The theory of motion of quantum electromechanical plasmoid nanobots in a condensed-state medium

Beznosyuk, S. А.; Zhukovskii, M. S.; Potekaev, A. I.

doi:10.1007/s11182-013-0067-8

Cited by 7 publications

(4 citation statements)

References 4 publications

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“…2 One can imagine that the nanobot include electron quantum motor and quantum mechanical moving part of nuclei. The nuclear quantum-mechanical moving part is driven by the electronic engine.…”

Section: The Theory Of Quantum Nems Accumulators Of Energy Storage Inmentioning

confidence: 99%

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Theory and Computer Simulation of Quantum NEMS Energy Storage in Materials

Beznosyuk

Zhukovsky

2015

Int. J. Nanosci.

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The theory of quantum relaxation of the nanoelectromechanical system (NEMS) energy storage in materials is taken under consideration. By using the method of quantum NEMS kinetics (NK) the relaxation NEMS energy storage in the form of limited planes (100) Fe 172 cube in fcc iron crystal was studied. For comparison, the calculation a similar structure atomic cluster Fe 172 was carried out by the molecular dynamics method (MD) for temperature T ¼ 293 K. Analysis of computer-related experiments have shown that the relaxation of the NEMS energy storage Fe 172 and the MD atomic cluster Fe 172 from an initial nonequilibrium state has signi¯cant di®erences both in the kinetics, and in a variety of structural transformations. It is shown that the iron MD cluster relaxation is insigni¯cant and its¯nal total binding energy per atom is 2 eV/at lower than the crystal one. The NK-method revealed that after relaxation there is a signi¯cant change in the shape and the pair radial distribution function of nuclei the NEMS energy storage. It signi¯cantly increases the binding energy up to 3.34 eV/at, which is only about 1 eV/at less than the binding energy of the crystalline iron. It is shown an opportunity to undergo a process of self-organization the NEMS energy storage through several intermediate metastable states. It is manifested that°uctuation rebuild the cube into a cuboid with a strong bending of the cube surfaces occurs at 20 ps of relaxation, and there is the second transformation being with trapezoid change of faces at 40 ps of relaxation process. This e®ect cardinally differentiates NK relaxation of the NEMS energy storage cube Fe 172 from MD relaxation of the atomic cluster Fe 172 in the crystalline iron.

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Section: The Theory Of Quantum Nems Accumulators Of Energy Storage Inmentioning

confidence: 99%

“…Simulated evolution of nanobot in fcc crystal of iron was held in the framework of quantum NEMS-kinetics (NK). 2 For comparison we present results of investigation of evolution the atomic cluster of iron having structure similar to the nanobot. The result was obtained by molecular dynamics (MD) method.…”

Section: Introductionmentioning

confidence: 99%

Theory and Computer Simulation of Quantum NEMS Energy Storage in Materials

Beznosyuk

Zhukovsky

2015

Int. J. Nanosci.

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“…Малые, менее 10 нм, металлические наночастицы в коллоидах являются распространенными объектами в экспериментах по облучению их фемтосекундными лазерными импульсами контролируемой мощности [1,2]. Использование фемтосекундных и более коротких по импульсам аттосекундных лазеров и пучков микрочастиц видится наиболее перспективным методом получения необычных состояний квантовых наноэлектромеханических систем (НЭМС) малых наночастиц в конденсированных средах [3][4][5][6]. Эти состояния не характерны для нанокластеров в вакууме или в инертных газах, описываемых методами квантовой фемтохимии или молекулярной динамики [7].…”

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Computer Simulation Of Copper and Iron Cuboids NEMS Quantum Kinetics Of Relaxation

Beznosjuk¹,

Zhukovsky²,

Maximov³

et al. 2014

izvasu

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“…Введение. Точечные одиночные субфемтосекундные импульсы излучения или пучков микрочастиц малой мощности предполагается использовать для активации в конденсированном состоянии мобильных квантовых наноэлектромеханических систем (НЭМС) атомов [1,2]. Эти системы не формируются в вакууме или инертных газах, так как для их устойчивости требуется наличие квантово-полевой континуальной по спектру возбуждений диссипативной электронной среды конденсированного состояния вещества.…”

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