Noninertial Relativistic Symmetry

Abstract

The definition of invariant time is fundamental to relativistic symmetry. Invariant time may be formulated as a degenerate orthogonal metric on a flat phase space with time, position, energy and momentum degrees of freedom that is also endowed with a symplectic metric ω =-d t d +δ i,jd qi d pj. For Einstein proper time, the degenerate orthogonal metric is d τo 2=d t2-1c2d q2 and, in the limit c ∞, becomes Newtonian absolute time, d t2. We show that the the resulting symmetry group leaving ω and d t2 invariant is the Jacobi group that gives the expected transformations between noninertial states defined by Hamilton's equations. The symmetry group for ω and d τo 2 is the semidirect product of the Lorentz and an abelian group parameterized by the time derivative of the energy-momentum tensor that characterizes noninertial states in special relativity. This leads to the consideration of invariant time based on a nondegenerate Born metric, d τ2=d t2-1c2d q2-1b2d p2+1b2c2d 2. b is a universal constant with dimensions of force that, with c, define the dimensional scales of phase space. We determine that the symmetry group for transformations between noninertial states is essentially a noncompact unitary group. It reduces to the noninertial symmetry group for Einstein proper time in the b ∞ limit and to the noninertial symmetry group for Hamiltonian mechanics in the b,c ∞ limit. The causal cones in phase space defined by the null surfaces dτ2=0 bound the rate of change of momentum as well as position. Furthermore, spacetime is no longer an invariant subspace of phase space but depends on the noninertial state; there is neither an absolute rest state nor an absolute inertial state that all observers agree on.