Aluminium oxynitride explained

Aluminium oxynitride (marketed under the name ALON by Surmet Corporation^[1]) is a transparent ceramic composed of aluminium, oxygen and nitrogen. Aluminium oxynitride is optically transparent (≥ 80%) in the near-ultraviolet, visible, and mid-wave-infrared regions of the electromagnetic spectrum. It is four times as hard as fused silica glass, 85% as hard as sapphire, and nearly 115% as hard as magnesium aluminate spinel. It can be fabricated into transparent windows, plates, domes, rods, tubes, and other forms using conventional ceramic powder processing techniques.

Aluminium oxynitride is the hardest polycrystalline transparent ceramic available commercially.^[2] Because of its relatively low weight, distinctive optical and mechanical properties, and resistance to oxidation or radiation, it shows promise for applications such as bulletproof, blast-resistant, and optoelectronic windows.^[3] Aluminium oxynitride-based armor has been shown to stop multiple armor-piercing projectiles of up to .50 BMG.^[4]

Properties

Aluminium oxynitride is resistant to various acids, bases, and water.^[5]

Mechanical

Aluminium oxynitride has the following mechanical properties:^[2]

• Compressive strength 2.68 GPa
• Flexural strength 0.38–0.7 GPa
• Fracture toughness 2.0 MPa·m^1/2
• Knoop hardness 1800 kg/mm² (0.2 kg load)
• Poisson ratio 0.24
• Shear modulus 135 GPa
• Young's modulus 334 GPa

Thermal and optical

Aluminium oxynitride has the following thermal and optical properties:

• Specific heat 0.781 J/(g·°C)
• Thermal conductivity 12.3 W/(m·°C)
• Thermal expansion coefficient ~4.7/°C
• Transparency range 200–5000 nm

Applications

Aluminium oxynitride is used for infrared-optical windows, with greater than 80% transparency at wavelengths below about 4 micrometers, dropping to near zero at about 6 micrometers.^[6] It has also been demonstrated as an interface passivation layer in some semiconductor-related applications.^[7]

Aluminium oxynitride has less than half the weight and thickness of glass-based transparent armor.^[8] Aluminium oxynitride armor of 1.6inches thickness is capable of stopping .50 BMG armor-piercing rounds, which can penetrate 3.7inches of traditional glass laminate.^[9]

In 2005, the United States Air Force began testing aluminium oxynitride-based armor.^[10]

Manufacture

Aluminium oxynitride can be fabricated as windows, plates, domes, rods, tubes and other forms using conventional ceramic powder processing techniques. Its composition can vary slightly: the aluminium content from about 30% to 36%, which has been reported to affect the bulk and shear moduli by only 1–2%.^[11] The fabricated greenware is subjected to heat treatment (densification) at elevated temperatures followed by grinding and polishing to transparency. It can withstand temperatures of about 2100C in inert atmospheres. The grinding and polishing substantially improves the impact resistance and other mechanical properties of armor.^[12]

Patents

Patents related to aluminium oxynitride include:

• Aluminium oxynitride having improved optical characteristics and method of manufacture TM Hartnett, RL Gentilman, 1984
• Process for producing polycrystalline cubic aluminium oxynitride JW McCauley, 1980
• Transparent aluminium oxynitride and method of manufacture RL Gentilman, EA Maguire, 1985;, 1988
• Transparent aluminium oxynitride-based ceramic article JP Mathers, 1993

See also

• Aluminium nitride
• Corundum
• Transparent ceramics

External links

• Processing of Optically Transparent Aluminum Oxynitride
• "Solubility Limits of La and Y in Aluminum Oxynitride (AlON) at 1870°C". Lior Miller and Wayne D. Kaplan. Department of Materials Engineering, Technion, Haifa, Israel, 2006.
• The Influence of Sintering Additives on the Microstructure and Properties of ALON. Yechezkel Ashuach. Master's Thesis, Technion – Israel Institute of Technology, 2003.

Notes and References

1. Transparent aluminum oxynitride and method of manufacture . May 28, 1985 . 4520116 . Richard L. Gentilman, Edward A. Maguire, Leonard E. Dolhert . Surmet Corp.
2. Mohan Ramisetty et al. Transparent Polycrystalline Spinels Protect and Defend, American Ceramic Society Bulletin, vol.92, 2, 20–24 (2013)
3. Web site: Domes & Infrared Optics. Surmet.
4. Mohan. Ramisetty. Suri A.. Sastri. Lee. Goldman. Transparent Ceramics Find Wide Use in Optics. Photonics Spectra. Aug 2013.
5. 10.1016/0955-2219(89)90030-7. Aluminum oxynitride spinel: A review. 1989. Corbin. N. Journal of the European Ceramic Society. 5. 3. 143–154 .
6. Goldman. Lee M.. Twedt. Rich. Balasubramanian. Sreeram. Sastri. Suri. Randal W. . Tustison . 2011-05-20. ALON optical ceramic transparencies for window, dome, and transparent armor applications. Window and Dome Technologies and Materials XII. SPIE. 8016. 64–77. 10.1117/12.886122. 2011SPIE.8016E..08G . 123044722 .
7. 10.1063/1.2388246. Aluminum oxynitride interfacial passivation layer for high-permittivity gate dielectric stack on gallium arsenide. 2006. Zhu. Ming. Tung. Chih-Hang. Yeo. Yee-Chia. Applied Physics Letters. 89. 20. 202903. 2006ApPhL..89t2903Z. 2022-02-11.
8. Security News (2015-06-03). Optically Clear Aluminium Provides Bulletproof Protection. TSS, 3 June 2015. Retrieved on 2015-07-10 from http://www.tssbulletproof.com/optically-clear-aluminum-provides-bulletproof-protection/ .
9. Web site: Surmet's ALON Transparent Armor 50 Caliber Test . . en. 2023-01-09.
10. Web site: Air Force testing lighter, transparent ALON armor . Schogol . Jeff . October 30, 2005 . . 2020-06-25 .
11. Elastic properties of polycrystalline aluminum oxynitride spinel and their dependence on pressure, temperature and composition. 10.1111/j.1151-2916.1988.tb07527.x. 1988. Graham. Earl K.. Munly. W.C.. McCauley. James W.. Corbin. Norman D.. Journal of the American Ceramic Society. 71. 10. 807–812.
12. Joseph M. Wahl et al. Recent Advances in ALON Optical Ceramic, Surmet