冷卻產生的收縮現象,可以有效抑制材料收縮量的增加。
(3)在模仁的功能上:可整合江忠晉同學的溫度和壓力微感測器,對 模仁表面溫度做即時的監控,由此可觀察模仁加熱溫度對材料熱 收縮應力的影響。
(4)熱壓實驗方面:由於本實驗是使用開放式的熱壓方式,材料在熱 壓的過程中會有側向的流動,使的壓力分佈由中心往邊緣方向會 逐漸遞減,導致在未施加功率時成形微結構有收縮不均勻的現 象,若改以封閉式的熱壓方式則材料所受到的正向壓力為一定 值,可以有效的改善收縮率不均的現象,在此條件下對模仁施加 功率與可完整脫模面積之間的關係可做更為精確的討論。
參考文獻
[1] E. W. Becher, W. Ehrfeld, P. Hagmann, A. Maner and D. Munchmeyer,
“Fabrication of microstructures with high aspect ratios and great
structural heights by synchrotron radiation lithography, galvanoforming, and plastic moulding (LIGA process)”, Microelectronic Engineering, Vol.
4, pp. 33-56, 1986.
[2] 程建人,”微機電系統技術與應用”,行政院國家科學委員會精密儀 器發展中心,民國 92 年 7 月。
[3] H. Becker and U. Heim “Hot embossing as a method for the fabrication of polymer high aspect ratio structures”, Sensors and Actuators A, Vol.
83, pp. 130-135, 1999.
[4] M. Heckele, W. Bacher, and K. D. Muller, “Hot embossing – The molding technique for plastic microstructures”, Microsystem Technologies, Vol. 4, pp. 122-124, 1998.
[5] L. Weber, W. Ehrfeld, H. Freimuth, M. Lacher, H. Lehr, and B. Pech, “Micro molding – A powerful tool for the large scale production of precise microstructure”, SPIE. 2879, pp. 156-167, 1996.
[6]J. Taniguchi, Y. Tokano, I. Miyamoto, M. Komuro and H. Hiroshima,
“Diamond nanoimprint lithography”, Nanotechnology, Vol. 13, pp.
592-596, 2002.
[7] J. Tao, Y. Chen, X. Zhao, A. Malik, and Z. Cui, “Room temperature nanoimprint lithography using a bilayer of HSQ /PMMA resist stack”, Microelectronic Engineering, Vol. 78-79, pp. 665-669, 2005.
[8] M. Bender, M.Otto, B. Hadam, B. Vratzov, B. Spangenberg, and H. Kurz,
“Fabrication of nanostructures using UV-based imprint technique”, Microelectronic Engineering, Vol. 53, pp.233-236, 2000.
[9] P. B. Grabiec, M. Zaborowski, K. Domanski, T. Gotszalk b, and I. W.
Rangelow, ”Nano-width lines using lateral pattern definition technique for nanoimprint template fabrication”, Microelectronic Engineering, Vol.
73-74, pp. 599-603, 2004.
[10] M. D. Austin, H. Ge, W. Wu, M. Li, Z. Yu, D. Wasserman, S. A.
Lyon, and S. Y. Chou, “Fabrication of 5 nm linewidth and 14 nm
pitch features by nanoimprint lithography”, Applied physics letter, Vol.
5299-5301, 2004.
[11] Y. Y. Zhang, J. Zhang, G. Luo, X. Zhou, G. Y. Xie, T. Zhu, and Z. F. Liu, “Fabrication of silicon-based multilevel nanostructures via scanning probe oxidation and anisotropic wet etching”,
Nanotechnology, Vol. 16, pp. 422-428, 2005.
[12] C.Perret, C. Gourgon, F. Lazzarino, J. Tallal, S. Landis and R. Pelzer,
“Characterization of 8-in. wafers printed by nanoimprint lithography”, Microelectronic Engineering, Vol. 73-74, pp.172-177, 2004.
[13] K. Seunarine, N. Gadegaard, M. O. Riehle and
C. D. W. Wilkinson, ”Optical heating for short hot embossing cycle times”, Microelectronic Engineering, Vol. 83, pp. 859-863, 2006.
[14] H. D. Rowland and W. P. William, “Polymer deformation and filling modes during microembossing”, Micromechanics and
Microengineering, Vol. 14, pp. 1625-1632, 2004.
[15] N. Roos, M. Wissen, T. Glinsner and H. C. Scheer, “Impact of vacuum environment on the hot embossing process”, Proceedings of SPIE, Vol.
5037, pp. 211-218, 2003.
[16] Y. Zhao, and T. Cui “Fabrication of high-aspect-ratio polymer-based electrostatic comb drives using the hot embossing technique”,
Micromechanics and Microengineering, Vol. 13, pp. 430-435, 2003.
[17] X. C. Shan, T. Ikehara, Y. Murakoshi, and R. Maeda
“Applications of micro hot embossing for optical switch
formation”, Sensors and Actuators A, Vol. 119, pp. 433-440, 2005.
[18] C. G. Choi, “Fabrication of optical waveguides in thermosetting polymers using hot embossing”, Micromechanics and
Microengineering, Vol. 14, pp. 945-949, 2004.
[19] Y. Guo, G. Liu, Y. Xiong, X. Zhu, W. Jun, and Y. Tian, “ Fabrication of LIGA mold insert using Ni-PTFE composite micro-electroforming”, Journal of Physics: Conference Series, Vol. 34 pp. 870-874, 2006.
[20] O.V. Makarova, D. C. Mancini, N. Moldovan, R. Divan, C. M. Tang, D. G.. Ryding, and R. H. Lee, “Microfabrication of freestanding metal structures using graphite substrate”, Sensor and actuators A, Vol. 103 pp.
182-186, 2003.
[21] C. Zhang, C. Yang, and D. Ding, ”Deep reactive ion etching of PMMA”, Applied Surface Science, Vol. 227 pp. 139-143, 2004.
[22] Kim, Sangwon Park, Harish Manohara, and Jeong-Bong Lee, “Rapid replication of polymeric and metallic high aspect ratio
microstructures using PDMS and LIGA technology”, Microsystem Technologies, Vol. 9, pp. 5-10, 2002.
[23] K. Sato, M. Shikida, T. Yamashiro, M. Tsunekawa, and S. Ito,
“Roughening of single-crystal silicon surface etched by KOH water”,
Sensor and Actuators A, Vol. 73, pp. 122-130, 1999.
[24]I. Zubel, I. Barycka, K. Kotowska, M. Kramkowska, “Silicon
anisotropic etching in alkaline solutions IV The effect of organic and inorganic agents on silicon anisotropic etching process
”,
Sensor and Actuators A, Vol. 87, pp. 163-171, 2001.[25] I. Zubel and M. Kramkowska, “The effect of isopropyl alcohol on etching rate and roughness of (1 0 0) Si surface etched in KOH and TMAH solutions”, Sensor and actuators A, Vol. 93, pp. 138-147,
2001.
[26] 賴文童,“微結構熱壓成形缺陷之探討”,國立交通大學碩 士論文,民國 89 年。
[27] 林威宇,“動態熱壓控制對微結構熱壓特性的影響既加工過程中聚 丙烯的結晶特性的初步探討”,國立交通大學碩士論文,民國 92 年。
[28] 黃重凱,“智慧型模仁的初步開發”,國立交通大學碩士論文,
民國 92 年。
[29] 蘇濬賢,“微機電系統化的模仁及其配套熱壓成形技術的 開發”,國立交通大學碩士論文,民國 94 年。
[30] Hong Xiao, “Introduction to semiconductor manufacturing technology”, Prentice Hall, 2004.
[31] 張俊彥,鄭晃忠,“積體電路製程及設備技術手冊”,中華 民國產業科技發展協進會,民國 86 年 7 月。
[32]H. Seidel, L. Csepregi, A. Heuberger, and H. Baumgartel, “Anisotropic etching of crystalline silicon in alkaline solutions”, J. Electrochem. Soc., Vol. 137, pp. 3612–3632, 1990.
[33] 劉士榮,“高分子流變學”,滄海書局,民國 94 年 2 月。
[34] Zehev Tadmor and Costas G. Gogos, “Principles of Polymer Processing”, John Wiley&Sons, 1979.