
"arxiv_id": "quant-ph/0603253",
"authors": [
"P. C. Garcia Quijas",
"L. M. Arevalo Aguilar"
],
"categories": [
"quant-ph"
],
"doi": "10.1088/0031-8949/75/2/012",
"journal_ref": "Phys. Scr. 75 (2007) 185--194",
"title": "Factorizing the time evolution operator",
"url": "https://arxiv.org/abs/quant-ph/0603253"
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