Abstract
The search for a theory of the elementary particles which is founded on the well-established principles of quantum mechanics and conforms at the same time with the requirements of the principle of relativity has, in recent years, taken several divergent directions. On the one hand, the second quantization of wave fields derived from a Lagrangian by a variational procedure(1) has succeeded in accounting for the existence and most of the properties of the electron, the photon, and the meson. On the other hand, many generalizations of the Dirac wave equation of the electron(2) have been attempted, with applications to the meson(3) and the proton(4). Heisenberg(5) has considered the much more difficult problem of the interaction between different particles, and has found that the key to the situation is the so-called ‘scattering matrix’, which is nothing other than a limiting form of the relativistic density matrix, as defined in § 2 of this paper. It seems probable that the relativistic density matrix ρ; or statistical operator, as it may be called without reference to representation, will play an important part in relativistic quantum mechanics in the future. It satisfies the same equation as the wave function, but differs from it in being a real linear operator, or a dynamical variable, in the terminology of Dirac.
Publisher
Cambridge University Press (CUP)
Cited by
4 articles.
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1. General relativity from gauge invariance;Mathematical Proceedings of the Cambridge Philosophical Society;1971-05
2. Approximate analysis of axisymmetric problems in fracture mechanics with application to a flat toroidal crack;International Journal of Fracture Mechanics;1971-03
3. First-Order Meson Wave Equations;Physical Review;1953-03-01
4. On the self-energies and cross-sections of orthodox quantum mechanics;Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences;1949-05-11