sg:pub.10.1007/s11082-019-1811-2 - Springer Nature SciGraph

Article Info

DATE

2019-04

AUTHORS

N. R. Sadykov, A. V. Aporoski

ABSTRACT

We investigate the mechanism of radiation generation, whose source are modulated with the variable (x-υt) surface currents in elongated nanoparticles forming a 3D structure. Carbon nanotubes and graphene nanoribbons are considered as elongated nanoparticles. The volume fraction f<<1 of nanoparticles is considered small (the distance between the centers of nanoparticles is several times greater than their length), thus allowing one to neglect the interaction of two identical nanotubes due to the tunneling effect. Since the velocity of modulated surface currents υ in 3D structure greater than the phase velocity of the light in a medium, then the process is qualitatively similar to the Cherenkov radiation by a system of dipoles that move with the velocity υ. In the case of α-aligned nanofilms based on nanotubes, the radiation wavefront will have a form of a divergent wedge. It is shown that such a structure can generate intense microwave and terahertz radiation and an estimate of the radiation value is made. More... »

PAGES

References to SciGraph publications

2015-08. Analogue of Vavilov-Cherenkov radiation in a medium based on an array of noninteracting nanotubes in THEORETICAL AND MATHEMATICAL PHYSICS

1981-06. Cherenkov radiation of tachyons in THEORETICAL AND MATHEMATICAL PHYSICS

2015-05. Effect of electromagnetic radiation on an array of noninteracting carbon nanoribbons in the presence of nanosecond electrical pulses in SEMICONDUCTORS

1997-04. Individual single-wall carbon nanotubes as quantum wires in NATURE

2013-10. Influence of powerful nanosecond electrical pulses on an array of double-walled nanotubes in THEORETICAL AND MATHEMATICAL PHYSICS

2013-05. Quantum approach to the description of amplification of radiation from an array of nanotubes in TECHNICAL PHYSICS

2005-10. Microwave devices: Carbon nanotubes as cold cathodes in NATURE

1996-12. Derivation of the pulse front tilt caused by angular dispersion in OPTICAL AND QUANTUM ELECTRONICS

2001-10. Plasma oscillations in nanotubes and the Aharonov-Bohm effect for plasmons in JOURNAL OF EXPERIMENTAL AND THEORETICAL PHYSICS

2012-01. Macroscopic QCD and quark-gluon plasma in THEORETICAL AND MATHEMATICAL PHYSICS

2013-09. Effect of electromagnetic radiation on an array of weakly interacting carbon nanotubes in the presence of nanosecond pulses in SEMICONDUCTORS

2016-07. Analogues of Vavilov–Cherenkov radiation in an array of noninteracting nanotubes in THEORETICAL AND MATHEMATICAL PHYSICS

1997-06. Characteristic features of the π-electron states of carbon nanotubes in JOURNAL OF EXPERIMENTAL AND THEORETICAL PHYSICS

2000-06. Generation of RF oscillations in the interaction of an electromagnetic shock with a synchronous backward wave in TECHNICAL PHYSICS

Journal

TITLE

Optical and Quantum Electronics

ISSUE

VOLUME

Subjects

FOR: Other Physical Sciences

FOR: Physical Sciences

Author Affiliations

Moscow Engineering Physics Institute

Identifiers

URI

http://scigraph.springernature.com/pub.10.1007/s11082-019-1811-2

DOI

http://dx.doi.org/10.1007/s11082-019-1811-2

DIMENSIONS

https://app.dimensions.ai/details/publication/pub.1112855228

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