1993
DOI: 10.1002/andp.19935050606
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δ‐function perturbations and boundary problems by path integration

Abstract: Abstract. A wide class of boundary problems in quantum mechanics is discussed by using path integrals. This includes motion in half-spaces, radial boxes, rings, and moving boundaries. As a preparation the formalism for the incorporation of δ-function perturbations is outlined, which includes the discussion of multiple δ-function perturbations, δ-function perturbations along perpendicular lines and planes, and moving δ-function perturbations. The limiting process, where the strength of the δ-function perturbati… Show more

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Cited by 37 publications
(34 citation statements)
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“…The retarded Green-function can be calculated recursively [8]. Adding a new impurity to a system with L impurities changes the Green-function the following way…”
Section: Of the Systemmentioning
confidence: 99%
“…The retarded Green-function can be calculated recursively [8]. Adding a new impurity to a system with L impurities changes the Green-function the following way…”
Section: Of the Systemmentioning
confidence: 99%
“…, where the system is being "squeezed" into a narrow shell a ≤ η ≤ b, simulating the quantization on a hyper-surface in the limit a → b in a manner similar to [4] (see the equation 2.15 in [4]), but the detailed analysis will be published elsewhere.…”
Section: Discussionmentioning
confidence: 99%
“…The denominator in the final expression is obtained from a factor (λ + α)(λ + α) in the denominator that arises from the exponent (2.17) in the generalized zero mode integral (2.13) on the one hand, and a factor ofλ + α in the numerator from the z-derivative of the angular variable θ on the other hand (arising from the zero mode lifting term (2.10)). Multiplying these, we find the final formula 20) which is the compact lattice sum form [8] of the cigar elliptic genus. We have given a direct derivation of the lattice sum form, using the non-linear sigma model description.…”
Section: The Lattice Summentioning
confidence: 99%
“…What follows is a review of the results derived in e.g. [18][19][20], albeit from an original perspective.…”
Section: Quantum Mechanics On a Half Linementioning
confidence: 99%