Field emitter array

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Silicon Carbide (SiC) Field Emitter made by NIST in 2013. It produces a flow of electrons comparable to thermionic emission but without a need for destructive heat. It was made by etching some material away to make a porous structure with a large surface area. As an electron emission point on an individual spike wears out, another is available to replace it, making the array more durable. Silicon Carbide Field Emitter (8536018059).jpg
Silicon Carbide (SiC) Field Emitter made by NIST in 2013. It produces a flow of electrons comparable to thermionic emission but without a need for destructive heat. It was made by etching some material away to make a porous structure with a large surface area. As an electron emission point on an individual spike wears out, another is available to replace it, making the array more durable.

A field emitter array (FEA) is a particular form of large-area field electron source. FEAs are prepared on a silicon substrate by lithographic techniques similar to those used in the fabrication of integrated circuits. Their structure consists of many individual, similar, small-field electron emitters, usually organized in a regular two-dimensional pattern. FEAs need to be distinguished from "film" or "mat" type large-area sources, where a thin film-like layer of material is deposited onto a substrate, using a uniform deposition process, in the hope or expectation that (as a result of statistical irregularities in the process) this film will contain a sufficiently large number of individual emission sites.

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Spindt arrays

The original field emitter array was the Spindt array, in which the individual field emitters are small sharp molybdenum cones. Each is deposited inside a cylindrical void in an oxide film, with a counterelectrode deposited on the top of the film. The counterelectrode (called the "gate") contains a separate circular aperture for each conical emitter. The device is named after Charles A. Spindt, who developed this technology at SRI International, publishing the first article describing a single emitter tip microfabricated on a wafer in 1968. [3] Spindt, Shoulders and Heynick filed a U.S. Patent [4] in 1970 for a vacuum device comprising an array of emitter tips.

Each individual cone is referred to as a Spindt tip. Because Spindt tips have sharp apices, they can generate a high local electric field using a relatively low gate voltage (less than 100 V). Using lithographic manufacturing techniques, individual emitters can be packed extremely close together, resulting in a high average (or "macroscopic") current density of up to 2×107 A/m2[ citation needed ]. Spindt-type emitters have a higher emission intensity and a more narrow angular distribution than other FEA technologies. [5]

nano-Spindt arrays

Nano-Spindt arrays represent an evolution of the traditional Spindt-type emitter. Each individual tip is several orders of magnitude smaller; as a result, gate voltages can be lower, since the distance from tip to gate is reduced. In addition, the current extracted from each individual tip is lower, which should result in improved reliability. [6]

Carbon Nanotube (CNT) arrays

An alternative form of FEA is fabricated by creating voids in an oxide film (as for a Spindt array) and then using standard methods to grow one or more carbon nanotubes (CNTs) in each void.

It is also possible to grow "free-standing" CNT arrays.

Applications

Essentially very small electron beam generators, FEAs, have been applied in many different domains. FEAs have been used to create flat panel displays (where they are known as field emission displays (or "nano-emissive displays"). They may also be used in microwave generators, and in RF communications, where they could serve as the cathode in traveling wave tubes (TWTs).

Recently, there has been renewed interest in using field effect arrays as cold cathodes in X-ray tubes. FEAs offer a number of potential advantages over conventional thermionic cathodes, including low power consumption, instantaneous switching, and independence of current and voltage.

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<span class="mw-page-title-main">Cathode-ray tube</span> Vacuum tube manipulated to display images on a phosphorescent screen

A cathode-ray tube (CRT) is a vacuum tube containing one or more electron guns, which emit electron beams that are manipulated to display images on a phosphorescent screen. The images may represent electrical waveforms (oscilloscope), pictures, radar targets, or other phenomena. A CRT on a television set is commonly called a picture tube. CRTs have also been used as memory devices, in which case the screen is not intended to be visible to an observer. The term cathode ray was used to describe electron beams when they were first discovered, before it was understood that what was emitted from the cathode was a beam of electrons.

<span class="mw-page-title-main">Cathode</span> Electrode where reduction takes place

A cathode is the electrode from which a conventional current leaves a polarized electrical device. This definition can be recalled by using the mnemonic CCD for Cathode Current Departs. A conventional current describes the direction in which positive charges move. Electrons have a negative electrical charge, so the movement of electrons is opposite to that of the conventional current flow. Consequently, the mnemonic cathode current departs also means that electrons flow into the device's cathode from the external circuit. For example, the end of a household battery marked with a + (plus) is the cathode.

<span class="mw-page-title-main">Vacuum tube</span> Device that controls current between electrodes

A vacuum tube, electron tube, valve, or tube, is a device that controls electric current flow in a high vacuum between electrodes to which an electric potential difference has been applied.

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<span class="mw-page-title-main">Cold cathode</span> Type of electrode and part of cold cathode fluorescent lamp.

A cold cathode is a cathode that is not electrically heated by a filament. A cathode may be considered "cold" if it emits more electrons than can be supplied by thermionic emission alone. It is used in gas-discharge lamps, such as neon lamps, discharge tubes, and some types of vacuum tube. The other type of cathode is a hot cathode, which is heated by electric current passing through a filament. A cold cathode does not necessarily operate at a low temperature: it is often heated to its operating temperature by other methods, such as the current passing from the cathode into the gas.

<span class="mw-page-title-main">Selectron tube</span> Early and obsolete type of computer memory

The Selectron was an early form of digital computer memory developed by Jan A. Rajchman and his group at the Radio Corporation of America (RCA) under the direction of Vladimir K. Zworykin. It was a vacuum tube that stored digital data as electrostatic charges using technology similar to the Williams tube storage device. The team was never able to produce a commercially viable form of Selectron before magnetic-core memory became almost universal.

Field electron emission, also known as field emission (FE) and electron field emission, is emission of electrons induced by an electrostatic field. The most common context is field emission from a solid surface into a vacuum. However, field emission can take place from solid or liquid surfaces, into a vacuum, a fluid, or any non-conducting or weakly conducting dielectric. The field-induced promotion of electrons from the valence to conduction band of semiconductors can also be regarded as a form of field emission. The terminology is historical because related phenomena of surface photoeffect, thermionic emission and "cold electronic emission", i.e. the emission of electrons in strong static electric fields, were discovered and studied independently from the 1880s to 1930s. When field emission is used without qualifiers it typically means "cold emission".

<span class="mw-page-title-main">Electron gun</span> Electrical component producing a narrow electron beam

An electron gun is an electrical component in some vacuum tubes that produces a narrow, collimated electron beam that has a precise kinetic energy.

<span class="mw-page-title-main">Electron-beam welding</span> Use of electrons to join metal parts via melting

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<span class="mw-page-title-main">X-ray tube</span> Vacuum tube that converts electrical input power into X-rays

An X-ray tube is a vacuum tube that converts electrical input power into X-rays. The availability of this controllable source of X-rays created the field of radiography, the imaging of partly opaque objects with penetrating radiation. In contrast to other sources of ionizing radiation, X-rays are only produced as long as the X-ray tube is energized. X-ray tubes are also used in CT scanners, airport luggage scanners, X-ray crystallography, material and structure analysis, and for industrial inspection.

<span class="mw-page-title-main">Field-emission display</span>

A field-emission display (FED) is a flat panel display technology that uses large-area field electron emission sources to provide electrons that strike colored phosphor to produce a color image. In a general sense, an FED consists of a matrix of cathode ray tubes, each tube producing a single sub-pixel, grouped in threes to form red-green-blue (RGB) pixels. FEDs combine the advantages of CRTs, namely their high contrast levels and very fast response times, with the packaging advantages of LCD and other flat-panel technologies. They also offer the possibility of requiring less power, about half that of an LCD system. FEDs can also be made transparent.

<span class="mw-page-title-main">Surface-conduction electron-emitter display</span> CRT screen

A surface-conduction electron-emitter display (SED) was a display technology for flat panel displays developed by a number of companies. SEDs used nanoscopic-scale electron emitters to energize colored phosphors and produce an image. In a general sense, a SED consists of a matrix of tiny cathode-ray tubes, each "tube" forming a single sub-pixel on the screen, grouped in threes to form red-green-blue (RGB) pixels. SEDs combine the advantages of CRTs, namely their high contrast ratios, wide viewing angles, and very fast response times, with the packaging advantages of LCD and other flat panel displays.

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<span class="mw-page-title-main">Electrodynamic tether</span> Long conducting wires which can act as electrical motors or generators

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<span class="mw-page-title-main">Hot cathode</span> Type of electrode

In vacuum tubes and gas-filled tubes, a hot cathode or thermionic cathode is a cathode electrode which is heated to make it emit electrons due to thermionic emission. This is in contrast to a cold cathode, which does not have a heating element. The heating element is usually an electrical filament heated by a separate electric current passing through it. Hot cathodes typically achieve much higher power density than cold cathodes, emitting significantly more electrons from the same surface area. Cold cathodes rely on field electron emission or secondary electron emission from positive ion bombardment, and do not require heating. There are two types of hot cathode. In a directly heated cathode, the filament is the cathode and emits the electrons. In an indirectly heated cathode, the filament or heater heats a separate metal cathode electrode which emits the electrons.

<span class="mw-page-title-main">Wehnelt cylinder</span> Electrode in the electron gun assembly of some thermionic devices

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Akintunde Ibitayo Akinwande is a Nigerian American engineering professor at the Electrical Engineering and Computer Science Department of Massachusetts Institute of Technology. He was appointed as chairman of Nigerian Electricity Regulatory Commission, NERC, and he said he will honour his appointment once he secure permission from his employers.

Vertically aligned carbon nanotube arrays (VANTAs) are a unique microstructure consisting of carbon nanotubes oriented with their longitudinal axis perpendicular to a substrate surface. These VANTAs effectively preserve and often accentuate the unique anisotropic properties of individual carbon nanotubes and possess a morphology that may be precisely controlled. VANTAs are consequently widely useful in a range of current and potential device applications.

References

  1. swenson (2013-03-05). "New Player in Electron Field Emitter Technology Makes for Better Imaging and Communications". NIST. Retrieved 2021-08-21.
  2. "Silicon Carbide Field Emitter". NIST. Retrieved 2021-08-21.
  3. Spindt, C. A. (1968). "A Thin‐Film Field‐Emission Cathode". Journal of Applied Physics. AIP Publishing. 39 (7): 3504–3505. doi:10.1063/1.1656810. ISSN   0021-8979.
  4. U.S. Patent 3,755,704 granted on August 28, 1973
  5. Spindt, C. A.; Brodie, I.; Humphrey, L.; Westerberg, E. R. (1976). "Physical properties of thin‐film field emission cathodes with molybdenum cones". Journal of Applied Physics. AIP Publishing. 47 (12): 5248–5263. doi:10.1063/1.322600. ISSN   0021-8979.
  6. Scaduto, David A.; Lubinsky, Anthony R.; Rowlands, John A.; Kenmotsu, Hidenori; Nishimoto, Norihito; et al. (2014-03-19). Investigation of spatial resolution and temporal performance of SAPHIRE (scintillator avalanche photoconductor with high resolution emitter readout) with integrated electrostatic focusing. Vol. 9033. SPIE. p. S-1. doi:10.1117/12.2043187.

See also