The Second Quantum Revolution: Development of Subatomic Quantum Nanotechnologies of Intelligent Materials

S. Beznosyuk
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Abstract

The article analyzes the future development of quantum nanotechnology based on attosecond physics of the subatomic level of the condensed state. There are considered the ways of realizing the main achievements of the second quantum revolution in subatomic nanotechnologies of materials, namely quantum entanglement, quantum contextuality and quantum dissipativity. The theoretical analysis of the prospects for this direction in the development of quantum subatomic nanotechnologies has been carried out within the framework of the well-known theory of thermal field dynamics of the condensed state. The analysis shows that subatomic en-tanglement of electron pairs is realized by attosecond single pulsed photons. The entangled electron pairs form the interfaces of supra-atomic capsules — quantum nanoelectromechanical systems (NEMS) of the con-densed state of the material. The Coulomb blockade of quantum NEMS interfaces is complemented by the fact that they are controlled by the infrastructure of subatomic two-electron sensors and actuators located at the interface boundaries. When the primary subatomic interfaces of NEMS function, secondary supra-atomic scale entangled pairs of electrons are generated, which dissipate the NEMS energy and form a dissipative multilevel hierarchy of condensed state interfaces at higher spatio-temporal scales of intelligent materials
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第二次量子革命:智能材料亚原子量子纳米技术的发展
本文分析了基于亚原子凝聚态阿秒物理的量子纳米技术的未来发展。讨论了亚原子纳米材料技术中第二次量子革命主要成果的实现途径,即量子纠缠、量子情境性和量子耗散性。在著名的凝聚态热场动力学理论框架内,对量子亚原子纳米技术的发展前景进行了理论分析。分析表明,电子对的亚原子纠缠是由阿秒单脉冲光子实现的。纠缠的电子对形成了超原子胶囊-材料凝聚态量子纳米机电系统(NEMS)的界面。量子NEMS界面的库仑封锁是由位于界面边界的亚原子双电子传感器和致动器的基础设施控制的。当NEMS的初级亚原子界面起作用时,会产生次级超原子尺度的纠缠电子对,这些纠缠电子对耗散NEMS能量,在智能材料的更高时空尺度上形成耗散的多层凝聚态界面
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