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A multivector derivative approach to Lagrangian field theory
Foundations of Physics 23 (10):1295-1327 (1993)
Abstract
A new calculus, based upon the multivector derivative, is developed for Lagrangian mechanics and field theory, providing streamlined and rigorous derivations of the Euler-Lagrange equations. A more general form of Noether's theorem is found which is appropriate to both discrete and continuous symmetries. This is used to find the conjugate currents of the Dirac theory, where it improves on techniques previously used for analyses of local observables. General formulas for the canonical stress-energy and angular-momentum tensors are derived, with spinors and vectors treated in a unified way. It is demonstrated that the antisymmetric terms in the stress-energy tensor are crucial to the correct treatment of angular momentum. The multivector derivative is extended to provide a functional calculus for linear functions which is more compact and more powerful than previous formalisms. This is demonstrated in a reformulation of the functional derivative with respect to the metric, which is then used to recover the full canonical stress-energy tensor. Unlike conventional formalisms, which result in a symmetric stress-energy tensor, our reformulation retains the potentially important antisymmetric contributionAuthor Profiles
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Citations of this work
Imaginary numbers are not real—The geometric algebra of spacetime.Stephen Gull, Anthony Lasenby & Chris Doran - 1993 - Foundations of Physics 23 (9):1175-1201.
States and operators in the spacetime algebra.Chris Doran, Anthony Lasenby & Stephen Gull - 1993 - Foundations of Physics 23 (9):1239-1264.
Electron paths, tunnelling, and diffraction in the spacetime algebra.Stephen Gull, Anthony Lasenby & Chris Doran - 1993 - Foundations of Physics 23 (10):1329-1356.
An Einstein addition law for nonparallel boosts using the geometric algebra of space-time.B. Tom King - 1995 - Foundations of Physics 25 (12):1741-1755.
References found in this work
Gravitation and cosmology: principles and applications of the general theory of relativity.Steven Weinberg - 1972 - New York,: Wiley.
Imaginary numbers are not real—The geometric algebra of spacetime.Stephen Gull, Anthony Lasenby & Chris Doran - 1993 - Foundations of Physics 23 (9):1175-1201.
States and operators in the spacetime algebra.Chris Doran, Anthony Lasenby & Stephen Gull - 1993 - Foundations of Physics 23 (9):1239-1264.
Electron paths, tunnelling, and diffraction in the spacetime algebra.Stephen Gull, Anthony Lasenby & Chris Doran - 1993 - Foundations of Physics 23 (10):1329-1356.
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