Authors: Rayan Iyer
We develop a unified formalism for Asymmetry–Irreversible Heterogeneous Quantum Cosmology (AIHQC) by synthesizing four foundational advances: (i) massless bending magneto-gravitational spacetime and baryon asymmetry generation, (ii) quantum cellular automata (QCA) formulations of hadronic time evolution, (iii) suppression mechanisms in hadronic lattice structures, and (iv) a coupled sense–gravity–parity–chirality (SGPC) framework. The central thesis is that cosmological irreversibility, parity violation, and matter–antimatter asymmetry arise from an intrinsically asymmetric, discrete, and information-theoretic spacetime substrate. We construct a mathematically rigorous model in which spacetime is represented as directed, yet heterogeneous quantum lattice governed by local unitary QCA update operators , that will have the chirality-dependent transition amplitudes. Magneto-gravitational coupling is introduced through a generalized action that is given by algorithm equation represented showing: , where the chiral connection encodes parity-violating gravitational effects that which induces further the asymmetrical fermionic propagations on the lattice. Within this framework, baryon asymmetry emerges dynamically via magnetically induced gravitational anomalies satisfying generalized original Sakharov conditions with a discrete-time QCA evolution. We further demonstrate that hadronic lattice modes exhibit a suppression mechanism typicaly governed by the non-linear dispersion relations , leading to scale-dependent overall damping of symmetric states and amplification of chiral modes. This generates observable typical parity-violating tensor perturbations in primordial gravitational wave spectra, with distinct signatures within polarization anisotropies. A key result is the explicit correspondence between discrete QCA evolution and continuum Einstein–Cartan–Yang–Mills dynamics through a coarse-graining limit quantifiably given by: , establishing a bridge between typical quantum information time and relativistic spacetime geometry. The inclusion of a “sense” operator S, essentially defined as an informational asymmetry functional over lattice states, provides a novel quantitative measure of irreversibility and directional time emergence. AIHQC framework yields testable predictions, including chirality-dependent gravitational wave birefringence, magneto-gravitational baryogenesis scaling laws, as well as overall the lattice-induced deviations typically from standard cosmological perturbation theory. These results offer unifiable pathway toward integrating quantum computation, hadronic structure, as well as gravitational physics into a single asymmetric cosmological paradigm.
Keywords: Quantum Cosmology; Irreversible Heterogeneity; Magneto-gravitational Baryogenesis; Quantum Cellular Automata; Discrete Spacetime Dynamics; Hadronic Lattice Theory; Gravitational Wave Chirality; Parity Violation; Einstein–Cartan–Yang–Mills Correspondence; Quantum Information Time; Chiral Gravity; Baryon Asymmetry Mechanisms; Suppression Dynamics; Mathematical Physics Unifications.
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