Equivalence and symmetries for variable coefficient linear heat type equations. II. Fundamental solutions

Güngör, F.

doi:10.1063/1.5003466

Cited by 9 publications

(25 citation statements)

References 17 publications

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“…Definition 2.1. A local Lie group of point transformations G is called a symmetry group of the system of partial differential equations (11) if f = g.f is a solution whenever f is.…”

Section: Differential Equations and Their Symmetry Groupmentioning

confidence: 99%

Notes on Lie symmetry group methods for differential equations

Güngör¹

2019

Preprint

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“…Definition 2.1. A local Lie group of point transformations G is called a symmetry group of the system of partial differential equations (11) if f = g.f is a solution whenever f is.…”

Section: Differential Equations and Their Symmetry Groupmentioning

confidence: 99%

Notes on Lie symmetry group methods for differential equations

Güngör¹

2019

Preprint

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“…For more details of this and another related method the reader is directed to Ref. [2]. We know from the results of [3] that this equation admits a four-dimensional Lie point symmetry algebra g, excluding the obvious infinite-dimensional one, because k = 0 (otherwise 6-dimensional).…”

Section: Calculation Of Fundamental Solution (Green Function)mentioning

confidence: 99%

“…Green function for the special potential when ω = 0 has already be obtained in Ref. [2] (page 6) using methods within the symmetry context (with k = −µ in notation of [2]). We reproduce it here for the purpose of reference (the replacement t → t/2 is done)…”

Section: The General Symmetry Vector Fieldmentioning

confidence: 99%

“…In another recent paper [2] with a reliance on the results of [3], we studied calculation of fundamental solutions of variable coefficient linear parabolic equations allowing sufficiently enough symmetry groups.…”

Section: Introductionmentioning

confidence: 99%

“…The purpose of this paper is to make use of methods from [2,3] as an alternative natural approach to the one pursued in [1] to derive fundamental solutions for the parabolic operator (1.1) and its Schrödinger variant.…”

Section: Introductionmentioning

confidence: 99%

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Calculation of the propagator of Schrödinger's equation on $(0,\infty)$ with the potential $kx^{-2} + ω^2x^2$ by Lie symmetry group method

Güngör¹

2018

Preprint

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The propagators (fundamental solutions) of the heat and Schrödinger's equations on the half-line with a combined harmonic oscillator and inversesquare potential calculated in the recent paper [J. Math. Phys. 59, 051507 (2018)] using Laplace's method are demonstrated to be obtainable alternatively within the framework of symmetry group methods discussed in a series of two papers in the same journal.

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The Schrödinger propagator on $$(0,\infty )$$ for a special potential by a Lie symmetry group method

Güngör

2020

Rend. Circ. Mat. Palermo, II. Ser

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Equivalence and symmetries for variable coefficient linear heat type equations. II. Fundamental solutions

Cited by 9 publications

References 17 publications

Notes on Lie symmetry group methods for differential equations

Notes on Lie symmetry group methods for differential equations

Calculation of the propagator of Schrödinger's equation on $(0,\infty)$ with the potential $kx^{-2} + ω^2x^2$ by Lie symmetry group method

The Schrödinger propagator on $$(0,\infty )$$ for a special potential by a Lie symmetry group method

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