Tom D. Imbo scite author profile

Supersymmetric quantum mechanics is formulated for spherically symmetric potentials in TV spatial dimensions. It is seen that the supersymmetric partner potential of a given potential can be effectively treated as being in N + 2 dimensions. This fact is exploited in calculations using the shifted \/N expansion. Also, the violation of the no-degeneracy theorem in one dimension by the Coulomb potential is seen as a consequence of this result.PACS numbers: ll.30.Pb, 03.65.Ge Given any one-dimensional potential, supersymmetric quantum mechanics provides a simple recipe for generating a partner potential with the same energy eigenvalues (except for the ground state). 1,2 Often, for many physical problems, it is profitable to deal with partner potentials. This possibility has been used by several people for finding classes of analytically solvable potentials, 3 evaluating the eigenvalues of a bistable potential, 4 studying atomic systems, 5 and improving the WKB approximation. 6 Recently, large-TV expansions, 7 " 10 particularly those involving shifted expansion parameters, 8 " 10 have proved to be very useful in the calculation of accurate eigenenergies for spherically symmetric potentials. The purpose of this paper is to show that the use of supersymmetric partner potentials can be exploited to improve further both the accuracy and the simplicity of large-A^ expansions. Typically, we find that just the leading term in a shifted large-N expansion using partner potentials yields all the energy levels correctly to three significant digits for essentially any threedimensional spherically symmetric potential of physical interest. Further accuracy is easily obtained from previously calculated higher-order terms. 9 We first review the ideas of supersymmetric quantum mechanics and set up the formalism for spherically symmetric potentials in N spatial dimensions. This will demonstrate that the supersymmetric partner of a given potential can be effectively treated as being in Af + 2 spatial dimensions. 11 This fact is responsible for substantially improving the convergence of large-A^ expansions.Several useful, illustrative potentials (Hulthen logarithmically screened Coulomb, quarkonium) are treated in order to demonstrate our approach. The Coulomb potential in one dimension is somewhat special since it is its own supersymmetric partner; the curious consequences of this (like intersecting energy levels and degeneracy in one dimension 12 ) are discussed.Assume that one has a potential V°(x) whose ground-state wave function \jj 0 (x) is known, and whose ground-state energy has been adjusted so that E 0 = 0. Then the Schrodinger equation for the ground state is (K = m = 1) and consequently ---+ V°(x) 2 dx 2 KX) = 0, H°-\ -d 2 { ftp] dx 2 $o J Define the operators ^ V2 d fto dx i// 0 This gives Q + Q~-= //°, 0-e+-/f i =-|^r+K i u), a) (2) (3) (4) 2 dx 2 where VHx) V°(x) dx *l>o */>P = -V°(x) + */>p */>p (5)If i//" is any eigenfunction of H° with eigenvalue E ny then Q~^n is an eigenfunction of H l with the same eigenvalue E...

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Tom D. Imbo

Energy eigenstates of spherically symmetric potentials using the shifted1Nexpansion

Identical particles, exotic statistics and braid groups

Configuration space topology and quantum internal symmetries

Shifted1Nexpansions for energy eigenvalues of the Schrödinger equation

Supersymmetric Quantum Mechanics and Large-NExpansions

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