Abstract
Abstract

LOYOLA COLLEGE (AUTONOMOUS), CHENNAI – 600 034
LOYOLA COLLEGE (AUTONOMOUS), CHENNAI – 600 034

Name________________________________ Block ______ Date
Name________________________________ Block ______ Date

4.8 Use the Quadratic formula and the discriminant Goal: To
4.8 Use the Quadratic formula and the discriminant Goal: To

LOYOLA COLLEGE (AUTONOMOUS), CHENNAI
LOYOLA COLLEGE (AUTONOMOUS), CHENNAI

Literal Equations Notes
Literal Equations Notes

Math I w Support
Math I w Support

Finding the Slope of a Line
Finding the Slope of a Line

6.4
6.4

An alternative quadratic formula
An alternative quadratic formula

Steps for solving an Empirical Formula Problem
Steps for solving an Empirical Formula Problem

Jonathan Butturini and Connor Bliss Chapter 1 Review
Jonathan Butturini and Connor Bliss Chapter 1 Review

The Nilpotent generalization of Dirac`s famous Equation D(N)
The Nilpotent generalization of Dirac`s famous Equation D(N)

CLASSICAL-QUANTUM CORRESPONDENCE AND WAVE PACKET SOLUTIONS OF THE DIRAC
CLASSICAL-QUANTUM CORRESPONDENCE AND WAVE PACKET SOLUTIONS OF THE DIRAC

Problem set 7
Problem set 7

Ex10
Ex10

q2.pdf
q2.pdf

FINAL REVIEW 1st SEMESTER 2014-2015
FINAL REVIEW 1st SEMESTER 2014-2015

Exercises in Statistical Mechanics
Exercises in Statistical Mechanics

Two-body Dirac equations

In quantum field theory, and in the significant subfields of quantum electrodynamics and quantum chromodynamics, the two-body Dirac equations (TBDE) of constraint dynamics provide a three-dimensional yet manifestly covariant reformulation of the Bethe–Salpeter equation for two spin-1/2 particles. Such a reformulation is necessary since without it, as shown by Nakanishi, the Bethe–Salpeter equation possesses negative-norm solutions arising from the presence of an essentially relativistic degree of freedom, the relative time. These ""ghost"" states have spoiled the naive interpretation of the Bethe–Salpeter equation as a quantum mechanical wave equation. The two-body Dirac equations of constraint dynamics rectify this flaw. The forms of these equations can not only be derived from quantum field theory they can also be derived purely in the context of Dirac's constraint dynamics and relativistic mechanics and quantum mechanics. Their structures, unlike the more familiar two-body Dirac equation of Breit, which is a single equation, are that of two simultaneous quantum relativistic wave equations. A single two-body Dirac equation similar to the Breit equation can be derived from the TBDE. Unlike the Breit equation, it is manifestly covariant and free from the types of singularities that prevent a strictly nonperturbative treatment of the Breit equation.In applications of the TBDE to QED, the two particles interact by way of four-vector potentials derived from the field theoretic electromagnetic interactions between the two particles. In applications to QCD, the two particles interact by way of four-vector potentials and Lorentz invariant scalar interactions, derived in part from the field theoretic chromomagnetic interactions between the quarks and in part by phenomenological considerations. As with the Breit equation a sixteen-component spinor Ψ is used.