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Leibnizian Relationalism and the Problem of Inertia*

Published online by Cambridge University Press:  01 January 2020

Barbara Lariviere
Barbara Lariviere*
Affiliation:
1620 Palmerston Ave., West Vancouver, B.C., CanadaV7V 2T8
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Extract

I consider the contrast between Leibniz's relational concept of spacetime and Einstein's special and general theories of relativity. I suggest that there are two interpretations of Leibniz's view, which I call L1 and L2. L1 amounts to saying that there is no real inertial structure to spacetime, whereas in general relativity the inertial structure is dynamical or real in Lande's sense (see Popper, 46); i.e., it can be ‘kicked’ and ‘kicks back,’ causing gravitational effects. If there is no real inertial structure to space-time then, as Weyl points out (Weyl, 105), the concept of the relative motive of several bodies has no more foundation than the concept of absolute motion for a single body. Thus, L1 seems to be untenable. L2 is a more sophisticated view which rejects the geometrical aspect of Newtonian space-time as a container for events, but accepts the existence of a real structure which determines the inertial properties of matter.

Type
Research Article
Information
Canadian Journal of Philosophy , Volume 17 , Issue 2 , June 1987 , pp. 437 - 447
Copyright
Copyright © The Authors 1987

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Footnotes

*

Informative discussions with Jeffrey Bub on Weyl and the inertial structure of space-time are gratefully acknowledged.

References

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