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http://dx.doi.org/10.3795/KSME-B.2013.37.2.119

Study of Specific Resistance of Conductive Ink According to Temperature During Laser Sintering Process  

Lee, Dae-Geon (Graduate School of Mechanical Engineering, Hanyang Univ.)
Park, Yong-Han (Graduate School of Mechanical Engineering, Hanyang Univ.)
Park, Ji-Young (Graduate School of Mechanical Engineering, Hanyang Univ.)
Kim, Dong-Keun (Graduate School of Mechanical Engineering, Hanyang Univ.)
Moon, Yoon-Jae (Graduate School of Mechanical Engineering, Hanyang Univ.)
Moon, Seung-Jae (Graduate School of Mechanical Engineering, Hanyang Univ.)
Hwang, Jun-Young (Korea Institute of Industrial Technology)
Kang, Heui-Seok (Korea Institute of Industrial Technology)
Publication Information
Transactions of the Korean Society of Mechanical Engineers B / v.37, no.2, 2013 , pp. 119-124 More about this Journal
Abstract
In this study, the two-dimensional transient temperature of printed Ag nanoparticle ink during continuous wave laser sintering was calculated. Ag nanoparticle ink was printed on a glass substrate by inkjet printing. Then, a 532-nm continuous wave laser with different laser intensities was irradiated on the printed Ag nanoparticle ink for 60 s. During laser irradiation, the in-situ specific resistance of the sintered ink was measured. To obtain the transient temperature of the sintered ink during the laser sintering process, a two-dimensional transient heat conduction equation was derived by applying the Wiedemann-Franz law. It was found that the specific resistance of the sintered ink decreased with an increase in the sintering temperature of the printed ink.
Keywords
Inkjet Printing; Conductive Ink; Laser Sintering; Temperature Calculation;
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1 van Osch, T. H. J., Perelaer, J., De Laat, A. W. M. and Schubert, U. S., 2008, "Inkjet Printing of Narrow Conductive Tracks on Untreated Polymeric Substrates," Adv. Mater., Vol. 20, pp. 343-345.   DOI   ScienceOn
2 Kim, T. Y., Hwang, J. Y. and Moon, S. J., 2010, "Laser Curing of the Silver/Copper Nanoparticle Ink via Optical Property Measurement and Calculation," J.J.A.P., Vol. 49, pp. 05EA09.
3 Lee, H. H., Chou, K. S. and Huang, K. C., 2005, "Inkjet Printing of Nanosized Silver Colloids," Nanotechnology, Vol. 16, pp. 2436-2441.   DOI   ScienceOn
4 Lee, H. H., Chou, K. S. and Huang, K. C., 2005, "Inkjet Printing of Nanosized Silver Colloids," Nanotechnology, Vol. 16, pp. 2436-2441.   DOI   ScienceOn
5 Bieri, N. R., Chung, J., Haferl, S. E., Poulikakos, D. and Grigoropoulos, C.P., 2003, "Microstructuring by Pring and Laser Curing of Nanoparticle Solutions," Appl. Phys, Lett., Vol. 82, pp. 3529-3531.   DOI   ScienceOn
6 Chiolerio, A., Maccioni, G., Martino, P., Cotto, M., Pandolfi, P., Rivolo, P., Ferrero, S. and Scaltrito, L., 2011, "Inkjet Printing and Low Power Laser Annealing of Silver Nanoparticle Traces for the Realization of Low Resistivity Lines for Flexible Electronics," Microelectronic Eng., Vol. 88, pp. 2481-2483.   DOI   ScienceOn
7 Modest, M. F., 1993, "Radiative Heat Transfer," McGraw Hill, 1, pp. 61.
8 Kittle, C., 2007, "Introduction to Solid State Physics," John wiley & Sons, Inc, 8, pp. 156.
9 Luo, W., Hu, W. and Xiao, S., 2008, "Size Effect on the Thermodynamic Properties of Silver Nanoparticles," J. Phys. Chem. C, Vol. 112, pp. 2359-2369.   DOI   ScienceOn
10 Yang, C. C. and Li, S., 2007, "Investigation of Cohesive Energy Effects on Size Dependent Physical and Chemical Properties of Nanocrystals," Phys. Rev. B, Vol. 75, p. 165413.   DOI   ScienceOn
11 Buffat, P. and Borel, J. P., 1976, "Size Effect on the Melting Temperature of Gold Particles," Phys. Rev. A, Vol. 13, p. 2287   DOI
12 Jak, M. J. J., Konstapel, C., Kreuningen, A. C., Verhoeven, J. and Frenken, J. W. M., 2000, "Scanning Tunneling Microscopy Study of the Growth of Small Palladium Particles on $TiO_{2}$(110)," Surf. Sci., Vol. 457, pp. 295-310.   DOI   ScienceOn
13 Datye, A. K., Xu, Q., Kharas, K. C. and Mccarty, J. M., 2006, "Particle Size Distributions in Heterogeneous Catalysts: What do They Tell us About the Sintering Mechanism?," Vol. 111, pp. 59-67.   DOI   ScienceOn
14 Zeng, P., Zajac, S., Clapp, P. C. and Rifkin,J. A., 1998, "Nanoparticle Sintering Simulations," Materials Science and Eng., Vol. A252, pp. 301-306.
15 Perelaer, J., Smith, P. J., Mager, D., Soltman, D., Volkman, S. K., Subramanian, V., Korvink, J. G. and Schubert, U. S., 2010, "Printed Electronics: the Challenge Involved in Printing Devices, Interconnects, and Contacts Based on Inorganic Materials," J. Mater. Chem., Vol. 20, pp. 8446-8453.   DOI   ScienceOn