Temperature compensated cuts with zero power flow in TI3VS4 and TI3TaSe4
Temperature compensated cuts with zero power flow in TI3VS4 and TI3TaSe4
- Author(s): A. Jhunjhunwala ; J.F. Vetelino ; J.C. Field
- DOI: 10.1049/el:19760523
For access to this article, please select a purchase option:
Buy article PDF
Buy Knowledge Pack
IET members benefit from discounts to all IET publications and free access to E&T Magazine. If you are an IET member, log in to your account and the discounts will automatically be applied.
Thank you
Your recommendation has been sent to your librarian.
- Author(s): A. Jhunjhunwala 1 ; J.F. Vetelino 1 ; J.C. Field 1
-
-
View affiliations
-
Affiliations:
1: Department of Electrical Engineering, University of Maine at Orono, Orono, USA
-
Affiliations:
1: Department of Electrical Engineering, University of Maine at Orono, Orono, USA
- Source:
Volume 12, Issue 25,
9 December 1976,
p.
683 – 684
DOI: 10.1049/el:19760523 , Print ISSN 0013-5194, Online ISSN 1350-911X
Crystallographic orientations have been identified in TI3VS4 and TI3TaSe4 which are temperature compensated and have zero power flow. The orientations appear in the (110) axis cylinder cut and possess rather low s.a.w. velocities and reasonably high coupling.
Inspec keywords: vanadium compounds; acoustic surface waves; thallium compounds; piezoelectric materials; tantalum compounds
Other keywords:
Subjects: Piezoelectricity and electrostriction; Acoustic wave devices; Mechanical and acoustical properties of solid surfaces and interfaces; Piezoelectric and ferroelectric materials
References
-
-
1)
- Weinert, R.W., Isaacs, T.J.: `New piezoelectric materials which exhibit temperature stability for surface waves', Frequency control symposium proceedings, 1975, Atlantic City, p. 139–142.
-
2)
- (1973) IEEE Trans..
-
3)
- Slobodnik, A.J.: `The temperature coefficients of acoustic surface wave velocity and delay on lithium niobate, lithium tantalate, quartz and tellurium oxide', AFCRL–72–0092, USAF Cambridge Res. Labs. Report, 1971, See, for example, (unpublished).
-
4)
- T.E. Parker , M.B. Shulz . SiO2 film overlays for temperature stable surface acoustic wave devices. Appl. Phys. Lett. , 75 - 77
-
5)
- M.T. Wauk . LiNbO3–quartz–LiNbO3 composite delay line with zero linear temperature coefficient of delay. Electron. Lett. , 109 - 110
-
6)
- Potter, B.R., Schoenwald, J.S.: `Temperature regulation of LiNbO', Ultrasonics symposium proceedings, 1975, Los Angeles, p. 499–502, (unpublished).
-
7)
- M. Tamura , M. Yonezawa . Temperature stablised piezoelectric ceramics for acoustic surface wave filters. Proc. IEEE
-
8)
- Slobodnik, A.J., Conway, E.D., Delmonico, K.T.: `Microwave acoustic handbook', AFCRL 73–0597, USAF Cambridge Res. Labs. Report, 1973, For a definition of this cut see (unpublished).
-
9)
- Parker, T.E., Shulz, M.B.: `Temperature stable surface acoustic wave delay lines with SiO', Ultrasonics symposium proceedings, 1974, Milwaukee, p. 295–298, (unpublished).
-
10)
- T.J. Isaacs , R.W. Weinert . Crystal growth and properties of TI3BX4 crystals for acoustic surface wave and bulk acoustic wave devices. J. Electron. Mat. , 13 - 22
-
11)
- Carr, P.H., O'Connell, R.M.: `New temperature compensated materials with high piezoelectric coupling', Frequency control symposium proceedings, 1976, Atlantic City, NJ, (in press).
-
12)
- Jhunjhumwala, A., Vetelino, J.F., Field, J.C.: `Berlinite, a temperature compensated material for surface acoustic wave applications', Ultrasonics symposium proceedings, 1976, Annapolis, (in press).
-
13)
- M. Kodama , H. Egami , S. Yoshida . Fabrication of temperature stabilized piezoelectric ceramics for surface wave applications. Japan. J. Appl. Phys. , 1847 - 1848
-
14)
- JHUNJHUNWALA, A., VETELINO, J. F., and FIELD, J. C.: (to be published).
-
15)
- Wauk, M.T.: `Surface wave scattering and loss for planar discontinuities in bonded acoustic composites', Ultrasonics symposium proceedings, 1973, Monterey, p. 355–358, (unpublished).
-
16)
- WEINERT, R. W.: Private communication.
-
1)
Related content
