Direct excitation of xenon by ballistic electrons emitted from nanocrystalline‐silicon planar cathode and vacuum‐ultraviolet light emission

Ichihara, Tsutomu; Hatai, Takashi; Koshida, Nobuyoshi

doi:10.1889/jsid18.3.223

Cited by 12 publications

(2 citation statements)

References 7 publications

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“…One of the most important devices based on the PS is the cold cathode electron emitter, which has significant advantages including a relatively simple structure, general processing, low operation voltage, ballistic emission, and insensitivity to gas pressure and gas species when emitting electrons [6]. Utilizing these advantages, applicability to vacuum-type flat panel displays [7], electron beam lithography [8],…”

Section: Introductionmentioning

confidence: 99%

Improved electron emission properties of the porous silicon emitter by chemical surface modification

Wang¹,

He²,

Zhang³

et al. 2017

Semicond. Sci. Technol.

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A new chemical dipping method using nickel chloride (NiCl 2 ) solution is proposed to improve the characteristics of an electron emitter based on porous silicon (PS). Two groups of PS samples were prepared, one group was then left untreated, while the other group was treated by the chemical dipping method. Energy dispersive x-ray (EDX) and x-ray photoemission spectroscopy (XPS) studies confirm the uniform filling of the reduced Ni and the formation of the SiO 2 in the chemically dipped sample. The gold electrode was sputtered on the modified PS surface and the study of J-V characteristics show that the modified samples have more favorable rectifying behavior and longer-term durability than the unmodified one. The measured results showed that the voltage threshold ∼8 V, PVCR value ∼1.08, emission current density ∼48 μA cm −2 , emission efficiency ∼0.72%, and stable emission were achieved for the modified sample; most of these electron emission characteristics were better than those from the unmodified emitter. Such improvements are mainly due to the decrease of the contact barrier height between the PS and the gold electrode, as is evident from analyzing the logarithmic J-V characteristics. The chemical dipping method is therefore expected to be a valuable technique to enhance the electron emission characteristics of the PS emitter.

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Section: Introductionmentioning

confidence: 99%

Improved electron emission properties of the porous silicon emitter by chemical surface modification

Wang¹,

He²,

Zhang³

et al. 2017

Semicond. Sci. Technol.

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“…In comparison with conventional cold cathodes, there are some advantageous features in this emitter: extremely high mean energies of as-emitted electrons (5-7 eV at an applied voltage of 15-20 V), 4 surface emissivity with a small angle dispersion (±10 • to the surface normal), 7 low sensitivity of emission to ambient pressure, and compatibility with planar process for device fabrication and with active-matrix drive. The usefulness of the nc-Si emitter has been demonstrated in vacuum (parallel electron beam (EB) lithography), 7 in atmospheric-pressure gases (VUV emission from Xe atoms), 8 and in aqueous solutions (H 2 generation). 9,10 When the nc-Si emitter is driven in metal salt solutions, ballistic hot electrons induces the reductive reaction leading to the deposition of thin metal films.…”

mentioning

confidence: 99%

Reductive Deposition of Thin Cu Films Using Ballistic Hot Electrons as a Printing Beam

Suda

Yagi

Kojima

et al. 2016

J. Electrochem. Soc.

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Alternative deposition of thin solid films is demonstrated using a nanocrystalline silicon ballistic electron emitter. Emitted ballistic hot electrons impinge upon a CuCl2-solution-coated Si substrate that is located in proximity close to the emitter. It is shown from spectroscopic characterizations that thin Cu films are deposited onto the target substrate with no contaminations. As-emitted ballistic hot electrons with energies of 5–7 eV promote preferential reduction of Cu2+ ions within the penetration depth in the solution followed by the nuclei formation for growth of thin film. The presented printing scheme is also available for oxidized Si substrates. The direct reduction model is supported separately by cyclic voltammetry analyses on the reducing activity of ballistic electrons.

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Porous Silicon Ballistic Hot Electron Emitter

Koshida¹

2016

Handbook of Porous Silicon

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Direct excitation of xenon by ballistic electrons emitted from nanocrystalline‐silicon planar cathode and vacuum‐ultraviolet light emission

Cited by 12 publications

References 7 publications

Improved electron emission properties of the porous silicon emitter by chemical surface modification

Improved electron emission properties of the porous silicon emitter by chemical surface modification

Reductive Deposition of Thin Cu Films Using Ballistic Hot Electrons as a Printing Beam

Porous Silicon Ballistic Hot Electron Emitter

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