We present a comprehensive formulation of Chrono-Grid Dynamics (CGD), a theory in which spacetime and general relativity emerge from a discrete, unitary evolution of quantum spins on a spatial lattice. The fundamental postulate is a universal quantum of proper time (the Takt), which drives the unitary step |₍+₁ = e^-iH|ₙ. Starting from a 3D cubic spin network with an extended Hamiltonian that includes dynamical SU (2) link variables, we show how tetrads and the Ashtekar connection arise from correlation matrices via singular value decomposition. By integrating out fermionic matter, we obtain the induced gravitational action with an R² term naturally generated by the Takt. All coupling constants of general relativity are expressed in terms of and a few dimensionless microscopic parameters. The theory is unitary, locally Lorentz invariant in the infrared, avoids the Weinberg–Witten obstruction, and passes the constraint-algebra consistency test in 1+1D. It predicts a modified photon dispersion v (E) 1 - E² / E₋² and a Starobinsky inflation with spectral index nₛ 0. 964 and tensor-to-scalar ratio r 0. 004, both in excellent agreement with observations. Using functional renormalization group techniques, we show that the R² coupling can acquire the large value required for inflation if the full higher-derivative sector (including R_²) is taken into account. The cosmological constant remains a challenge, but we discuss possible mechanisms for its cancellation within the framework.
Небојша Јовановић (Tue,) studied this question.
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