Quantized Irreversible Null-geometry: Foundation and Applications
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Abstract
Formulating a consistent integration measure for quantum geometric fluctuations without violating diffeomorphism invariance remains a theoretical challenge.
In this work, a framework rooted in the statistics of discrete Poisson point processes is proposed.
The formulation yields a double-exponential probability functional characterized by a capacity limit, which acts as an amplitude regularizer suppressing ultraviolet singularities.
To evaluate this model at macroscopic scales, a statistical bifurcation of the stochastic action is identified.
First, the macroscopic mean condenses to define the classical continuous spacetime background and its matter distribution.
Second, at macroscopic scales, the Law of Large Numbers dictates that the residual ultraviolet noise maps into an infrared continuous zero-mean Gaussian martingale within the bulk.
Third, this zero-mean Gaussian noise linearly generates standard quantum kinematic effects.
Fourth, evaluating the non-linear exponential action separates the variance of this Gaussian noise from the linear cancellation, rectifying it into a macroscopic drift that manifests as the dark energy density.
Diluted by the Bekenstein-Hawking entropy of the observable universe, this bulk variance dictates a continuous field cutoff at 6 TeV.
Building upon this framework, broad phenomenological applications are demonstrated: (1) establishing a UV-finite effective field theory preserving gauge symmetries in 4D; (2) constructing a topological model of particles deriving Standard Model hierarchies; (3) formulating a non-singular cosmological model predicting observed large-scale power suppression in the cosmic microwave background; and (4) deriving foundational axioms of quantum mechanics as emergent statistical phenomenologies.
Collectively, this framework provides a falsifiable synthesis bridging discrete quantum geometry and continuous macroscopic physics.