Semiconductor

A semiconductor is a material that has an electrical conductivity value falling between that of a conductor, such as copper, and an insulator, such as glass. Its resistivity generally falls as its temperature rises; metals behave in the opposite way.^[1] In many cases their conducting properties may be altered in useful ways by introducing impurities ("doping") into the crystal structure. When two differently doped regions exist in the same crystal, a semiconductor junction is created. The behavior of charge carriers, which include electrons, ions, and electron holes, at these junctions is the basis of diodes, transistors, and most modern electronics. Some examples of semiconductors are silicon, germanium, gallium arsenide, and elements near the so-called "metalloid staircase" on the periodic table. After silicon, gallium arsenide is the second-most common semiconductor and is used in laser diodes, solar cells, microwave-frequency integrated circuits, and others. Silicon is a critical element for fabricating most electronic circuits.

Semiconductor devices can display a range of different useful properties, such as passing current more easily in one direction than the other, showing variable resistance, and having sensitivity to light or heat. Because the electrical properties of a semiconductor material can be modified by doping and by the application of electrical fields or light, devices made from semiconductors can be used for amplification, switching, and energy conversion. The term semiconductor is also used to describe materials used in high capacity, medium to high-voltage cables part of their insulation, these materials are often plastic XLPE (Cross-linked polyethylene) with carbon black.^[2]

The conductivity of silicon is increased by adding a small amount (of the order of 1 in 10⁸) of pentavalent (antimony, phosphorus, or arsenic) or trivalent (boron, gallium, indium) atoms.^[3] This process is known as doping, and the resulting semiconductors are known as doped or extrinsic semiconductors. Apart from doping, the conductivity of a semiconductor can be improved by increasing its temperature. This is contrary to the behavior of a metal, in which conductivity decreases with an increase in temperature.^[4]

The modern understanding of the properties of a semiconductor relies on quantum physics to explain the movement of charge carriers in a crystal lattice.^[5] Doping greatly increases the number of charge carriers within the crystal. When a doped semiconductor contains free holes, it is called "p-type", and when it contains free electrons, it is known as "n-type". The semiconductor materials used in electronic devices are doped under precise conditions to control the concentration and regions of p- and n-type dopants. A single semiconductor device crystal can have many p- and n-type regions; the p–n junctions between these regions are responsible for the useful electronic behavior. Using a hot-point probe, one can determine quickly whether a semiconductor sample is p- or n-type.^[6]

A few of the properties of semiconductor materials were observed throughout the mid-19th and first decades of the 20th century. The first practical application of semiconductors in electronics was the 1904 development of the cat's-whisker detector, a primitive semiconductor diode used in early radio receivers. Developments in quantum physics led in turn to the invention of the transistor in 1947^[7] and the integrated circuit in 1958.

^ Tatum, Jeremy (13 December 2016). "Resistance and Temperature". LibreTexts. Retrieved 2023-12-22.
^ Worzyk, Thomas (11 August 2009). Submarine Power Cables: Design, Installation, Repair, Environmental Aspects. Springer. ISBN 978-3-642-01270-9.
^ "Electrical Conduction in Semiconductors". www.mks.com. Retrieved 2024-04-01.
^ "Joshua Halpern". Chemistry 003. 2015-01-12. Retrieved 2024-04-01.
^ Feynman, Richard. Feynman Lectures on Physics.
^ "2.4.7.9 The "hot-probe" experiment". ecee.colorado.edu. Archived from the original on 6 March 2021. Retrieved 27 November 2020.
^ Shockley, William (1950). Electrons and holes in semiconductors: with applications to transistor electronics. R. E. Krieger Pub. Co. ISBN 978-0-88275-382-9.

[1] Tatum, Jeremy (13 December 2016). "Resistance and Temperature". LibreTexts. Retrieved 2023-12-22.

[2] Worzyk, Thomas (11 August 2009). Submarine Power Cables: Design, Installation, Repair, Environmental Aspects. Springer. ISBN 978-3-642-01270-9.

[3] "Electrical Conduction in Semiconductors". www.mks.com. Retrieved 2024-04-01.

[4] "Joshua Halpern". Chemistry 003. 2015-01-12. Retrieved 2024-04-01.

[Feynman-5] Feynman, Richard. Feynman Lectures on Physics.

[6] "2.4.7.9 The "hot-probe" experiment". ecee.colorado.edu. Archived from the original on 6 March 2021. Retrieved 27 November 2020.

[7] Shockley, William (1950). Electrons and holes in semiconductors: with applications to transistor electronics. R. E. Krieger Pub. Co. ISBN 978-0-88275-382-9.

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Semiconductor device fabrication

MOSFET scaling (process nodes)
020 µm – 1968 010 µm – 1971 006 µm – 1974 003 µm – 1977 1.5 µm – 1981 001 µm – 1984 800 nm – 1987 600 nm – 1990 350 nm – 1993 250 nm – 1996 180 nm – 1999 130 nm – 2001 090 nm – 2003 065 nm – 2005 045 nm – 2007 032 nm – 2009 028 nm – 2010 022 nm – 2012 014 nm – 2014 010 nm – 2016 007 nm – 2018 005 nm – 2020 003 nm – 2022
Future 002 nm ~ 2024
Half-nodes Density CMOS Device (multi-gate) Moore's law Transistor count Semiconductor Industry Nanoelectronics
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