scholarly journals Two Schrödinger-like Equations for hadrons

2022 ◽  
Vol 258 ◽  
pp. 10009
Author(s):  
Ruben Sandapen
Keyword(s):  
Schrödinger Equation ◽  
Atomic Physics ◽  
Schrodinger Equation ◽  
Light Front ◽  
Hadronic Physics ◽  
Hadron Spectroscopy ◽  
First Approximation

In this talk, based on [1, 2], I argue that the holographic Schrödinger Equation of (3 +1)-dim, conformal light-front QCD and the ’t Hooft Equation of (1+1)-dim, large Nc QCD, can be complementary to each other in providing a first approximation to hadron spectroscopy. Together, the two equations play a role in hadronic physics analogous that of the ordinary Schrödinger Equation in atomic physics.

scholarly journals Hadron spectroscopy using the light-front holographic Schrödinger equation and the ’t Hooft equation

2021 ◽  
Vol 104 (7) ◽  
Author(s):  
Mohammad Ahmady ◽  
Sugee Lee MacKay ◽  
Satvir Kaur ◽  
Chandan Mondal ◽  
Ruben Sandapen
Keyword(s):  
Schrödinger Equation ◽  
Schrodinger Equation ◽  
Light Front ◽  
Hadron Spectroscopy

The Schrödinger equation as a singular perturbation problem

1978 ◽  
Vol 82 (1-2) ◽  
pp. 1-11 ◽  
Author(s):  
E. M. de Jager ◽  
T. Küpper
Keyword(s):  
Schrödinger Equation ◽  
Singular Perturbation ◽  
Schrodinger Equation ◽  
Eigenvalue Problems ◽  
Singular Perturbation Problem ◽  
Perturbation Problem ◽  
First Approximation ◽  
Image Position

SynopsisComparisons have been made of the eigenvalues and the corresponding eigenfunctions of the eigenvalue problemsandwith φ ∈ C(-∞, +∞) and 0≦φ(x)≦C|x|i+1(1+|x|1), −∞<x<+∞ where i and l are arbitrary positive numbers with i≧2k≧2, k integer. In first approximation the eigenvalues λ and λ− and the corresponding eigenfunctions ψ and ψ are the same for ε→0; the error decreases whenever the exponent i increases.

The “accidental” degeneracy of the hydrogen atom is no accident

2015 ◽  
Vol 93 (3) ◽  
pp. 312-317
Author(s):  
P.C. Deshmukh ◽  
Aarthi Ganesan ◽  
N. Shanthi ◽  
Blake Jones ◽  
James Nicholson ◽  
...  
Keyword(s):  
Quantum Mechanics ◽  
Energy Spectrum ◽  
Hydrogen Atom ◽  
Schrödinger Equation ◽  
Atomic Physics ◽  
Schrodinger Equation ◽  
Spin States ◽  
Interesting Aspect ◽  
Accidental Degeneracy ◽  
Pedagogical Analysis

The Schrödinger equation does not account for the 2n2degeneracy of the hydrogen atom, which it dismisses as an “accidental” degeneracy. The factor of “2” in the 2n2degeneracy is well-accounted-for in the relativistic formulation by the two spin states of the electron. The n2degeneracy is nevertheless not quite an “accident”; it is due to the SO(4), rather than SO(3), symmetry of the hydrogen atom. This result is well known, but is inadequately commented upon in most courses in quantum mechanics and atomic physics, leaving the student wondering about the origins of the n2degeneracy of the hydrogen atom. A pedagogical analysis of this interesting aspect, which highlights the fundamental principles of quantum mechanics, is presented in this article. While doing so, not only is the n2degeneracy of the hydrogen atom explained, but its energy spectrum and eigenfunctions are obtained without even using the Schrödinger equation, employing only the fundamental principles of quantum mechanics rather than the Schrödinger equation.

scholarly journals LIGHT-FRONT HOLOGRAPHY AND THE LIGHT-FRONT SCHRÖDINGER EQUATION

2012 ◽  
Vol 20 ◽  
pp. 53-65 ◽  
Author(s):  
STANLEY J. BRODSKY ◽  
GUY DE TÉRAMOND
Keyword(s):  
Schrödinger Equation ◽  
Schrodinger Equation ◽  
Bound States ◽  
Light Quark ◽  
Form Factors ◽  
Light Front ◽  
Hadron Structure ◽  
Hadron Spectrum ◽  
Excitation Spectra ◽  
Fifth Dimension

One of the most important nonperturbative methods for solving QCD is quantization at fixed light-front time τ = t + z/c – Dirac's "Front Form". The eigenvalues of the light-front QCD Hamiltonian predict the hadron spectrum and the eigensolutions provide the light-front wavefunctions which describe hadron structure. More generally, we show that the valence Fock-state wavefunctions of the light-front QCD Hamiltonian satisfy a single-variable relativistic equation of motion, analogous to the nonrelativistic radial Schrödinger equation, with an effective confining potential U which systematically incorporates the effects of higher quark and gluon Fock states. We outline a method for computing the required potential from first principles in QCD. The holographic mapping of gravity in AdS space to QCD, quantized at fixed light-front time, yields the same light front Schrödinger equation; in fact, the soft-wall AdS/QCD approach provides a model for the light-front potential which is color-confining and reproduces well the light-hadron spectrum. One also derives via light-front holography a precise relation between the bound-state amplitudes in the fifth dimension of AdS space and the boost-invariant light-front wavefunctions describing the internal structure of hadrons in physical space-time. The elastic and transition form factors of the pion and the nucleons are found to be well described in this framework. The light-front AdS/QCD holographic approach thus gives a frame-independent first approximation of the color-confining dynamics, spectroscopy, and excitation spectra of relativistic light-quark bound states in QCD.

scholarly journals Light-front holographic QCD and color confinement

2014 ◽  
Vol 29 (21) ◽  
pp. 1444013 ◽  
Author(s):  
Stanley J. Brodsky ◽  
Guy F. de Teramond ◽  
Hans Günter Dosch
Keyword(s):  
Schrödinger Equation ◽  
Schrodinger Equation ◽  
Dimensional Space ◽  
Form Factors ◽  
Mass Scale ◽  
Light Front ◽  
Classical Level ◽  
Conformally Invariant ◽  
Color Confinement ◽  
Soft Wall Model

One of the most fundamental problems in Quantum Chromodynamics is to understand the origin of the mass scale which controls the range of color confinement and the hadronic spectrum. For example, if one sets the Higgs couplings of quarks to zero, then no mass parameters appear in the QCD Lagrangian, and the theory is conformal at the classical level. Nevertheless, hadrons have a finite mass. We show that a mass gap and a fundamental color confinement scale arise when one extends the formalism of de Alfaro, Fubini and Furlan (dAFF) to frame-independent light-front Hamiltonian theory. Remarkably, the resulting light-front potential has a unique form of a harmonic oscillator in the light-front invariant impact variable if one requires that the action remains conformally invariant. The result is a single-variable relativistic equation of motion for [Formula: see text] bound states, a "Light-Front Schrödinger Equation," analogous to the nonrelativistic radial Schrödinger equation, which incorporates color confinement and other essential spectroscopic and dynamical features of hadron physics, including a massless pion for zero quark mass and linear Regge trajectories with the same slope in the radial quantum number and orbital angular momentum. The same light-front equations with the correct hadron spin dependence arise from the holographic mapping of "soft-wall model" modification of AdS5 space with a specific dilaton profile. The corresponding light-front Dirac equation provides a dynamical and spectroscopic model of nucleons. A fundamental mass parameter κ appears, determining the hadron masses and the length scale which underlies hadron structure. Quark masses can be introduced to account for the spectrum of strange hadrons. This Light-Front Holographic approach predicts not only hadron spectroscopy successfully, but also hadron dynamics — hadronic form factors, the QCD running coupling at small virtuality, the light-front wavefunctions of hadrons, ρ electroproduction, distribution amplitudes, valence structure functions, etc. Thus the combination of light-front dynamics, its holographic mapping to gravity in a higher-dimensional space and the dAFF procedure provides new insight into the physics underlying color confinement, chiral invariance, and the QCD mass scale, among the most profound questions in physics.

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