低溫無壓電流輔助奈米銅粒子燒結機制之研究

以作者查詢圖書館館藏

、以作者查詢臺灣博碩士

、以作者查詢全國書目

、勘誤回報

、線上人數：53

、訪客IP：18.118.142.230

姓名

沈子豪(Tzu-Hao Shen) 查詢紙本館藏

畢業系所

化學工程與材料工程學系

論文名稱

低溫無壓電流輔助奈米銅粒子燒結機制之研究
(Mechanism of Low-temperature Pressureless Electrical Current Enhanced Sintering for Cu Nanoparticles)

相關論文

★ 錫碲擴散偶之擴散阻障層界面反應	★ 熱電材料與擴散阻障層在電流影響下的界面反應研究
★ 無鉛銲料與無電鍍鈷基板於多次迴焊之界面反應與可靠度測試	★ 無電鍍鎳磷層應用於熱電材料與無鉛銲料之界面研究
★ 高可靠度車用印刷電路板之表面處理層開發	★ 共濺鍍銅鈦薄膜之相分離演化機制與其對機械性質於3DIC接合的影響
★ 添加微量錫銀銅合金之銅薄膜與銅基板之接合研究	★ 新式低溫合金焊料之開發與界面反應探討及可靠度分析
★ 電遷移對純錫導線晶粒旋轉之研究	★ 以同步輻射臨場量測電遷移對純錫導線應力分佈之研究
★ 鋁鍺薄膜封裝研究	★ 無鉛銲料錫銀鉍銦與銅電極之電遷移研究
★ 以表面處理及塗佈奈米粒子抑制錫晶鬚生長	★ 鋁鍺雙層薄膜之擴散行為與金屬誘發結晶現象研究
★ 鋁(銅)與鎳混合導線於矽通孔製程之電遷移現象研究	★ 無鉛銲料與碲化鉍基材之界面反應研究

檔案

[Endnote RIS 格式]

[Bibtex 格式]

[相關文章]

[文章引用]

[完整記錄]

[館藏目錄]

至系統瀏覽論文 (2028-7-31以後開放)

摘要(中)

近年來隨著功率元件的發展及研發技術提升，產品開始追求高功率密度的元件堆疊。此外，高效能及微縮化的結構將提高元件承載之電流密度，當高密度電流通過銲點時，更容易發生電遷移與焦耳熱的效應，最終可能導致元件失效。因7878\]8/此，為了促進功率元件的發展與應用，電流對於接點之影響為提升元件可靠度之必要研究，後續更可作為未來產業界提升元件良率的研究基礎。
本研究開發出在低電流密度且低溫無壓的條件下以電流輔助奈米銅膠燒結方法。實驗結果顯示奈米銅顆粒在經過低電流密度之電流處理後擁有較緊密且連續的微結構、較佳的電性以及較低的孔洞率。本研究討論的模型與文獻中所提之燒結機制不同，除了由電子風力和表面擴散的化學勢作為燒結之驅動力，電流擁塞效應亦是燒結過程中的另一個重要機制。當電流密度僅有102-104 A/cm2時，產生的焦耳熱很少，因此在本系統中焦耳熱對燒結之影響可忽略不計。
本研究亦研究電流對於顆粒間燒結時頸部之成長動力學，藉由建立兩模型來定義頸部生長行為與頸部載子濃度之間的關係。此模型也表明了當電流流經顆粒間的頸部時，頸部的大小將會影響頸部載子濃度、頸部電流密度以及頸部原子擴散通量。此外，相較於傳統燒結模型，此模型更能精準預測及研究電流對顆粒間頸部生長動力學和原子擴散的行為。

摘要(英)

With the development of high-power devices such as automobiles and 5G telecommunication technology, the performance of high power materials is becoming increasingly demanding. In addition, with the trend toward high efficiency and small form factors in electronic devices, the current density carried by their components is increasing. When high-density current passes through a solder joint, the effect of Joule heating and electromigration may lead to component failure. Therefore, studying the effects of current on these joints is crucial to improve the reliability of power devices and promoting their development and application.
Herein, the sintering of Cu nanoparticles (NPs) was explored under low electrical current density at 25°C in the ambient atmosphere. The NPs were printed in a V-groove etch on a silicon wafer and were subjected to stress using an electrical current. Voids in the current-enhanced sintered Cu are considerably less than that without current. Sintering at room temperature avoided interference from Joule heating. Besides surface diffusion along the particles and atomic motion driven by the current, the current crowding effect at the necking region was identified as a critical factor. The influence of electric current on the densification and electrical properties of Cu NPs were investigated. Herein, two mathematical models were proposed to elucidate the underlying sintering mechanism. The results prove that the kinetics of neck growth affects the carrier concentration and total atomic diffusion fluxes in the necking region when the current flows through two NPs. These proposed mathematic models implement traditional sintering mechanisms, providing improved prediction for the enhanced sintering of particles with an electrical current.

關鍵字(中)

★ 無壓
★ 低溫製程
★ 互連
★ 電流燒結機制
★ 焦耳熱

關鍵字(英)

★ Pressureless
★ Low temperature process
★ Interconnect
★ Electrically sintering mechanism
★ Joule heating

論文目次

摘要 i
ABSTRACT ii
致謝辭 iii
TABLE OF CONTENTS v
LIST OF FIGURES vii
LIST OF TABLES ix
EXPLANATION OF SYMBOLS x
CHAPTER 1 INTRODUCTION 1
1-1 Background 1
1-2 Issue of high temperature packaging materials 4
1-2-1 Development of Pb free solders 4
1-2-2 Au-based Alloys 6
1-2-3 Bi-based Alloys 8
1-2-4 Zn-based Alloys 10
1-3 Cu-to-Cu Bonding 10
1-4 Ag Nanoparticle Sintering 11
1-5 Cu Nanoparticle Sintering 13
1-6 Sintering Process 15
1-6-1 Sintering Methods 16
1-6-2 Thermal Sintering 16
1-6-3 Plasma Sintering 17
1-6-4 Laser Sintering 18
1-6-5 Microwave Sintering 19
1-6-6 Electric Sintering 19
1-7 Influence of The Electric Current in Materials 21
1-7-1 Joule Heating Effect 24
1-7-1 Neck Growth Behavior of Metal Powder 26
1-8 Challenge and Future Perspectives in Interconnects 30
CHAPTER 2 MOTIVATION, AIMS AND OBJECTIVES 31
CHAPTER 3 EXPERIMENTAL PROCEDURE 33
3-1 Prepartion of V-groove Substrate 33
3-2 Prepartion of The Cu Paste 34
3-3 Sintering Process 34
3-4 Prepartion of The Paste 34
CHAPTER 4 RESULTS AND DISCUSSION 36
4-1 The Cu NP Paste 36
4-2 Effect of Pre-heating temperature and Time of Cu NPs 38
4-3 Microstructure of The Sintered Cu NPs 40
4-3-1 Effect of Current Stressing on Particle and Neck Growth 44
4-3-2 Effect of Current Stressing on Crystal Orientation of Cu NPs 45
4-3-3 Electrical Behavior of Cu NPs During Current Stressing 46
4-4 Joule heating of Sintered Cu NPs 47
4-5 Sintering Mechanism of Cu NPs 50
4-6 Kinetic of Neck Growth During Sintering 52
4-7 Perspective of Particle Sintering 65
CHAPTER 5 CONCLUSION 67
REFERENCE 68

參考文獻

[1] A. Ahmad, "Automotive Semiconductor Industry-Trends, Safety and Security Challenges," 2020 8th International Conference on Reliability, Infocom Technologies and Optimization (Trends and Future Directions)(ICRITO) pp. 1373-1377, 2020.
[2] Z. He, "Analysis on the development of semiconductor manufacturing process," Journal of Physics: Conference Series p. 012009, 2022.
[3] J. Millán, "Wide band-gap power semiconductor devices", IET Circuits, Devices & Systems, Vol, 1, p. 372, 2007.
[4] F. Roccaforte, P. Fiorenza, G. Greco et al., "Challenges for energy efficient wide band gap semiconductor power devices", physica status solidi (a), Vol, 211, pp. 2063-2071, 2014.
[5] J. Millán, P. Godignon, and A. Pérez-Tomás, "Wide band gap semiconductor devices for power electronics", Automatika: časopis za automatiku, mjerenje, elektroniku, računarstvo i komunikacije, Vol, 53, pp. 107-116, 2012.
[6] Y. Chen, C. Yang, C. Kuo et al., "Ultra high density SoIC with sub-micron bond pitch," 2020 IEEE 70th Electronic Components and Technology Conference (ECTC) pp. 576-581, 2020.
[7] M.-F. Chen, F.-C. Chen, W.-C. Chiou et al., "System on integrated chips (SoIC (TM) for 3D heterogeneous integration," 2019 IEEE 69th Electronic Components and Technology Conference (ECTC) pp. 594-599, 2019.
[8] C. Hu, M. Chen, W. Chiou et al., "3D multi-chip integration with system on integrated chips (SoIC™)," 2019 Symposium on VLSI Technology pp. T20-T21, 2019.
[9] N. Islam, G. Kim, and K. Kim, "Electromigration for advanced Cu interconnect and the challenges with reduced pitch bumps," 2014 IEEE 64th Electronic Components and Technology Conference (ECTC) pp. 50-55, 2014.
[10] Y. Liu, M. Li, M. Jiang et al., "Joule heating enhanced electromigration failure in redistribution layer in 2.5 D IC," 2016 IEEE 66th Electronic Components and Technology Conference (ECTC) pp. 1359-1363, 2016.
[11] G. Zeng, S. McDonald, and K. Nogita, "Development of high-temperature solders", Microelectronics Reliability, Vol, 52, pp. 1306-1322, 2012.
[12] H. Inoue, Y. Kurihara, and H. Hachino, "Pb-Sn solder for die bonding of silicon chips", IEEE transactions on components, hybrids, and manufacturing technology, Vol, 9, pp. 190-194, 1986.
[13] S. Wiese, A. Schubert, H. Walter et al., "Constitutive behaviour of lead-free solders vs. lead-containing solders-experiments on bulk specimens and flip-chip joints," 2001 Proceedings. 51st Electronic Components and Technology Conference (Cat. No. 01CH37220) pp. 890-902, 2001.
[14] S.K. Kang and A.K. Sarkhel, "Lead (Pb)-free solders for electronic packaging", Journal of electronic materials, Vol, 23, pp. 701-707, 1994.
[15] G. Zeng, S. Xue, L. Zhang et al., "Recent advances on Sn–Cu solders with alloying elements", Journal of Materials Science: Materials in Electronics, Vol, 22, pp. 565-578, 2011.
[16] M. Zhao, L. Zhang, Z.-Q. Liu et al., "Structure and properties of Sn-Cu lead-free solders in electronics packaging", Science and technology of advanced materials, Vol, 20, pp. 421-444, 2019.
[17] F. Wang, H. Chen, Y. Huang et al., "Recent progress on the development of Sn–Bi based low-temperature Pb-free solders", Journal of Materials Science: Materials in Electronics, Vol, 30, pp. 3222-3243, 2019.
[18] Z. Mei and J. Morris, "Characterization of eutectic Sn-Bi solder joints", Journal of Electronic Materials, Vol, 21, pp. 599-607, 1992.
[19] W.K. Jones, Y. Liu, M. Shah et al., "Mechanical properties of Pb/Sn Pb/In and Sn‐In solders", Soldering & Surface Mount Technology, 1998.
[20] Y. Liu and K. Tu, "Low melting point solders based on Sn, Bi, and In elements", Materials Today Advances, Vol, 8, p. 100115, 2020.
[21] W. Yang, R.W. Messler, and L.E. Felton, "Microstructure evolution of eutectic Sn-Ag solder joints", Journal of Electronic Materials, Vol, 23, pp. 765-772, 1994.
[22] I. Dutta, P. Kumar, and G. Subbarayan, "Microstructural coarsening in Sn-Ag-based solders and its effects on mechanical properties", JOM, Vol, 61, pp. 29-38, 2009.
[23] C. Wu, D.Q. Yu, C. Law et al., "Properties of lead-free solder alloys with rare earth element additions", Materials Science and Engineering: R: Reports, Vol, 44, pp. 1-44, 2004.
[24] Y. Kang, J.-J. Choi, D.-G. Kim et al., "The Effect of Bi and Zn Additives on Sn-Ag-Cu Lead-Free Solder Alloys for Ag Reduction", Metals, Vol, 12, p. 1245, 2022.
[25] M.R. Chowdhury, S. Ahmed, A. Fahim et al., "Mechanical characterization of doped SAC solder materials at high temperature," 2016 15th IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm) pp. 1202-1208, 2016.
[26] H.-T. Lee, M.-H. Chen, H.-M. Jao et al., "Influence of interfacial intermetallic compound on fracture behavior of solder joints", Materials Science and Engineering: A, Vol, 358, pp. 134-141, 2003.
[27] S. Hayes, N. Chawla, and D. Frear, "Interfacial fracture toughness of Pb-free solders", Microelectronics reliability, Vol, 49, pp. 269-287, 2009.
[28] M.-y. Xiong and L. Zhang, "Interface reaction and intermetallic compound growth behavior of Sn-Ag-Cu lead-free solder joints on different substrates in electronic packaging", Journal of materials science, Vol, 54, pp. 1741-1768, 2019.
[29] M. Park and R. Arróyave, "Early stages of intermetallic compound formation and growth during lead-free soldering", ACTA materialia, Vol, 58, pp. 4900-4910, 2010.
[30] G. Zeng, S. Xue, L. Zhang et al., "A review on the interfacial intermetallic compounds between Sn–Ag–Cu based solders and substrates", Journal of Materials Science: Materials in Electronics, Vol, 21, pp. 421-440, 2010.
[31] L. Xu, J.H. Pang, K.H. Prakash et al., "Isothermal and thermal cycling aging on IMC growth rate in lead-free and lead-based solder interface", IEEE Transactions on Components and Packaging Technologies, Vol, 28, pp. 408-414, 2005.
[32] H. Xiao, X. Li, Y. Zhu et al., "Intermetallic growth study on SnAgCu/Cu solder joint interface during thermal aging", Journal of Materials Science: Materials in Electronics, Vol, 24, pp. 2527-2536, 2013.
[33] C. Buttay, D. Planson, B. Allard et al., "State of the art of high temperature power electronics", Materials Science and Engineering: B, Vol, 176, pp. 283-288, 2011.
[34] H. Liu, S. Xue, Y. Tao et al., "Design and solderability characterization of novel Au–30Ga solder for high-temperature packaging", Journal of Materials Science: Materials in Electronics, Vol, 31, pp. 2514-2522, 2020.
[35] D. Ivey, "Microstructural characterization of Au/Sn solder for packaging in optoelectronic applications", Micron, Vol, 29, pp. 281-287, 1998.
[36] J.-W. Yoon, H.-S. Chun, J.-M. Koo et al., "Au–Sn flip-chip solder bump for microelectronic and optoelectronic applications", Microsystem Technologies, Vol, 13, pp. 1463-1469, 2007.
[37] V. Chidambaram, J. Hattel, and J. Hald, "High-temperature lead-free solder alternatives", Microelectronic Engineering, Vol, 88, pp. 981-989, 2011.
[38] J. Wang, C. Leinenbach, and M. Roth, "Thermodynamic description of the Au–Ge–Sb ternary system", Journal of alloys and compounds, Vol, 485, pp. 577-582, 2009.
[39] J. Wang, C. Leinenbach, and M. Roth, "Thermodynamic modeling of the Au–Ge–Sn ternary system", Journal of Alloys and Compounds, Vol, 481, pp. 830-836, 2009.
[40] V. Chidambaram, J. Hald, and J. Hattel, "Development of Au–Ge based candidate alloys as an alternative to high-lead content solders", Journal of alloys and compounds, Vol, 490, pp. 170-179, 2010.
[41] V. Chidambaram, J. Hald, R. Ambat et al., "A corrosion investigation of solder candidates for high-temperature applications", JOM, Vol, 61, pp. 59-65, 2009.
[42] M. Nahavandi, M. Hanim, Z. Ismarrubie et al., "Effects of silver and antimony content in lead-free high-temperature solders of Bi-Ag and Bi-Sb on copper substrate", Journal of electronic materials, Vol, 43, pp. 579-585, 2014.
[43] J.H. Kim, S.W. Jeong, and H.M. Lee, "Thermodynamics-aided alloy design and evaluation of Pb-free solders for high-temperature applications", Materials transactions, Vol, 43, pp. 1873-1878, 2002.
[44] J.-M. Song, H.-Y. Chuang, and T.-X. Wen, "Thermal and tensile properties of Bi-Ag alloys", Metallurgical and Materials Transactions A, Vol, 38, pp. 1371-1375, 2007.
[45] J.-M. Song, H.-Y. Chuang, and Z.-M. Wu, "Substrate dissolution and shear properties of the joints between Bi-Ag alloys and Cu substrates for high-temperature soldering applications", Journal of Electronic Materials, Vol, 36, pp. 1516-1523, 2007.
[46] F.-Q. Zu, X.-F. Li, H.-F. Ding et al., "Electrical resistivity of liquid Bi–Sb alloys", Phase Transitions, Vol, 79, pp. 277-283, 2006.
[47] J. Cho, S. Mallampati, H. Schoeller et al., "Developments of Bi-Sb-Cu alloys as a high-temperature Pb-free solder," 2015 IEEE 65th Electronic Components and Technology Conference (ECTC) pp. 1251-1256, 2015.
[48] C. Wu, C. Law, D. Yu et al., "The wettability and microstructure of Sn-Zn-RE alloys", Journal of Electronic Materials, Vol, 32, pp. 63-69, 2003.
[49] S. Vaynman and M. Fine, "Flux development for lead-free solders containing zinc", Journal of Electronic materials, Vol, 29, pp. 1160-1163, 2000.
[50] S. Vaynman and M. Fine, "Development of fluxes for lead-free solders containing zinc", Scripta materialia, Vol, 41, 1999.
[51] H. Zhang, J. Minter, and N.-C. Lee, "A brief review on high-temperature, Pb-free die-attach materials", Journal of Electronic Materials, Vol, 48, pp. 201-210, 2019.
[52] J.-Y. Juang, C.-L. Lu, Y.-J. Li et al., "Correlation between the microstructures of bonding interfaces and the shear strength of Cu-to-Cu joints using (111)-oriented and nanotwinned Cu", Materials, Vol, 11, p. 2368, 2018.
[53] Y.-S. Tang, Y.-J. Chang, and K.-N. Chen, "Wafer-level Cu–Cu bonding technology", Microelectronics Reliability, Vol, 52, pp. 312-320, 2012.
[54] T. Kim, M. Howlader, T. Itoh et al., "Room temperature Cu–Cu direct bonding using surface activated bonding method", Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films, Vol, 21, pp. 449-453, 2003.
[55] Q. Jiang, S. Zhang, and J. Li, "Grain size-dependent diffusion activation energy in nanomaterials
", Solid State Communications, Vol, 130, pp. 581-584, 2004.
[56] P. Buffat and J.P. Borel, "Size effect on the melting temperature of gold particles", Physical review A, Vol, 13, p. 2287, 1976.
[57] M. Asoro, J. Damiano, and P. Ferreira, "Size effects on the melting temperature of silver nanoparticles: In-situ TEM observations", Microscopy and Microanalysis, Vol, 15, pp. 706-707, 2009.
[58] C. Huang, M.F. Becker, J.W. Keto et al., "Annealing of nanostructured silver films produced by supersonic deposition of nanoparticles", Journal of Applied Physics, Vol, 102, p. 054308, 2007.
[59] J.G. Bai, J. Yin, Z. Zhang et al., "High-temperature operation of SiC power devices by low-temperature sintered silver die-attachment", IEEE transactions on advanced packaging, Vol, 30, pp. 506-510, 2007.
[60] R. Zhang, K.-s. Moon, W. Lin et al., "Preparation of highly conductive polymer nanocomposites by low temperature sintering of silver nanoparticles", Journal of Materials Chemistry, Vol, 20, pp. 2018-2023, 2010.
[61] B. Hu, F. Yang, Y. Peng et al., "Rapid formation of Cu–Cu joints with high shear strength using multiple-flocculated Ag nanoparticle paste", Journal of Materials Science: Materials in Electronics, Vol, 30, pp. 8071-8079, 2019.
[62] D. Yang, Y. Huang, and Y. Tian, "Microstructure of Ag nano paste joint and its influence on reliability", Crystals, Vol, 11, p. 1537, 2021.
[63] Y. NormanáZhou, "Room-temperature pressureless bonding with silver nanowire paste: towards organic electronic and heat-sensitive functional devices packaging", Journal of Materials Chemistry, Vol, 22, pp. 12997-13001, 2012.
[64] C. Chen and K. Suganuma, "Large-scale ceramic–metal joining by nano-grained Ag particles paste sintering in low-temperature pressure-less conditions", Scripta Materialia, Vol, 195, p. 113747, 2021.
[65] J. Liu, H. Chen, H. Ji et al., "Highly conductive Cu–Cu joint formation by low-temperature sintering of formic acid-treated Cu nanoparticles", ACS applied materials & interfaces, Vol, 8, pp. 33289-33298, 2016.
[66] J.H. Kim, K.S. Kim, K.R. Jang et al., "Enhancing adhesion of screen‐printed silver nanopaste films", Advanced Materials Interfaces, Vol, 2, p. 1500283, 2015.
[67] J.-W. Yoon and J.-H. Back, "Effect of sintering conditions on the mechanical strength of Cu-sintered joints for high-power applications", Materials, Vol, 11, p. 2105, 2018.
[68] R. Riva, C. Buttay, B. Allard et al., "Migration issues in sintered-silver die attaches operating at high temperature", Microelectronics Reliability, Vol, 53, pp. 1592-1596, 2013.
[69] Y. Gao, H. Zhang, W. Li et al., "Die bonding performance using bimodal Cu particle paste under different sintering atmospheres", Journal of Electronic Materials, Vol, 46, pp. 4575-4581, 2017.
[70] Y. Jianfeng, Z. Guisheng, H. Anming et al., "Preparation of PVP coated Cu NPs and the application for low-temperature bonding", Journal of Materials Chemistry, Vol, 21, pp. 15981-15986, 2011.
[71] C.-J. Lee, K.-H. Jung, B.-G. Park et al., "Effect of PVP on fabrication of Cu nanoparticles using an electrical wire explosion method", Journal of Materials Science: Materials in Electronics, Vol, 30, pp. 4079-4084, 2019.
[72] R. Gao, S. He, Y.-A. Shen et al., "Effect of substrates on fracture mechanism and process optimization of oxidation–reduction bonding with copper microparticles", Journal of Electronic Materials, Vol, 48, pp. 2263-2271, 2019.
[73] Y. Gao, W. Li, C. Chen et al., "Novel copper particle paste with self-reduction and self-protection characteristics for die attachment of power semiconductor under a nitrogen atmosphere", Materials & Design, Vol, 160, pp. 1265-1272, 2018.
[74] R. German, Thermodynamics of sintering, Sintering of advanced materials, Elsevier2010, pp. 3-32.
[75] B.K. Park, D. Kim, S. Jeong et al., "Direct writing of copper conductive patterns by ink-jet printing", Thin solid films, Vol, 515, pp. 7706-7711, 2007.
[76] S. Jeong, K. Woo, D. Kim et al., "Controlling the thickness of the surface oxide layer on Cu nanoparticles for the fabrication of conductive structures by ink‐jet printing", Advanced functional materials, Vol, 18, pp. 679-686, 2008.
[77] S. Wünscher, R. Abbel, J. Perelaer et al., "Progress of alternative sintering approaches of inkjet-printed metal inks and their application for manufacturing of flexible electronic devices", Journal of Materials Chemistry C, Vol, 2, pp. 10232-10261, 2014.
[78] J. Kwon, H. Cho, H. Eom et al., "Low-temperature oxidation-free selective laser sintering of Cu nanoparticle paste on a polymer substrate for the flexible touch panel applications", ACS Applied Materials & Interfaces, Vol, 8, pp. 11575-11582, 2016.
[79] J.G. Lee, D.Y. Kim, T.G. Kim et al., "Supersonically Sprayed Copper–Nickel Microparticles as Flexible and Printable Thin‐Film High‐Temperature Heaters", Advanced Materials Interfaces, Vol, 4, p. 1700075, 2017.
[80] C. Tendero, C. Tixier, P. Tristant et al., "Atmospheric pressure plasmas: A review", Spectrochimica Acta Part B: Atomic Spectroscopy, Vol, 61, pp. 2-30, 2006.
[81] K.I. Rybakov, E.A. Olevsky, and E.V. Krikun, "Microwave sintering: fundamentals and modeling", Journal of the American Ceramic Society, Vol, 96, pp. 1003-1020, 2013.
[82] R. Roy, D. Agrawal, J. Cheng et al., "Full sintering of powdered-metal bodies in a microwave field", Nature, Vol, 399, pp. 668-670, 1999.
[83] Z.A. Munir, D.V. Quach, and M. Ohyanagi, "Electric current activation of sintering: a review of the pulsed electric current sintering process", Journal of the American Ceramic Society, Vol, 94, pp. 1-19, 2011.
[84] S. Grasso, Y. Sakka, and G. Maizza, "Electric current activated/assisted sintering (ECAS): a review of patents 1906–2008", Science and Technology of Advanced Materials, Vol, 10, p. 053001, 2009.
[85] W. Liu, H. Wang, K.-S. Huang et al., "Low temperature and pressureless Cu-to-Cu direct bonding by green synthesized Cu nanoparticles", Journal of the Taiwan Institute of Chemical Engineers, Vol, 125, pp. 394-401, 2021.
[86] Y. Zhang, P. Zhu, G. Li et al., "Facile preparation of monodisperse, impurity-free, and antioxidation copper nanoparticles on a large scale for application in conductive ink", ACS Applied Materials & Interfaces, Vol, 6, pp. 560-567, 2014.
[87] A. Klein, R. Cardoso, H. Pavanati et al., "DC plasma technology applied to powder metallurgy: an overview", Plasma Science and Technology, Vol, 15, p. 70, 2013.
[88] Y. Gao, H. Zhang, J. Jiu et al., "Fabrication of a flexible copper pattern based on a sub-micro copper paste by a low temperature plasma technique", RSC advances, Vol, 5, pp. 90202-90208, 2015.
[89] Y.-T. Kwon, Y.-I. Lee, S. Kim et al., "Full densification of inkjet-printed copper conductive tracks on a flexible substrate utilizing a hydrogen plasma sintering", Applied Surface Science, Vol, 396, pp. 1239-1244, 2017.
[90] J.H. Yu, K.-T. Kang, J.Y. Hwang et al., "Rapid sintering of copper nano ink using a laser in air", International journal of precision engineering and manufacturing, Vol, 15, pp. 1051-1054, 2014.
[91] J.H. Park, S. Jeong, E.J. Lee et al., "Transversally extended laser plasmonic welding for oxidation-free copper fabrication toward high-fidelity optoelectronics", Chemistry of Materials, Vol, 28, pp. 4151-4159, 2016.
[92] W.H. Sutton, "Microwave processing of ceramics-an overview", MRS Online Proceedings Library (OPL), Vol, 269, 1992.
[93] Y.V. Bykov, S. Egorov, A. Eremeev et al., "Evidence for microwave enhanced mass transport in the annealing of nanoporous alumina membranes", Journal of materials science, Vol, 36, pp. 131-136, 2001.
[94] J.H. Booske, R.F. Cooper, and S.A. Freeman, "Microwave enhanced reaction kinetics in ceramics", Materials Research Innovations, Vol, 1, pp. 77-84, 1997.
[95] Y. Huang, C. Hang, Y. Tian et al., "Rapid sintering of copper nanopaste by pulse current for power electronics packaging," 2017 18th International Conference on Electronic Packaging Technology (ICEPT) pp. 561-564, 2017.
[96] Y. Mei, L. Li, X. Li et al., "Electric-current-assisted sintering of nanosilver paste for copper bonding", Journal of Materials Science: Materials in Electronics, Vol, 28, pp. 9155-9166, 2017.
[97] H. Orchard and A. Greer, "Electromigration effects on compound growth at interfaces", Applied Physics Letters, Vol, 86, p. 231906, 2005.
[98] U. Anselmi-Tamburini, P. Asoka-Kumar, J. Garay et al., "Electric Current Enhanced Point Defect Mobility in Ni3Ti Intermetallic", Applied Physics Letters, Vol, 85, 2004.
[99] P. Asoka‐Kumar, K. O’brien, K. Lynn et al., "Detection of current‐induced vacancies in thin aluminum–copper lines using positrons", Applied physics letters, Vol, 68, pp. 406-408, 1996.
[100] K.-N. Tu, Y. Liu, and M. Li, "Effect of Joule heating and current crowding on electromigration in mobile technology", Applied Physics Reviews, Vol, 4, p. 011101, 2017.
[101] L. Zhang, S. Ou, J. Huang et al., "Effect of current crowding on void propagation at the interface between intermetallic compound and solder in flip chip solder joints", Applied physics letters, Vol, 88, p. 012106, 2006.
[102] T. Shao, S.-W. Liang, T. Lin et al., "Three-dimensional simulation on current-density distribution in flip-chip solder joints under electric current stressing", Journal of applied physics, Vol, 98, p. 044509, 2005.
[103] J. Garay, U. Anselmi-Tamburini, and Z. Munir, "Enhanced growth of intermetallic phases in the Ni–Ti system by current effects", Acta Materialia, Vol, 51, pp. 4487-4495, 2003.
[104] B. Liu, Y. Tian, C. Wang et al., "Ultrafast formation of unidirectional and reliable Cu3Sn-based intermetallic joints assisted by electric current", Intermetallics, Vol, 80, pp. 26-32, 2017.
[105] C. Liu and K.-N. Tu, "Reactive flow of molten Pb (Sn) alloys in Si grooves coated with Cu film", Physical Review E, Vol, 58, p. 6308, 1998.
[106] K.-N. Tu, C. Yeh, C. Liu et al., "Effect of current crowding on vacancy diffusion and void formation in electromigration", Applied Physics Letters, Vol, 76, pp. 988-990, 2000.
[107] S. Chiu, T. Shao, C. Chen et al., "Infrared microscopy of hot spots induced by Joule heating in flip-chip SnAg solder joints under accelerated electromigration", Applied physics letters, Vol, 88, p. 022110, 2006.
[108] J. Wu, P. Zheng, K. Lee et al., "Electromigration failures of UBM/bump systems of flip-chip packages," 52nd Electronic Components and Technology Conference 2002.(Cat. No. 02CH37345) pp. 452-457, 2002.
[109] T.-B. Song, Y. Chen, C.-H. Chung et al., "Nanoscale joule heating and electromigration enhanced ripening of silver nanowire contacts", ACS nano, Vol, 8, pp. 2804-2811, 2014.
[110] O. Yanagisawa, H. Kuramoto, K. Matsugi et al., "Observation of particle behavior in copper powder compact during pulsed electric discharge", Materials Science and Engineering: A, Vol, 350, pp. 184-189, 2003.
[111] M.M. Ristić and S. Milosević, "Frenkel′s theory of sintering", Science of Sintering, Vol, 38, pp. 7-11, 2006.
[112] H.E. Exner and E. Arzt, "Sintering processes", Sintering Key Papers, pp. 157-184, 1990.
[113] D. Demirskyi, D. Agrawal, and A. Ragulya, "Neck growth kinetics during microwave sintering of copper", Scripta Materialia, Vol, 62, pp. 552-555, 2010.
[114] Z.S. Nikolic, I. Mitrovic, and V.V. Mitic, Computer Simulation of Neck Growth During Sintering Process, Advanced Science and Technology of Sintering, Springer1999, pp. 61-66.
[115] A. Moitra, S. Kim, S.-G. Kim et al., "Investigation on sintering mechanism of nanoscale tungsten powder based on atomistic simulation", Acta Materialia, Vol, 58, pp. 3939-3951, 2010.
[116] L. Ding, R.L. Davidchack, and J. Pan, "A molecular dynamics study of sintering between nanoparticles", Computational Materials Science, Vol, 45, pp. 247-256, 2009.
[117] C. Suryanarayana, "Mechanical alloying and milling", Progress in materials science, Vol, 46, pp. 1-184, 2001.
[118] Y. Kitahara, S. Takahashi, and T. Fujii, "Thermal analysis of polyethylene glycol: Evolved gas analysis with ion attachment mass spectrometry", Chemosphere, Vol, 88, pp. 663-669, 2012.
[119] H. Ashassi-Sorkhabi, B. Rezaei-Moghadam, E. Asghari et al., "Sonoelectrosynthesized polypyrrole-graphene oxide nanocomposite modified by carbon nanotube and Cu2O nanoparticles on copper electrode for electrocatalytic oxidation of methanol", Journal of the Taiwan Institute of Chemical Engineers, Vol, 69, pp. 118-130, 2016.
[120] D. Kim, S. Lee, C. Chen et al., "Fracture mechanism of microporous Ag-sintered joint in a GaN power device with Ti/Ag and Ni/Ti/Ag metallization layer at different thermo-mechanical stresses", Journal of Materials Science, Vol, 56, pp. 9852-9870, 2021.
[121] C. Chen, J. Yeom, C. Choe et al., "Necking growth and mechanical properties of sintered Ag particles with different shapes under air and N2 atmosphere", Journal of Materials Science, Vol, 54, pp. 13344-13357, 2019.
[122] C.-M. Liu, H.-w. Lin, Y.-C. Chu et al., "Low-temperature direct copper-to-copper bonding enabled by creep on highly (111)-oriented Cu surfaces", Scripta Materialia, Vol, 78, pp. 65-68, 2014.
[123] K.-N. Tu, "Recent advances on electromigration in very-large-scale-integration of interconnects", Journal of applied physics, Vol, 94, pp. 5451-5473, 2003.
[124] A. Paul, T. Laurila, V. Vuorinen et al., Thermodynamics, diffusion and the Kirkendall effect in solids: Springer, 2014.
[125] C.-K. Hu, R. Rosenberg, and K. Lee, "Electromigration path in Cu thin-film lines", Applied Physics Letters, Vol, 74, pp. 2945-2947, 1999.
[126] W. Tyson, "Surface energies of solid metals", Canadian Metallurgical Quarterly, Vol, 14, pp. 307-314, 1975.

指導教授

吳子嘉(Albert T. Wu)

審核日期

2023-8-7

推文