The Bianchi Identities in the Generalized Theory of Gravitation

A. Einstein

doi:10.4153/CJM-1950-011-4

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1. General remarks. The heuristic strength of the general principle of relativity lies in the fact that it considerably reduces the number of imaginable sets of field equations; the field equations must be covariant with respect to all continuous transformations of the four coordinates. But the problem becomes mathematically well-defined only if we have postulated the dependent variables which are to occur in the equations, and their transformation properties (field-structure). But even if we have chosen the field-structure (in such a way that there exist sufficiently strong relativistic field-equations), the principle of relativity does not determine the field-equations uniquely. The principle of “logical simplicity” must be added (which, however, cannot be formulated in a non-arbitrary way). Only then do we have a definite theory whose physical validity can be tested a posteriori.

References

1 Ann. of Math., vol. 46 (1945), no. 4; vol. 47(1946), no. 4.

2 It is a consequence of (1) that (2) and (3) are equivalent. This will be proven in sec. 5

3 The names “conjugate” and “Hermitian” can be justified as follows: an interesting possibility is to choose imaginary. Then is really the conjugate of g. Hence A is the conjugate Y of A, and the definition of “Hermitian” agrees with the usual one.

4 Thus in our theory the condition of symmetry is generalized to that of being Hermitian. are all Hermitian in .

5 Since , the two kinds of differentiation coincide when applied to g. This must be so since there is no index which could have a + or - character.

Crossref Citations

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Kurşunoğlu, Behram 1952. Gravitation and Electrodynamics. Physical Review, Vol. 88, Issue. 6, p. 1369.

Kursunoglu, Behram 1952. Einstein's Unified Field Theory. Proceedings of the Physical Society. Section A, Vol. 65, Issue. 2, p. 81.

Kilmister, C. W. and Stephenson, G. 1954. An axiomatic criticism of unified field theories—I. Il Nuovo Cimento, Vol. 11, Issue. S1, p. 91.

Kilmister, C. W. and Stephenson, G. 1954. An axiomatic criticism of unified field theories—II. Il Nuovo Cimento, Vol. 11, Issue. S1, p. 118.

Lanczos, C. 1955. Albert Einstein and the theory of relativity. Il Nuovo Cimento, Vol. 2, Issue. S5, p. 1193.

Moffat, John 1956. Generalized Riemann spaces. Mathematical Proceedings of the Cambridge Philosophical Society, Vol. 52, Issue. 4, p. 623.

Moffat, John 1957. The foundations of a generalization of gravitation theory. Mathematical Proceedings of the Cambridge Philosophical Society, Vol. 53, Issue. 2, p. 473.

Bargmann, V. 1957. Relativity. Reviews of Modern Physics, Vol. 29, Issue. 2, p. 161.

Pachner, Jaroslav 1959. Die unitäre Feldtheorie der Schwere und Elektrizität. Annalen der Physik, Vol. 460, Issue. 1-2, p. 70.

Sciama, D. W. 1961. On the Interpretation of the Einstein-Schrödinger Unified Field Theory. Journal of Mathematical Physics, Vol. 2, Issue. 4, p. 472.

Johnson, Coates R. 1971. Motion of Particles in Einstein's Relativistic Field Theory. I. Introduction and General Theory. Physical Review D, Vol. 4, Issue. 2, p. 295.

Johnson, Coates R. 1973. Motion of Particles in Einstein's Relativistic Field Theory. VI. Conservation Laws and Motion. Physical Review D, Vol. 7, Issue. 10, p. 2825.

Tautz, M. F. 1973. A new variational method for the nonsymmetric unified field theory. Il Nuovo Cimento B, Vol. 16, Issue. 2, p. 311.

Johnson, Coates R. 1973. Motion of Particles in Einstein's Relativistic Field Theory. VIII. Displacement Field, Fundamental Field, and Geodesics. Physical Review D, Vol. 8, Issue. 6, p. 1645.

Kursunoglu, Behram 1974. Fundamental Theories in Physics. p. 19.

Kurşunoǧlu, Behram 1974. Gravitation and magnetic charge. Physical Review D, Vol. 9, Issue. 10, p. 2723.

Kursunoglu, Behram 1975. Theories and Experiments in High-Energy Physics. p. 131.

Mehra, Jagdish 1975. Satyendra Nath Bose, 1 January 1894 - 4 February 1974. Biographical Memoirs of Fellows of the Royal Society, Vol. 21, Issue. , p. 116.

Kurşunoǧlu, Behram 1976. Consequences of nonlinearity in the generalized theory of gravitation. Physical Review D, Vol. 13, Issue. 6, p. 1538.

Kurşunoğlu, Behram 1976. New Pathways in High-Energy Physics I. p. 15.

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