We present a unified framework for quantum gravity synthesising Loop Quantum Gravity (LQG), Causal Dynamical Triangulations (CDT), and holographic principles with rigorous mathematical foundations and systematic matter-field integration. Key results include: (1) quantisation of geometric operators with discrete area spectrum providing ultraviolet regularisation; (2) CDT Monte Carlo simulations on 320, 000 four-simplices confirming spectral dimension flow from dS = 1. 80 ± 0. 25 at the Planck scale to dS = 3. 95 ± 0. 10 at macroscopic scales; (3) microscopic derivation of the Bekenstein–Hawking entropy with logarithmic quantum corrections; (4) singularity resolution through discrete geometry with finite maximum curvature and density; (5) complete matter coupling via densitised triads and connections with explicit anomaly cancellation; (6) spin foam dynamics resolving the Hamiltonian constraint with verified semiclassical limit; and (7) coherent states demonstrating the quantum-to-classical transition. The framework predicts modified photon dispersion yielding time delays of 2. 4 ± 1. 2 ms for 10 GeV gamma-rays at z = 1, testable by Fermi-LAT and CTA; gravitational-wave echoes of 3. 0 ± 0. 2 s for 30 solar-mass mergers, detectable by the Einstein Telescope; and CMB power-spectrum suppression of (7 ± 3) % at multipoles below 30, measurable by LiteBIRD and CMB-S4. This establishes quantum gravity as a mathematically consistent, computationally verifiable theory making falsifiable predictions within 10–15 years, without requiring supersymmetry or extra dimensions.
Manan Limbad (Thu,) studied this question.