Bridging Quantum and Classical Mechanics in Polymer Systems through Transitionless Quantum Driving: Experimental Insights
Abstract
In this paper, Transitionless quantum driving has been used to investigate the electric and mechanical properties in polymers and link quantum and classical mechanics in the material. The electric conductivity enhancement by TQD was reported to be 1.85×, and it improved the charge transport. Furthermore, Young's modulus and the strain at break under quantum conditions increased very highly; hence, the mechanical properties of the material improve regarding resilience and flexibility. These were closely in line with theoretical predictions that set the quantum charge transport model. These insights can be valuable for utilizing quantum principles in creating polymers-based materials for applications such as flexible electronics, energy storage, and highperformance structural materials.
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