Current Research in Next Generation Materials Engineering
Cosmological Geodesic Flow in Topologically Protected Lattice: A Friedmann-Riemann Framework for Room-Temperature Superconductivity
Abstract
Chur Chin
The pursuit of room-temperature superconductivity has remained one of the most challenging frontiers in condensed matter physics. Recent controversial claims surrounding LK-99 (lead-apatite) highlighted both the promise and pitfalls of conventional materials-based approaches [1]. This study presents a paradigm shift by introducing a cosmological framework to understand and engineer superconducting states. We demonstrate that the anomalous behaviors observed in LK-99 can be reinterpreted through the lens of Friedmann equation dynamics applied to crystalline lattice structures [2,3]. By mapping the scale factor a(t) from cosmological expansion to lattice constant variations, we establish that local spacetime curvature control can stabilize topological superconducting channels that would otherwise collapse under thermal fluctuations at room temperature [4,5]. Utilizing Google’s Willow quantum chip architecture as a simulation platform, we implemented Friedmann-Riemann optimization protocols that demonstrate geodesic electron flow with resistance approaching 10−12 Ω under ambient conditions [6]. Our results suggest that the fundamental limitation of room-temperature superconductivity is not material chemistry alone, but rather the absence of proper geometric control over the charge carrier pathways [7,8]. This work establishes theoretical foundations and experimental parameters for achieving stable room-temperature superconductivity through spacetime engineering rather than traditional doping strategies [9].