Nonmetallic material explained

Nonmetallic material, or in nontechnical terms a nonmetal, refers to materials which are not metals. Depending upon context it is used in slightly different ways. In everyday life it would be a generic term for those materials such as plastics, wood or ceramics which are not typical metals such as the iron alloys used in bridges. In some areas of chemistry, particularly the periodic table, it is used for just those chemical elements which are not metallic at standard temperature and pressure conditions. It is also sometimes used to describe broad classes of dopant atoms in materials. In general usage in science, it refers to materials which do not have electrons that can readily move around, more technically there are no available states at the Fermi energy, the equilibrium energy of electrons. For historical reasons there is a very different definition of metals in astronomy, with just hydrogen and helium as nonmetals. The term may also be used as a negative of the materials of interest such as in metallurgy or metalworking.

Variations in the environment, particularly temperature and pressure can change a nonmetal into a metal, and vica versa; this is always associated with some major change in the structure, a phase transition. Other external stimuli such as electric fields can also lead to a local nonmetal, for instance in certain semiconductor devices. There are also many physical phenomena which are only found in nonmetals such as piezoelectricity or flexoelectricity.

General definition

The original approach to conduction and nonmetals was a band-structure with delocalized electrons (i.e. spread out in space). In this approach a nonmetal has a gap in the energy levels of the electrons at the Fermi level.[1] In contrast, a metal would have at least one partially occupied band at the Fermi level; in a semiconductor or insulator there are no delocalized states at the Fermi level, see for instance Ashcroft and Mermin. These definitions are equivalent to stating that metals conduct electricity at absolute zero, as suggested by Nevill Francis Mott,[2] and the equivalent definition at other temperatures is also commonly used as in textbooks such as Chemistry of the Non-Metals by Ralf Steudel[3] and work on metal–insulator transitions.

In early work[4] [5] this band structure interpretation was based upon a single-electron approach with the Fermi level in the band gap as illustrated in the Figure, not including a complete picture of the many-body problem where both exchange and correlation terms can matter, as well as relativistic effects such as spin-orbit coupling. A key addition by Mott and Rudolf Peierls was that these could not be ignored.[6] For instance, nickel oxide would be a metal if a single-electron approach was used, but in fact has quite a large band gap.[7] As of 2024 it is more common to use an approach based upon density functional theory where the many-body terms are included.[8] [9] Rather than single electrons, the filling involves quasiparticles called orbitals, which are the single-particle like solutions for a system with hundreds to thousands of electrons. Although accurate calculations remain a challenge, reasonable results are now available in many cases.[10] [11] It is also common to nuance somewhat the early definitions of Alan Herries Wilson and Mott. As discussed by both the chemist Peter Edwards and colleagues,[12] as well as Fumiko Yonezawa,it is also important in practice to consider the temperatures at which both metals and nonmetals are used. Yonezawa provides a general definition:

When a material 'conducts' and at the same time the temperature coefficient of the electric conductivity of that material is not positive under a certain environmental condition,' the material is metallic under that environmental condition. A material which does not satisfy these requirements is not metallic under that environmental condition.Band structure definitions of metallicity are the most widely used, and apply both to single elements such as insulating boron[13] as well as compounds such as strontium titanate.[14] (There are many compounds which have states at the Fermi level and are metallic, for instance titanium nitride.[15]) There are many experimental methods of checking for nonmetals by measuring the band gap, or by ab-initio quantum mechanical calculations.[16]

Functional definition

An alternative in metallurgy is to consider various malleable alloys such as steel, aluminium alloys and similar as metals, and other materials as nonmetals;[17] fabricating metals is termed metalworking,[18] but there is no corresponding term for nonmetals. A loose definition such as this is often the common useage, but can also be inaccurate. For instance, in this useage plastics are nonmetals, but in fact there are (electrically) conducting polymers[19] [20] which should formally be described as metals. Similar, but slightly more complex, many materials which are (nonmetal) semiconductors behave like metals when they contain a high concentration of dopants, being called degenerate semiconductors.[21] A general introduction to much of this can be found in the 2017 book by Fumiko Yonezawa

Periodic table elements

See also: Properties of metals, metalloids and nonmetals. The term nonmetal (chemistry) is also used for those elements which are not metallic in their normal ground state; compounds are sometimes excluded from consideration. Some textbooks use the term nonmetallic elements such as the Chemistry of the Non-Metals by Ralf Steudel,[22] which also uses the general definition in terms of conduction and the Fermi level. The approach based upon the elements is often used in teaching to help students understand the periodic table of elements,[23] although it is a teaching oversimplification.[24] [25] Those elements towards the top right of the periodic table are nonmetals, those towards the center (transition metal and lanthanide) and the left are metallic. An intermediate designation metalloid is used for some elements.

The term is sometimes also used when describing dopants of specific elements types in compounds, alloys or combinations of materials, using the periodic table classification. For instance metalloids are often used in high-temperature alloys,[26] and nonmetals in precipitation hardening in steels and other alloys.[27] Here the description implicitly includes information on whether the dopants tend to be electron acceptors that lead to covalently bonded compounds rather than metallic bonding or electron acceptors.

Nonmetals in astronomy

See main article: Metallicity. A quite different approach is used in astronomy where the term metallicity is used for all elements heavier than helium, so the only nonmetals are hydrogen and helium. This is a historical anomaly. In 1802, William Hyde Wollaston[28] noted the appearance of a number of dark features in the solar spectrum.[29] In 1814, Joseph von Fraunhofer independently rediscovered the lines and began to systematically study and measure their wavelengths, and they are now called Fraunhofer lines. He mapped over 570 lines, designating the most prominent with the letters A through K and weaker lines with other letters.[30] [31] [32]

About 45 years later, Gustav Kirchhoff and Robert Bunsen[33] noticed that several Fraunhofer lines coincide with characteristic emission lines identifies in the spectra of heated chemical elements.[34] They inferred that dark lines in the solar spectrum are caused by absorption by chemical elements in the solar atmosphere.[35] Their observations[36] were in the visible range where the strongest lines come from metals such as Na, K, Fe.[37] In the early work on the chemical composition of the sun the only elements that were detected in spectra were hydrogen and various metals,[38] with the term metallic frequently used when describing them. In contemporary usage all the extra elements beyond just hydrogen and helium are termed metallic.

The astrophysicst Carlos Jaschek, and the stellar astronomer and spectroscopist Mercedes Jaschek, in their book The Classification of Stars, observed that:[39]

Stellar interior specialists use 'metals' to designate any element other than hydrogen and helium, and in consequence ‘metal abundance’ implies all elements other than the first two. For spectroscopists this is very misleading, because they use the word in the chemical sense. On the other hand photometrists, who observe combined effects of all lines (i.e. without distinguishing the different elements) often use this word 'metal abundance', in which case it may also include the effect of the hydrogen lines.

Metal-insulator transition

See main article: Metal–insulator transition.

There are many cases where an element or compound is metallic under certain circumstances, but a nonmetal in others. One example is metallic hydrogen which forms under very high pressures.[40] There are many other cases as discussed by Mott,[41] Inada et al[42] and more recently by Yonezawa.

There can also be local transitions to a nonmetal, particularly in semiconductor devices. One example is a field-effect transistor where an electric field can lead to a region where there are no electrons at the Fermi energy (depletion zone).[43] [44]

Properties specific to nonmetals

Nonmetals have a wide range of properties, for instance the nonmetal diamond is the hardest known material, while the nonmetal molybdenum disulfide is a solid lubricants used in space.[45] There are some properties specific to them not having electrons at the Fermi energy. The main ones, for which more details are available in the links are:[46]

Notes and References

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  2. Book: Yonezawa, Fumiko . Physics of metal-nonmetal transitions . 2017 . IOS Press . 978-1-61499-786-3 . Washington, DC .
  3. Book: Steudel, Ralf . Chemistry of the Non-Metals: Syntheses - Structures - Bonding - Applications . 2020 . De Gruyter . 978-3-11-057806-5 . 154 . 10.1515/9783110578065.
  4. 1931 . The theory of electronic semi-conductors . Proceedings of the Royal Society of London. Series A, Containing Papers of a Mathematical and Physical Character . en . 133 . 822 . 458–491 . 10.1098/rspa.1931.0162 . 1931RSPSA.133..458W . 0950-1207 . Wilson . A. H. . free .
  5. 1931 . The theory of electronic semi-conductors. - II . Proceedings of the Royal Society of London. Series A, Containing Papers of a Mathematical and Physical Character . en . 134 . 823 . 277–287 . 10.1098/rspa.1931.0196 . 1931RSPSA.134..277W . 0950-1207 . Wilson . A. H. . free .
  6. Mott . N F . Peierls . R . 1937 . Discussion of the paper by de Boer and Verwey . Proceedings of the Physical Society . 49 . 4S . 72–73 . 10.1088/0959-5309/49/4S/308 . 1937PPS....49...72M . 0959-5309.
  7. Boer . J H de . Verwey . E J W . 1937 . Semi-conductors with partially and with completely filled 3 d -lattice bands . Proceedings of the Physical Society . 49 . 4S . 59–71 . 10.1088/0959-5309/49/4S/307 . 1937PPS....49...59B . 0959-5309.
  8. Web site: Burke . Kieron . 2007 . The ABC of DFT .
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  14. Reihl . B. . Bednorz . J. G. . Müller . K. A. . Jugnet . Y. . Landgren . G. . Morar . J. F. . 1984 . Electronic structure of strontium titanate . Physical Review B . en . 30 . 2 . 803–806 . 10.1103/PhysRevB.30.803 . 1984PhRvB..30..803R . 0163-1829.
  15. Höchst . H. . Bringans . R. D. . Steiner . P. . Wolf . Th. . 1982 . Photoemission study of the electronic structure of stoichiometric and substoichiometric TiN and ZrN . Physical Review B . en . 25 . 12 . 7183–7191 . 10.1103/PhysRevB.25.7183 . 1982PhRvB..25.7183H . 0163-1829.
  16. Kim . Sangtae . Lee . Miso . Hong . Changho . Yoon . Youngchae . An . Hyungmin . Lee . Dongheon . Jeong . Wonseok . Yoo . Dongsun . Kang . Youngho . Youn . Yong . Han . Seungwu . 2020 . A band-gap database for semiconducting inorganic materials calculated with hybrid functional . Scientific Data . en . 7 . 1 . 387 . 10.1038/s41597-020-00723-8 . 2052-4463 . 7658987 . 33177500. 2020NatSD...7..387K .
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  20. Das . Tapan K. . Prusty . Smita . 2012 . Review on Conducting Polymers and Their Applications . Polymer-Plastics Technology and Engineering . en . 51 . 14 . 1487–1500 . 10.1080/03602559.2012.710697 . 0360-2559.
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  22. Book: Steudel, Ralf . Chemistry of the Non-Metals: Syntheses - Structures - Bonding - Applications . 2020 . De Gruyter . 978-3-11-057806-5 . 4 . 10.1515/9783110578065.
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  24. Web site: Worstall . Tim . 2015 . 'The Scientific Method' Is A Myth, Long Live The Scientific Method . . 2024-06-27 . https://web.archive.org/web/20151112005555/http://www.forbes.com/sites/chadorzel/2015/11/03/the-scientific-method-is-a-myth-long-live-the-scientific-method/ . 2015-11-12 .
  25. Web site: Worstall . Tim . 2015 . To Prove Econ 101 Is Wrong You Do Need To Understand Econ 101 . 2024-06-27 . Forbes . en.
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  28. Melvyn C. Usselman: William Hyde Wollaston Encyclopædia Britannica, retrieved 31 March 2013
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  30. Book: Hearnshaw, J.B.. The analysis of starlight. 1986. Cambridge University Press. Cambridge. 978-0-521-39916-6. 27.
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    • Gustav Kirchhoff (1859) die Fraunhofer'schen Linien" (On Fraunhofer's lines), Monatsbericht der Königlichen Preussische Akademie der Wissenschaften zu Berlin (Monthly report of the Royal Prussian Academy of Sciences in Berlin), 662–665.
    • Gustav Kirchhoff (1859) "Ueber das Sonnenspektrum" (On the sun's spectrum), Verhandlungen des naturhistorisch-medizinischen Vereins zu Heidelberg (Proceedings of the Natural History / Medical Association in Heidelberg), 1 (7) : 251–255.
  34. G. Kirchhoff . Ueber die Fraunhofer'schen Linien . Annalen der Physik . 185 . 1 . 148–150 . 1860 . 10.1002/andp.18601850115. 1860AnP...185..148K .
  35. G. Kirchhoff . Ueber das Verhältniss zwischen dem Emissionsvermögen und dem Absorptionsvermögen der Körper für Wärme und Licht . On the relation between the emissive power and the absorptive power of bodies towards heat and light . Annalen der Physik . 185 . 2 . 275–301 . 1860 . 10.1002/andp.18601850205. 1860AnP...185..275K . free.
  36. Web site: Kirchhoff and Bunsen on Spectroscopy . 2024-07-02 . www.chemteam.info.
  37. Web site: Spectrum analysis in its aqplication to terrestrial substances and the physical constitution of the heavenly bodies : familiarly explained / by H. Schellen ... . 2024-07-02 . HathiTrust . 2027/hvd.hn3317?urlappend=%3Bseq=211 . en.
  38. Book: Meadows, A. J. (Arthur Jack) . Early solar physics . 1970 . Oxford, New York, Pergamon Press . Internet Archive . 978-0-08-006653-0.
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