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| ???org.dspace.app.webui.jsptag.ItemTag.dcfield??? | Value | Language |
|---|---|---|
| dc.contributor.advisor | 林招松 | zh_TW |
| dc.contributor.advisor | Chao-Sung Lin | en |
| dc.contributor.author | 林昂櫻 | zh_TW |
| dc.contributor.author | Ang-Ying Lin | en |
| dc.date.accessioned | 2026-01-13T16:04:23Z | - |
| dc.date.available | 2026-01-14 | - |
| dc.date.copyright | 2026-01-13 | - |
| dc.date.issued | 2026 | - |
| dc.date.submitted | 2026-01-05 | - |
| dc.identifier.citation | [1] 邵樂峰. (2021.08.05). 先進封裝:八仙過海各顯神通. EE Times. Retrieved June 30, 2023, from https://www.eettaiwan.com/20210805nt61-advanced-packaging/
[2] Tummala, R. R. (2001). Fundamentals of microsystems packaging. New York, NY: McGraw-Hill. [3] McLellan, P. (2019, December 6). System in package, why now? (Part I & Part II). Cadence. Retrieved July 3, 2023, from https://community.cadence.com/cadence_blogs_8/b/breakfast-bytes/posts/chiplets2 [4] Lau, J. H. (2022). Recent advances and trends in advanced packaging. IEEE Transactions on Components, Packaging and Manufacturing Technology, 12(2), 228-252. [5] Brewer Science. (n.d.). What is wafer-level packaging? Retrieved July 3, 2023, from https://tw.brewerscience.com/products/advanced-packaging/ [6] Sperling, E. (2018, September 10). Sorting out packaging options. Semiconductor Engineering. Retrieved July 4, 2023, from https://semiengineering.com/sorting-out-packaging-options/ [7] Zhu, C. (2020). Experimental and theoretical investigation of bifurcated wafer warpage evolution in the wafer level packaging processes. Journal of Materials Science: Materials in Electronics, 31(19), 16531-16538. [8] Braun, T., Becker, K. F., Hoelck, O., Voges, S., Kahle, R., Dreissigacker, M., & Schneider-Ramelow, M. (2019). Fan-out wafer and panel level packaging as packaging platform for heterogeneous integration. Micromachines, 10(5), 342. [9] Lin, Y. M., Wu, S. T., Shen, W. W., Huang, S. Y., Kuo, T. Y., Lin, A. Y., ... & Chen, K. N. (2018, May). An RDL-first fan-out wafer level package for heterogeneous integration applications. In 2018 IEEE 68th Electronic Components and Technology Conference (ECTC) (pp. 349-354). IEEE. [10] McCleary, R., Cochet, P., Swarbrick, T., Sim, C., Singh, G., Bum, Y. C., & Aung, A. K. (2016, May). Panel level advanced packaging. In 2016 IEEE 66th Electronic Components and Technology Conference (ECTC) (pp. 25-30). IEEE. [11] Lau, J. H., Chen, G. C. F., Huang, J. Y. C., Chou, R. T. S., Yang, C. C. L., Liu, H. N., & Tseng, T. J. (2021). Hybrid substrate by fan-out RDL-first panel-level packaging. IEEE Transactions on Components, Packaging and Manufacturing Technology, 11(8), 1301-1309. [12] Lau, J. H. (2018). Fan-out wafer-level packaging. Singapore: Springer Nature. [13] CoWoS-Base All Programmable-3D-ICFamilies. Accessed:Oct. 20, 2013. [Online]. Available: http://press.xilinx.com/2013-10-20-Xilinx-and-TSMCReach-Volume-Production-on-all-28nm-CoWoSbased-All-Programmable-3D-IC-Families [14] Dina Medhat. (2022.8.1) "2.5/3D IC Reliability Verification Has Come A Long Way" Semiconductor Engineering. Retrieved July 5, 2023, from https://semiengineering.com/2-5-3d-ic-reliability-verification-has-come-a-long-way/ [15] Chen, M. F., Lin, C. S., Liao, E. B., Chiou, W. C., Kuo, C. C., Hu, C. C., ... & Yu, D. (2020, June). SoIC for low-temperature, multi-layer 3D memory integration. In 2020 IEEE 70th Electronic Components and Technology Conference (ECTC) (pp. 855-860). IEEE. [16] Ramalingam, Suresh. "Advanced Packaging–Future Challenges." CMC Conference. 2016. [17] Q. Tong, G. Fountain, and P. Enquist, “Method for low temperature bonding and bonded structure,” U.S. Patent 6 902 987, B1, Feb. 16, 2000. [18] Q. Tong, G. Fountain, and P. Enquist, “Method for low temperature bonding and bonded structure,” U.S. Patent 7 387 944, B2, Aug. 14, 2005. [19] Adeia Inc. (2022). Second quarter 2022 earnings conference call transcripts. Retrieved July 5, 2023, from https://statementdog.com/analysis/ADEA/earnings_calls/236134 [20] "Die Attach Equipment Market Report 2019", YOLE. Retrieved July 5, 2023, from https://s3.i-micronews.com/uploads/2019/10/YD19042_Die-Attach-Equipment-Market-Report-2019_Yole_sample.pdf?fbclid=IwAR24gXNlg1gsmAmOWLwRR2XIU4JY8WABWufq6BimVEzPHeOiD7UBPBgjMGg [21] Lee, B., Mrozek, P., Fountain, G., Posthill, J., Theil, J., Gao, G., ... & Mirkarimi, L. (2019, May). Nanoscale topography characterization for direct bond interconnect. In 2019 IEEE 69th Electronic Components and Technology Conference (ECTC) (pp. 1041-1046). IEEE. [22] Dylan Patel. (2022.1.6) "Advanced Packaging Part 2 - Review Of Options/Use From Intel, TSMC, Samsung, AMD, ASE, Sony, Micron, SKHynix, YMTC, Tesla, and Nvidia" Semianalysis. Retrieved July 6, 2023, https://www.semianalysis.com/p/advanced-packaging-part-2-review [23] Prophesee. (2022.4.13) "Prophesee launches Event-Based Vision evaluation kit based on new Sony IMX636ES HD sensor realized in collaboration between Sony and Prophesee." Retrieved July 6, 2023, from https://www.prophesee.ai/2022/04/13/new-sony-imx636es-hd-sensor-realized-in-collaboration-between-sony-and-prophesee/ [24] David Schor. (2021.7.26) "Intel Unveils Foveros Omni And Foveros Direct; Leveraging Hybrid Bonding" Wikichip Fuse. Retrieved July 6, 2023, from https://fuse.wikichip.org/news/5949/intel-unveils-foveros-omni-and-foveros-direct-leveraging-hybrid-bonding/ [25] Dr. Ian Cutress. (2021.5.31) "AMD Demonstrates Stacked 3D V-Cache Technology: 192 MB at 2 TB/sec" AnandTech. Retrieved July 6, 2023, from https://www.anandtech.com/show/16725/amd-demonstrates-stacked-vcache-technology-2-tbsec-for-15-gaming [26] Phil Garrou. (2021.12.6) "IFTLE 504: YMTC Implements Hybrid Bonding for 128-Layer 3D NAND" 3DInCites. Retrieved July 6, 2023, from https://www.3dincites.com/2021/12/iftle-504-ymtc-implements-hybrid-bonding-for-128-layer-3d-nand/ [27] Brandstätter, Birgit, et al. "High-speed ultra-accurate direct C2W bonding." 2020 IEEE 70th Electronic Components and Technology Conference (ECTC). IEEE, 2020. [28] EVG. "GEMINI® FB Automated Collective Die-to-Wafer Bonding System." Retrieved July 6, 2023, from https://www.evgroup.com/zh/products/bonding/die-to-wafer-bonding-systems/gemini-fb-d2w/ [29] SUSS MicroTec. "XBS300 Hybrid Bonding Platform" Retrieved July 6, 2023, from https://www.suss.com/en/products-solutions/wafer-bonder/xbs300-hybrid-bonder [30] Bourjot, E., Castan, C., Nadi, N., Bond, A., Bresson, N., Sanchez, L., ... & Cheramy, S. (2021, June). Towards $5\\\\mu\\\\mathrm {m} $ interconnection pitch with Die-to-Wafer direct hybrid bonding. In 2021 IEEE 71st Electronic Components and Technology Conference (ECTC) (pp. 470-475). IEEE. [31] Sakuma, Katsuyuki, et al. "Surface Energy Characterization for Die-Level Cu Hybrid Bonding." 2022 IEEE 72nd Electronic Components and Technology Conference (ECTC). IEEE, 2022. [32] T. Kim, M. Howlader, T. Itoh, T. Suga, Room temperature Cu–Cu direct bonding using surface activated bonding method, J. Vac. Sci. Technol. A: Vac. Surf. Films 21 (2003) 449–453. [33] C.-M. Liu, H.-W. Lin, Y.-S. Huang, Y.-C. Chu, C. Chen, D.-R. Lyu, K.-N. Chen, K.- N. Tu, Low-temperature direct copper-to-copper bonding enabled by creep on (111) surfaces of nanotwinned Cu, Sci. Rep. 5 (2015) 9734. [34] W. -L. Chiu, K. -W. Chou and H. -H. Chang, "Nanotwinned Copper Hybrid Bonding and Wafer-On-Wafer Integration," 2020 IEEE 70th Electronic Components and Technology Conference (ECTC), Orlando, FL, USA, 2020, pp. 210-215 [35] Yang, S. C., Tran, D. P., Ong, J. J., Chiu, W. L., Chang, H. H., & Chen, C. (2023). Periodic reverse electrodeposition of (1 1 1)-oriented nanotwinned Cu in small damascene SiO2 vias. Journal of Electroanalytical Chemistry, 935, 117328. [36] Mirkarimi, L., Uzoh, C., Suwito, D., Lee, B., Fountain, G., Workman, T., ... & Ponnuswamy, T. (2022, May). The influence of Cu microstructure on thermal budget in hybrid bonding. In 2022 IEEE 72nd Electronic Components and Technology Conference (ECTC) (pp. 162-167). IEEE. [37] Chiu, W. L., Lee, O. H., Chiang, C. W., & Chang, H. H. (2022, May). Low-Temperature wafer-to-wafer hybrid bonding by nanocrystalline copper. In 2022 IEEE 72nd Electronic Components and Technology Conference (ECTC) (pp. 679-684). IEEE. [38] Haisma, J., & Spierings, G. A. C. M. (2002). Contact bonding, including direct-bonding in a historical and recent context of materials science and technology, physics and chemistry: historical review in a broader scope and comparative outlook. Materials Science and Engineering: R: Reports, 37(1-2), 1-60. [39] Kilby, J. S. (1976). Invention of the integrated circuit. IEEE Transactions on electron devices, 23(7), 648-654. [40] Peter Ramm, James Jian-Qiang Lu, Maaike M. V. Taklo. (2011.11.17). Handbook of Wafer Bonding. John Wiley & Sons [41] Boettge , B. , Dresbach , C. , Graff , A. , and Petzold , M. ( 2008 ) Mechanical characterization and microstructure diagnostics of glass frit bonded interfaces . Electrochem. Soc. Trans., 16 (8), 441 – 448 . [42] Niklaus, F., Stemme, G., Lu, J. Q., & Gutmann, R. J. (2006). Adhesive wafer bonding. Journal of applied physics, 99(3). [43] Pomerantz, D.I. (1968) Anodic bonding. US Patent 3,397,278. [44] Wallis, G. and Pomerantz, D.I. (1969) Field - assisted glass – metal sealing. J. Appl. Phys., 40, 3946 - 3949. [45] Knowles, K. M., & Van Helvoort, A. T. J. (2006). Anodic bonding. International materials reviews, 51(5), 273-311. [46] Lasky, J.B. (1986) Wafer bonding for silicon - on - insulator technologies. Appl. Phys. Lett., 48, 78-80. [47] Shimbo, M., Furukawa, K., Fukuda, K., and Tanzawa, K. (1986) Silicon - to - silicon direct bonding method. J. Appl. Phys., 60, 2987-2989. [48] 林建泰,林光隆 (2002) 覆晶接合銲錫隆點之製程及以真空技術製作之UBM. 真空科技,15:4 2002.11[民91.11],頁40-47 [49] Miller, L. F. (1969). Controlled collapse reflow chip joining. IBM Journal of Research and Development, 13(3), 239-250. [50] Ezawa, H., Miyata, M., Honma, S., Inoue, H., Tokuoka, T., Yoshioka, J., & Tsujimura, M. (2001). Eutectic Sn-Ag solder bump process for ULSI flip chip technology. IEEE transactions on electronics packaging manufacturing, 24(4), 275-281. [51] Wu, C. L., & Huang, M. L. (2002). Creep behavior of eutectic Sn-Cu lead-free solder alloy. Journal of electronic materials, 31(5), 442-448. [52] Anhock, S., Oppermann, H., Kallmayer, C., Aschenbrenner, R., Thomas, L., & Reichl, H. (1998, April). Investigations of Au-Sn alloys on different end-metallizations for high temperature applications [solders]. In Twenty Second IEEE/CPMT International Electronics Manufacturing Technology Symposium. IEMT-Europe 1998. Electronics Manufacturing and Development for Automotives (Cat. No. 98CH36204) (pp. 156-165). IEEE. [53] Chuang, T. H., Hsu, S. W., Lin, Y. C., Yeh, W. T., Chen, C. H., Lee, P. I., ... & Cheng, H. P. (2020). Improvement of Sn-3Ag-0.5 Cu Soldered Joints Between Bi 0.5 Sb 1.5 Te 3 Thermoelectric Material and a Cu Electrode. Journal of Electronic Materials, 1-9. [54] Nai, S. M. L., Wei, J., Lim, P. C., & Wong, C. K. (2003, December).Silicon-to-silicon wafer bonding with gold as intermediate layer. In Proceedings of the 5th Electronics Packaging Technology Conference (EPTC 2003) (pp. 119-124). IEEE. [55] Wolffenbuttel, R. F., & Wise, K. D. (1994). Low-temperature silicon wafer-to-wafer bonding using gold at eutectic temperature. Sensors and Actuators A: Physical, 43(1-3), 223-229. [56] Chen, K. N., Tan, C. S., Fan, A., & Reif, R. (2003). Morphology and bond strength of copper wafer bonding. Electrochemical and Solid-State Letters, 7(1), G14. [57] Tan, C. S., & Reif, R. (2005). Silicon multilayer stacking based on copper wafer bonding. Electrochemical and Solid-State Letters, 8(6), G147. [58] Tan, C. S., Peng, L., Fan, J., Li, H., & Gao, S. (2012). Three-dimensional wafer stacking using Cu–Cu bonding for simultaneous formation of electrical, mechanical, and hermetic bonds. IEEE Transactions on Device and Materials Reliability, 12(2), 194-200. [59] Tan, Chuan Seng, et al. "Low temperature CuCu thermo-compression bonding with temporary passivation of self-assembled monolayer and its bond strength enhancement." Microelectronics Reliability 52.2 (2012): 321-324. [60] Huang, Yan-Pin, et al. "Demonstration and electrical performance of Cu–Cu bonding at 150° C with Pd passivation." IEEE Transactions on Electron Devices 62.8 (2015): 2587-2592. [61] Panigrahi, Asisa Kumar, et al. "Demonstration of sub 150° C Cu-Cu thermocompression bonding for 3D IC applications, utilizing an ultra-thin layer of Manganin alloy as an effective surface passivation layer." Materials Letters 194 (2017): 86-89. [62] Liu, Ziyu, et al. "Modified pulse laser deposition of Ag nanostructure as intermediate for low temperature Cu-Cu bonding." Applied Surface Science 445 (2018): 16-23. [63] Juang, Jing-Ye, et al. "Copper-to-copper direct bonding on highly (111)-oriented nanotwinned copper in no-vacuum ambient." Scientific reports 8.1 (2018): 13910. [64] Liu, C. M. et al. Low-temperature direct copper-to-copper bonding enabled by creep on highly (1 1 1)-oriented Cu surfaces. Scr. Mater. 78-79, 65-68 (2014). [65] Liu, Chien-Min, et al. "Low-temperature direct copper-to-copper bonding enabled by creep on (111) surfaces of nanotwinned Cu." Scientific reports 5.1 (2015): 1-11. [66] Lai, Yu-Chang, Po-Ching Wu, and Tung-Han Chuang. "Characterization of interfacial structure for low-temperature direct bonding of Si substrates sputtered with Ag nanotwinned films." Materials Characterization 175 (2021): 111060. [67] Chang, Leh-Ping, et al. "Direct metal bonding using nanotwinned Ag films with (1 1 1) surface orientation under air atmosphere for heterogeneous integration." Applied Surface Science 576 (2022): 151845. [68] Wu, Po-Ching, and Tung-Han Chuang. "Evaporation of Ag nanotwinned films on Si substrates with ion beam assistance." IEEE Transactions on Components, Packaging and Manufacturing Technology 11.12 (2021): 2222-2228. [69] Wu, John A., et al. "Fabrication of (111)-oriented nanotwinned Au films for Au-to-Au direct bonding." Materials 11.11 (2018): 2287. [70] Sun, Ligang, Xiaoqiao He, and Jian Lu. "Nanotwinned and hierarchical nanotwinned metals: A review of experimental, computational and theoretical efforts." npj Computational Materials 4.1 (2018): 6. [71] Uttam, Prateek, et al. "Nanotwinning: Generation, properties, and application." Materials & Design 192 (2020): 108752. [72] Aasmundtveit, K. E., Tollefsen, T. A., Luu, T. T., Duan, A., Wang, K., & Hoivik,N. (2013, September). Solid-Liquid Interdiffusion (SLID) bonding—Intermetallic bonding for high temperature applications. In 2013 Eurpoean Microelectronics Packaging Conference (EMPC) (pp. 1-6). IEEE. [73] Kim, J. Y., Park, S. W., Yoon, J. Y., Kim, H. Y., Lee, D. Y., Kim, G. T., ... & Kang, E. G. (2004). The characteristics of joints with Indium-silver alloy using diffusion soldering method. MRS Online Proceedings Library Archive, 817. [74] Cook, G. O., & Sorensen, C. D. (2011). Overview of transient liquid phase and partial transient liquid phase bonding. Journal of materials science, 46(16), 5305-5323. [75] Bosco, N. S., & Zok, F. W. (2004). Critical interlayer thickness for transient liquid phase bonding in the Cu–Sn system. Acta Materialia, 52(10), 2965-2972. [76] Lu, J. - Q. (2009) 3D hyper - integration and packaging technologies for micro - nano -systems. Proc. IEEE, 97 (1), 18 – 30. [77] Lu, J. - Q., Jay McMahon, J., and Gutmann, R.J. (2007) Wafer bonding of damascene - patterned metal/adhesive redistribution layers. US Patent Application 20070207592, 6 September 2007. [78] McMahon, J.J., Lu, J. - Q., and Gutmann, R.J. (2005) Wafer bonding of damascene -patterned metal/adhesive redistribution layers for via - fi rst 3D interconnect. 55 th IEEE Electronic Components and Technology Conference (ECTC 2005), pp. 331-336. [79] McMahon, J. J., Niklaus, F., Kumar, R. J., Yu, J., Lu, J. Q., & Gutmann, R. J. (2005). CMP compatibility of partially cured benzocyclobutene (BCB) for a via-first 3D IC process. MRS Online Proceedings Library (OPL), 867. [80] McMahon, J. J., Chan, E., Lee, S. H., Gutmann, R. J., & Lu, J. Q. (2008, May). Bonding interfaces in wafer-level metal/adhesive bonded 3D integration. In 2008 58th Electronic Components and Technology Conference (pp. 871-878). IEEE. [81] Christopher Netzband, Kevin Ryan, Yuji Mimura, Son Ilseok, Hirokazu Aizawa, Nathan Ip, Xuemei Chen, Hideyuki Fukushima, Shinichi Tan (2023) 0.5μm Pitch Next Generation Hybrid Bonding with High Alignment Accuracy for 3D Integration. 73rd IEEE Electronic Components and Technology Conference (ECTC 2023) pp. 1100 – 1104. [82] Kai Ma, Nikolaos Bekiaris, Sesh Ramaswami, Taotao Ding, Gernot Probst, Jürgen Burggraf, Thomas Uhrmann (2023) 0.5 μm Pitch Wafer-to-wafer Hybrid Bonding with SiCN Bonding Interface for Advanced Memory. 73rd IEEE Electronic Components and Technology Conference (ECTC 2023), pp. 1110 – 1114 [83] E. Beyne, S. Kim, L. Peng, N. Heylen, J. Messemaeker, O. Okudur, et. al., "Scalable, sub 2μm pitch, Cu/SiCN to Cu/SiCN hybrid wafer-to-wafer bonding technology," 2017 IEEE International Electron Devices Meeting (IEDM), San Francisco, CA, USA, 2017, pp. 32.4.1-32.4.4. [84] Murugesan, M., et al. "Cu-SiO 2 Hybrid Bonding Yield Enhancement Through Cu Grain Enlargement." 2022 IEEE 72nd Electronic Components and Technology Conference (ECTC). IEEE, 2022. [85] Panchenko, Iuliana, et al. "Microstructure Development of Cu/SiO₂Hybrid Bond Interconnects After Reliability Tests." IEEE Transactions on Components, Packaging and Manufacturing Technology 12.3 (2022): 410-421. [86] Inoue, F., Bertheau, J., Suhard, S., Phommahaxay, A., Ohashi, T., Kinoshita, T., ... & Beyne, E. (2019, October). Protective layer for collective die to wafer hybrid bonding. In 2019 International 3D Systems Integration Conference (3DIC) (pp. 1-4). IEEE. [87] Suhard, S., Phommahaxay, A., Kennes, K., Bex, P., Fodor, F., Liebens, M., ... & Beyne, E. (2020, June). Demonstration of a collective hybrid die-to-wafer integration. In 2020 IEEE 70th Electronic Components and Technology Conference (ECTC) (pp. 1315-1321). IEEE. [88] Plach, T., Hingerl, K., Tollabimazraehno, S., Hesser, G., Dragoi, V., & Wimplinger, M. (2013). Mechanisms for room temperature direct wafer bonding. Journal of Applied Physics, 113(9). [89] W. D. Kingery, H. K. Bowen, D. R. Uhlmann, Introduction to ceramics, John Weily & Sons. Inc., 1976 [90] Gambino, J. P., Winzenread, R., Thomas, K., Muller, R., Truong, H., Defibaugh, D., ... & Oldham, N. (2017, May). Reliability of hybrid bond interconnects. In 2017 IEEE International Interconnect Technology Conference (IITC) (pp. 1-3). IEEE. [91] Seo, H., Park, H., & Kim, S. E. (2020). Cu-SiO2 Hybrid Bonding. Journal of the Microelectronics and Packaging Society, 27(1), 17-24. https://doi.org/10.6117/KMEPS.2020.27.1.0017 [92] Suni, T., Henttinen, K., Suni, I., & Mäkinen, J. (2002). Effects of plasma activation on hydrophilic bonding of Si and SiO2. Journal of the Electrochemical Society, 149(6), G348. [93] Hu, L., Goh, S. C. K., Tao, J., Lim, Y. D., Zhao, P., Lim, M. J. Z., & Tan, C. S. (2021, June). In-depth parametric study of Ar or N2 plasma activated Cu surfaces for Cu-Cu direct bonding. In 2021 IEEE 71st Electronic Components and Technology Conference (ECTC) (pp. 420-425). IEEE. [94] Hu, L., Lim, Y. D., Zhao, P., Lim, M. J. Z., & Tan, C. S. (2022, March). Plasma-activated Cu-Cu direct bonding in ambient for die-die and die-wafer bonding. In 2022 6th IEEE Electron Devices Technology & Manufacturing Conference (EDTM) (pp. 276-278). IEEE. [95] Hu, L., Lim, Y. D., Zhao, P., Lim, M. J. Z., Miao, W., Ju, X., & Tan, C. S. (2023, April). Time Evolution Study of Two-Step Plasma-Treated Copper-Copper Direct Bonding in Ambient. In 2023 International Conference on Electronics Packaging (ICEP) (pp. 45-46). IEEE. [96] Marks, M. R., Hassan, Z., & Cheong, K. Y. (2015). Ultrathin wafer pre-assembly and assembly process technologies: A review. Critical Reviews in Solid State and Materials Sciences, 40(5), 251-290. [97] 林明彥、張嘉升、黎文龍,2005,『原子力顯微儀的原理 (上)』,科儀新知,第二十七卷第二期,94.10 [98] 洪瑞華、黃少華,2002,『非破壞性檢測新助手-掃瞄式聲波顯微鏡』,科儀新知,第二十四卷第二期,91.10 [99] Integrated Service Technology. Scanning Electron Microscope (SEM) Retrieved July 14, 2023, from https://www.istgroup.com/en/service/sem/ [100] 彭裕庭、劉宇倫、陳健群,2022,『三維原子級電子斷層顯微技術在半導體元件之應用』,科儀新知,第 232 期,9月,原子解析度穿透式電子顯微鏡專題 [101] 李昀達、張友同,2023,『從材料晶體結構強化先進封裝-EBSD精準解析掌握封裝可靠度』,新電子科技雜誌,第 446 期,第29-32頁。5月。技術探勘專題 [102] Koh, D., Wang, A., Schneider, P., Bosinski, B., & Oh, K. W. (2017). Introduction of a chemical-free metal PDMS thermal bonding for fabrication of flexible electrode by metal transfer onto PDMS. Micromachines, 8(9), 280, [103] Kagawa, Y., Hashiguchi, H., Kamibayashi, T., Haneda, M., Fujii, N., Furuse, S., ... & Iwamoto, H. (2020, October). Impacts of misalignment on 1μm pitch Cu-Cu hybrid bonding. In 2020 IEEE International Interconnect Technology Conference (IITC) (pp. 148-150). IEEE. [104] Chiu, W. L., Lee, O. H., Chiang, C. W., & Chang, H. H. (2021, June). Low temperature wafer-to-wafer hybrid bonding by nanotwinned copper. In 2021 IEEE 71st Electronic Components and Technology Conference (ECTC) (pp. 365-370). IEEE. [105] Bai, D., Zhong, X. F., Puligadda, R., Burggraf, J., Burgstaller, D., Lypka, C., & Verzosa, J. (2009). Edge protection of temporarily bonded wafers during backgrinding. ECS Transactions, 18(1), 757. [106] Engineering R&D Division, Operation V, The effects of edge trimming, DISCO Technical Review Mar. 2016 [107] Roshanghias, A., Kaczynski, J., Rodrigues, A., Karami, R., Pires, M., Burggraf, J., & Schmidt, A. (2023). 3D Integration via D2D Bump-Less Cu Bonding with Protruded and Recessed Topographies. ECS Journal of Solid State Science and Technology, 12(8), 084001. [108] Kang, Q., Li, G., Li, Z., Tian, Y., & Wang, C. (2023). Surface co-hydrophilization via ammonia inorganic strategy for low-temperature Cu/SiO2 hybrid bonding. Journal of Materials Science & Technology, 149, 161-166. [109] Lee, J. R., Aziz, M. S. A., Ishak, M. H. H., & Khor, C. Y. (2022). A review on numerical approach of reflow soldering process for copper pillar technology. The International Journal of Advanced Manufacturing Technology, 121(7-8), 4325-4353. [110] Zhang, Y., Dong, P., Wang, J., Zhang, X., Leyendecker, K., Herkommer, M., ... & Liang, J. (2023, May). All Nanograined Copper Is Not Created Equal. In 2023 IEEE 73rd Electronic Components and Technology Conference (ECTC) (pp. 1124-1128). IEEE. [111] Schmidt, R., & Schwarz, C. (2023, May). Optimization of the Cu Microstructure to Improve Copper-to-Copper Direct Bonding for 3D Integration. In 2023 IEEE 73rd Electronic Components and Technology Conference (ECTC) (pp. 2024-2028). IEEE. [112] "Die Top System®", Heraeus. Retrieved May 29, 2024, from https://www.heraeus.com/media/media/het/doc_het/products_and_solutions_het_documents/material_systems_1/die_top_system_docs/DPIS_Die_Top_System-05-2018.pdf [113] Siepe, D.; Bayerer, R.; Roth, R.: The Future of Wire Bonding is? Wire Bonding!. 6th CIPs 2010 in Nürnberg (16-18 March 2010). Paper 3.7. [114] Liu, D., Kuo, T. Y., Liu, Y. W., Hong, Z. J., Chung, Y. T., Chou, T. C., ... & Chen, K. N. (2021). Investigation of low-temperature Cu–Cu direct bonding with Pt passivation layer in 3-D integration. IEEE Transactions on Components, Packaging and Manufacturing Technology, 11(4), 573-578. [115] Hong, Z. J., Liu, D., Hu, H. W., Cho, C. I., Weng, M. W., Liu, J. H., & Chen, K. N. (2022). Investigation of bonding mechanism for low-temperature CuCu bonding with passivation layer. Applied Surface Science, 592, 153243. [116] Wang, L., Wang, W., Hueting, R. J., Rietveld, G., & Ferreira, J. A. (2022). Review of topside interconnections for wide bandgap power semiconductor packaging. IEEE Transactions on Power Electronics, 38(1), 472-490. [117] H. Takagi, R. Maeda, T.R. Chung, N. Hosoda, T. Suga, Effect of surface roughness on roomtemperature wafer bonding by Ar beam surface activation, Jpn. J. Appl. Phys. 37 (1998) 4197–4203. 67 https://doi.org/10.1143/jjap.37.4197. [118] Zhou, S., Wan, S., Zou, B., Yang, Y., Sun, H., Zhou, Y., & Liang, J. (2023). Interlayer Investigations of GaN Heterostructures Integrated into Silicon Substrates by Surface Activated Bonding. Crystals, 13(2), 217. [119] Franke, J., Syed-Khaja, A., Schramm, R., & Ochs, R. (2015). Investigations in the optimization of power electronics packaging through additive plasma technology. Procedia CIRP, 37, 59-64. [120] Wang, L., Wang, W., Zeng, K., Deng, J., Rietveld, G., & Hueting, R. J. (2023). Opportunities and challenges of pressure contact packaging for wide bandgap power modules. IEEE Transactions on Power Electronics, 39(2), 2401-2419. [121] M. Montazeri et al., “Vertically stacked, flip-chip wide bandgap MOSFET co-optimized for reliability and switching performance,” IEEE Trans. Emerg. Sel. Topics Power Electron., vol. 9, no. 4, pp. 3904–3915, Aug. 2021. [122] T. Nishimura, K. Mimura, K. Yamamoto, S. Idaka, and T. Shinohara, “High heat dissipation and high heat durability technologies for transfermolded power modules with insulating sheets,” in Proc. 9th Int. Conf. Integr. Power Electron. Syst., 2016, pp. 1–5. [123] Huesgen, T. (2022). Printed circuit board embedded power semiconductors: A technology review. Power Electronic Devices and Components, 3, 100017. [124] Gan, C. L., Francis, C., Chan, B. L., & Uda, H. (2014). Copper Wire Bonding, Preeti S., Chauhan, Anupam Choubey, ZhaoWei Zhong, Michael G. Pecht, Springer (2014). XXVI, pp. 235, ISBN: 978-1-4614-5760-2 (Print), 978-1-4614-5761-9 (Online). Microelectronics Reliability, 54(2), 490-490. [125] Zhang Wenwu, Pan Hao, Ma Qiuchen, Li Mingyu, Ji Hongjun. Review of Power Ultrasonic Micro-nano Joining Technology for Electronic Manufacturing. Journal of Mechanical Engineering, 58(2), 100-121. [126] Kang, H., Sharma, A., & Jung, J. P. (2020). Recent progress in transient liquid phase and wire bonding technologies for power electronics. Metals, 10(7), 934. [127] Zhou, H., Chang, A., Fan, J., Cao, J., An, B., Xia, J., ... & Zhang, Y. (2023). Copper wire bonding: A review. Micromachines, 14(8), 1612. [128] Zhou, H., Zhang, Y., Cao, J., Su, C., Li, C., Chang, A., & An, B. (2023). Research progress on bonding wire for microelectronic packaging. Micromachines, 14(2), 432. [129] Lykova, M.; Panchenko, I.; Künzelmann, U.; Johanna, R.; Geidel, M.; Wolf, J.; Lang, K.D. Characterisation of Cu/Cu bonding using self-assembled monolayer. Solder. Surf. Mt. Technol. 2018, 30, 106–111. [130] Hsu, S.T.; Hung, F.Y.; Wu, B.D. Study of tensile properties, electrothermal characteristics and packaging reliability on Cu–Pt–Au–Pd fine micro-alloyed wire. J. Mater. Sci. Mater. Electron. 2023, 34, 1130 [131] L. Lu, Y. Shen, X. Chen, L. Qian, K. Lu, Ultrahigh strength and high electrical conductivity in copper, Science, 304(5669) (2004) 422-426. [132] T.-H. Chuang, P.-C. Wu, Y.-C. Lin, Lattice buffer effect of Ti film on the epitaxial growth of Ag nanotwins on Si substrates with various orientations, Materials Characterization, 167 (2020) 110509. [133] Brökelmann, M., Siepe, D., Hunstig, M., McKeown, M., & Oftebro, K. (2015, October). Copper wire bonding ready for industrial mass production. In International Symposium on Microelectronics (Vol. 2015, No. 1, pp. 000399-000405). International Microelectronics Assembly and Packaging Society. [134] Huang, Q., Peng, C., Ellen, S. F. M., Zhu, W., & Wang, L. (2020). A finite element analysis on the reliability of heavy bonding wire for high-power IGBT module. IEEE transactions on components, packaging and manufacturing technology, 11(2), 212-221. [135] Liu, K., Yang, J., Luo, J., Wang, L., Huang, Q., & Chen, F. (2020, August). The characterization and application of chip topside bonding materials for power modules packaging: A review. In Journal of Physics: Conference Series (Vol. 1605, No. 1, p. 012168). IOP Publishing. [136] Lai, W. L., & Chen, C. (2016, October). Mechanical properties of highly (111)-oriented nanotwinned Cu lines. In 2016 11th International Microsystems, Packaging, Assembly and Circuits Technology Conference (IMPACT) (pp. 220-222). IEEE. [137] Cheng, H. C., Syu, J. Y., Wang, H. H., Liu, Y. C., Kao, K. S., & Chang, T. C. (2024). Power cycling modeling and lifetime evaluation of SiC power MOSFET module using a modified physical lifetime model. IEEE Transactions on Device and Materials Reliability, 24(1), 142-153. [138] F. Kawashiro, Kentaro Takao, Tatsuya Kobayashi et al., “Effect of copper over-pad metallization on reliability of aluminum wire bonds,” Microelectronics Reliability, vol. 99, pp. 168–176, Aug. 2019. [139] Mei, X., Peng, C., Liu, X., Zhu, W., & Wang, L. (2022, August). A FE analysis on reliability of thick aluminum wire with different pad structures in power module. In 2022 23rd International Conference on Electronic Packaging Technology (ICEPT) (pp. 1-4). IEEE. [140] Bahl, S., Hu, X., Sisco, K., Haynes, J. A., & Shyam, A. (2020). Influence of copper content on the high temperature tensile and low cycle fatigue behavior of cast Al-Cu-Mn-Zr alloys. International Journal of Fatigue, 140, 105836. [141] Raman, S. G. S., & Radhakrishnan, V. M. (2002). On cyclic stress–strain behaviour and low cycle fatigue life. Materials & design, 23(3), 249-254. [142] T. Sakurai. Low-voltage design or the end of CMOS scaling? In International Solid-State Circuits Conference, San Francisco, Feb. 2002, Evening Panel. [143] Tanie, H., Nakane, K., Urata, Y., Tsuda, M., & Ohno, N. (2011). Warpage variations of Si/solder/OFHC-Cu layered plates subjected to cyclic thermal loading. Microelectronics Reliability, 51(9-11), 1840-1844. [144] Naumann, F., Schischka, J., Koetter, S., Milke, E., & Petzold, M. (2012, September). Reliability characterization of heavy wire bonding materials. In 2012 4th Electronic System-Integration Technology Conference (pp. 1-5). IEEE. [145] Josell, D., Brongersma, S. H., & Tőkei, Z. (2009). Size-dependent resistivity in nanoscale interconnects. Annual Review of Materials Research, 39(1), 231-254. [146] Maitrejean, S., Carreau, V., Thomas, O., Labat, S., Kaouache, B., Verdier, M., ... & Normandon, P. (2009, June). Cu grain growth in damascene narrow trenches. In AIP Conference Proceedings (Vol. 1143, No. 1, pp. 135-150). American Institute of Physics. | - |
| dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101245 | - |
| dc.description.abstract | 隨著後摩爾時代來臨,為了超越摩爾定律,半導體產業加速推動了2.5D/3D封裝技術的發展。在半導體製程演進中,銅憑藉其優異的導熱性、電阻率、抗電遷移能力、良好的耐腐蝕性與低廉成本,高性能的銅金屬互連逐漸成為先進製程不可或缺的架構。而特殊微結構的銅-銅金屬直接接合可大幅降低接合溫度與電阻,亦可提升產品可靠度,因此引起諸多先進製程研究團隊的興趣。本論文的研究主題聚焦於特殊微結構之銅金屬在微電子3D-IC封裝技術與功率模組打線接合技術的發展,深入研究低溫微細間距混合鍵合技術與粗銅線超音波接合技術,探討奈米尺寸晶粒的銅金屬(細晶銅、奈米孿晶銅)在高密度異質整合封裝與功率模組應用中的潛力。
第一部分的研究針對3D-IC中低溫細間距奈米晶銅/二氧化矽混合鍵合技術進行深入探討。隨著異質整合封裝的需求日益增加,傳統封裝技術的高溫接合工藝已無法滿足多晶片高密度互連結構的需求。為了克服這一挑戰,本研究提出了使用奈米晶銅作為低溫混合鍵合材料,實現了在250°C以下進行的晶片對晶圓(C2W)鍵合。透過縮小銅金屬的晶粒尺寸,使得晶界面積大幅增加,並利用晶界擴散速度大於晶粒擴散速度之優勢,可有效降低接合溫度。本研究採用了平坦的奈米級細晶銅金屬接點與SiO2介電材料的混合鍵合方式,成功完成了2µm、 3µm及5µm不同尺寸接點的高密度連接,達到了每平方公分6.26 × 10^6個接點的密度。實驗成果顯示,通過奈米晶銅的微結構設計,在接合界面進行的Cu-Cu相互擴散可以在低溫條件下實現高鍵合強度,且其對位精度達到了<0.5µm,最大鍵合強度達到9.01 MPa。此外,經過熱循環測試後,該混合鍵合結構展現了優越的可靠性。綜合以上所述,奈米晶銅的混合鍵合結構不僅能降低封裝過程中的高溫需求、提升鍵合性能,尤其適用於高密度堆疊的晶片封裝,是微電子領域中高密度異質整合技術發展的重要突破。 第二部分的研究則聚焦於功率模組中的粗銅線超音波打線接合技術。傳統的打線接合多使用鋁線、鍍鈀銅線和銀合金線,但這些材料在現今高電流、高電壓的應用需求中易受限於其導電性能與成本效益。為了解決這一問題,本研究針對銅線硬度高、接合負荷大的問題,提出了使用奈米孿晶結構銅金屬化層作為銲墊的創新方法。奈米孿晶銅具有高密度的(111)單一方向奈米級柱狀晶粒,能顯著促進超音波打線接合時的原子擴散反應,加速接合界面的形成,並大幅降低接合負荷。本研究中使用了15mil (380µm)的粗銅線進行超音波接合測試,並比較了不同材料與不同厚度之金屬化層(包括奈米孿晶銅、粗晶銅、奈米孿晶銅+粗晶銅雙層疊構)對接合強度的影響。實驗結果顯示,表層為奈米孿晶銅之銲墊結構可有效提升超音波打線接合的強度、打線機械應力耐受性。此外,透過進一步模擬結果顯示,採用表層奈米孿晶銅(4 µm)與底層粗晶銅(8 µm)為單層奈米孿晶銅(8µm)的 1.28 倍,顯示複合式金屬化層在維持高打線接合強度的同時,亦能有效提升熱循環下的可靠度,為兼顧可靠度與製程可行性的潛力設計。 本論文結合了奈米晶銅在低溫混合鍵合技術與粗銅線超音波接合技術的優勢,展示了其在微電子先進封裝與功率模組應用中的技術創新與突破。透過材料上微結構調整與封裝架構設計優化,不僅可解決高溫、高負荷製程對敏感晶片的影響,還提升了接合的可靠性與強度。這些研究成果不僅拓展了高密度異質整合封裝技術的應用潛力,也為功率模組提供了更具成本效益與高效能的解決方案。 | zh_TW |
| dc.description.abstract | As the post-Moore era approaches, the semiconductor industry has accelerated the development of 2.5D/3D packaging technologies to move past Moore's Law. In this evolution, copper has become an indispensable component of advanced processes due to its excellent thermal conductivity, low electrical resistivity, resistance to electromigration, corrosion resistance, and cost-effectiveness. The copper with the unique microstructure of direct bonding significantly reduces bonding temperature and electrical resistance while improving product reliability, drawing attention among advanced process research teams. This thesis focuses on researching copper metal with specialized microstructures in microelectronics 3D-IC packaging and power module wiring bonding techniques. Specifically, it explores low-temperature, fine-pitch hybrid bonding and ultrasonic bonding of thick copper wires, investigating the potential of nanocrystalline copper (fine-grained copper, nanotwinned copper) in high-density heterogeneous integration and power module applications.
The first part of this study delves into the development of low-temperature, fine-pitch hybrid bonding using nano-grained copper and silicon dioxide for 3D-IC packaging. As the demand for heterogeneous integration continues to grow, traditional high-temperature bonding techniques struggle to meet the requirements of high-density multi-chip interconnections. In order to surpass this challenge, this study proposes using nano-grained copper as a low-temperature hybrid bonding material, achieving chip-to-wafer (C2W) bonding at temperatures below 250°C. By reducing the grain size of copper, the grain boundary area increases, allowing for enhanced grain boundary diffusion, which proceeds faster than grain diffusion, thus decreasing the bonding temperature. This research employed a flat, nano-scale fine-grained copper bonding interface alongside SiO2 dielectric materials, successfully achieving high-density connections with 2µm, 3µm, and 5µm bond pad sizes, resulting in a connection density of 6.26 × 10^6 per cm². Experimental results show that the microstructural design of nano-grained copper enabled effective Cu-Cu interdiffusion at low temperatures, achieving a bonding strength of up to 9.01 MPa with alignment accuracy below 0.5µm. Additionally, the hybrid bonding structure demonstrated excellent reliability after thermal cycling tests. Overall, the hybrid bonding structure using nano-grained copper not only reduces the thermal budget of packaging but also enhances bonding performance, making it a significant breakthrough for high-density, heterogeneous integration in microelectronics. The second part of the study focuses on ultrasonic bonding of thick copper wires for power modules. Traditional wire bonding materials, such as aluminum, palladium-coated copper, and silver alloy wires, are limited by their conductivity and cost-effectiveness in the trend toward high-current, high-voltage applications. Owning to address the challenges posed by the high hardness and bonding load of copper wires, this study introduces an innovative solution: using a nanotwinned copper layer as the backside metallization. Nanotwinned copper, with its high density of (111)-oriented nano-scale columnar grains, significantly enhances atomic diffusion during ultrasonic bonding, accelerating the formation of the bonding interface and substantially reducing the required bonding load. In this study, ultrasonic bonding tests were conducted using 15 mil (380 µm) thick copper wires, and the effects of various metallization materials and thicknesses including nanotwinned copper (nt-Cu), coarse-grained copper (cg-Cu), and a bilayer structure of nt-Cu and cg-Cu on bonding strength were investigated. Experimental results demonstrated that bonding pads with a nanotwinned copper surface layer significantly enhanced ultrasonic bonding strength. Furthermore, simulation results indicate that the fatigue life of the bilayer structure comprising a 4 µm nt-Cu top layer and an 8 µm cg-Cu bottom layer is approximately 1.28 times that of a single 8 µm nt-Cu layer. This suggests that the composite metallization structure can effectively enhance reliability under thermal cycling while maintaining high bonding strength, offering a promising solution that balances both reliability and manufacturing feasibility. This thesis integrates the advantages of nano-grained copper in low-temperature hybrid bonding and thick copper wire ultrasonic bonding, demonstrating technological innovations and breakthroughs in microelectronics packaging and power module applications. Through precise microstructural design and packaging architecture optimization, this study addresses the challenges posed by high-temperature, high-load processes on sensitive chips, while improving bonding reliability and strength. These research findings expand the potential applications of high-density heterogeneous integration as well as offer cost-effective, high-performance solutions for power modules. | en |
| dc.description.provenance | Submitted by admin ntu (admin@lib.ntu.edu.tw) on 2026-01-13T16:04:23Z No. of bitstreams: 0 | en |
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| dc.description.tableofcontents | 誌謝 i
摘要 ii Abstract vi 目次 vii 圖次 xi 表次 xviii 第1章 緒論 1 1.1 研究背景 1 1.1.1 前言 1 1.1.2 先進封裝製程 3 1.1.3 混合鍵合技術發展 20 1.1.4 功率模組封裝製程 22 1.2 研究動機與目的 27 1.2.1 低溫細間距奈米晶銅/二氧化矽混合鍵合技術研究 27 1.2.2 功率模組晶片奈米孿晶金屬化層之銅線超音波接合研究 31 第2章 理論基礎與文獻回顧 34 2.1 晶圓接合原理(wafer bonding) 34 2.1.1 黏著接合 (adhesive bonding) 35 2.1.1.1 玻璃燒結鍵合(Glass frit bonding) 35 2.1.1.2 高分子膠黏著接合(polymer adhesive bonding) 36 2.1.2 陽極接合法(Anodic bonding) 37 2.1.3 直接晶圓接合 (direct wafer bonding) 37 2.1.4 表面活化接合. (Surface Activated Bonding, SAB) 38 2.1.5 金屬接合(metal bonding) 39 2.1.5.1 焊錫接合(Solder bonding) 39 2.1.5.2 共晶接合法(Eutectic bonding) 40 2.1.5.3 熱壓接合(thermocompression bonding) 41 2.1.5.4 奈米孿晶金屬直接接合(nanotwinned metal to metal direct bonding) 43 2.1.5.5 固液擴散接合(Solid–Liquid Interdiffusion Bonding) 44 2.1.6 混合金屬/介電質接合 (hybrid metal/dielectric bonding) 46 2.2 矽晶圓直接鍵合技術原理 56 2.3 超音波打線接合原理 60 第3章 實驗方法 66 3.1 實驗流程圖 66 3.1.1 (一)低溫細間距奈米晶銅/二氧化矽混合鍵合流程 66 3.1.2 (二)功率模組晶片奈米孿晶銅金屬化層之銅線超音波接合流程 66 3.2 材料種類及其預處理 69 3.2.1 混合鍵合試片前處理 69 3.2.1.1 混合鍵合晶圓製作 69 3.2.1.2 晶圓切割製程 70 3.2.1.3 試片清潔活化 72 3.2.2 打線鍵合試片前處理 74 3.2.2.1 不同金屬化層晶片製作 74 3.2.2.2 試片清潔活化 76 3.3 接合設備與接合製程 76 3.3.1 混合鍵合接合設備 76 3.3.2 打線接合設備 78 3.4 退火製程與設備 80 3.5 材料性質分析 82 3.5.1 原子力顯微鏡(AFM) 82 3.5.2 超音波掃描(SAT 檢測) 82 3.5.3 掃描式電子顯微鏡(SEM&EDS) 83 3.5.4 聚焦離子束顯微鏡(FIB) 84 3.5.5 電子背向散射繞射技術(EBSD) 85 3.5.6 接合強度測試(Bond strength test) 86 3.5.7 電性測試(Electrical Test) 87 3.6 粗銅打線可靠度模擬 88 第4章 結果與討論 92 4.1 矽晶圓直接接合 92 4.1.1 環境潔淨度分析 92 4.1.2 不同電漿參數之矽晶圓接合可行性分析 94 4.1.3 矽晶圓直接接合界面觀察 97 4.1.3.1 不同退火溫度之矽晶圓直接接合界面觀察 97 4.1.3.2 不同切割方式之矽晶圓直接接合界面觀察 99 4.2 Cu/SiO2混合鍵合 100 4.2.1 奈米晶銅前段CMP製程 100 4.2.2 不同電漿參數之混合鍵合晶圓表面分析 102 4.2.3 對位精度分析 105 4.2.4 接合面SAT分析 106 4.2.5 SEM分析 108 4.2.6 背向散射之電子繞射技術(EBSD)分析 109 4.2.6.1 晶粒尺寸分布 109 4.2.6.2 晶界分布 111 4.2.6.3 晶粒取向 112 4.2.7 電性分析 114 4.2.7.1 Sheet resistance 114 4.2.7.2 Kelvin structure 115 4.2.7.3 菊鏈電阻分析(Daisy Chain Resistance Analysis) 117 4.2.7.4 漏電流量測(Leakage Current Analysis) 119 4.2.8 接合強度分析 121 4.2.8.1 Shear test 121 4.2.8.2 Pull test 122 4.2.9 可靠度分析 124 4.2.9.1 SAT與SEM分析 125 4.2.9.2 EBSD分析 126 4.2.9.3 電性分析 129 4.2.9.4 Pull test 134 4.3 奈米孿晶銅金屬化層之銅線超音波接合 138 4.3.1 第一階段測試:打線可行性評估 138 4.3.2 第二階段測試:打線參數優化 143 4.3.3 奈米孿晶銅金屬化層對粗銅打線可靠度模擬 149 第5章 結論 157 5.1 (一) 低溫細間距奈米晶銅/二氧化矽混合鍵合技術研究 157 5.2 (二) 奈米孿晶銅金屬化層之銅線超音波接合研究 158 第6章 參考文獻 159 | - |
| dc.language.iso | zh_TW | - |
| dc.subject | 低溫接合 | - |
| dc.subject | 直接接合 | - |
| dc.subject | 打線接合 | - |
| dc.subject | 混合鍵合 | - |
| dc.subject | 奈米晶銅 | - |
| dc.subject | 奈米孿晶銅 | - |
| dc.subject | low-temperature bonding | - |
| dc.subject | direct bonding | - |
| dc.subject | wire bonding | - |
| dc.subject | hybrid bonding | - |
| dc.subject | nanocrystalline copper | - |
| dc.subject | nanotwinned copper | - |
| dc.title | 應用於先進封裝之奈米晶粒銅混合直接鍵合與銅打線互連技術研究 | zh_TW |
| dc.title | A Study on Hybrid Direct Bonding and Copper Wire Bonding Technologies Using Nano-grained Copper for Advanced Packaging | en |
| dc.type | Thesis | - |
| dc.date.schoolyear | 114-1 | - |
| dc.description.degree | 博士 | - |
| dc.contributor.oralexamcommittee | 莊東漢;陳俊豪;張景堯;陳蓉萱;陳正閔;王彰盟;蔡幸樺;高學武 | zh_TW |
| dc.contributor.oralexamcommittee | Tung-Han Chuang;Chun-Hao Chen;Jing-Yao Chang;Jung-Hsuan Chen;Cheng-Min Chen;Chang-Meng Wang;Hsing-Hua Tsai;Syue-Wu Gao | en |
| dc.subject.keyword | 低溫接合,直接接合打線接合混合鍵合奈米晶銅奈米孿晶銅 | zh_TW |
| dc.subject.keyword | low-temperature bonding,direct bondingwire bondinghybrid bondingnanocrystalline coppernanotwinned copper | en |
| dc.relation.page | 172 | - |
| dc.identifier.doi | 10.6342/NTU202504861 | - |
| dc.rights.note | 同意授權(全球公開) | - |
| dc.date.accepted | 2026-01-05 | - |
| dc.contributor.author-college | 工學院 | - |
| dc.contributor.author-dept | 材料科學與工程學系 | - |
| dc.date.embargo-lift | 2030-12-30 | - |
| Appears in Collections: | 材料科學與工程學系 | |
Files in This Item:
| File | Size | Format | |
|---|---|---|---|
| ntu-114-1.pdf Until 2030-12-30 | 22.21 MB | Adobe PDF |
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