Indium aluminium nitride (InAlN) is a direct bandgap semiconductor material used in the manufacture of electronic and photonic devices. It is part of the III-V group of semiconductors, being an alloy of indium nitride and aluminium nitride, and is closely related to the more widely used gallium nitride. It is of special interest in applications requiring good stability and reliability, owing to its large direct bandgap and ability to maintain operation at temperatures of up to 1000 °C.,[1] making it of particular interest to areas such as the space industry.[2] InAlN high-electron-mobility transistors (HEMTs) are attractive candidates for such applications owing to the ability of InAlN to lattice-match to gallium nitride, eliminating a reported failure route in the closely related aluminium gallium nitride HEMTs.

InAlN is grown epitaxially by metalorganic chemical vapour deposition[3] or molecular beam epitaxy[4] in combination with other semiconductor materials such as gallium nitride, aluminium nitride and their associated alloys to produce semiconductor wafers, which are then used as the active component in semiconductor device manufacture. InAlN is an especially difficult material to grow epitaxially due to the widely different properties of aluminium nitride and indium nitride,[5] and the resulting narrow window for optimised growth can lead to contamination (i.e. to produce indium gallium aluminium nitride) and poor crystal quality,[6] at least when compared to AlGaN. Similarly, device fabrication techniques optimised for AlGaN devices may require adjustment to account for the different material properties of InAlN [7]

References

  1. Maier, D.; Alomari, M.; Grandjean, N.; Carlin, J.-F.; Diforte-Poisson, M.-A.; et al. (2012). "InAlN/GaN HEMTs for Operation in the 1000°C Regime: A First Experiment". IEEE Electron Device Letters. Institute of Electrical and Electronics Engineers (IEEE). 33 (7): 985–987. doi:10.1109/led.2012.2196972. ISSN 0741-3106. S2CID 328833.
  2. Smith, M D; O’Mahony, D; Vitobello, F; Muschitiello, M; Costantino, A; et al. (2015-12-14). "A comparison of the 60Co gamma radiation hardness, breakdown characteristics and the effect of SiNx capping on InAlN and AlGaN HEMTs for space applications". Semiconductor Science and Technology. IOP Publishing. 31 (2): 025008. doi:10.1088/0268-1242/31/2/025008. ISSN 0268-1242.
  3. Xue, JunShuai; Hao, Yue; Zhou, XiaoWei; Zhang, JinCheng; Yang, ChuanKai; et al. (2011). "High quality InAlN/GaN heterostructures grown on sapphire by pulsed metal organic chemical vapor deposition". Journal of Crystal Growth. Elsevier BV. 314 (1): 359–364. Bibcode:2011JCrGr.314..359X. doi:10.1016/j.jcrysgro.2010.11.157. ISSN 0022-0248.
  4. Higashiwaki, M., et al, (2006), Molecular Beam Epitaxy, 2002 International Conference on, p. 235
  5. Smith, Matthew D.; Sadler, Thomas C.; Li, Haoning; Zubialevich, Vitaly Z.; Parbrook, Peter J. (2013-08-19). "The effect of a varied NH3 flux on growth of AlN interlayers for InAlN/GaN heterostructures". Applied Physics Letters. AIP Publishing. 103 (8): 081602. Bibcode:2013ApPhL.103h1602S. doi:10.1063/1.4818645. hdl:10468/4280. ISSN 0003-6951.
  6. Smith, M. D.; Taylor, E.; Sadler, T. C.; Zubialevich, V. Z.; Lorenz, K.; et al. (2014). "Determination of Ga auto-incorporation in nominal InAlN epilayers grown by MOCVD" (PDF). Journal of Materials Chemistry C. Royal Society of Chemistry (RSC). 2 (29): 5787. doi:10.1039/c4tc00480a. ISSN 2050-7526.
  7. Smith, M. D.; O'Mahony, D.; Conroy, M.; Schmidt, M.; Parbrook, P. J. (2015-09-14). "InAlN high electron mobility transistor Ti/Al/Ni/Au Ohmic contact optimisation assisted by in-situ high temperature transmission electron microscopy". Applied Physics Letters. AIP Publishing. 107 (11): 113506. Bibcode:2015ApPhL.107k3506S. doi:10.1063/1.4930880. ISSN 0003-6951.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.