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Application of high-thermal-conductivity diamond for space phased array antenna

Wei Lu ,
Jin Li ,
Jianyin Miao ,
Liangxian Chen ,
Junjun Wei ,
Jinlong Liu ,
Chengming Li
Volume 1, Issue 1 (2021)
DOI: 10.1080/26941112.2021.1996211
Full content

Abstract

Active phased array antenna typically featured high performance, high device integration, and high heat flux, making it difficult to dissipate heat. Diamond, the substance with the closest arrangement of atoms in nature, has the advantages of a high thermal conductivity and strong adaptability to the space environment. The batch applications of high-thermal-conductivity diamonds for the thermal management of the phased array antennas of the inter-satellite links were introduced in this paper. The diamond was developed by the direct-current arc-plasma chemical vapor deposition method. The product size, thermal conductivity, precision, and application scale all met the engineering requirements. The high-precision assembly of the diamond and the structural frame enabled the efficient heat collection and transfer from the distributed point heat sources of multiple transmit/receive (T/R) modules. Verified on the ground, the thermal matching design between the diamond and the metal frame exhibited an outstanding heat dissipation performance. After four satellites using the diamonds were launched, the flight data showed good antenna thermal control, with temperature gradients of the T/R modules less than 2.2 °C, further verifying the rationality and effectiveness of using high-thermal-conductivity diamonds in the thermal design and implementation of antennas.

Keywords

diamond; thermal control; phased array; high heat flux

References

  • Schuh P, Sledzik H, Reber R, et al. T/R-module technologies today and future trends[C]. The proceedings of the 40th European microwave conference, Paris, France, 2010. p. 1540–1543. doi:https://doi.org/10.23919/EUMC.2010.5616412.
  • Ogura S, Mizutani T, Hatakeyama H, et al. High power L-band T/R module utilizing GaN HPA for satellite use[C]. The 20th AIAA international communications satellite systems conference (ICSSC), Nara Japan, 2011.
  • Lu W, Du ZL. Thermal design, analysis and experimental verification of a phased array T/R module. The 11th Space Thermal Physics Conference, Beijing, 2013. p.163–169. (in Chinese).
  • Masanobu Y, Tomonori K, Tsuyoshi M. Active phased array antenna for WINDS satellite[C]. AIAA. 2007;3240.
  • Whiteman DE, Valencia LM, Birr RB. Space-based telemetry and range safety project Ku-band and Ka-band phased array antenna [R]. NASA TM-212872. 2005. p. 1–16.
  • Lu W, Li J. High-efficiency thermal control and flight verification of the Ka phased array antenna. The 7th Shanghai Conference on Aerospace Science and Technology Innovation and Development, Shanghai, 2020. p. 364–371. (in Chinese).
  • Parlak M, McGlen RJ. Cooling of high power active phased array antenna using axially grooved heat pipe for a space application[C]. 2015 7th International Conference on Recent Advances in Space Technologies (RAST), Istanbul, Turkey, 2015. p. 743–748. doi:https://doi.org/10.1109/RAST.2015.7208439.
  • Berman R. The properties of diamond[M]. New York: Academic Press, 1979.
  • Chen GH, Zhang Y. 2004. Fabrication and application of diamond film. Beijing: Chemical Industry Press, 90. (in Chinese).
  • Lu FX, ed. Fabrication and application of diamond film. Vol. 1. Beijing: Science Press; 2014. p. 542. (in Chinese).
  • Andrew MB, Eugene A. CVD diamond for high power laser applications[C]. High-Power laser materials processing: Lasers, beam delivery, diagnostics, and applications II. San Francisco, USA, 2013.
  • Alexander M, Daniel T, Henk DW. Diamond Meta-Surfaces for high power laser applications [C]. IEEE Research and Applications of Photonics in Defense Conference (RAPID), Miramar Beach, USA, 2018.
  • Dayton JA, Mearini GT, Chen H, et al. Diamond-studded helical traveling wave tube[J]. IEEE Trans Electron Devices. 2005;52(5):695–701.
  • Ackemann T, Alduraibi M, Campbell S, et al. Diamond heat sinking of terahertz antennas for continuous-wave photomixing [J]. J Appl Phys. 2012;112(12):123109.
  • Han Y, Lau BL, Tang GY, et al. Heat dissipation improvement with diamond heat spreader on hybrid Si micro-cooler for GaN devices[C]. IEEE Electron Devices and Solid-State Circuits (EDSSC), Singapore, 2015.
  • Tyhach M, Altman D, Bernstein S, et al. Next generation gallium nitride HEMTs enabled by diamond substrates [C]. Lester Eastman Conference on High Performance Devices (LEC), Ithaca, USA, 2014.
  • Kuball M. Ultra-high power semiconductor devices: heat-sinking using GaN-on-diamond [C]. Sixteenth International Conference on Solid State Lighting and LED-based Illumination Systems, San Diego, USA, 2017.
  • Campbell G, Eppich H, Lang K, et al. Advanced cooling designs for GaN-on-Diamond MMICs [C]. ASME International Technical Conference and Exhibition on Packaging and Integration of Electronic and Photonic, San Diego, USA, 2015.
  • Davydov LN, Rybka AV, Vierovkin SF, et al. Registration of high-intensity electron and x-ray fields with polycrystalline CVD diamond detectors[C]. SPIE Hard X-Ray, Gamma-Ray, and Neutron Detector Physics XIV, San Diego, USA, 2012.
  • Jaynes RL, Cook AM, Abe DK, et al. Study of W-band diamond RF windows for high-average- power TWTs[C]. Eighteenth international vacuum electronics conference (IVEC), London, UK, 2017.
  • Wickham B, Schoofs F, Olsson-Robbie S, et al. Pushing the boundaries of high power lasers: low loss, large area CVD diamond. [C]. SPIE Components and Packaging for Laser Systems IV, San Francisco, USA, 2018.
  • Vladimir JT, Evaldo JC, Joao RM, et al. CVD-diamond as a new material and its space application [C]. 51st International Astronautical Congress, Rio, Brazil, 2000.
  • Nedoskin P, Gladchenkov E, Zakharchenko K, et al. Review the space radiation CVD diamond multi-layer detector [C]. ISBCON, Moscow, Russia; 2016. p. 1–4, doi:https://doi.org/10.1109/SIBCON.2016.7491780.
  • Liu JL, An K, Chen LX, et al. Research progress of freestanding CVD diamond films [J]. Surface Technol. 2018;47(4):1–10. (in Chinese) doi:https://doi.org/10.16490/j.cnki.issn.1001-3660.2018.04.001
  • Li CM, Chen LX, Liu JL, et al. Recent progress of free-standing diamond films prepared by DC aec plasma jet method [J]. Diamond & Abrasives Engin. 2018;38(1):16–27. (in Chinese).
  • Liu XC, Guo H, An XM, et al. Progress of high quality diamond single crystal prepared by CVD method [J]. J Synthetic Crystals. 2017;46(10):1897–1901. (in Chinese) doi:https://doi.org/10.3969/j.issn.1000-985X.2017.10.004
  • Baba K, Aikawa Y, Shohata N. Thermal conductivity of diamond films. J Appl Phys. 1991;69(10):7313–7315. doi:https://doi.org/10.1063/1.347580
  • Zhu RH, Miao JY, Liu JL, et al. High temperature thermal conductivity of free-standing diamond films prepared by DC arc plasma jet CVD. Diamond & Related Mater. 2014;50(11):55–59.
  • Li CM, Wang LM, Chen LX, et al. Effect of area arc distribution on properties of free-standing diamond films in DC arc plasma jet deposition [J]. J Synthetic Crystals. 2010;9(4):900–905. (in Chinese).
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