Field emission from carbon nanostructures: models and experiment

E.D. Eidelman^a, b, c, A.V. Arkhipov^c
^aIoffe Institute, ul. Polytekhnicheskaya 26, St. Petersburg, 194021, Russian Federation
^bSt. Petersburg Chemical-Pharmaceutical Academy, ul. prof. Popova 14, St. Petersburg, 197376, Russian Federation
^cPeter the Great St. Petersburg Polytechnic University, Politehnicheskaya st. 29, St. Petersburg, 195251, Russian Federation

Models of field (cold, autoelectron) emission from various types of carbon nanostructures, other than graphene, are described. The experimental results are compared with theoretical predictions.

Keywords: carbon nanostructures, field emission properties, field emission models, emission threshold, emitters, cathodes for emission devices
PACS: 71.38.Ht, 73.63.−b, 79.70.+q (all)
DOI: 10.3367/UFNe.2019.06.038576
URL: https://ufn.ru/en/articles/2020/7/b/
Web of Science

000575189200002
Scopus

2-s2.0-85092467557
ADS NASA

2020PhyU...63..648E
Citation: Eidelman E D, Arkhipov A V "Field emission from carbon nanostructures: models and experiment" Phys. Usp. 63 648–667 (2020)

BibTexBibNote ® (generic)BibNote ® (RIS)MedlineRefWorks

Received: 16th, April 2019, revised: 31st, May 2019, accepted: 5th, June 2019

Оригинал: Эйдельман Е Д, Архипов А В «Полевая эмиссия из углеродных наноструктур: модели и эксперимент» УФН 190 693–714 (2020); DOI: 10.3367/UFNr.2019.06.038576

References (183) Cited by (15) Similar articles (20) ↓

A.V. Eletskii “Carbon nanotube-based electron field emitters” 53 863–892 (2010)
E.D. Eidelman “Thermoelectric effect and thermoelectric generator based on carbon nanostructures: achievements and prospects” 64 535–557 (2021)
A.V. Eletskii “Transport properties of carbon nanotubes” 52 209–224 (2009)
A.V. Eletskii “Mechanical properties of carbon nanostructures and related materials” 50 225–261 (2007)
B.M. Smirnov “Metal nanostructures: from clusters to nanocatalysis and sensors” 60 1236–1267 (2017)
S.P. Bugaev, E.A. Litvinov et al “Explosive emission of electrons” 18 51–61 (1975)
V.S. Beskin “Radio pulsars --- already fifty years!” 61 353–380 (2018)
M.B. Partenskii “Self-consistent electron theory of a metallic surface” 22 330–351 (1979)
M.I. Klinger “Self-trapped electron and hole states” 28 391–413 (1985)
A.L. Suvorov, V.V. Trebukhovskii “Mass analysis and field-ion microscopy” 15 471–485 (1973)
E.Ya. Zandberg, N.I. Ionov “Surface ionization” 2 255–281 (1959)
N.A. Lotova “Current ideas concerning the spectrum of the irregularities in the interplanetary plasma” 17 292–300 (1975)
I.K. Gainullin “Resonant charge transfer during ion scattering on metallic surfaces” 63 888–906 (2020)
E.M. Nadgornyĭ “The properties of whiskers” 5 462–477 (1962)
Yu.G. Abov, P.A. Krupchitskii “Parity violation in nuclear interactions” 19 75–93 (1976)
M.Yu. Kagan, A.V. Turlapov “BCS—BEC crossover, collective excitations, and hydrodynamics of superfluid quantum fluids and gases” 62 215–248 (2019)
R.A. Andrievski “High-melting point compounds: new approaches and new results” 60 276–289 (2017)
V.T. Dolgopolov “Integer quantum Hall effect and related phenomena” 57 105–127 (2014)
A.V. Eletskii, A.A. Knizhnik et al “Electrical characteristics of carbon nanotube doped composites” 58 209–251 (2015)
A.V. Eletskii “Carbon nanotubes and their emission properties” 45 369–402 (2002)

The list is formed automatically.