Fabrication of Small Triode-Type Cold-Cathode Field Emission Display with Staggered Gate-Electrode Layer

Yu Kui Li; Yun Peng Liu

doi:10.4028/www.scientific.net/MSF.663-665.791

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HomeMaterials Science ForumMaterials Science Forum Vols. 663-665Fabrication of Small Triode-Type Cold-Cathode...

Fabrication of Small Triode-Type Cold-Cathode Field Emission Display with Staggered Gate-Electrode Layer

Abstract:

Carbon nanotube used as cold cathode, the triode FED with staggered gate-electrode layer structure was fabricated with the screen-printing technique and conventional sintering process. Using superior mica plate as gate substrate material, the silver slurry was prepared to form the staggered gate electrode. The insulation layer was also manufactured over the gate substrate surface. The design and fabrication of the staggered gate-electrode layer was described in detail. By means of glass frit, the whole panel structure was vacuum-sealed. With the fabricated staggered gate-electrode layer, the modulation of electron emission from CNT field emitter by the gate voltage was confirmed. The packaged tridoe FED possessed better field emission uniformity, good image display performance and high display image brightness.

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Materials Science Forum (Volumes 663-665)

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791-794

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.663-665.791

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Online since:

November 2010

Authors:

Yu Kui Li, Yun Peng Liu

Keywords:

Device, Field Emission, Gate, Screen Printing

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References

[1] Y.S. Choi: Thin solid films Vol. 516 (2008), p.3357.

Google Scholar

[2] T. Kim, S. Kwon and H. Yoon et al.: Colloids and surface A: Physicochemical and engineer aspects Vol. 313-314 (2008), p.448.

Google Scholar

[3] S. Darbari, Y. Abdi, S. Mohajerzadeh et al.: Carbon. Vol. 48 (2010), p.2493.

Google Scholar

[4] P.S. Guo, T. Chen and Y.W. Chen et al.: Solid-state Electronics Vol. 52 (2008), p.877.

Google Scholar

[5] A.H. Jayatissa and K. Guo: Vacuum. Vol. 83 (2009), p.853.

Google Scholar

[6] D. Banerjee, A. Jha and K.K. Chattopadhyay: Physical E Vol. 41 (2009), p.1174.

Google Scholar

[7] S.G. Shang, C.C. Zhu and W.H. Liu: Thin solid films Vol. 516 (2008), p.5127.

Google Scholar

[8] Y.C. Choi and N. Lee: Diamond and related materials Vol. 17 (2008), p.270.

Google Scholar

[9] R. B. Rakhi, K. Sethupathi, S. Ramaprabhu. Applied Surface Science Vol. 254 (2008), p.6770.

Google Scholar

[10] F.G. Zeng, C.C. Zhu, W.H. Liu et al.: Microelectronics Journal Vol. 37 (2006), p.495.

Google Scholar

[11] A.A. Kuznetzov, S.B. Lee and M. Zhang et al. : Carbon. Vol. 48 (2009), p.41.

Google Scholar

[12] Y.K. Li, C.C. Zhu and X.H. Liu: Diamond and related materials Vol. 11 (2002), p.1845.

Google Scholar