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Title: Polynomial conservation laws in (1 + 1) -dimensional classical and quantum field theory

Journal Article · · Phys. Rev., D; (United States)

The quantum-mechanical implications of the inverse-scattering-transform method and its relationship to the structure of Bethe's ansatz are discussed in the context of the nonlinear Schroedinger equation (many-body problem) associated with the classical (quantum) field theory L = (i/2) phi*partial/sub 0/phi - vertical-barpartial/sub 1/phivertical-bar/sup 2/ - cvertical-barphivertical-bar/sup 4/. We review the transformation of the classical problem to action and angle variables and the derivation of an infinite number of polynomial conservation laws. The values of the conserved constants are given by the moments of the classical action variable. It is suggested that there exists a corresponding set of conserved polynomial operators in the quantum field theory and that they reflect the conservation of velocity content which characterizes the solution of the many-body scattering problem (Bethe's ansatz). This implies that the quantized action variable is just the occupation-number density operator in the asymptotic momentum- (velocity-) parameter space of Bethe's ansatz, and that Bethe's wave functions are eigenstates of all conserved operators with eigenvalues given by the moments of the N-particle distribution in asymptotic momentum space. These statements are verified for the first four operators, including one which has not previously been studied.

Research Organization:
Fermi National Accelerator Laboratory, Batavia, Illinois 60510
OSTI ID:
7276328
Journal Information:
Phys. Rev., D; (United States), Vol. 17:4
Country of Publication:
United States
Language:
English

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Related Subjects

72 PHYSICS OF ELEMENTARY PARTICLES AND FIELDS
71 CLASSICAL AND QUANTUM MECHANICS
GENERAL PHYSICS
QUANTUM FIELD THEORY
CONSERVATION LAWS
QUANTUM MECHANICS
BOUND STATE
EIGENSTATES
EIGENVALUES
EQUATIONS OF MOTION
LAGRANGIAN FUNCTION
MANY-BODY PROBLEM
SCATTERING
SCHROEDINGER EQUATION
WAVE FUNCTIONS
DIFFERENTIAL EQUATIONS
EQUATIONS
FIELD THEORIES
FUNCTIONS
MECHANICS
WAVE EQUATIONS
645400* - High Energy Physics- Field Theory
657002 - Theoretical & Mathematical Physics- Classical & Quantum Mechanics