Abstract
Recently, non-standard Lagrangians have gained a growing importance in theoretical physics and in the theory of non-linear differential equations. However, their formulations and implications in general relativity are still in their infancies despite some advances in contemporary cosmology. The main aim of this paper is to fill the gap. Though non-standard Lagrangians may be defined by a multitude form, in this paper, we considered the exponential type. One basic feature of exponential non-standard Lagrangians concerns the modified Euler-Lagrange equation obtained from the standard variational analysis. Accordingly, when applied to spacetime geometries, one unsurprisingly expects modified geodesic equations. However, when taking into account the time-like paths parameterization constraint, remarkably, it was observed that mutually discrete gravity and discrete spacetime emerge in the theory. Two different independent cases were obtained: A geometrical manifold with new spacetime coordinates augmented by a metric signature change and a geometrical manifold characterized by a discretized spacetime metric. Both cases give raise to Einstein’s field equations yet the gravity is discretized and originated from “spacetime discreteness”. A number of mathematical and physical implications of these results were discussed though this paper and perspectives are given accordingly.
Highlights
Well-known examples of non-standard Lagrangians (NSL) are Dirac-Born-Infeld field Lagrangians and p-adic string for tachyon field in theoretical cosmology [30,31,32,33], NSL which arise in dissipative dynamical systems with variable coefficients [4,5], NSL which arise in fractional dynamics [7], power-law and exponential Lagrangians introduced in [10] and so on
We choose the exponential NSL (ENSL) and we will discuss some of their implications in differential geometry and general relativity (GR)
The above results suggest that gravity originates from “spacetime discreteness” if the standard action is replaced by the ENSL
Summary
The theory of non-natural or non-standard Lagrangians (NSL) which are characterized by a deformed Lagrangian or deformed kinetic and potential energy terms have recently gained an increasing importance due to their wide applications in applied mathematics [1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22] and theoretical physics [23,24,25,26,27,28,29]. We argue that the constraint e 1 , which yields to discreteness, may be relevant for more general theories in which Einstein’s general relativity is an emergent theory from a more fundamental theory that requires a primary version of diffeomorphism invariance and general covariance This is an open problem that deserves a careful analysis.
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