Surface Acoustic Wave sensor based on AlN/Sapphire structure for high temperature and high frequency applications

被引:0
|
作者
Blampain, E. [1 ]
Elmazria, O. [1 ]
Aubert, T. [1 ]
Assouar, B. [1 ]
Legrani, O. [1 ]
机构
[1] Nancy Univ, IJL, CNRS, UMR7198, F-54506 Vandoeuvre Les Nancy, France
来源
2011 IEEE SENSORS | 2011年
关键词
SAW sensor; High temperature; AlN; Sapphire;
D O I
暂无
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
In this work, the performance of AlN/Sapphire structure in high frequencies is investigated. Several SAW devices were performed with various designs (gap, wavelength, metallization ratio, ... ) to study simultaneously different parameters (acoustic velocity, electromechanical coupling (K-2), acoustic propagation loss (alpha), TCF) versus frequency and temperature. Experimental results showed that as expected, alpha increases with temperature while K-2 is enhanced at high temperatures. Due to the antagonistic evolution of these two parameters, insertion loss decreases or increases as function of the gap. We also evidenced that this structure allows fabrication of devices operating up to 1.5 GHz and that the frequency varies linearly with temperature.
引用
收藏
页码:610 / 613
页数:4
相关论文
共 50 条
  • [31] High-Temperature Piezoelectric Crystals for Acoustic Wave Sensor Applications
    Zu, Hongfei
    Wu, Huiyan
    Wang, Qing-Ming
    [J]. IEEE TRANSACTIONS ON ULTRASONICS FERROELECTRICS AND FREQUENCY CONTROL, 2016, 63 (03) : 486 - 505
  • [32] A wireless surface acoustic wave temperature sensor using langasite as substrate material for high-temperature applications
    Wang, SQ
    Harada, J
    Uda, S
    [J]. JAPANESE JOURNAL OF APPLIED PHYSICS PART 1-REGULAR PAPERS SHORT NOTES & REVIEW PAPERS, 2003, 42 (9B): : 6124 - 6127
  • [33] Is AlN/Sapphire bilayer structure an alternative to Langasite for ultra-high-temperature SAW applications ?
    Aubert, Thierry
    Elmazria, Omar
    Bardong, Jochen
    Bruckner, Gudrun
    Assouar, Badreddine
    [J]. 2011 IEEE INTERNATIONAL ULTRASONICS SYMPOSIUM (IUS), 2011, : 2082 - 2085
  • [34] High frequency surface acoustic wave resonator-based sensor for particulate matter detection
    Thomas, Sanju
    Cole, Marina
    Villa-Lopez, Farah H.
    Gardner, Julian W.
    [J]. SENSORS AND ACTUATORS A-PHYSICAL, 2016, 244 : 138 - 145
  • [35] Surface Acoustic Wave Devices on AlN/Single-Crystal Diamond for High Frequency and High Performances Operation
    Benetti, M.
    Cannata, D.
    Di Pietrantonio, F.
    Verona, E.
    Almaviva, S.
    Prestopino, G.
    Verona, C.
    Verona-Rinati, G.
    [J]. 2008 IEEE ULTRASONICS SYMPOSIUM, VOLS 1-4 AND APPENDIX, 2008, : 1924 - +
  • [36] AlN sensor based on surface acoustic wave with signal amplification by AlN/GaN HEMT
    Tsarik, Konstantin A.
    Lavrentiev, Kirill K.
    Nevolin, Vladimir K.
    Petukhov, Vladimir A.
    [J]. 2015 INTERNATIONAL CONFERENCE ON CONTROL, INSTRUMENTATION, COMMUNICATION AND COMPUTATIONAL TECHNOLOGIES (ICCICCT), 2015, : 718 - 721
  • [37] High-sensitivity photonic crystal diaphragm based sapphire Fabry-Perot acoustic sensor for high-temperature applications
    Wang, Jiayan
    Yuan, Weizheng
    Ma, Zhibo
    Guo, Tongxin
    [J]. 2020 IEEE SENSORS, 2020,
  • [38] A new high-frequency surface acoustic wave sensor for humidity measurement
    Kawalec, Adam
    Pasternak, Mateusz
    [J]. IEEE TRANSACTIONS ON INSTRUMENTATION AND MEASUREMENT, 2008, 57 (09) : 2019 - 2023
  • [39] High-frequency stability oscillator for surface acoustic wave gas sensor
    He, Shitang
    Wang, Wen
    Li, Shunzhou
    Pan, Yong
    Liu, Minghua
    [J]. ACOUSTICAL SCIENCE AND TECHNOLOGY, 2009, 30 (01) : 7 - 12
  • [40] Growth of AlN piezoelectric film on diamond for high-frequency surface acoustic wave devices
    Benetti, M
    Cannatà, D
    Di Pietrantonio, F
    Verona, E
    [J]. IEEE TRANSACTIONS ON ULTRASONICS FERROELECTRICS AND FREQUENCY CONTROL, 2005, 52 (10) : 1806 - 1811
12345