Modern hyper-scale AI models and spatial edge applications face severe power dissipation bottlenecks and the von Neumann memory wall. According to Landauer's principle, traditional non-reversible computing systems inevitably generate thermodynamic heat during state transitions. Here, we report the hardware-level experimental realization of an ultra-low-power virtual Quantum Processing Unit (vQPU) based on Adiabatic Charge-Recovery Logic (ACRL). By executing logically reversible coordinate mappings (ΔSₗogic = 0), this architecture intrinsically bypasses the thermodynamic limits of energy dissipation (ΔEdissip = 0). Instead of dumping residual charge to ground, the ACRL circuit utilizes a multi-phase power clock to recover the charge back to the power supply. Experimental validation demonstrates that the vQPU operates at a micro-watt scale power consumption (23. 9 μW), while materializing a 4. 2 GB 4D spatiotemporal dataset utilizing an invariant 11. 2 MB heap memory (O (1) space complexity) and zero network bandwidth. This thermodynamically reversible hardware paradigm provides a foundational framework for integrating the HSKG protocol directly into commercial mobile NPUs and hyper-scale data centers, enabling a net-zero carbon computing infrastructure ecosystem that reduces global computing emissions to near-zero.
Min Ho Jung (Wed,) studied this question.