Zone melting

Crystallization
Crystallization
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Last updated November 24, 2023

(left) Pfann, at left, showing the first zone refining tube, Bell Labs, 1953
(right) Vertical zone refining, 1961. The induction heating coil melts a section of the metal bar in the tube. The coil moves slowly down the tube, moving the molten zone to the end of the bar.

Zone melting (or zone refining, or floating-zone method, or floating-zone technique) is a group of similar methods of purifying crystals, in which a narrow region of a crystal is melted, and this molten zone is moved along the crystal. The molten region melts impure solid at its forward edge and leaves a wake of purer material solidified behind it as it moves through the ingot. The impurities concentrate in the melt, and are moved to one end of the ingot. Zone refining was invented by John Desmond Bernal ^[1] and further developed by William G. Pfann ^[2] in Bell Labs as a method to prepare high-purity materials, mainly semiconductors, for manufacturing transistors. Its first commercial use was in germanium, refined to one atom of impurity per ten billion,^[3] but the process can be extended to virtually any solute–solvent system having an appreciable concentration difference between solid and liquid phases at equilibrium.^[4] This process is also known as the float zone process, particularly in semiconductor materials processing.

Process details

The principle is that the segregation coefficient k (the ratio of an impurity in the solid phase to that in the liquid phase) is usually less than one. Therefore, at the solid/liquid boundary, the impurity atoms will diffuse to the liquid region. Thus, by passing a crystal boule through a thin section of furnace very slowly, such that only a small region of the boule is molten at any time, the impurities will be segregated at the end of the crystal. Because of the lack of impurities in the leftover regions which solidify, the boule can grow as a perfect single crystal if a seed crystal is placed at the base to initiate a chosen direction of crystal growth. When high purity is required, such as in semiconductor industry, the impure end of the boule is cut off, and the refining is repeated.^{[ citation needed ]}

In zone refining, solutes are segregated at one end of the ingot in order to purify the remainder, or to concentrate the impurities. In zone leveling, the objective is to distribute solute evenly throughout the purified material, which may be sought in the form of a single crystal. For example, in the preparation of a transistor or diode semiconductor, an ingot of germanium is first purified by zone refining. Then a small amount of antimony is placed in the molten zone, which is passed through the pure germanium. With the proper choice of rate of heating and other variables, the antimony can be spread evenly through the germanium. This technique is also used for the preparation of silicon for use in integrated circuits ("chips").^{[ citation needed ]}

Heaters

A variety of heaters can be used for zone melting, with their most important characteristic being the ability to form short molten zones that move slowly and uniformly through the ingot. Induction coils, ring-wound resistance heaters, or gas flames are common methods. Another method is to pass an electric current directly through the ingot while it is in a magnetic field, with the resulting magnetomotive force carefully set to be just equal to the weight in order to hold the liquid suspended. Optical heaters using high-powered halogen or xenon lamps are used extensively in research facilities particularly for the production of insulators, but their use in industry is limited by the relatively low power of the lamps, which limits the size of crystals produced by this method. Zone melting can be done as a batch process, or it can be done continuously, with fresh impure material being continually added at one end and purer material being removed from the other, with impure zone melt being removed at whatever rate is dictated by the impurity of the feed stock.^{[ citation needed ]}

Indirect-heating floating zone methods use an induction-heated tungsten ring to heat the ingot radiatively, and are useful when the ingot is of a high-resistivity semiconductor on which classical induction heating is ineffective.^{[ citation needed ]}

Mathematical expression of impurity concentration

When the liquid zone moves by a distance $dx$ , the number of impurities in the liquid change. Impurities are incorporated in the melting liquid and freezing solid.^[5]^{[ clarification needed ]}

k_{O}

: segregation coefficient

L

: zone length

C_{O}

: initial uniform impurity concentration of the solidified rod

C_{L}

: concentration of impurities in the liquid melt per length

I

: number of impurities in the liquid

I_{O}

: number of impurities in zone when first formed at bottom

C_{S}

: concentration of impurities in the solid rod

The number of impurities in the liquid changes in accordance with the expression below during the movement $dx$ of the molten zone

dI=(C_{O}-k_{O}C_{L})\,dx\;

C_{L}=I/L\;

\int _{0}^{x}dx=\int _{I_{O}}^{I}{\frac {dI}{C_{O}-{\frac {k_{O}I}{L}}}}

I_{O}=C_{O}L\;

C_{S}=k_{O}I/L\;

C_{S}(x)=C_{O}\left(1-(1-k_{O})e^{-{\frac {k_{O}x}{L}}}\right)

Applications

Solar cells

In solar cells, float zone processing is particularly useful because the single-crystal silicon grown has desirable properties. The bulk charge carrier lifetime in float-zone silicon is the highest among various manufacturing processes. Float-zone carrier lifetimes are around 1000 microseconds compared to 20–200 microseconds with Czochralski method, and 1–30 microseconds with cast polycrystalline silicon. A longer bulk lifetime increases the efficiency of solar cells significantly.^{[ citation needed ]}

High-resistivity devices

It's used for production of float-zone silicon-based high-power semiconductor devices.^[6]^: 364

Related processes

Zone remelting

Another related process is zone remelting, in which two solutes are distributed through a pure metal. This is important in the manufacture of semiconductors, where two solutes of opposite conductivity type are used. For example, in germanium, pentavalent elements of group V such as antimony and arsenic produce negative (n-type) conduction and the trivalent elements of group III such as aluminium and boron produce positive (p-type) conduction. By melting a portion of such an ingot and slowly refreezing it, solutes in the molten region become distributed to form the desired n-p and p-n junctions.^{[ citation needed ]}

Related Research Articles

An alloy is a mixture of chemical elements of which at least one is a metal. Unlike chemical compounds with metallic bases, an alloy will retain all the properties of a metal in the resulting material, such as electrical conductivity, ductility, opacity, and luster, but may have properties that differ from those of the pure metals, such as increased strength or hardness. In some cases, an alloy may reduce the overall cost of the material while preserving important properties. In other cases, the mixture imparts synergistic properties to the constituent metal elements such as corrosion resistance or mechanical strength.

<span class="mw-page-title-main">Melting</span> Material phase change

Melting, or fusion, is a physical process that results in the phase transition of a substance from a solid to a liquid. This occurs when the internal energy of the solid increases, typically by the application of heat or pressure, which increases the substance's temperature to the melting point. At the melting point, the ordering of ions or molecules in the solid breaks down to a less ordered state, and the solid melts to become a liquid.

<span class="mw-page-title-main">Wafer (electronics)</span> Thin slice of semiconductor used for the fabrication of integrated circuits

In electronics, a wafer is a thin slice of semiconductor, such as a crystalline silicon (c-Si), used for the fabrication of integrated circuits and, in photovoltaics, to manufacture solar cells. The wafer serves as the substrate for microelectronic devices built in and upon the wafer. It undergoes many microfabrication processes, such as doping, ion implantation, etching, thin-film deposition of various materials, and photolithographic patterning. Finally, the individual microcircuits are separated by wafer dicing and packaged as an integrated circuit.

<span class="mw-page-title-main">Czochralski method</span> Method of crystal growth

The Czochralski method, also Czochralski technique or Czochralski process, is a method of crystal growth used to obtain single crystals of semiconductors, metals, salts and synthetic gemstones. The method is named after Polish scientist Jan Czochralski, who invented the method in 1915 while investigating the crystallization rates of metals. He made this discovery by accident: instead of dipping his pen into his inkwell, he dipped it in molten tin, and drew a tin filament, which later proved to be a single crystal. The method is still used in over 90 percent of all electronics in the world that use semiconductors.

Refining is the process of purification of a (1) substance or a (2) form. The term is usually used of a natural resource that is almost in a usable form, but which is more useful in its pure form. For instance, most types of natural petroleum will burn straight from the ground, but it will burn poorly and quickly clog an engine with residues and by-products. The term is broad, and may include more drastic transformations, such as the reduction of ore to metal.

An ingot is a piece of relatively pure material, usually metal, that is cast into a shape suitable for further processing. In steelmaking, it is the first step among semi-finished casting products. Ingots usually require a second procedure of shaping, such as cold/hot working, cutting, or milling to produce a useful final product. Non-metallic and semiconductor materials prepared in bulk form may also be referred to as ingots, particularly when cast by mold based methods. Precious metal ingots can be used as currency, or as a currency reserve, as with gold bars.

Freezing-point depression is a drop in the maximum temperature at which a substance freezes, caused when a smaller amount of another, non-volatile substance is added. Examples include adding salt into water, alcohol in water, ethylene or propylene glycol in water, adding copper to molten silver, or the mixing of two solids such as impurities into a finely powdered drug.

In semiconductor production, doping is the intentional introduction of impurities into an intrinsic semiconductor for the purpose of modulating its electrical, optical and structural properties. The doped material is referred to as an extrinsic semiconductor.

<span class="mw-page-title-main">Boule (crystal)</span> Synthetic ingot of crystal

A boule is a single-crystal ingot produced by synthetic means.

<span class="mw-page-title-main">Bridgman–Stockbarger method</span> Method of crystallization

The Bridgman–Stockbarger method, or Bridgman–Stockbarger technique, is named after Harvard physicist Percy Williams Bridgman (1882–1961) and MIT physicist Donald C. Stockbarger (1895–1952). The method includes two similar but distinct techniques primarily used for growing boules, but which can be used for solidifying polycrystalline ingots as well.

<span class="mw-page-title-main">Crystallization</span> Process by which a solid with a highly organized atomic or molecular structure forms

Crystallization is the process by which solid forms, where the atoms or molecules are highly organized into a structure known as a crystal. Some ways by which crystals form are precipitating from a solution, freezing, or more rarely deposition directly from a gas. Attributes of the resulting crystal depend largely on factors such as temperature, air pressure, and in the case of liquid crystals, time of fluid evaporation.

The Betterton-Kroll Process is a pyrometallurgical process for refining lead from lead bullion. Developed by William Justin Kroll in 1922, the Betterton–Kroll process is one of the final steps in conventional lead smelting. After gold, copper, and silver are removed from the lead, significant amounts of bismuth and antimony remain. The Betterton–Kroll process is used to remove these impurities. In the process, calcium and magnesium are added to the molten lead at temperatures around 380 °C. The calcium and magnesium react with the bismuth and antimony in the bullion to form alloys with a higher melting point, which then can be skimmed off of the surface. This process leaves behind lead with less than 0.01 percent bismuth by weight. The process is crucial to cheap industrial lead smelting and offers significant advantages over more expensive processes like the Betts Electrolytic process and fractional crystallization.

Float-zone silicon is very pure silicon obtained by vertical zone melting. The process was developed at Bell Labs by Henry Theuerer in 1955 as a modification of a method developed by William Gardner Pfann for germanium. In the vertical configuration molten silicon has sufficient surface tension to keep the charge from separating. The major advantages is crucibleless growth that prevents contamination of the silicon from the vessel itself and therefore an inherently high-purity alternative to boule crystals grown by the Czochralski method.

Electroslag remelting (ESR), also known as electro-flux remelting, is a process of remelting and refining steel and other alloys for mission-critical applications in aircraft, thermal power stations, nuclear power plants, military technology and others.

<span class="mw-page-title-main">Verneuil method</span> Manufacturing process of synthetic gemstones

The Verneuil method, also called flame fusion, was the first commercially successful method of manufacturing synthetic gemstones, developed in the late 1883 by the French chemist Auguste Verneuil. It is primarily used to produce the ruby, sapphire and padparadscha varieties of corundum, as well as the diamond simulants rutile, strontium titanate and spinel. The principle of the process involves melting a finely powdered substance using an oxyhydrogen flame, and crystallising the melted droplets into a boule. The process is considered to be the founding step of modern industrial crystal growth technology, and remains in wide use to this day.

In metallurgy, refining consists of purifying an impure metal. It is to be distinguished from other processes such as smelting and calcining in that those two involve a chemical change to the raw material, whereas in refining, the final material is usually identical chemically to the original one, only it is purer. The processes used are of many types, including pyrometallurgical and hydrometallurgical techniques.

Monocrystalline silicon, more often called single-crystal silicon, in short mono c-Si or mono-Si, is the base material for silicon-based discrete components and integrated circuits used in virtually all modern electronic equipment. Mono-Si also serves as a photovoltaic, light-absorbing material in the manufacture of solar cells.

In thermodynamics, the enthalpy of fusion of a substance, also known as (latent) heat of fusion, is the change in its enthalpy resulting from providing energy, typically heat, to a specific quantity of the substance to change its state from a solid to a liquid, at constant pressure.

William Gardner Pfann was an inventor and materials scientist with Bell Labs. Pfann is known for his development of zone melting which is essential to the semiconductor industry. As stated in an official history of Bell Labs, "Timely invention of zone refining by W.G.Pfann ... was a major contribution that helped bring the impurities in germanium and silicon under control."

<span class="mw-page-title-main">Kyropoulos method</span> Method of bulk crystal growth used to obtain single crystals

The Kyropoulos method, KY method, or Kyropoulos technique, is a method of bulk crystal growth used to obtain single crystals.

References

↑ Brown, Andrew (2005-11-24). J. D. Bernal: The Sage of Science. OUP Oxford. ISBN 9780198515449.
↑ William G. Pfann (1966) Zone Melting, 2nd edition, John Wiley & Sons
↑ ”Zone melting”, entry in The World Book Encyclopedia, Volume 21, W-X-Y-Z, 1973, page 501.
↑ Float Zone Crystal Growth
↑ James D. Plummer, Michael D. Deal, and Peter B. Griffin (2000) Silicon VLSI Technology, Prentice Hall, page 129
↑ Sze, S. M. (2012). Semiconductor devices: physics and technology. M. K. Lee (3 ed.). New York, NY: Wiley. ISBN 978-0-470-53794-7. OCLC 869833419.

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[1] Brown, Andrew (2005-11-24). J. D. Bernal: The Sage of Science. OUP Oxford. ISBN 9780198515449.

[Pfann-2] William G. Pfann (1966) Zone Melting, 2nd edition, John Wiley & Sons

[WB1973-3] ”Zone melting”, entry in The World Book Encyclopedia, Volume 21, W-X-Y-Z, 1973, page 501.

[4] Float Zone Crystal Growth

[5] James D. Plummer, Michael D. Deal, and Peter B. Griffin (2000) Silicon VLSI Technology, Prentice Hall, page 129

[:0-6] Sze, S. M. (2012). Semiconductor devices: physics and technology. M. K. Lee (3 ed.). New York, NY: Wiley. ISBN 978-0-470-53794-7. OCLC 869833419.

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