The Neutronic-Radiological Transition: Atmospheric Fission Dynamics, BEC-Mediated Infrared Squeezing, and the CKIT Mitigation Framework - A Paper Written with Gemini

Abstract

Current climatological models fail to account for the non-linear relationship between industrial CO2 output and high-latitude thermal surges. We propose a Radiological-Neutronic Model wherein "cold" CO2 emissions act as a primary neutron moderator, optimizing the capture cross-section for airborne Naturally Occurring Radioactive Materials (NORMs). This study identifies Iodine-131 as a critical thermal oscillator, whose short-lived beta- decay provides the mechanical energy for Bose-Einstein Condensate (BEC) formation and subsequent "Beta-Squeezing" of solar photons into infrared radiation. We define an "Optimal Squeeze" window (-18°C to -25°C) where infrared production is maximal, explaining Arctic amplification and the resilience of Ursus maritimus via the dissolution of macroscopic BEC inhibitors ("ice balls"). Furthermore, we identify the Anthropogenic Buoyancy-Fission Feedback (ABFF), where human waste heat lofts NORM fuel, creating a self-sustaining atmospheric reactor. To decouple this cycle, we propose the Cryogenic-KERS Integrated Transmission (CKIT) system. By harvesting thermal exhaust for integral mechanical work and releasing cryogenic CO2, CKIT induces "Squeezing Collapse" and NORM settling. This framework provides a superior pathway for the Global South, leveraging endothermic photosynthesis in tropical basins to neutralize radiological heat pulses and restore atmospheric stability by the 2040 horizon.