Low-power X-ray tubes: the current status

A.S. Bugaev^a, b, P.A. Eroshkin^a, V.A. Romanko^c, E.P. Sheshin^a
^aMoscow Institute of Physics and Technology (National Research University), Institutskii per. 9, Dolgoprudny, Moscow Region, 141701, Russian Federation
^bKotel'nikov Institute of Radio Engineering and Electronics, Russian Academy of Sciences, ul. Mokhovaya 11, kor. 7, Moscow, 125009, Russian Federation
^cVekshinsky State Research Institute of Vacuum Technology, Nagornyi proezd 7, Moscow, 117105, Russian Federation

The principles and designs of X-ray tubes are discussed. Historical highlights and the current status of X-ray technology are reviewed and prospects for its improvement are outlined. A comparison of the properties of X-ray tubes with those of hot cathodes and field-emission cathodes is given.

PACS: 07.85.Fv, 41.50.+h, 79.70.+q (all)
DOI: 10.3367/UFNe.0183.201307c.0727
URL: https://ufn.ru/en/articles/2013/7/c/
Web of Science

000325716100003
Scopus

2-s2.0-84886066974
ADS NASA

2013PhyU...56..691B
Citation: Bugaev A S, Eroshkin P A, Romanko V A, Sheshin E P "Low-power X-ray tubes: the current status" Phys. Usp. 56 691–703 (2013)

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Received: 22nd, March 2012, accepted: 11th, December 2012

Оригинал: Бугаев А С, Ерошкин П А, Романько В А, Шешин Е П «Маломощные рентгеновские трубки (современное состояние)» УФН 183 727–740 (2013); DOI: 10.3367/UFNr.0183.201307c.0727

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A.S. Bugaev, V.B. Kireev et al “Cathodoluminescent light sources: status and prospects” 58 792–818 (2015)
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M.M. Barysheva, A.E. Pestov et al “Precision imaging multilayer optics for soft X-rays and extreme ultraviolet bands” 55 681–699 (2012)
V.V. Lider “X-ray microscopy” 60 187–203 (2017)
V.V. Lider “Talbot and Talbot—Lau X-ray interferometers” 66 987–1007 (2023)
V.A. Belyakov, V.E. Dmitrienko “Polarization phenomena in x-ray optics” 32 697–719 (1989)
V.A. Arkad’ev, A.I. Kolomiitsev et al “Wide-band x-ray optics with a large angular aperture” 32 271–276 (1989)
V.V. Lider “X-ray crystal interferometers” 57 1099–1117 (2014)
E.N. Ragozin, E.A. Vishnyakov et al “Soft X-ray spectrometers based on aperiodic reflection gratings and their application” 64 495–514 (2021)
M.D. Gabovich “Liquid-metal ion emitters” 26 447–455 (1983)
V.V. Lider “X-ray refraction introscopy” 67 (4) (2024)
Ya.S. Greenberg, Yu.A. Pashkin, E. Il’ichev “Nanomechanical resonators” 55 382–407 (2012)
N.M. Blashenkov, G.Ya. Lavrent’ev “Surface-ionization field mass-spectrometry studies of nonequilibrium surface ionization” 50 53–78 (2007)
S.A. Barengolts, G.A. Mesyats “Explosive emission processes in thermonuclear facilities with magnetic plasma confinement and in linear electron—positron colliders” 66 704–721 (2023)
A.I. Vorob’eva “Equipment and techniques for carbon nanotube research” 53 257–277 (2010)
A.E. Dubinov, L.A. Mytareva “Invisible cloaking of material bodies using the wave flow method” 53 455–479 (2010)
G.R. Ivanitskii “Modern matrix thermovision in biomedicine” 49 1263–1288 (2006)
M.A. Proskurnin, V.R. Khabibullin et al “Photothermal and optoacoustic spectroscopy: state of the art and prospects” 65 270–312 (2022)
D.A. Zolotov, V.E. Asadchikov et al “New approaches to three-dimensional dislocation reconstruction in silicon from X-ray topo-tomography data” 66 943–950 (2023)

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