This paper presents a novel theoretical model of black hole interiors based on a microstructural space-time framework called Density-Driven Internal Contraction (DDIC). By introducing the concept of the Chrono-Reflective Singularity (CRS), the study redefines classical singularity as a time-reflective boundary arising from lattice density saturation. The model proposes that space-time consists of quantized lattice cells whose internal contraction increases with matter-energy density, leading to extreme densification at the black hole core. The CRS framework eliminates the need for a true singularity by proposing a mirror-like layer that reflects quantum information and gravitational signals, forming the basis for phenomena such as echo entropy and observable gravitational wave echoes. The paper also explores thermodynamic consistency, entropy corrections, and potential cosmological nesting structures. Additionally, it offers testable predictions for gravitational wave detectors and cosmic microwave background anisotropies, and discusses compatibility with quantum gravity approaches such as Loop Quantum Gravity (LQG). This framework provides a fresh perspective on the resolution of singularities and the quantum structure of space-time. This paper is currently presented as a formal hypothesis and has not yet been tested experimentally. It is shared for theoretical review and academic discussion.
Sedat Büyük (Wed,) studied this question.