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Magnetic semiconductor

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Unsolved problem in physics:
Can we build materials that show properties of both ferromagnets and semiconductors at room temperature?

Magnetic semiconductors are semiconductor materials that exhibit both ferromagnetism (or a similar response) and useful semiconductor properties. If implemented in devices, these materials could provide a new type of control of conduction. Whereas traditional electronics are based on control of charge carriers (n- or p-type), practical magnetic semiconductors would also allow control of quantum spin state (up or down). This would theoretically provide near-total spin polarization (as opposed to iron and other metals, which provide only ~50% polarization), which is an important property for spintronics applications, e.g. spin transistors.

While many traditional magnetic materials, such as magnetite, are also semiconductors (magnetite is a semimetal semiconductor with bandgap 0.14 eV), materials scientists generally predict that magnetic semiconductors will only find widespread use if they are similar to well-developed semiconductor materials. To that end, dilute magnetic semiconductors (DMS) have recently been a major focus of magnetic semiconductor research. These are based on traditional semiconductors, but are doped with transition metals instead of, or in addition to, electronically active elements. They are of interest because of their unique spintronics properties with possible technological applications.[1][2] Doped wide band-gap metal oxides such as zinc oxide (ZnO) and titanium oxide (TiO2) are among the best candidates for industrial DMS due to their multifunctionality in opticomagnetic applications. In particular, ZnO-based DMS with properties such as transparency in visual region and piezoelectricity have generated huge interest among the scientific community as a strong candidate for the fabrication of spin transistors and spin-polarized light-emitting diodes,[3] while copper doped TiO2 in the anatase phase of this material has further been predicted to exhibit favorable dilute magnetism.[4]

Hideo Ohno and his group at the Tohoku University were the first to measure ferromagnetism in transition metal doped compound semiconductors such as indium arsenide[5] and gallium arsenide[6] doped with manganese (the latter is commonly referred to as GaMnAs). These materials exhibited reasonably high Curie temperatures (yet below room temperature) that scales with the concentration of p-type charge carriers. Ever since, ferromagnetic signals have been measured from various semiconductor hosts doped with different transition atoms.

Theory

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The pioneering work of Dietl et al. showed that a modified Zener model for magnetism[7] well describes the carrier dependence, as well as anisotropic properties of GaMnAs. The same theory also predicted that room-temperature ferromagnetism should exist in heavily p-type doped ZnO and GaN doped by Co and Mn, respectively. These predictions were followed of a flurry of theoretical and experimental studies of various oxide and nitride semiconductors, which apparently seemed to confirm room temperature ferromagnetism in nearly any semiconductor or insulator material heavily doped by transition metal impurities. However, early Density functional theory (DFT) studies were clouded by band gap errors and overly delocalized defect levels, and more advanced DFT studies refute most of the previous predictions of ferromagnetism.[8] Likewise, it has been shown that for most of the oxide based materials studies for magnetic semiconductors do not exhibit an intrinsic carrier-mediated ferromagnetism as postulated by Dietl et al.[9] To date, GaMnAs remains the only semiconductor material with robust coexistence of ferromagnetism persisting up to rather high Curie temperatures around 100–200 K.

Materials

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The manufacturability of the materials depend on the thermal equilibrium solubility of the dopant in the base material. E.g., solubility of many dopants in zinc oxide is high enough to prepare the materials in bulk, while some other materials have so low solubility of dopants that to prepare them with high enough dopant concentration thermal nonequilibrium preparation mechanisms have to be employed, e.g. growth of thin films.

Permanent magnetization has been observed in a wide range of semiconductor based materials. Some of them exhibit a clear correlation between carrier density and magnetization, including the work of T. Story and co-workers where they demonstrated that the ferromagnetic Curie temperature of Mn2+-doped Pb1−xSnxTe can be controlled by the carrier concentration.[10] The theory proposed by Dietl required charge carriers in the case of holes to mediate the magnetic coupling of manganese dopants in the prototypical magnetic semiconductor, Mn2+-doped GaAs. If there is an insufficient hole concentration in the magnetic semiconductor, then the Curie temperature would be very low or would exhibit only paramagnetism. However, if the hole concentration is high (>~1020 cm−3), then the Curie temperature would be higher, between 100 and 200 K. [7] However, many of the semiconductor materials studied exhibit a permanent magnetization extrinsic to the semiconductor host material.[9] A lot of the elusive extrinsic ferromagnetism (or phantom ferromagnetism) is observed in thin films or nanostructured materials.[11]

Several examples of proposed ferromagnetic semiconductor materials are listed below. Notice that many of the observations and/or predictions below remain heavily debated.

References

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  1. ^ Furdyna, J.K. (1988). "Diluted magnetic semiconductors". J. Appl. Phys. 64 (4): R29. Bibcode:1988JAP....64...29F. doi:10.1063/1.341700.
  2. ^ Ohno, H. (1998). "Making Nonmagnetic Semiconductors Ferromagnetic". Science. 281 (5379): 951–5. Bibcode:1998Sci...281..951O. doi:10.1126/science.281.5379.951. PMID 9703503.
  3. ^ Ogale, S.B (2010). "Dilute doping, defects, and ferromagnetism in metal oxide systems". Advanced Materials. 22 (29): 3125–3155. Bibcode:2010AdM....22.3125O. doi:10.1002/adma.200903891. PMID 20535732. S2CID 25307693.
  4. ^ a b Assadi, M.H.N; Hanaor, D.A.H (2013). "Theoretical study on copper's energetics and magnetism in TiO2 polymorphs". Journal of Applied Physics. 113 (23): 233913–233913–5. arXiv:1304.1854. Bibcode:2013JAP...113w3913A. doi:10.1063/1.4811539. S2CID 94599250.
  5. ^ Munekata, H.; Ohno, H.; von Molnar, S.; Segmüller, Armin; Chang, L. L.; Esaki, L. (1989-10-23). "Diluted magnetic III-V semiconductors". Physical Review Letters. 63 (17): 1849–1852. Bibcode:1989PhRvL..63.1849M. doi:10.1103/PhysRevLett.63.1849. ISSN 0031-9007. PMID 10040689.
  6. ^ Ohno, H.; Shen, A.; Matsukura, F.; Oiwa, A.; Endo, A.; Katsumoto, S.; Iye, Y. (1996-07-15). "(Ga,Mn)As: A new diluted magnetic semiconductor based on GaAs". Applied Physics Letters. 69 (3): 363–365. Bibcode:1996ApPhL..69..363O. doi:10.1063/1.118061. ISSN 0003-6951.
  7. ^ a b Dietl, T.; Ohno, H.; Matsukura, F.; Cibert, J.; Ferrand, D. (February 2000). "Zener model description of ferromagnetism in zinc-blende magnetic semiconductors". Science. 287 (5455): 1019–22. Bibcode:2000Sci...287.1019D. doi:10.1126/science.287.5455.1019. PMID 10669409. S2CID 19672003.
  8. ^ Alex Zunger, Stephan Lany and Hannes Raebiger (2010). "The quest for dilute ferromagnetism in semiconductors: Guides and misguides by theory". Physics. 3: 53. Bibcode:2010PhyOJ...3...53Z. doi:10.1103/Physics.3.53.
  9. ^ a b J. M. D. Coey, P. Stamenov, R. D. Gunning, M. Venkatesan, and K. Paul (2010). "Ferromagnetism in defect-ridden oxides and related materials". New Journal of Physics. 12 (5): 053025. arXiv:1003.5558. Bibcode:2010NJPh...12e3025C. doi:10.1088/1367-2630/12/5/053025. S2CID 55748696.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  10. ^ Story, T.; Gała̧zka, R.; Frankel, R.; Wolff, P. (1986). "Carrier-concentration–induced ferromagnetism in PbSnMnTe". Physical Review Letters. 56 (7): 777–779. Bibcode:1986PhRvL..56..777S. doi:10.1103/PhysRevLett.56.777. PMID 10033282.
  11. ^ L. M. C. Pereira (2017). "Experimentally evaluating the origin of dilute magnetism in nanomaterials". Journal of Physics D: Applied Physics. 50 (39): 393002. Bibcode:2017JPhD...50M3002P. doi:10.1088/1361-6463/aa801f. S2CID 126213268.
  12. ^ "Muons in Magnetic Semiconductors". Triumf.info. Archived from the original on 2008-11-21. Retrieved 2010-09-19.
  13. ^ Fukumura, T; Toyosaki, H; Yamada, Y (2005). "Magnetic oxide semiconductors". Semiconductor Science and Technology. 20 (4): S103–S111. arXiv:cond-mat/0504168. Bibcode:2005SeScT..20S.103F. doi:10.1088/0268-1242/20/4/012. S2CID 96727752.
  14. ^ Philip, J.; Punnoose, A.; Kim, B. I.; Reddy, K. M.; Layne, S.; Holmes, J. O.; Satpati, B.; LeClair, P. R.; Santos, T. S. (April 2006). "Carrier-controlled ferromagnetism in transparent oxide semiconductors". Nature Materials. 5 (4): 298–304. Bibcode:2006NatMa...5..298P. doi:10.1038/nmat1613. ISSN 1476-1122. PMID 16547517. S2CID 30009354.
  15. ^ Raebiger, Hannes; Lany, Stephan; Zunger, Alex (2008-07-07). "Control of Ferromagnetism via Electron Doping in In 2 O 3 : Cr". Physical Review Letters. 101 (2): 027203. Bibcode:2008PhRvL.101b7203R. doi:10.1103/PhysRevLett.101.027203. ISSN 0031-9007. PMID 18764222.
  16. ^ Kittilstved, Kevin; Schwartz, Dana; Tuan, Allan; Heald, Steve; Chambers, Scott; Gamelin, Daniel (2006). "Direct Kinetic Correlation of Carriers and Ferromagnetism in Co2+: ZnO". Physical Review Letters. 97 (3): 037203. Bibcode:2006PhRvL..97c7203K. doi:10.1103/PhysRevLett.97.037203. PMID 16907540.
  17. ^ Lany, Stephan; Raebiger, Hannes; Zunger, Alex (2008-06-03). "Magnetic interactions of Cr − Cr and Co − Co impurity pairs in ZnO within a band-gap corrected density functional approach". Physical Review B. 77 (24): 241201. Bibcode:2008PhRvB..77x1201L. doi:10.1103/PhysRevB.77.241201. ISSN 1098-0121.
  18. ^ Martínez-Boubeta, C.; Beltrán, J. I.; Balcells, Ll.; Konstantinović, Z.; Valencia, S.; Schmitz, D.; Arbiol, J.; Estrade, S.; Cornil, J. (2010-07-08). "Ferromagnetism in transparent thin films of MgO" (PDF). Physical Review B. 82 (2): 024405. Bibcode:2010PhRvB..82b4405M. doi:10.1103/PhysRevB.82.024405. hdl:2445/33086.
  19. ^ Jambois, O.; Carreras, P.; Antony, A.; Bertomeu, J.; Martínez-Boubeta, C. (2011-12-01). "Resistance switching in transparent magnetic MgO films". Solid State Communications. 151 (24): 1856–1859. Bibcode:2011SSCom.151.1856J. doi:10.1016/j.ssc.2011.10.009. hdl:2445/50485.
  20. ^ "New room-temperature magnetic semiconductor material holds promise for 'spintronics' data-storage devices". KurzweilAI. Retrieved 2013-09-17.
  21. ^ Lee, Y. F.; Wu, F.; Kumar, R.; Hunte, F.; Schwartz, J.; Narayan, J. (2013). "Epitaxial integration of dilute magnetic semiconductor Sr3SnO with Si (001)". Applied Physics Letters. 103 (11): 112101. Bibcode:2013ApPhL.103k2101L. doi:10.1063/1.4820770.
  22. ^ Chambers, Scott A. (2010). "Epitaxial Growth and Properties of Doped Transition Metal and Complex Oxide Films". Advanced Materials. 22 (2): 219–248. Bibcode:2010AdM....22..219C. doi:10.1002/adma.200901867. PMID 20217685. S2CID 5415994.
  23. ^ Frandsen, Benjamin A.; Gong, Zizhou; Terban, Maxwell W.; Banerjee, Soham; Chen, Bijuan; Jin, Changqing; Feygenson, Mikhail; Uemura, Yasutomo J.; Billinge, Simon J. L. (2016-09-06). "Local atomic and magnetic structure of dilute magnetic semiconductor ( Ba , K ) ( Zn , Mn ) 2 As 2". Physical Review B. 94 (9): 094102. arXiv:1608.02684. Bibcode:2016PhRvB..94i4102F. doi:10.1103/PhysRevB.94.094102. ISSN 2469-9950.
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