Resonance width for a particle–core coupling model with a square-well potential

Abstract We derive a compact formula for the width of a multi-channel resonance state. To this end, we use a deformed square-well potential and solve the coupled-channels equations. We obtain the $S$-matrix in the Breit–Wigner form, from which partial widths can be extracted. We apply the resultant formula to a deformed nucleus and discuss the behavior of partial width for an $s$-wave channel.

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Estimating the error in variational scattering calculations

Canadian Journal of Physics ◽

10.1139/p78-177 ◽

1978 ◽

Vol 56 (10) ◽

pp. 1358-1364 ◽

Cited By ~ 5

Author(s):

J. W. Darewych ◽

R. Pooran

Keyword(s):

Wave Scattering ◽

Exponential Potential ◽

S Wave ◽

Order Error ◽

Absolute Value ◽

First Order ◽

Scattering Phase ◽

Square Well ◽

Scattering Phase Shifts ◽

Made In

We derive bounds to the absolute value of the error that is made in variational estimates of scattering phase shifts. These bounds, like the variational estimates, are second order in 'small' quantities and are, in this respect, an improvement on similar but first-order error bounds derived previously by Bardsley, Gerjuoy, and Sukumar. The s-wave scattering by a square well potential, in the Born approximation, and by an exponential potential, using a many parameter trial function, are used to illustrate the results.

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Flow of S-matrix poles for elementary quantum potentials1This research was supported in part by an NSERC Undergraduate Summer Research Award (SGN) and an NSERC Discovery Grant (MAW).

Canadian Journal of Physics ◽

10.1139/p11-107 ◽

2011 ◽

Vol 89 (11) ◽

pp. 1127-1140 ◽

Cited By ~ 5

Author(s):

B. Belchev ◽

S.G. Neale ◽

M.A. Walton

Keyword(s):

Bound States ◽

Scattering Matrix ◽

Nucl Phys ◽

Quantum Scattering ◽

Research Award ◽

Momentum Plane ◽

S Matrix ◽

Potential Depth ◽

Square Well ◽

Insight Into

The poles of the quantum scattering matrix (S-matrix) in the complex momentum plane have been studied extensively. Bound states give rise to S-matrix poles, and other poles correspond to non-normalizable antibound, resonance, and antiresonance states. They describe important physics but their locations can be difficult to determine. In pioneering work, Nussenzveig (Nucl. Phys. 11, 499 (1959)) performed the analysis for a square well (wall), and plotted the flow of the poles as the potential depth (height) varied. More than fifty years later, however, little has been done in the way of direct generalization of those results. We point out that today we can find such poles easily and efficiently using numerical techniques and widely available software. We study the poles of the scattering matrix for the simplest piecewise flat potentials, with one and two adjacent (nonzero) pieces. For the finite well (wall) the flow of the poles as a function of the depth (height) recovers the results of Nussenzveig. We then analyze the flow for a potential with two independent parts that can be attractive or repulsive, the two-piece potential. These examples provide some insight into the complicated behavior of the resonance, antiresonance, and antibound poles.

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Finite-dimensional approximation of the scattering matrix

Canadian Journal of Physics ◽

10.1139/p86-113 ◽

1986 ◽

Vol 64 (5) ◽

pp. 611-616 ◽

Cited By ~ 3

Author(s):

Helmut Kröger ◽

Anais Smailagic ◽

Ralph Girard

Keyword(s):

Weak Coupling ◽

Weak Coupling Regime ◽

S Wave ◽

Proton Proton ◽

Time Evolution Operator ◽

Finite Dimensional Approximation ◽

Finite Dimensional ◽

Dimensional Approximation ◽

S Matrix ◽

Computer Calculations

A finite-dimensional nonperturbative approximation scheme of the time-evolution operator and the S matrix for relativistic field theories is discussed. It is amenable to computer calculations. Parallels with lattice-field theory are drawn. The method is outlined for the ϕ4 theory. Equivalence to standard perturbation theory in the weak-coupling regime is obtained in the limit of the approximation parameters. The method is tested numerically for nonrelativistic proton–proton s-wave scattering and the the ϕ4 model in the weak-coupling regime in 1 + 1 dimensions. In both examples, convergence to the reference solution is found.

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THE VIRTUAL BLACK HOLE IN 2D QUANTUM GRAVITY AND ITS RELEVANCE FOR THE S-MATRIX

International Journal of Modern Physics A ◽

10.1142/s0217751x02010406 ◽

2002 ◽

Vol 17 (06n07) ◽

pp. 989-992 ◽

Cited By ~ 7

Author(s):

DANIEL GRUMILLER

Keyword(s):

Black Hole ◽

Quantum Gravity ◽

Wave Scattering ◽

Black Hole Mass ◽

Hole Formation ◽

S Wave ◽

Scalar Matter ◽

S Matrix ◽

Tree Vertex ◽

Classical Mechanism

As shown recently 2d quantum gravity theories — including spherically reduced Einstein-gravity — after an exact path integral of its geometric part can be treated perturbatively in the loops of (scalar) matter. Obviously the classical mechanism of black hole formation should be contained in the tree approximation of the theory. This is shown to be the case for the scattering of two scalars through an intermediate state which by its effective black hole mass is identified as a "virtual black hole". We discuss the lowest order tree vertex for minimally and non-minimally coupled scalars and find a non-trivial finite S-matrix for gravitational s-wave scattering in the latter case.

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One-Dimensional Jost Solutions: The S-Matrix Revisited

Rays, Waves, and Scattering ◽

10.23943/princeton/9780691148373.003.0026 ◽

2017 ◽

Author(s):

John A. Adam

Keyword(s):

Boundary Conditions ◽

Transmission Coefficient ◽

Radial Equation ◽

Scattering Problems ◽

One Dimensional ◽

S Matrix ◽

Jost Functions ◽

Jost Solutions ◽

Square Well ◽

Matrix Problems

This chapter examines the properties of one-dimensional Jost solutions for S-matrix problems. It first considers how the left–right transmission and reflections coefficients can be expressed in terms of the elements of the S-matrix for one-dimensional scattering problems on, focusing on poles of the transmission coefficient. It then uses the radial equation to revisit the problem of the square-well potential from the perspective of the Jost solution, with Jost boundary conditions at r = 0 and as r approaches infinity. It also presents the notations for the Jost functions and the S-matrix before discussing the problem of scattering from a constant spherical inhomogeneity.

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Calculating the S -matrix of low-energy heavy-ion collisions using quantum coupled-channels wave-packet dynamics

Physical Review C ◽

10.1103/physrevc.104.064601 ◽

2021 ◽

Vol 104 (6) ◽

Author(s):

Terence Vockerodt ◽

Alexis Diaz-Torres

Keyword(s):

Wave Packet ◽

Heavy Ion Collisions ◽

Heavy Ion ◽

Low Energy ◽

Ion Collisions ◽

Wave Packet Dynamics ◽

Coupled Channels ◽

S Matrix

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Erratum to: “S-matrix for s-wave gravitational scattering”

Physics Letters B ◽

10.1016/s0370-2693(02)01540-x ◽

2002 ◽

Vol 532 (3-4) ◽

pp. 373 ◽

Cited By ~ 9

Author(s):

P. Fischer ◽

D. Grumiller ◽

W. Kummer ◽

D.V. Vassilevich

Keyword(s):

S Wave ◽

S Matrix ◽

Gravitational Scattering

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$\bar KNN$ RESONANCE $\bar KNN - \pi YN$ COUPLED CHANNEL FADDEEV EQUATION

Modern Physics Letters A ◽

10.1142/s0217732309000255 ◽

2009 ◽

Vol 24 (11n13) ◽

pp. 895-900 ◽

Cited By ~ 1

Author(s):

T. SATO ◽

Y. IKEDA

Keyword(s):

Faddeev Equation ◽

Resonance Energy ◽

Body Interaction ◽

Coupled Channels ◽

S Matrix ◽

Body Dynamics ◽

Unphysical Sheet ◽

Three Body ◽

Coupled Channel

The three-body resonance of [Formula: see text] system is investigated by using the [Formula: see text] coupled channels Faddeev equation. The resonance energy is determined from the pole of S -matrix on the unphysical sheet. It is found that the pole positions of the predicted amplitudes are significantly modified when the three-body dynamics is approximately treated by introducing the effective [Formula: see text] two-body interaction.

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Lattice phase shifts and mixing angles for an arbitrary number of coupled channels

SciPost Physics Proceedings ◽

10.21468/scipostphysproc.3.052 ◽

2020 ◽

Author(s):

Lukas Bovermann ◽

Evgeny Epelbaum ◽

Hermann Krebs ◽

Dean Lee

Keyword(s):

Arbitrary Number ◽

Scattering Problem ◽

Full Rank ◽

Phase Shifts ◽

Lattice Method ◽

Radial Wave ◽

Mixing Angles ◽

Coupled Channels ◽

S Matrix ◽

Scattering Phase

We present a lattice method for determining scattering phase shifts and mixing angles for the case of an arbitrary number of coupled channels. The proposed method combines a spherical wall boundary condition and a channel-mixing auxiliary potential to extract the full-rank S-matrix from the radial wave functions. We consider the scattering problem of two spin-1 bosons interacting with a test potential involving up to four coupled channels. For this benchmark system, the phase shifts and mixing angles are shown to agree on the lattice and in the continuum. Our method should allow to extend previous two-channel nuclear lattice EFT simulations to mixing of more than two partial waves.

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Thermal study of a coupled-channel system: a brief review

The European Physical Journal A ◽

10.1140/epja/s10050-021-00378-y ◽

2021 ◽

Vol 57 (2) ◽

Author(s):

Pok Man Lo

Keyword(s):

Density Of States ◽

Particle Dynamics ◽

Thermal Study ◽

S Wave ◽

Channel System ◽

System A ◽

S Matrix ◽

Coupled Channel

AbstractWe demonstrate the construction of a density of states from the S-matrix describing a coupled-channel (S-wave $$\pi \pi , K {\bar{K}}$$ π π , K K ¯ ) system, and examine the influences from various structures of particle dynamics: poles, roots, and Riemann sheets.

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