SAW filter manufacture and piezoelectric materials evaluation based on printed electronics technology

Xiao-chen Liu , Kun Li , Xiu-wei Xuan , Yang Cao , Jian-fu Teng

Optoelectronics Letters ›› 2014, Vol. 10 ›› Issue (5) : 340 -342.

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Optoelectronics Letters ›› 2014, Vol. 10 ›› Issue (5) :340 -342. DOI: 10.1007/s11801-014-4117-4
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SAW filter manufacture and piezoelectric materials evaluation based on printed electronics technology
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Abstract

In this paper, the silver nanoparticle ink and ink-jet printing technology are used to manufacture the surface acoustic wave (SAW) filters. The characteristics of three common substrate piezoelectric materials of ST-quartz, Y36°-LiTaO3 and Y128°-LiNbO3 are evaluated. The experimental results show that Y128°-LiNbO3 matches the ink much better than others. The printed SAW filter with Y128°-LiNbO3 as piezoelectric substrate is realized, and its center frequency and bandwidth are 18.4 MHz and 500 kHz, respectively.

Keywords

Surface Acoustic Wave / Apply Physic Letter / Minimum Attenuation / Piezoelectric Substrate / Print Electronic

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Xiao-chen Liu, Kun Li, Xiu-wei Xuan, Yang Cao, Jian-fu Teng. SAW filter manufacture and piezoelectric materials evaluation based on printed electronics technology. Optoelectronics Letters, 2014, 10(5): 340-342 DOI:10.1007/s11801-014-4117-4

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Park S K, Kim Y H, Han J I, Moon D G, Kim W K. IEEE Transactions on Electron Devices. 2002, 49: 2008

[2]

Sirringhaus H, Kawase T, Friend R H, Shimoda T, Inbasekaran M, Wu W, Woo E P. Science. 2000, 290: 2123

[3]

Schneider J J, Hoffmann R C, Engstler J, Soffke O, Jaegermann W, Issanin A, Klyszcz A. Advanced Materials. 2008, 20: 3383

[4]

Noh Y Y, Cheng X Y, Sirringhaus H, Sohn J I, Welland M E, Kang D J. Applied Physics Letters. 2007, 91: 043109

[5]

Vaillancourt J, Zhang H Y, Vasinajindakaw P, Xia H T, Lu X J, Han X L, Janzen D C, Shih W S, Jones C S, Stroder M, Chen M Y, Subbaraman H, Chen R T, Berger U, Renn M. Applied Physics Letters. 2008, 93: 243301

[6]

Harting M, Zhang J, Gamota D R, Britton D T. Applied Physics Letters. 2009, 94: 193509

[7]

Ersman P A, Nilsson D, Kawahara J, Gustafsson G, Berggren M. Organic Electronics. 2013, 14: 1276

[8]

Baeg K J, Khim D, Kim J, Kim D Y, Sung S W, Yang B D, Noh Y Y. IEEE Electron Device Letters. 2013, 34: 126

[9]

Kawahara J, Ersman P A, Nilsson D, Katoh K, Nakata Y, Sandberg M, Nilsson M, Gustafsson G, Berggren M. Journal of Polymer Science Part B: Polymer Physics. 2013, 51: 265

[10]

Ersman P A, Kawahara J, Berggren M. Organic Electronics. 2013, 14: 3371

[11]

Andersson H A, Manuilskiy A, Haller S, Hummelgard M, Siden J, Hummelgard C, Olin H, Nilsson H E. Nanotechnology. 2014, 25: 4002
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