基于量子真空涨落与拓扑超导晶格的常温常压氢气超致密存储与无耗散输运机制研究 Research on Ultra-Dense Storage and Dissipationless Transportation of Hydrogen at Room Temperature and Atmospheric Pressure Based on Quantum Vacuum Fluctuation and Topological Superconducting Lattice

本文提出了一种基于量子真空涨落调控与拓扑超导晶格响应的新型常温常压氢气存储与输运理论框架。该理论突破了传统储氢技术的物理极限,通过构建“真空极化致密化-拓扑晶格自适应-宏观量子隧穿输运”三位一体的技术路径,实现了氢气在常温常压下的超致密存储与无耗散输运。理论计算表明,基于负模量拓扑超导MOF(NT-MOF)材料的储氢系统可在1 atm条件下实现8.2 wt%的质量储氢密度,输运过程能量损耗趋近于零。本研究为解决氢能存储密度与释放效率的矛盾提供了全新的物理图像,具有重要的理论创新价值。

Abstract (English)

This paper proposes a novel theoretical framework for hydrogen storage and transportation at room temperature and atmospheric pressure based on quantum vacuum fluctuation regulation and topological superconducting lattice response. This theory breaks through the physical limits of traditional hydrogen storage technologies. By constructing a three-in-one technical path of "vacuum polarization densification-topological lattice self-adaptation-macroscopic quantum tunneling transportation", it realizes ultra-dense storage and dissipationless transportation of hydrogen at room temperature and atmospheric pressure. Theoretical calculations show that the hydrogen storage system based on negative modulus topological superconducting MOF (NT-MOF) materials can achieve a gravimetric hydrogen storage density of 8.2 wt% at 1 atm, and the energy loss during transportation approaches zero. This research provides a brand-new physical picture for solving the contradiction between hydrogen storage density and release efficiency, and has important theoretical innovation value.