Stabilization of field electron emission from carbon nanofibers using ballast resistance

Kita, S.; Sakai, Yusuke; Endo, Toyoshi; Sugimoto, Wataru; Goto, Hideto

doi:10.1116/1.3700237

Cited by 4 publications

(4 citation statements)

References 17 publications

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“…Further improvements can be achieved by introducing a ballast resistance in series with the extraction voltage [104]. Kita et al [105] have investigated the stabilization of the FE current by using a ballast resistance in the range from 1 to 1500 MΩ at an emission current of 1 to 100 µA. They demonstrated excellent stability where the ratio (∆I/I) of the current fluctuation with respect the absolute current was as small as 0.0018, using 10 MΩ ballast resistance on an average current of about 80 µA.…”

Section: Emission From Cnt Filmsmentioning

confidence: 99%

Field Emission from Carbon Nanostructures

et al. 2018

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Field emission electron sources in vacuum electronics are largely considered to achieve faster response, higher efficiency and lower energy consumption in comparison with conventional thermionic emitters. Carbon nanotubes had a leading role in renewing attention to field emission technologies in the early 1990s, due to their exceptional electron emitting properties enabled by their large aspect ratio, high electrical conductivity, and thermal and chemical stability. In the last decade, the search for improved emitters has been extended to several carbon nanostructures, comprising carbon nanotubes, either individual or films, diamond structures, graphitic materials, graphene, etc. Here, we review the main results in the development of carbon-based field emitters.

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Section: Emission From Cnt Filmsmentioning

confidence: 99%

Field Emission from Carbon Nanostructures

et al. 2018

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“…Moreover, we have tried to estimate the reliability of HTE CNT field emitters in the triode configuration in the very harsh environment of a tiny vacuum-sealed vessel without any active vacuum pump. In most studies on field electron emitters the performance has been evaluated using the diode configuration in a chamber evacuated continuously by active vacuum pumps, such as turbo molecular pumps and ion pumps [37][38][39][40], which is an even friendlier environment than real field emission devices, including miniature x-ray tubes, encounter. Although field emitters in a diode structure can be easily implemented, the field emission current and the acceleration voltage are coupled to each other by the anode voltage, limiting their controllability and thus their applications.…”

Section: Resultsmentioning

confidence: 99%

Highly reliable field electron emitters produced from reproducible damage-free carbon nanotube composite pastes with optimal inorganic fillers

Kim¹,

Jeong²,

Kang³

et al. 2014

Nanotechnology

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Highly reliable field electron emitters were developed using a formulation for reproducible damage-free carbon nanotube (CNT) composite pastes with optimal inorganic fillers and a ball-milling method. We carefully controlled the ball-milling sequence and time to avoid any damage to the CNTs, which incorporated fillers that were fully dispersed as paste constituents. The field electron emitters fabricated by printing the CNT pastes were found to exhibit almost perfect adhesion of the CNT emitters to the cathode, along with good uniformity and reproducibility. A high field enhancement factor of around 10,000 was achieved from the CNT field emitters developed. By selecting nano-sized metal alloys and oxides and using the same formulation sequence, we also developed reliable field emitters that could survive high-temperature post processing. These field emitters had high durability to post vacuum annealing at 950 °C, guaranteeing survival of the brazing process used in the sealing of field emission x-ray tubes. We evaluated the field emitters in a triode configuration in the harsh environment of a tiny vacuum-sealed vessel and observed very reliable operation for 30 h at a high current density of 350 mA cm(-2). The CNT pastes and related field emitters that were developed could be usefully applied in reliable field emission devices.

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“…This techique permits one to regulate the anode potential using the voltage drop at a resistance put in series in the electron-extacting circuit. Using ballast resistance, Kita et al [45] recently succeeded in stabilizing electron currents field-emitted from carbon nanofibers. Due to its simplicity, their method is far more practical than the current feedback.…”

Section: Proposalsmentioning

confidence: 99%

Miniature x-ray tubes: current state and future prospects

Filip¹,

Filip²,

Okuyama³

2013

J. Inst.

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Over the last decade, field emission miniature x-ray tubes emerged as cutting-edge applications of nanotechnology, possessing massive potential for use in various important fields, including that of precision medical therapy. The article essentially presents a review of such new devices reported in the literature. Additional discussions on the necessity of stabilizing the electron beam that generates x-rays are also included, and a simple technique for minimizing the current fluctuations is described. It is also pointed out that further miniaturization of field emission x-ray sources may need new concepts in designing the tube in shapes acting as "self focusing" structures for the electron beams. KEYWORDS: X-ray generators and sources; Radiotherapy concepts; X-ray radiography and digital radiography (DR)

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Stabilization of field electron emission from carbon nanofibers using ballast resistance

Cited by 4 publications

References 17 publications

Field Emission from Carbon Nanostructures

Field Emission from Carbon Nanostructures

Highly reliable field electron emitters produced from reproducible damage-free carbon nanotube composite pastes with optimal inorganic fillers

Miniature x-ray tubes: current state and future prospects

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