Silicon carbide

(Redirected from SiC)

Silicon carbide (SiC), also known as carborundum (/ˌkɑːrbəˈrʌndəm/), is a hard chemical compound containing silicon and carbon. A wide bandgap semiconductor, it occurs in nature as the extremely rare mineral moissanite, but has been mass-produced as a powder and crystal since 1893 for use as an abrasive. Grains of silicon carbide can be bonded together by sintering to form very hard ceramics that are widely used in applications requiring high endurance, such as car brakes, car clutches and ceramic plates in bulletproof vests. Large single crystals of silicon carbide can be grown by the Lely method and they can be cut into gems known as synthetic moissanite.

Silicon carbide
Sample of silicon carbide as a boule
A laboratory-grown synthetic SiC monocrystal
Names
IUPAC name
Methanidylidynesilanylium
Preferred IUPAC name
Silicon carbide
Other names
Carborundum
Moissanite
Identifiers
3D model (JSmol)
ChEBI
ChemSpider
ECHA InfoCard 100.006.357 Edit this at Wikidata
EC Number
  • 206-991-8
13642
MeSH Silicon+carbide
RTECS number
  • VW0450000
UNII
  • InChI=1S/CSi/c1-2 checkY
    Key: HBMJWWWQQXIZIP-UHFFFAOYSA-N checkY
  • Key: HBMJWWWQQXIZIP-UHFFFAOYAF
  • InChI=1/CSi/c1-2
  • [C-]#[Si+]
Properties
SiC
Molar mass 40.096 g/mol
Appearance Yellow to green to bluish-black, iridescent crystals[1]
Density 3.16 g⋅cm-3 (hex.)[2]
Melting point 2,830 °C (5,130 °F; 3,100 K)[2] (decomposes)
Solubility Insoluble in water, soluble in molten alkalis and molten iron[3]
Electron mobility ~900 cm2/(V⋅s) (all polytypes)
−12.8 × 10−6 cm3/mol[4]
2.55 (infrared; all polytypes)[5]
Hazards
GHS labelling:fibres[6]
GHS08: Health hazard
Danger
H350i
P201, P202, P260, P261, P264, P270, P271, P280, P281, P302+P352, P304+P340, P305+P351+P338, P308+P313, P312, P314, P321, P332+P313, P337+P313, P362, P403+P233, P405, P501
NFPA 704 (fire diamond)
NFPA 704 four-colored diamondHealth 1: Exposure would cause irritation but only minor residual injury. E.g. turpentineFlammability 0: Will not burn. E.g. waterInstability 0: Normally stable, even under fire exposure conditions, and is not reactive with water. E.g. liquid nitrogenSpecial hazards (white): no code
1
0
0
NIOSH (US health exposure limits):
PEL (Permissible)
TWA 15 mg/m3 (total) TWA 5 mg/m3 (resp)[1]
REL (Recommended)
TWA 10 mg/m3 (total) TWA 5 mg/m3 (resp)[1]
IDLH (Immediate danger)
N.D.[1]
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
checkY verify (what is checkY☒N ?)

Electronic applications of silicon carbide such as light-emitting diodes (LEDs) and detectors in early radios were first demonstrated around 1907. SiC is used in semiconductor electronics devices that operate at high temperatures or high voltages, or both.

Natural occurrence

edit
 
Moissanite single crystal (≈ 1 mm in size)

Naturally occurring moissanite is found in only minute quantities in certain types of meteorite, corundum deposits, and kimberlite. Virtually all the silicon carbide sold in the world, including moissanite jewels, is synthetic.

Natural moissanite was first found in 1893 as a small component of the Canyon Diablo meteorite in Arizona by Ferdinand Henri Moissan, after whom the material was named in 1905.[7] Moissan's discovery of naturally occurring SiC was initially disputed because his sample may have been contaminated by silicon carbide saw blades that were already on the market at that time.[8]

While rare on Earth, silicon carbide is remarkably common in space. It is a common form of stardust found around carbon-rich stars, and examples of this stardust have been found in pristine condition in primitive (unaltered) meteorites. The silicon carbide found in space and in meteorites is almost exclusively the beta-polymorph. Analysis of SiC grains found in the Murchison meteorite, a carbonaceous chondrite meteorite, has revealed anomalous isotopic ratios of carbon and silicon, indicating that these grains originated outside the solar system.[9]

History

edit

Early experiments

edit

Non-systematic, less-recognized and often unverified syntheses of silicon carbide include:

  • César-Mansuète Despretz's passing an electric current through a carbon rod embedded in sand (1849)
  • Robert Sydney Marsden's dissolution of silica in molten silver in a graphite crucible (1881)
  • Paul Schuetzenberger's heating of a mixture of silicon and silica in a graphite crucible (1881)
  • Albert Colson's heating of silicon under a stream of ethylene (1882).[10]

Wide-scale production

edit
 
A replication of H.J. Round's LED experiments

Wide-scale production is credited to Edward Goodrich Acheson in 1891.[11] Acheson was attempting to prepare artificial diamonds when he heated a mixture of clay (aluminium silicate) and powdered coke (carbon) in an iron bowl. He called the blue crystals that formed carborundum, believing it to be a new compound of carbon and aluminium, similar to corundum. Moissan also synthesized SiC by several routes, including dissolution of carbon in molten silicon, melting a mixture of calcium carbide and silica, and by reducing silica with carbon in an electric furnace.

Acheson patented the method for making silicon carbide powder on February 28, 1893.[12] Acheson also developed the electric batch furnace by which SiC is still made today and formed the Carborundum Company to manufacture bulk SiC, initially for use as an abrasive.[13] In 1900 the company settled with the Electric Smelting and Aluminum Company when a judge's decision gave "priority broadly" to its founders "for reducing ores and other substances by the incandescent method".[14]

The first use of SiC was as an abrasive. This was followed by electronic applications. In the beginning of the 20th century, silicon carbide was used as a detector in the first radios.[15] In 1907 Henry Joseph Round produced the first LED by applying a voltage to a SiC crystal and observing yellow, green and orange emission at the cathode. The effect was later rediscovered by O.V. Losev in the Soviet Union, in 1923.[16]

Production

edit
 
Synthetic SiC crystals ~3 mm in diameter
 
Two six-inch (≈ 15 cm) wafers made of silicon carbide

Because natural moissanite is extremely scarce, most silicon carbide is synthetic. Silicon carbide is used as an abrasive, as well as a semiconductor and diamond simulant of gem quality. The simplest process to manufacture silicon carbide is to combine silica sand and carbon in an Acheson graphite electric resistance furnace at a high temperature, between 1,600 °C (2,910 °F) and 2,500 °C (4,530 °F). Fine SiO2 particles in plant material (e.g. rice husks) can be converted to SiC by heating in the excess carbon from the organic material.[17] The silica fume, which is a byproduct of producing silicon metal and ferrosilicon alloys, can also be converted to SiC by heating with graphite at 1,500 °C (2,730 °F).[18]

The material formed in the Acheson furnace varies in purity, according to its distance from the graphite resistor heat source. Colorless, pale yellow and green crystals have the highest purity and are found closest to the resistor. The color changes to blue and black at greater distance from the resistor, and these darker crystals are less pure. Nitrogen and aluminium are common impurities, and they affect the electrical conductivity of SiC.[19]

 
Synthetic SiC Lely crystals

Pure silicon carbide can be made by the Lely process,[20] in which SiC powder is sublimed into high-temperature species of silicon, carbon, silicon dicarbide (SiC2), and disilicon carbide (Si2C) in an argon gas ambient at 2,500 °C and redeposited into flake-like single crystals,[21] sized up to 2 × 2 cm, at a slightly colder substrate. This process yields high-quality single crystals, mostly of 6H-SiC phase (because of high growth temperature).

A modified Lely process involving induction heating in graphite crucibles yields even larger single crystals of 4 inches (10 cm) in diameter, having a section 81 times larger compared to the conventional Lely process.[22]

Cubic SiC is usually grown by the more expensive process of chemical vapor deposition (CVD) of silane, hydrogen and nitrogen.[19][23] Homoepitaxial and heteroepitaxial SiC layers can be grown employing both gas and liquid phase approaches.[24]

To form complexly shaped SiC, preceramic polymers can be used as precursors which form the ceramic product through pyrolysis at temperatures in the range 1,000–1,100 °C.[25] Precursor materials to obtain silicon carbide in such a manner include polycarbosilanes, poly(methylsilyne) and polysilazanes.[26] Silicon carbide materials obtained through the pyrolysis of preceramic polymers are known as polymer derived ceramics or PDCs. Pyrolysis of preceramic polymers is most often conducted under an inert atmosphere at relatively low temperatures. Relative to the CVD process, the pyrolysis method is advantageous because the polymer can be formed into various shapes prior to thermalization into the ceramic.[27][28][29][30]

SiC can also be made into wafers by cutting a single crystal either using a diamond wire saw or by using a laser. SiC is a useful semiconductor used in power electronics.[31]

Structure and properties

edit
Structure of major SiC polytypes.
 
 
 
(β)3C-SiC 4H-SiC (α)6H-SiC
 
Silicon carbide, image taken under a stereoscopic microscope.

Silicon carbide exists in about 250 crystalline forms.[32] Through inert atmospheric pyrolysis of preceramic polymers, silicon carbide in a glassy amorphous form is also produced.[33] The polymorphism of SiC is characterized by a large family of similar crystalline structures called polytypes. They are variations of the same chemical compound that are identical in two dimensions and differ in the third. Thus, they can be viewed as layers stacked in a certain sequence.[34]

Alpha silicon carbide (α-SiC) is the most commonly encountered polymorph, and is formed at temperatures greater than 1,700 °C and has a hexagonal crystal structure (similar to Wurtzite). The beta modification (β-SiC), with a zinc blende crystal structure (similar to diamond), is formed at temperatures below 1,700 °C.[35] Until recently, the beta form has had relatively few commercial uses, although there is now increasing interest in its use as a support for heterogeneous catalysts, owing to its higher surface area compared to the alpha form.

Properties of major SiC polytypes[5][27]
Polytype 3C (β) 4H 6H (α)
Crystal structure Zinc blende (cubic) Hexagonal Hexagonal
Space group T2d-F43m C46v-P63mc C46v-P63mc
Pearson symbol cF8 hP8 hP12
Lattice constants (Å) 4.3596 3.0730; 10.053 3.0810; 15.12
Density (g/cm3) 3.21 3.21 3.21
Bandgap (eV) 2.36 3.23 3.05
Bulk modulus (GPa) 250 220 220
Thermal conductivity (W⋅m−1⋅K−1)
@300 K (see [36][37] for temp. dependence)
320 348 325
Thermal Expansion Coefficient (10−6 K−1)
@300 K (see [38] for temp. dependence)
-- 2.28 (⊥ c); 2.49 (∥ c) 2.25

Pure SiC is colorless. The brown to black color of the industrial product results from iron impurities.[39] The rainbow-like luster of the crystals is due to the thin-film interference of a passivation layer of silicon dioxide that forms on the surface.

The high sublimation temperature of SiC (approximately 2,700 °C) makes it useful for bearings and furnace parts. Silicon carbide does not melt but begins to sublimate near 2,700 °C like graphite, having an appreciable vapor pressure near that temp. It is also highly inert chemically, partly due to the formation of a thin passivated layer of SiO2. There is currently much interest in its use as a semiconductor material in electronics, where its high thermal conductivity, high electric field breakdown strength and high maximum current density make it more promising than silicon for high-powered devices.[40] SiC has a very low coefficient of thermal expansion of about 2.3 × 10−6 K−1 near 300 K (for 4H and 6H SiC) and experiences no phase transitions in the temperature range 5 K to 340 K that would cause discontinuities in the thermal expansion coefficient.[19][38]

Electrical conductivity

edit

Silicon carbide is a semiconductor, which can be doped n-type by nitrogen or phosphorus and p-type by beryllium, boron, aluminium, or gallium.[5] Metallic conductivity has been achieved by heavy doping with boron, aluminium or nitrogen.

Superconductivity has been detected in 3C-SiC:Al, 3C-SiC:B and 6H-SiC:B at similar temperatures ~1.5 K.[35][41] A crucial difference is however observed for the magnetic field behavior between aluminium and boron doping: 3C-SiC:Al is type-II. In contrast, 3C-SiC:B is type-I, as is 6H-SiC:B. Thus the superconducting properties seem to depend more on dopant (B vs. Al) than on polytype (3C- vs 6H-). In an attempt to explain this dependence, it was noted that B substitutes at C sites in SiC, but Al substitutes at Si sites. Therefore, Al and B "see" different environments, in both polytypes.[42]

Uses

edit

Abrasive and cutting tools

edit
 
Cutting disks made of SiC

In the arts, silicon carbide is a popular abrasive in modern lapidary due to the durability and low cost of the material. In manufacturing, it is used for its hardness in abrasive machining processes such as grinding, honing, water-jet cutting and sandblasting. SiC provides a much sharper and harder alternative for sand blasting as compared to aluminium oxide. Particles of silicon carbide are laminated to paper to create sandpapers and the grip tape on skateboards.[43]

In 1982 an exceptionally strong composite of aluminium oxide and silicon carbide whiskers was discovered. Development of this laboratory-produced composite to a commercial product took only three years. In 1985, the first commercial cutting tools made from this alumina and silicon carbide whisker-reinforced composite were introduced into the market.[44]

Structural material

edit
 
Silicon carbide is used for trauma plates of ballistic vests

In the 1980s and 1990s, silicon carbide was studied in several research programs for high-temperature gas turbines in Europe, Japan and the United States. The components were intended to replace nickel superalloy turbine blades or nozzle vanes.[45] However, none of these projects resulted in a production quantity, mainly because of its low impact resistance and its low fracture toughness.[46]

Like other hard ceramics (namely alumina and boron carbide), silicon carbide is used in composite armor (e.g. Chobham armor), and in ceramic plates in bulletproof vests. Dragon Skin, which was produced by Pinnacle Armor, used disks of silicon carbide.[47] Improved fracture toughness in SiC armor can be facilitated through the phenomenon of abnormal grain growth or AGG. The growth of abnormally long silicon carbide grains may serve to impart a toughening effect through crack-wake bridging, similar to whisker reinforcement. Similar AGG-toughening effects have been reported in Silicon nitride (Si3N4).[48]

Silicon carbide is used as a support and shelving material in high temperature kilns such as for firing ceramics, glass fusing, or glass casting. SiC kiln shelves are considerably lighter and more durable than traditional alumina shelves.[49]

In December 2015, infusion of silicon carbide nano-particles in molten magnesium was mentioned as a way to produce a new strong and plastic alloy suitable for use in aeronautics, aerospace, automobile and micro-electronics.[50]

Automobile parts

edit
 
The Porsche Carrera GT's silicon carbide "carbon-ceramic" disc brake

Silicon-infiltrated carbon-carbon composite is used for high performance "ceramic" brake discs, as they are able to withstand extreme temperatures. The silicon reacts with the graphite in the carbon-carbon composite to become carbon-fiber-reinforced silicon carbide (C/SiC). These brake discs are used on some road-going sports cars, supercars, as well as other performance cars including the Porsche Carrera GT, the Bugatti Veyron, the Chevrolet Corvette ZR1, the McLaren P1,[51] Bentley, Ferrari, Lamborghini and some specific high-performance Audi cars. Silicon carbide is also used in a sintered form for diesel particulate filters.[52] It is also used as an oil additive[dubiousdiscuss][clarification needed] to reduce friction, emissions, and harmonics.[53][54]

Foundry crucibles

edit

SiC is used in crucibles for holding melting metal in small and large foundry applications.[55][56]

Electric systems

edit

The earliest electrical application of SiC was as a surge protection in lightning arresters in electric power systems. These devices must exhibit high resistance until the voltage across them reaches a certain threshold VT at which point their resistance must drop to a lower level and maintain this level until the applied voltage drops below VT flushing current into the ground.[57]

It was recognized early on[when?] that SiC had such a voltage-dependent resistance, and so columns of SiC pellets were connected between high-voltage power lines and the earth. When a lightning strike to the line raises the line voltage sufficiently, the SiC column will conduct, allowing strike current to pass harmlessly to the earth instead of along the power line. The SiC columns proved to conduct significantly at normal power-line operating voltages and thus had to be placed in series with a spark gap. This spark gap is ionized and rendered conductive when lightning raises the voltage of the power line conductor, thus effectively connecting the SiC column between the power conductor and the earth. Spark gaps used in lightning arresters are unreliable, either failing to strike an arc when needed or failing to turn off afterwards, in the latter case due to material failure or contamination by dust or salt. Usage of SiC columns was originally intended to eliminate the need for the spark gap in lightning arresters. Gapped SiC arresters were used for lightning-protection and sold under the GE and Westinghouse brand names, among others. The gapped SiC arrester has been largely displaced by no-gap varistors that use columns of zinc oxide pellets.[58]

Electronic circuit elements

edit

Silicon carbide was the first commercially important semiconductor material. A crystal radio "carborundum" (synthetic silicon carbide) detector diode was patented by Henry Harrison Chase Dunwoody in 1906. It found much early use in shipboard receivers.

Power electronic devices

edit

In 1993, the silicon carbide was considered a semiconductor in both research and early mass production providing advantages for fast, high-temperature and/or high-voltage devices. The first devices available were Schottky diodes, followed by junction-gate FETs and MOSFETs for high-power switching. Bipolar transistors and thyristors were described.[40]

A major problem for SiC commercialization has been the elimination of defects: edge dislocations, screw dislocations (both hollow and closed core), triangular defects and basal plane dislocations.[59] As a result, devices made of SiC crystals initially displayed poor reverse blocking performance, though researchers have been tentatively finding solutions to improve the breakdown performance.[60] Apart from crystal quality, problems with the interface of SiC with silicon dioxide have hampered the development of SiC-based power MOSFETs and insulated-gate bipolar transistors. Although the mechanism is still unclear, nitriding has dramatically reduced the defects causing the interface problems.[61]

In 2008, the first commercial JFETs rated at 1,200 V were introduced to the market,[62] followed in 2011 by the first commercial MOSFETs rated at 1200 V. JFETs are now available rated 650 V to 1,700 V with resistance as low as 25 mΩ. Beside SiC switches and SiC Schottky diodes (also Schottky barrier diode, SBD) in the popular TO-247 and TO-220 packages, companies started even earlier to implement the bare chips into their power electronic modules.

SiC SBD diodes found wide market spread being used in PFC circuits and IGBT power modules.[63] Conferences such as the International Conference on Integrated Power Electronics Systems (CIPS) report regularly about the technological progress of SiC power devices. Major challenges for fully unleashing the capabilities of SiC power devices are:

  • Gate drive: SiC devices often require gate drive voltage levels that are different from their silicon counterparts and may be even unsymmetric, for example, +20 V and −5 V.[64]
  • Packaging: SiC chips may have a higher power density than silicon power devices and are able to handle higher temperatures exceeding the silicon limit of 150 °C. New die attach technologies such as sintering are required to efficiently get the heat out of the devices and ensure a reliable interconnection.[65]

Beginning with Tesla Model 3 the inverters in the drive unit use 24 pairs of silicon carbide (SiC) MOSFET chips rated for 650 volts each. Silicon carbide in this instance gave Tesla a significant advantage over chips made of silicon in terms of size and weight. A number of automobile manufacturers are planning to incorporate silicon carbide into power electronic devices in their products. A significant increase in production of silicon carbide is projected, beginning with a large plant opened 2022 by Wolfspeed, in upstate New York.[66][67]

 
Ultraviolet LED (based on InGaN)

LEDs

edit

The phenomenon of electroluminescence was discovered in 1907 using silicon carbide and some of the first commercial LEDs were based on this material. When General Electric of America introduced its SSL-1 Solid State Lamp in March 1967, using a tiny chip of semi-conducting SiC to emit a point of yellow light, it was then the world's brightest LED.[68] By 1970 it had been usurped by brighter red LEDs, but yellow LEDs made from 3C-SiC continued to be manufactured in the Soviet Union in the 1970s[69] and blue LEDs (6H-SiC) worldwide in the 1980s.[70]

Carbide LED production soon stopped when a different material, gallium nitride, showed 10–100 times brighter emission. This difference in efficiency is due to the unfavorable indirect bandgap of SiC, whereas GaN has a direct bandgap which favors light emission. However, SiC is still one of the important LED components: It is a popular substrate for growing GaN devices, and it also serves as a heat spreader in high-power LEDs.[70]

Astronomy

edit

The low thermal expansion coefficient,[38] high hardness, rigidity and thermal conductivity make silicon carbide a desirable mirror material for astronomical telescopes. The growth technology (chemical vapor deposition) has been scaled up to produce disks of polycrystalline silicon carbide up to 3.5 m (11 ft) in diameter, and several telescopes like the Herschel Space Telescope are already equipped with SiC optics,[71][72] as well the Gaia space observatory spacecraft subsystems are mounted on a rigid silicon carbide frame, which provides a stable structure that will not expand or contract due to heat.

Thin-filament pyrometry

edit
 
Test flame and glowing SiC fibers. The flame is about 7 cm (2.8 in) tall.

Silicon carbide fibers are used to measure gas temperatures in an optical technique called thin-filament pyrometry. It involves the placement of a thin filament in a hot gas stream. Radiative emissions from the filament can be correlated with filament temperature. Filaments are SiC fibers with a diameter of 15 micrometers, about one fifth that of a human hair. Because the fibers are so thin, they do little to disturb the flame and their temperature remains close to that of the local gas. Temperatures of about 800–2,500 K can be measured.[73][74]

Heating elements

edit

References to silicon carbide heating elements exist from the early 20th century when they were produced by Acheson's Carborundum Co. in the U.S. and EKL in Berlin. Silicon carbide offered increased operating temperatures compared with metallic heaters. Silicon carbide elements are used today in the melting of glass and non-ferrous metal, heat treatment of metals, float glass production, production of ceramics and electronics components, igniters in pilot lights for gas heaters, etc.[75]

Heat shielding

edit

The outer thermal protection layer of NASA's LOFTID inflatable heat shield incorporates a woven ceramic made from silicon carbide, with fiber of such small diameter that it can be bundled and spun into a yarn.[76]

Nuclear applications

edit

Due to SiC's exceptional neutron absorption capability, it is used as fuel cladding in nuclear reactors and as nuclear waste containment material.[77] It is also used in producing radiation detectors for monitoring radiation levels in nuclear facilities, environmental monitoring, and medical imaging.[78] Again, SiC sensors and electronics for nuclear reactor applications are being developed potentially for future Martian nuclear power and the emerging terrestrial micro nuclear power plants.[79]

Nuclear fuel particles and cladding

edit

Silicon carbide is an important material in TRISO-coated fuel particles, the type of nuclear fuel found in high temperature gas cooled reactors such as the Pebble Bed Reactor. A layer of silicon carbide gives coated fuel particles structural support and is the main diffusion barrier to the release of fission products.[80]

Silicon carbide composite material has been investigated for use as a replacement for Zircaloy cladding in light water reactors. One of the reasons for this investigation is that, Zircaloy experiences hydrogen embrittlement as a consequence of the corrosion reaction with water. This produces a reduction in fracture toughness with increasing volumetric fraction of radial hydrides. This phenomenon increases drastically with increasing temperature to the detriment of the material.[81] Silicon carbide cladding does not experience this same mechanical degradation, but instead retains strength properties with increasing temperature. The composite consists of SiC fibers wrapped around a SiC inner layer and surrounded by an SiC outer layer.[82] Problems have been reported with the ability to join the pieces of the SiC composite.[83]

Jewelry

edit
 
A moissanite engagement ring

As a gemstone used in jewelry, silicon carbide is called "synthetic moissanite" or just "moissanite" after the mineral name. Moissanite is similar to diamond in several important respects: it is transparent and hard (9–9.5 on the Mohs scale, compared to 10 for diamond), with a refractive index between 2.65 and 2.69 (compared to 2.42 for diamond). Moissanite is somewhat harder than common cubic zirconia. Unlike diamond, moissanite can be strongly birefringent. For this reason, moissanite jewels are cut along the optic axis of the crystal to minimize birefringent effects. It is lighter (density 3.21 g/cm3 vs. 3.53 g/cm3), and much more resistant to heat than diamond. This results in a stone of higher luster, sharper facets, and good resilience. Loose moissanite stones may be placed directly into wax ring moulds for lost-wax casting, as can diamond,[84] as moissanite remains undamaged by temperatures up to 1,800 °C (3,270 °F). Moissanite has become popular as a diamond substitute, and may be misidentified as diamond, since its thermal conductivity is closer to diamond than any other substitute. Many thermal diamond-testing devices cannot distinguish moissanite from diamond, but the gem is distinct in its birefringence and a very slight green or yellow fluorescence under ultraviolet light. Some moissanite stones also have curved, string-like inclusions, which diamonds never have.[85]

Steel production

edit
 
Piece of silicon carbide used in steel making

Silicon carbide, dissolved in a basic oxygen furnace used for making steel, acts as a fuel. The additional energy liberated allows the furnace to process more scrap with the same charge of hot metal. It can also be used to raise tap temperatures and adjust the carbon and silicon content. Silicon carbide is cheaper than a combination of ferrosilicon and carbon, produces cleaner steel and lower emissions due to low levels of trace elements, has a low gas content, and does not lower the temperature of steel.[86]

Catalyst support

edit

The natural resistance to oxidation exhibited by silicon carbide, as well as the discovery of new ways to synthesize the cubic β-SiC form, with its larger surface area, has led to significant interest in its use as a heterogeneous catalyst support. This form has already been employed as a catalyst support for the oxidation of hydrocarbons, such as n-butane, to maleic anhydride.[87][88]

Carborundum printmaking

edit

Silicon carbide is used in carborundum printmaking – a collagraph printmaking technique. Carborundum grit is applied in a paste to the surface of an aluminium plate. When the paste is dry, ink is applied and trapped in its granular surface, then wiped from the bare areas of the plate. The ink plate is then printed onto paper in a rolling-bed press used for intaglio printmaking. The result is a print of painted marks embossed into the paper.

Carborundum grit is also used in stone Lithography. Its uniform particle size allows it to be used to "Grain" a stone which removes the previous image. In a similar process to sanding, coarser grit Carborundum is applied to the stone and worked with a Levigator, typically a round plate eccentric on a perpendicular shaft, then gradually finer and finer grit is applied until the stone is clean. This creates a grease sensitive surface.[89]

Graphene production

edit

Silicon carbide can be used in the production of graphene because of its chemical properties that promote the production of graphene on the surface of SiC nanostructures.

When it comes to its production, silicon is used primarily as a substrate to grow the graphene. But there are actually several methods that can be used to grow the graphene on the silicon carbide. The confinement controlled sublimation (CCS) growth method consists of a SiC chip that is heated under vacuum with graphite. Then the vacuum is released very gradually to control the growth of graphene. This method yields the highest quality graphene layers. But other methods have been reported to yield the same product as well.

Another way of growing graphene would be thermally decomposing SiC at a high temperature within a vacuum.[90] But, this method turns out to yield graphene layers that contain smaller grains within the layers.[91] So, there have been efforts to improve the quality and yield of graphene. One such method is to perform ex situ graphitization of silicon terminated SiC in an atmosphere consisting of argon. This method has proved to yield layers of graphene with larger domain sizes than the layer that would be attainable via other methods. This new method can be very viable to make higher quality graphene for a multitude of technological applications.

When it comes to understanding how or when to use these methods of graphene production, most of them mainly produce or grow this graphene on the SiC within a growth enabling environment. It is utilized most often at rather higher temperatures (such as 1,300 °C) because of SiC thermal properties.[92] However, there have been certain procedures that have been performed and studied that could potentially yield methods that use lower temperatures to help manufacture graphene. More specifically this different approach to graphene growth has been observed to produce graphene within a temperature environment of around 750 °C. This method entails the combination of certain methods like chemical vapor deposition (CVD) and surface segregation. And when it comes to the substrate, the procedure would consist of coating a SiC substrate with thin films of a transition metal. And after the rapid heat treating of this substance, the carbon atoms would then become more abundant at the surface interface of the transition metal film which would then yield graphene. And this process was found to yield graphene layers that were more continuous throughout the substrate surface.[93]

Quantum physics

edit

Silicon carbide can host point defects in the crystal lattice, which are known as color centers. These defects can produce single photons on demand and thus serve as a platform for single-photon source.[94] Such a device is a fundamental resource for many emerging applications of quantum information science. If one pumps a color center via an external optical source or electric current, the color center will be brought to the excited state and then relax with the emission of one photon.[95][96]

One well known point defect in silicon carbide is the divacancy which has a similar electronic structure as the nitrogen-vacancy center in diamond. In 4H-SiC, the divacancy has four different configurations which correspond to four zero-phonon lines (ZPL). These ZPL values are written using the notation VSi-VC and the unit eV: hh(1.095), kk(1.096), kh(1.119), and hk(1.150).[97]

Fishing rod guides

edit

Silicon carbide is used in the manufacturing of fishing guides because of its durability and wear resistance.[98] Silicon Carbide rings are fit into a guide frame, typically made from stainless steel or titanium which keep the line from touching the rod blank. The rings provide a low friction surface which improves casting distance while providing adequate hardness that prevents abrasion from braided fishing line.[99]

Pottery glazes

edit

Silicon carbide is used as a raw ingredient in some glazes applied to ceramics. At high temperatures it can reduce metal oxides forming silica and carbon dioxide. This can be used to make the glaze foam and crater due to the evolved carbon dioxide gas, or to reduce the colorant oxides and achieve colors such as copper reds otherwise only possible in a fuel powered reduction firing in an electric kiln.[100]

See also

edit

References

edit
  1. ^ a b c d NIOSH Pocket Guide to Chemical Hazards. "#0555". National Institute for Occupational Safety and Health (NIOSH).
  2. ^ a b Haynes, William M., ed. (2011). CRC Handbook of Chemistry and Physics (92nd ed.). Boca Raton, FL: CRC Press. p. 4.88. ISBN 1-4398-5511-0.
  3. ^ Pubchem. "Silicon carbide". pubchem.ncbi.nlm.nih.gov. Retrieved 2018-11-27.
  4. ^ Haynes, William M., ed. (2011). CRC Handbook of Chemistry and Physics (92nd ed.). Boca Raton, FL: CRC Press. p. 4.135. ISBN 1-4398-5511-0.
  5. ^ a b c "Properties of Silicon Carbide (SiC)". Ioffe Institute. Retrieved 2009-06-06.
  6. ^ "C&L Inventory". echa.europa.eu. Retrieved 12 December 2021.
  7. ^ Moissan, Henri (1904). "Nouvelles recherches sur la météorité de Cañon Diablo". Comptes rendus. 139: 773–86.
  8. ^ Di Pierro S.; Gnos E.; Grobety B.H.; Armbruster T.; Bernasconi S.M. & Ulmer P. (2003). "Rock-forming moissanite (natural α-silicon carbide)". American Mineralogist. 88 (11–12): 1817–21. Bibcode:2003AmMin..88.1817D. doi:10.2138/am-2003-11-1223. S2CID 128600868.
  9. ^ Kelly, Jim. "The Astrophysical Nature of Silicon Carbide". University College London. Archived from the original on May 4, 2017. Retrieved 2009-06-06.
  10. ^ Weimer, A. W. (1997). Carbide, nitride, and boride materials synthesis and processing. Springer. p. 115. ISBN 978-0-412-54060-8.
  11. ^ Encyclopædia Britannica, eb.com
  12. ^ Acheson, G. (1893) U.S. patent 492,767 "Production of artificial crystalline carbonaceous material"
  13. ^ "The Manufacture of Carborundum- a New Industry". Scientific American. April 7, 1894. Archived from the original on January 23, 2009. Retrieved 2009-06-06.
  14. ^ Mabery, Charles F. (1900). "Notes, On Carborundum". Journal of the American Chemical Society. XXII (Part II): 706–707. doi:10.1021/ja02048a014. Retrieved 2007-10-28.
  15. ^ Dunwoody, Henry H.C. (1906) U.S. patent 837,616 Wireless telegraph system (silicon carbide detector)
  16. ^ Hart, Jeffrey A.; Stefanie Ann Lenway; Thomas Murtha. "A History of Electroluminescent Displays". Archived from the original on 2012-04-30. Retrieved 2005-06-21.
  17. ^ Vlasov, A.S.; et al. (1991). "Obtaining silicon carbide from rice husks". Refractories and Industrial Ceramics. 32 (9–10): 521–523. doi:10.1007/bf01287542. S2CID 135784055.
  18. ^ Zhong, Y.; Shaw, Leon L.; Manjarres, Misael & Zawrah, Mahmoud F. (2010). "Synthesis of Silicon Carbide Nanopowder Using Silica Fume". Journal of the American Ceramic Society. 93 (10): 3159–3167. doi:10.1111/j.1551-2916.2010.03867.x.
  19. ^ a b c Harris, Gary Lynn (1995). Properties of silicon carbide. IET. p. 19; 170–180. ISBN 978-0-85296-870-3.
  20. ^ Lely, Jan Anthony (1955). "Darstellung von Einkristallen von Silicium Carbid und Beherrschung von Art und Menge der eingebauten Verunreinigungen". Berichte der Deutschen Keramischen Gesellschaft. 32: 229–236.
  21. ^ Lely SiC Wafers. Nitride-crystals.com. Retrieved on 2013-05-04.
  22. ^ Ohtani, N.; et al. (2001). Nippon Steel Technical Report no. 84 : Large high-quality silicon carbide substrates (PDF). Archived from the original (PDF) on 2010-12-17.
  23. ^ Byrappa, K.; Ohachi, T. (2003). Crystal growth technology. Springer. pp. 180–200. ISBN 978-3-540-00367-0.
  24. ^ Bakin, Andrey S. (2006). "SiC Homoepitaxy and Heteroepitaxy". In M. Shur; S. Rumyantsev; M. Levinshtein (eds.). SiC materials and devices. Vol. 1. World Scientific. pp. 43–76. ISBN 978-981-256-835-9.
  25. ^ AM of Ceramics from Preceramic Polymers Published in Additive Manufacturing 2019, vol. 27 pp 80–90
  26. ^ Europe Makes Ceramics Archived 2020-08-07 at the Wayback Machine Preceramics
  27. ^ a b Park, Yoon-Soo (1998). SiC materials and devices. Academic Press. pp. 20–60. ISBN 978-0-12-752160-2.
  28. ^ Pitcher, M. W.; Joray, S. J.; Bianconi, P. A. (2004). "Smooth Continuous Films of Stoichiometric Silicon Carbide from Poly(methylsilyne)". Advanced Materials. 16 (8): 706–709. Bibcode:2004AdM....16..706P. doi:10.1002/adma.200306467. S2CID 97161599.
  29. ^ Bunsell, A. R.; Piant, A. (2006). "A review of the development of three generations of small diameter silicon carbide fibres". Journal of Materials Science. 41 (3): 823–839. Bibcode:2006JMatS..41..823B. doi:10.1007/s10853-006-6566-z. S2CID 135586321.
  30. ^ Laine, Richard M.; Babonneau, Florence (1993). "Preceramic polymer routes to silicon carbide". Chemistry of Materials. 5 (3): 260–279. doi:10.1021/cm00027a007.
  31. ^ "KABRA|DISCO Corporation".
  32. ^ Cheung, Rebecca (2006). Silicon carbide microelectromechanical systems for harsh environments. Imperial College Press. p. 3. ISBN 978-1-86094-624-0.
  33. ^ Additive Manufacturing of Ceramics from Preceramic Polymers Published in Additive Manufacturing 2019, vol. 27 pp 80-90
  34. ^ Morkoç, H.; Strite, S.; Gao, G. B.; Lin, M. E.; Sverdlov, B.; Burns, M. (1994). "Large-band-gap SiC, III-V nitride, and II-VI ZnSe-based semiconductor device technologies". Journal of Applied Physics. 76 (3): 1363. Bibcode:1994JAP....76.1363M. doi:10.1063/1.358463.
  35. ^ a b Muranaka, T.; Kikuchi, Yoshitake; Yoshizawa, Taku; Shirakawa, Naoki; Akimitsu, Jun (2008). "Superconductivity in carrier-doped silicon carbide". Sci. Technol. Adv. Mater. 9 (4): 044204. Bibcode:2008STAdM...9d4204M. doi:10.1088/1468-6996/9/4/044204. PMC 5099635. PMID 27878021.
  36. ^ Silicon Carbide. Thermal properties. Ioffe Institute Semiconductors Database.
  37. ^ Zheng, Qiye; Li, Chunhua; Rai, Akash; Leach, Jacob H.; Broido, David A.; Cahill, David G. (2019-01-03). "Thermal conductivity of GaN, $^{71}\mathrm{GaN}$, and SiC from 150 K to 850 K". Physical Review Materials. 3 (1): 014601. doi:10.1103/PhysRevMaterials.3.014601. S2CID 139945430.
  38. ^ a b c Neumeier, J.J.; Shvyd'ko, Y.V.; Haskel, Daniel (2024). "Thermal expansion of 4H and 6H SiC from 5 K to 340 K". Journal of Physics and Chemistry of Solids. 187 (1): 11860. Bibcode:2024JPCS..18711860N. doi:10.1016/j.jpcs.2023.111860. S2CID 267488637.
  39. ^ "Adept Armor - Silicon Carbide". ADEPT. 6 December 2022. Retrieved 21 March 2023.
  40. ^ a b Bhatnagar, M.; Baliga, B.J. (March 1993). "Comparison of 6H-SiC, 3C-SiC, and Si for power devices". IEEE Transactions on Electron Devices. 40 (3): 645–655. Bibcode:1993ITED...40..645B. doi:10.1109/16.199372.
  41. ^ Kriener, M.; Muranaka, Takahiro; Kato, Junya; Ren, Zhi-An; Akimitsu, Jun; Maeno, Yoshiteru (2008). "Superconductivity in heavily boron-doped silicon carbide". Science and Technology of Advanced Materials. 9 (4): 044205. arXiv:0810.0056. Bibcode:2008STAdM...9d4205K. doi:10.1088/1468-6996/9/4/044205. PMC 5099636. PMID 27878022.
  42. ^ Yanase, Y. & Yorozu, N. (2008). "Superconductivity in compensated and uncompensated semiconductors". Science and Technology of Advanced Materials. 9 (4): 044201. Bibcode:2008STAdM...9d4201Y. doi:10.1088/1468-6996/9/4/044201. PMC 5099632. PMID 27878018.
  43. ^ Fuster, Marco A. (1997). "Skateboard grip tape", U.S. patent 5,622,759.
  44. ^ Tiegs, Terry (2005). "Chapter 13: Whisker Reinforced Alumina". In Bansal, Narottam P. (ed.). Handbook of Ceramic Composites. Boston: Kluwer Academic Publishers. p. 319. ISBN 978-1-4020-8133-0. OCLC 58542120.
  45. ^ "Production of Silicon Carbide". siliconcarbide.net.
  46. ^ "Ceramics for turbine engines". unipass.com. Archived from the original on 2009-04-06. Retrieved 2009-06-06.
  47. ^ "Dragon Skin – Most Protective Body Armor – Lightweight". Future Firepower. Archived from the original on 2012-02-17. Retrieved 2009-06-06.
  48. ^ Hanaor, Dorian A.H.; Xu, Wanqiang; Ferry, Michael; Sorrell, Charles C. (2012). "Abnormal grain growth of rutile TiO2 induced by ZrSiO4". Journal of Crystal Growth. 359: 83–91. arXiv:1303.2761. Bibcode:2012JCrGr.359...83H. doi:10.1016/j.jcrysgro.2012.08.015. S2CID 94096447.
  49. ^ "Silicon Carbide". Ceramic Arts Daily. Archived from the original on 2012-01-26. Retrieved 2012-02-09.
  50. ^ "UCLA researchers create exceptionally strong and lightweight new metal". UCLA.
  51. ^ "Top 10 Fast Cars". topmost10.com. Archived from the original on 2009-03-26. Retrieved 2009-06-06.
  52. ^ O'Sullivan, D.; Pomeroy, M.J.; Hampshire, S.; Murtagh, M.J. (2004). "Degradation resistance of silicon carbide diesel particulate filters to diesel fuel ash deposits". MRS Proceedings. 19 (10): 2913–2921. Bibcode:2004JMatR..19.2913O. doi:10.1557/JMR.2004.0373. S2CID 136537033.
  53. ^ "SiC Lubrication". Cerma.
  54. ^ Studt, P. (1987). "Influence of lubricating oil additives on friction of ceramics under conditions of boundary lubrication". Wear. 115 (1–2): 185–191. doi:10.1016/0043-1648(87)90208-0.
  55. ^ Friedrichs, Peter; Kimoto, Tsunenobu; Ley, Lothar; Pensl, Gerhard (2011). Silicon Carbide: Volume 1: Growth, Defects, and Novel Applications. John Wiley & Sons. pp. 49–. ISBN 978-3-527-62906-0.
  56. ^ Brown, John (1999). Foseco Non-Ferrous Foundryman's Handbook. Butterworth-Heinemann. pp. 52–. ISBN 978-0-08-053187-8.
  57. ^ Whitaker, Jerry C. (2005). The electronics handbook. CRC Press. p. 1108. ISBN 978-0-8493-1889-4.
  58. ^ Bayliss, Colin R. (1999). Transmission and distribution electrical engineering. Newnes. p. 250. ISBN 978-0-7506-4059-6.
  59. ^ Chen, H.; Raghothamachar, Balaji; Vetter, William; Dudley, Michael; Wang, Y.; Skromme, B.J. (2006). "Effects of Different Defect Types on the Performance of Devices Fabricated on a 4H-SiC Homoepitaxial Layer". MRS Proceedings. 911: 169. doi:10.1557/PROC-0911-B12-03.
  60. ^ Madar, Roland (26 August 2004). "Materials science: Silicon carbide in contention". Nature. 430 (7003): 974–975. Bibcode:2004Natur.430..974M. doi:10.1038/430974a. PMID 15329702. S2CID 4328365.
  61. ^ Chen, Z.; Ahyi, A.C.; Zhu, X.; Li, M.; Isaacs-Smith, T.; Williams, J.R.; Feldman, L.C. (2010). "MOS Characteristics of C-Face 4H-SiC". Journal of Electronic Materials. 39 (5): 526–529. Bibcode:2010JEMat..39..526C. doi:10.1007/s11664-010-1096-5. S2CID 95074081.
  62. ^ "At 1200 V and 45 milliohms, SemiSouth introduces the industry's lowest resistance SiC power transistor for efficient power management". Reuters (Press release). 5 May 2011. Archived from the original on 15 March 2016.
  63. ^ "Cree launches industry's first commercial silicon carbide power MOSFET; destined to replace silicon devices in high-voltage (≥ 1200 V) power electronics" (Press release). Cree. 17 January 2011. Archived from the original on 26 November 2016. Retrieved 11 September 2015.
  64. ^ Meißer, Michael (2013). Resonant Behaviour of Pulse Generators for the Efficient Drive of Optical Radiation Sources Based on Dielectric Barrier Discharges. KIT Scientific Publishing. p. 94. ISBN 978-3-7315-0083-4.
  65. ^ Horio, Masafumi; Iizuka, Yuji; Ikeda, Yoshinari (2012). "Packaging Technologies for SiC Power Modules" (PDF). Fuji Electric Review. 58 (2): 75–78.
  66. ^ Barbarini, Elena (June 25, 2018). STMicroelectronics SiC Module in Tesla Model3 Inverter (PDF) (Report). SystemPlus Consulting. Archived (PDF) from the original on December 27, 2020. Retrieved September 20, 2018. full SiC power module, in its Model 3. ... STMicroelectronics ... Tesla inverter ... 24 1-in-1 power modules ... module contains two SiC MOSFETs
  67. ^ Amos Zeeberg (May 16, 2022). "What's Down the Road for Silicon?: Meet the new materials overpowering the electric economy". The New York Times. Retrieved May 17, 2022.
  68. ^ Hooker, James. "GE SSL-1 Yellow SiC LED at the Museum of Electric Lamp Technology". Retrieved 21 October 2024.
  69. ^ Klipstein, Don. "Yellow SiC LED". Retrieved 6 June 2009.
  70. ^ a b Stringfellow, Gerald B. (1997). High brightness light emitting diodes. Academic Press. pp. 48, 57, 425. ISBN 978-0-12-752156-5.
  71. ^ "The Largest Telescope Mirror Ever Put into Space". European Space Agency. 23 February 2004. Retrieved 6 June 2009.
  72. ^ Petrovsky, Gury Timofeevic; Tolstoy, Michael N.; Lubarsky, Sergey V.; Khimitch, Yuri P.; Robb, Paul N. (June 1994). Stepp, Larry M. (ed.). "2.7-meter-diameter silicon carbide primary mirror for the SOFIA telescope". Proc. SPIE. Advanced Technology Optical Telescopes V. 2199: 263. Bibcode:1994SPIE.2199..263P. doi:10.1117/12.176195. S2CID 120854083.
  73. ^ "Thin-Filament Pyrometry Developed for Measuring Temperatures in Flames". NASA. Archived from the original on 2012-03-15. Retrieved 2009-06-06.
  74. ^ Maun, Jignesh D.; Sunderland, P. B.; Urban, D. L. (2007). "Thin-filament pyrometry with a digital still camera" (PDF). Applied Optics. 46 (4): 483–8. Bibcode:2007ApOpt..46..483M. doi:10.1364/AO.46.000483. hdl:1903/3602. PMID 17230239.
  75. ^ Deshmukh, Yeshvant V. (2005). Industrial heating: principles, techniques, materials, applications, and design. CRC Press. pp. 383–393. ISBN 978-0-8493-3405-4.
  76. ^ "NASA Inflatable Heat Shield Finds Strength in Flexibility". NASA. Archived from the original on 2022-11-11. Retrieved 2022-11-10.
  77. ^ "Silicon Carbide (SiC)". Precise Ceramics. Retrieved June 10, 2024.
  78. ^ Napoli, Marzio (2022). "SiC detectors: A review on the use of silicon carbide as radiation detection material". Frontiers in Physics. 10. Bibcode:2022FrP....10.8833D. doi:10.3389/fphy.2022.898833.
  79. ^ "Silicon Carbide Sensors and Electronics Technology for Extreme Environments: Opportunities for Nuclear Power Applications". NASA. 30 November 2022. Retrieved June 10, 2024.
  80. ^ López-Honorato, E.; Tan, J.; Meadows, P. J.; Marsh, G.; Xiao, P. (2009). "TRISO coated fuel particles with enhanced SiC properties". Journal of Nuclear Materials. 392 (2): 219–224. Bibcode:2009JNuM..392..219L. doi:10.1016/j.jnucmat.2009.03.013.
  81. ^ Bertolino, Meyer, G. (2002). "Degradation of the mechanical properties of Zircaloy-4 due to hydrogen embrittlement". Journal of Alloys and Compounds. 330–332: 408–413. doi:10.1016/S0925-8388(01)01576-6.
  82. ^ Carpenter, David; Ahn, K.; Kao, S.P.; Hejzlar, Pavel; Kazimi, Mujid S. "Assessment of Silicon Carbide Cladding for High Performance Light Water Reactors". Nuclear Fuel Cycle Program, Volume MIT-NFC-TR-098 (2007). Archived from the original on 2012-04-25. Retrieved 2011-10-13.
  83. ^ Ames, Nate (June 17, 2010). "SiC Fuel Cladding". Nuclear Fabrication Consortium, nuclearfabrication.org. Archived from the original on April 25, 2012. Retrieved 2011-10-13.
  84. ^ Teague, Tyler. Casting Metal Directly onto Stones Archived 2016-09-10 at the Wayback Machine, Jett Industries
  85. ^ O'Donoghue, M. (2006). Gems. Elsevier. p. 89. ISBN 978-0-7506-5856-0.
  86. ^ "Silicon carbide (steel industry)". Archived from the original on 2012-02-04. Retrieved 2009-06-06.
  87. ^ Rase, Howard F. (2000). Handbook of commercial catalysts: heterogeneous catalysts. CRC Press. p. 258. ISBN 978-0-8493-9417-1.
  88. ^ Singh, S. K.; Parida, K. M.; Mohanty, B. C.; Rao, S. B. (1995). "High surface area silicon carbide from rice husk: A support material for catalysts". Reaction Kinetics and Catalysis Letters. 54 (1): 29–34. doi:10.1007/BF02071177. S2CID 95550450.
  89. ^ "Printmaking". Bircham Gallery, birchamgallery.co.uk. Retrieved 2009-07-31.
  90. ^ Ruan, Ming; Hu, Yike; Guo, Zelei; Dong, Rui; Palmer, James; Hankinson, John; Berger, Claire; Heer, Walt A. de (December 2012). "Epitaxial graphene on silicon carbide: Introduction to structured graphene" (PDF). MRS Bulletin. 37 (12): 1138–1147. Bibcode:2012MRSBu..37.1138R. doi:10.1557/mrs.2012.231. ISSN 0883-7694. S2CID 40188237.
  91. ^ Emtsev, Konstantin V.; Bostwick, Aaron; Horn, Karsten; Jobst, Johannes; Kellogg, Gary L.; Ley, Lothar; McChesney, Jessica L.; Ohta, Taisuke; Reshanov, Sergey A. (2009-02-08). "Towards wafer-size graphene layers by atmospheric pressure graphitization of silicon carbide". Nature Materials. 8 (3): 203–207. Bibcode:2009NatMa...8..203E. doi:10.1038/nmat2382. hdl:11858/00-001M-0000-0010-FA05-E. ISSN 1476-1122. PMID 19202545.
  92. ^ de Heer, Walt A.; Berger, Claire; Wu, Xiaosong; First, Phillip N.; Conrad, Edward H.; Li, Xuebin; Li, Tianbo; Sprinkle, Michael; Hass, Joanna (July 2007). "Epitaxial graphene". Solid State Communications. 143 (1–2): 92–100. arXiv:0704.0285. Bibcode:2007SSCom.143...92D. doi:10.1016/j.ssc.2007.04.023. ISSN 0038-1098. S2CID 44542277.
  93. ^ Juang, Zhen-Yu; Wu, Chih-Yu; Lo, Chien-Wei; Chen, Wei-Yu; Huang, Chih-Fang; Hwang, Jenn-Chang; Chen, Fu-Rong; Leou, Keh-Chyang; Tsai, Chuen-Horng (2009-07-01). "Synthesis of graphene on silicon carbide substrates at low temperature". Carbon. 47 (8): 2026–2031. Bibcode:2009Carbo..47.2026J. doi:10.1016/j.carbon.2009.03.051. ISSN 0008-6223.
  94. ^ Castelletto, Stefania; Johnson, Brett; Iv{\'a}dy, Viktor; Stavrias, Nicholas; Umeda, T; Gali, Adam; Ohshima, Takeshi (2014). "A silicon carbide room-temperature single-photon source". Nature Materials. 13 (2): 151–156. Bibcode:2014NatMa..13..151C. doi:10.1038/nmat3806. PMID 24240243. S2CID 37160386.
  95. ^ Lohrmann, A.; Iwamoto, N.; Bodrog, Z.; Castalletto, S.; Ohshima, T.; Karle, T.J.; Gali, A.; Prawer, S.; McCallum, J.C.; Johnson, B.C. (2015). "Single-photon emitting diode in silicon carbide". Nature Communications. 6: 7783. arXiv:1503.07566. Bibcode:2015NatCo...6.7783L. doi:10.1038/ncomms8783. PMID 26205309. S2CID 205338373.
  96. ^ Khramtsov, I.A.; Vyshnevyy, A.A.; Fedyanin, D. Yu. (2018). "Enhancing the brightness of electrically driven single-photon sources using color centers in silicon carbide". npj Quantum Information. 4: 15. Bibcode:2018npjQI...4...15K. doi:10.1038/s41534-018-0066-2.
  97. ^ Davidsson, J.; Ivády, V.; Armiento, R.; Son, N.T.; Gali, A.; Abrikosov, I. A. (2018). "First principles predictions of magneto-optical data for semiconductor point defect identification: the case of divacancy defects in 4H–SiC". New Journal of Physics. 20 (2): 023035. arXiv:1708.04508. Bibcode:2018NJPh...20b3035D. doi:10.1088/1367-2630/aaa752. S2CID 4867492.
  98. ^ "The best spinning rod". Retrieved 2020-06-27.
  99. ^ C. Boyd Pfeiffer (15 January 2013). Complete Book of Rod Building and Tackle Making. Rowman & Littlefield. ISBN 978-0-7627-9502-4.
  100. ^ Hansen, Tony. "Silicon carbide". Digital Fire. Retrieved 30 April 2023.
edit
  NODES
3d 2
camera 1
Experiments 3
HOME 1
Intern 1
iOS 7
languages 1
mac 4
Note 4
os 79
text 1
Verify 1