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Article

A Reliable Way to Improve Electrochemical Migration (ECM) Resistance of Nanosilver Paste as a Bonding Material

1
School of Materials Science and Engineering, Tianjin University, Tianjin 300072, China
2
Beijing Century Goldray Semiconductor Co., Ltd., Beijing 100176, China
3
School of Electrical Engineering, Tiangong University, Tianjin 300350, China
4
The Bradley Department of Electrical and Computer Engineering, Virginia Tech, Blacksburg, VA 24061, USA
*
Author to whom correspondence should be addressed.
Appl. Sci. 2022, 12(9), 4748; https://doi.org/10.3390/app12094748
Submission received: 2 April 2022 / Revised: 30 April 2022 / Accepted: 6 May 2022 / Published: 9 May 2022
(This article belongs to the Special Issue Optoelectronic Materials, Devices, and Applications)

Abstract

:
Electrochemical migration (ECM) of sintered nano-Ag could be a serious reliability concern for power devices with high-density packaging. An anti-ECM nano-Ag-SiOx paste was proposed by doping 0.1wt% SiOx nanoparticles rather than previously used expensive noble metals, e.g., palladium. The ECM lifetime of the sintered nano-Ag-SiOx was 1.5 to 3 times longer than that of the sintered nano-Ag, due to the fact that the SiOx could protect the Ag from oxidation. The thermo-mechanical reliability of the sintered nano-Ag-SiOx was also improved by sintering under 5 MPa assisted pressure. The lesser porosity and smaller grain boundaries of the sintered nano-Ag-SiOx could also be beneficial to retard the silver ECM. In the end, a double-sided semiconductor device was demonstrated to validate the better resistance to the ECM using the sintered nano-Ag-SiOx.

1. Introduction

Die-attach materials are crucial to power devices. It bonds the chip to the substrate and performs the functions of conducting current and heat. Traditional lead-free and Sn-Pb solders harm the environment and have lower operating temperatures, thus nano-Ag paste as a die-attach material is a feasible option with excellent electrical and thermal conductivity [1,2,3].
However, silver is prone to electrochemical migration (ECM) and forms dendritic crystals, which result in short-circuit failure [4,5]. Generally, moisture is believed to play a crucial role in the migration of silver, and as a result, silver migration is described as a moisture migration phenomenon. However, recent studies have found that ECM failure of silver occurs even in high temperature and dry environments. The role of O2 in dry environments is similar to that of H2O in the classical moisture migration process [6]. Firstly, silver oxidized at the anode and form the intermediate species Ag2O, which dissociated into silver cations and oxygen anions at a high temperature above 250 °C. Driven by the bias voltage, the silver cations move from anode to cathode through the insulating gap, while the oxygen anions move in the opposite direction to maintain charge neutrality. The continuous depletion of silver cations at the anode drives oxidation and dissociation until silver dendrites formed between the two electrodes. Subsequently, silver dendrites gradually appeared and result in short circuits [7,8].
It was concerned that the ECM of the sintered nano-Ag should be a failure risk for packaging wide band-gap (WBG) power semiconductors devices, which can theoretically be operated at extreme temperatures of 500 °C, not to mention the great increase of electrical bias [9]. Furthermore, the previous ECM of silver was only focused on thick film conductors in conventional printed circuit boards (PCBs) [4,10]. Double-sided cooling (DSC) silicon carbide (SiC) power devices have attracted more and more attention in industries, especially in electric vehicle applications, because of their superior heat dissipation capability and power density [11]. However, the DSC SiC devices have a very small electrode spacing, e.g., 250 μm [12]. When the great sintered nano-Ag was used as die attachment in the DSC SiC devices, it is crucial to avoid the ECM failure of sintered nano-Ag to guarantee the reliability of electric vehicles. Unfortunately, there is a current lack of research on the ECM of silver suppression for the DSC SiC power devices.
Inhibition of the ECM of silver, such as alloying silver with indium or copper to form anti-ECM Ag-In and Ag-Cu alloys, had been studied [13,14]. Recently, we proposed the method of alloying silver with palladium aimed at inhibiting the formation of silver ions through oxidation and decomposition in the anode to delay the ECM of silver [15]. However, these alloying methods need very high processing temperatures in order to improve the resistance to the ECM of silver by alloying more at the higher temperature, not to mention the extremely high cost of indium, palladium, and so on.
In this paper, a nano-Ag composite paste was proposed with the 0.1wt% SiOx nanoparticles (NPs) as fillers. The conventional nano-Ag paste was compared as a reference. The lifetime for reaching the ECM failure was characterized in the first place. Then the thermo-mechanical reliability of the proposed nano-Ag-SiOx paste was verified in the aspects of die-shearing strength and thermal impedance by thermal shocking tests because it is critical to ensure promising thermo-mechanical reliability besides the improvement of the resistance to the ECM. Microstructures and porosity were analyzed to clarify the effects of SiOx doping on the ECM and the thermo-mechanical reliability. In the end, the proposed nano-Ag-SiOx paste was used as a die attachment for a DSC power device. The improvement of the lifetime of the ECM was validated in the high power density demonstration.

2. Materials and Methods

2.1. Materials

The nano-Ag composite paste was made by ultrasonically mixing the 30 nm Ag NPs and the 30 nm SiOx NPs with a specific weight ratio such as 0.1 wt%, accompanied by organic vehicles that included surfactants, binders, and thinners [16]. Figure 1a shows that the surfactant, binders, and thinners are dissolved by acetone in a beaker as a mixture. As seen from Figure 1b, in order to disperse the SiOx NPs and the Ag NPs uniformly in the mixture, the mixture was stirred at 2000 rpm for 10 min using a planetary centrifugal mixer (THINKY ARE310).

2.2. Methods of Reliability Verification

Firstly, the capability of the sintered nano-Ag or nano-Ag-SiOx against the ECM was verified in this work. The ECM samples were formed by stencil-printed the proposed anti-ECM nano-Ag composite paste on an alumina ceramic substrate (30 × 30 mm2) to form pairs of electrodes with identical gaps of 0.5 mm for ensuring uniform electrical bias distributions (Figure 1c). The as-printed ECM samples were then heated to 280 °C at a ramp rate of 5 °C/min and sintered at 280 °C for 30 min. These processes are shown in Figure 1d. The leakage currents between the electrodes are monitored by a Pico ammeter (RIGOL DM3068). The time when the leakage current first reaches 1 mA was defined as the lifetime of the ECM. The environment temperature during the ECM test was 25 ± 2 °C and the environment humidity during the ECM test was 50%.
Then thermal shocking tests were carried out according to the standard of JESD22-A104C to verify the reliability of the nano-Ag composite paste. The temperature swung from −40 °C to +125 °C and the soaking time at the extreme temperatures was 10 min. Each period was about 25 min. The degradation of shear strength and thermal resistance of the ECM samples was recorded every 100 cycles until 1000 cycles. The shear strength was measured by a die-shearing tester (XYZTEC, CONDOR 150) and the thermal resistance was recorded by a thermal resistance measurement system that used Vge as temperature sensitive parameter [17,18].
For the thermal resistance measurement, a 3.92 × 3.88 × 0.07 mm3 Insulated Gate-Bipolar-Transistor (IGBT) (INFINEON, IGC15T65QE) was sinter-bonded on a 30 × 30 × 1 mm3 silver-plated direct-bond-copper (DBC) substrate under the same process as that of the ECM samples.
For the die-shearing tests, a 3 × 3 × 0.25 mm3 dummy silicon chip with bottom metallization layer of Al-Ti-Ni-Ag (1.2 μm) was sinter-bonded on a 30 × 30 × 1 mm3 silver-plated DBC substrate using the same process as the ECM samples, under an additional pressure of 5 MPa.
In the end, a DSC power device was demonstrated to verify the anti-ECM of the proposed nano-Ag composite paste. The fabrication process of the DSC demonstration is shown in Figure 2. Firstly, the top side of a silicon carbide (SiC) dummy chip of 4 × 4 × 0.17 mm3 was metalized with Ti-Ni-Ag using magnetron sputtering technology. Then the proposed nano-Ag composite paste was printed onto two silver-plated DBC substrates of 20 × 20 × 1 mm3 and the top Ti-Ni-Ag metallization of the SiC chip separately. Then the chip, the silver-plated copper block buffer of 2 × 2 × 2.2 mm3, and the silver-plated power terminals were assembled with the DBC substrates. The as-assembled DBC substrates were sintered at 280 °C and 5 MPa as the process of the previous samples for the die-shearing tests.
During the ECM test for the demonstrated DSC power devices, a direct current (DC) power supplier (Topower TN-XX702) was connected with the power terminals of the device. A controllable heating plate was used to provide the ambient temperature required for the ECM test. The leakage currents in the device were monitored by the Pico ammeter (RIGOL DM3068).

3. Results and Discussion

The ECM experimental lifespan findings of the suggested nano-Ag composite paste and the control samples of conventional nano-Ag paste are listed in Table 1. According to Table 1, the nano-Ag-0.1%SiOx paste has a substantially longer failure lifetime than the nano-Ag paste under identical conditions. The 0.1wt% SiOx doping in the original nano-Ag paste serves a critical function in preventing the silver from migrating electrochemically. Furthermore, the lifetime reduces greatly when the temperature and the electric field are increased.
It was believed that the ECM behavior of the sintered nano-Ag at high temperatures initiates from the oxidation of the sintered anode and the decomposition of Ag2O [6]. When the temperature is constant, the higher the electrode voltage applied, the faster the Ag+ formed after anodic oxidation. These Ag ions would reduce at the negative electrode as metallic Ag under the action of the electric field, resulting in the accelerated growth of conductive silver dendrites from the cathode and extended to the anode. As a result, the leakage current can be detected between the anode and the cathode. When the voltage remains constant, the higher the ambient temperature, the faster the ions travel. Then the produced Ag+ speeds up the creation of silver dendrites under the specific electric field. Therefore, the ECM lifetime of the sintered nano-Ag-SiOx in the temperature range of 573–673 K is 1.5 to 3 times that of the sintered nano-Ag. It was likely that the SiOx covered on the silver, as shown in Figure 3a,b, should be susceptible to oxidation. The oxidation electrode potential of SiOx oxidation to SiO2, i.e., ~0.06 VSCE, was reported as more than one time lower than that of Ag oxidation to Ag2O, i.e., 0.13 VSCE [7,19]. As a result, silver oxidation was reduced and the ECM was delayed.
Figure 3c shows the change in shear strength following temperature cycling. The shear strength falls as the number of cycles increases. It should be noted that the shear strength of the Ag-SiOx paste drops to less than 30 MPa after 600 cycles, but the shear strength of the nano-Ag control samples remains ~30 MPa after 1000 cycles. It was likely that the atomic diffusion rate of Ag into Ag, i.e., ~1.455 × 10−23 m2/s [20], is much higher than that of Ag into SiOx, i.e., ~8.76 × 10−29 m2/s [21], resulting in an insufficient driving force for the sinter-bonding of Ag-SiOx heterogeneous particles under the same pressure-free and sintering temperature conditions [22]. The Young’s modulus of the SiOx nanoparticles, on the other hand, is much higher than that of the Ag nanoparticles, and the thermal expansion coefficient is much lower than that of the sintered nano-Ag, so the interfacial bonds of the sintered Ag-SiOx were subjected to thermo-mechanical stress fatigue during temperature cycling, eventually leading to its shear strength dropping faster in the case of pressureless sintering [23].
It was known the driving force for the sintering can be increased greatly if assisted pressure was applied [24]. An extra 5 MPa pressure was applied to promote the sintering of the Ag-SiOx paste for better long-term reliability. Fortunately, the shear strength of the pressure-assisted sintered Ag-SiOx can be kept at ~35 MPa even after 1000 cycles. It was even higher than the shear strength of the nano-Ag control samples after 1000 cycles. It was believed that the pressure can ensure the better thermo-mechanical reliability of the nano-Ag-SiOx paste.
Figure 3c also shows the change in thermal resistance after the temperature cycling. The thermal resistance grows steadily as the number of cycles increases. The thermal resistance of the nano-Ag paste improves by ~9% after 1000 cycles, while the thermal resistance of the nano-Ag-SiOx paste sintered with 5 MPa pressure increases by ~12%. It was consistent with the variation of the die shear strength. Fortunately, the increase in thermal resistance of the nano-Ag-SiOx pastes is still less than the common industrial failure criterion in power electronics, which is usually required as less than 20% of the thermal resistance after 1000 cycles of the temperature cycling.
Figure 4 shows the microstructures and porosity of sintered Ag and sintered nano-Ag-SiOx before and after the thermal shocking aging. The porosity of the sintered nano-Ag-SiOx before and after the thermal shocking aging is always lower than that of the sintered nano-Ag. It was believed that the nucleation of metallic Ag occurs preferentially adjacent to the SiOx nanoparticles as seeds; this is called heterogeneous nucleation [25,26]. Therefore, for example, the porosity of the as-sintered nano-Ag-SiOx, i.e., 21.8%, can be much lower than that of the as-sintered nano-Ag, i.e., 34.5%.
Furthermore, the grains of the sintered nano-Ag-SiOx grew more than that of the sintered nano-Ag under a similar sintering profile. The larger grain size indicated a smaller grain boundary density as well. Considering that the grain boundaries are close to the free surface as fast diffusion paths [27], the more the grain boundary, the more the Ag hillocks could be formed by atomic diffusion or stress migration through the grain boundaries. The fewer grain boundaries of the sintered nano-Ag-SiOx may be also beneficial to retard the silver ECM to some extent as a result.
For the ECM verification for device packaging applications at 400 °C under the applied voltage of 400 V, the ECM lifetime of the DSC device using the sintered nano-Ag-SiOx and the sintered nano-Ag as die attachment is 240 h and only 96 h, respectively. The ECM of silver was suppressed successfully. As seen from Figure 5, although silver dendrites appeared after 240 h ECM testing of DSC devices using sintered nano-Ag-SiOx, significant improvement in ECM lifetime was achieved by nano-Ag-SiOx paste. Herein, the nano-Ag-SiOx paste could be a promising option to be used as a bonding material against specific metal corrosion.

4. Conclusions

Silver ECM at high temperatures could be significantly retarded by the addition of SiOx nanoparticles in the nano-Ag paste. The thermo-mechanical reliability of the proposed nano-Ag-SiOx paste has been verified and proved to be improved by sintering under 5 MPa assisted pressures. It seems suitable as a new promising bonding material to prevent silver ECM failure because its die shear strength and thermal resistance degradation still did not reach the common failure criterion even after 1000 cycles of the thermal shock test. Finally, the ECM verification of the DSC power device further confirms the improvement of the sintered nano-Ag-SiOx as die attachment against the sintered nano-Ag ECM failure at high temperatures. It is interesting to pay more attention to reducing the ECM failure of sintered nano-Ag in economical and promising ways in the future.

Author Contributions

Conceptualization, Y.-H.M. and G.-Q.L.; methodology, Y.-H.M. and B.Z.; validation, Z.D.; formal analysis, Z.D., Z.W. and Y.-H.M.; investigation, Z.D. and Y.-H.M.; resources, Y.-H.M. and Z.W.; data curation, B.Z. and Y.-H.M.; writing—original draft preparation, Z.D. and Y.-H.M.; writing—review and editing, Y.-H.M. and B.Z.; visualization, Z.D. and Y.-H.M.; supervision, Y.-H.M.; project administration, Y.-H.M.; funding acquisition, Y.-H.M. and Z.W. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the National Natural Science Foundation of China, grant numbers 52177189, 51922075, and 52107203, and by Tianjin Municipal Science and Technology Bureau, grant number 21JCJQJC00150. The APC was funded by the National Natural Science Foundation of China.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

In this section, you can acknowledge the equipment support given by Xin Li and her students from Tianjin University.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Wang, T.; Chen, X.; Lu, G.Q.; Lei, G.Y. Low-Temperature Sintering with Nano-Silver Paste in Die-Attached Interconnection. J. Electron. Mater. 2007, 36, 1333–1340. [Google Scholar] [CrossRef]
  2. Matkowski, P.K.; Falat, T.; Zaluk, Z.; Felba, J.; Moscicki, A. Structure of the Thermal Interface Connection Made of Sintered Nano Silver. In Proceedings of the 2014 IEEE Electronics System-Integration Technology Conference, Dresden, Germany, 7–11 May 2014; pp. 1–6. [Google Scholar]
  3. Yang, C.A.; Kao, C.R.; Nishikawa, H. Development of Die Attachment Technology for Power IC Module by Introducing Indium into Sintered Nano-Silver Joint. In Proceedings of the 2017 IEEE 67th Electronic Components and Technology Conference (ECTC), Orlando, FL, USA, 30 May–2 June 2017; pp. 2377–5726. [Google Scholar]
  4. Kim, K.S.; Bang, J.O.; Jung, S.B. Electrochemical Migration Behavior of Silver Nanopaste Screen-Printed for Flexible and Printable Electronics. Curr. Appl. Phys. 2013, 13, S190–S194. [Google Scholar] [CrossRef]
  5. Yang, S.; Christou, A. Failure Model for Silver Electrochemical Migration. IEEE Trans. Device Mater. Reliab. 2007, 7, 188–196. [Google Scholar] [CrossRef]
  6. Noh, B.I.; Yoon, J.W.; Kim, K.S.; Lee, Y.C.; Jung, S.B. Microstructure, Electrical Properties, and Electrochemical Migration of a Directly Printed Ag Pattern. J. Electron. Mater. 2011, 40, 35–41. [Google Scholar] [CrossRef]
  7. Li, D.; Mei, Y.H.; Tian, Y.; Xin, Y. Doping Low-Cost SiOx (1.2 < x < 1.6) Nanoparticles to Inhibit Electrochemical Migration of Sintered Silver at High Temperatures. J. Alloys Compd. 2020, 830, 154587. [Google Scholar]
  8. Medgyes, B.; Illés, B.; Harsányi, G. Electrochemical Migration Behaviour of Cu, Sn, Ag and Sn63/Pb37. J. Mater. Sci. Mater. Electron. 2012, 23, 551–556. [Google Scholar] [CrossRef]
  9. Mei, Y.H.; Lu, G.Q.; Chen, X.; Luo, S.; Ibitayo, D. Migration of Sintered Nanosilver Die-Attach Material on Alumina Substrate Between 250 °C and 400 °C in Dry Air. IEEE Trans. Device Mater. Reliab. 2011, 11, 316–322. [Google Scholar] [CrossRef]
  10. Mcnutt, T.; Passmore, B.; Fraley, J.; Mcpherson, B.; Shaw, R.; Olejniczak, K.; Lostetter, A. High-Performance, Wide-Bandgap Power Electronics. J. Electron. Mater. 2014, 43, 4552–4559. [Google Scholar] [CrossRef]
  11. Zhou, Y.; Huo, Y. The Comparison of Electrochemical Migration Mechanism between Electroless Silver Plating and Silver Electroplating. J. Mater. Sci. Mater. Electron. 2016, 27, 931–941. [Google Scholar] [CrossRef]
  12. Liu, X.; Wu, Z.; Yan, Y.; Kang, Y.; Chen, C. A Novel Double-Sided Cooling Inverter Leg for High Power Density EV Based on Customized SiC Power Module. In Proceedings of the 2020 IEEE Energy Conversion Congress and Exposition (ECCE), Detroit, MI, USA, 11–15 October 2020; pp. 3151–3154. [Google Scholar]
  13. Cheng, T.H.; Nishiguchi, K.; Fukawa, Y.; Baliga, B.J.; Hopkins, D.C. Characterization of Highly Thermally Conductive Organic Substrates for a Double-Sided Cooled Power Module. Int. Symp. Microelectron. 2020, 1, 277–281. [Google Scholar] [CrossRef]
  14. Yang, C.A.; Wu, J.; Lee, C.C.; Kao, C.R. Analyses and Design for Electrochemical Migration Suppression by Alloying Indium into Silver. J. Mater. Sci. Mater. Electron. 2018, 29, 13878–13888. [Google Scholar] [CrossRef] [Green Version]
  15. Zhang, D.; Zou, G.; Liu, L.; Zhang, Y.; Yu, C.; Bai, H.; Zhou, N. Synthesis with Glucose Reduction Method and Low Temperature Sintering of Ag-Cu Alloy Nanoparticle Pastes for Electronic Packaging. Jpn. Inst. Met. Mater. 2015, 56, 1252–1256. [Google Scholar] [CrossRef] [Green Version]
  16. Wang, D.; Mei, Y.H.; Xie, H.; Zhang, K.; Siow, K.S.; Li, X.; Lu, G.Q. Roles of Palladium Particles in Enhancing the Electrochemical Migration Resistance of Sintered Nano-Silver Paste as a Bonding Material. Mater. Lett. 2017, 206, 1–4. [Google Scholar] [CrossRef]
  17. Bai, J.G.; Calata, J.N.; Lu, G.Q. Processing and Characterization of Nanosilver Pastes for Die-Attaching SiC Devices. IEEE Trans. Electron. Packag. Manuf. 2007, 30, 241–245. [Google Scholar] [CrossRef]
  18. Gang, C.; Dan, H.; Mei, Y.H.; Cao, X.; Tao, W.; Xu, C.; Lu, G.Q. Transient Thermal Performance of IGBT Power Modules Attached by Low-Temperature Sintered Nanosilver. IEEE Trans. Device Mater. Reliab. 2012, 12, 124–132. [Google Scholar]
  19. Mei, Y.; Tao, W.; Xiao, C.; Gang, C.; Lu, G.Q.; Xu, C. Transient Thermal Impedance Measurements on Low-Temperature-Sintered Nanoscale Silver Joints. J. Electron. Mater. 2012, 41, 3152–3160. [Google Scholar] [CrossRef]
  20. Li, D.; Mei, Y.; Xin, Y.; Li, Z.; Chu, P.K.; Ma, C.; Lu, G.Q. Reducing Migration of Sintered Ag for Power Devices Operating at High Temperature. IEEE Trans. Power Electron. 2020, 35, 12646–12650. [Google Scholar] [CrossRef]
  21. Wazzan, A.R.; Tung, p.; Robinson, L.B. Diffusion of Silver into Nickel Single Crystals. J. Appl. Phys. 1971, 42, 5316–5320. [Google Scholar] [CrossRef]
  22. Friedland, E.; Malherbe, J.B.; van der Berg, N.G.; Hlatshwayo, T.; Botha, A.J.; Wendler, E.; Wesch, W. Study of Silver Diffusion in Silicon Carbide. J. Nucl. Mater. 2009, 389, 326–331. [Google Scholar] [CrossRef]
  23. Hu, B.; Yang, F.; Peng, Y.; Hang, C.; Chen, H.; Lee, C.; Yang, S.; Li, M. Effect of SiC Reinforcement on the Reliability of Ag Nanoparticle Paste for High-Temperature Applications. J. Mater. Sci. Mater. Electron. 2019, 30, 2413–2418. [Google Scholar] [CrossRef]
  24. Zhang, H.; Chen, C.; Nagao, S.; Suganuma, K. Thermal Fatigue Behavior of Silicon-Carbide-Doped Silver Microflake Sinter Joints for Die Attachment in Silicon/Silicon Carbide Power Devices. J. Electron. Mater. 2017, 46, 1055–1060. [Google Scholar] [CrossRef]
  25. Yan, H.; Liang, P.; Mei, Y.H.; Feng, Z. Brief Review of Silver Sinter-bonding Processing for Packaging High-temperature Power Devices. Chin. J. Electr. Eng. 2020, 6, 25–34. [Google Scholar] [CrossRef]
  26. Li, W.; Hu, D.; Li, L.; Li, C.F.; Jiu, J.; Chen, C.; Ishina, T.; Sugahara, T.; Suganuma, K. Printable and Flexible Copper-Silver Alloy Electrodes with High Conductivity and Ultrahigh Oxidation Resistance. ACS Appl. Mater. Inter. 2017, 9, 24711–24721. [Google Scholar] [CrossRef] [PubMed]
  27. Lin, S.K.; Nagao, S.; Yokoi, E.; Oh, C.; Zhang, H.; Liu, Y.C.; Lin, S.G.; Suganuma, K. Nano-Volcanic Eruption of Silver. Sci. Rep. 2016, 6, 34769. [Google Scholar] [CrossRef]
Figure 1. (a) Preparation process of nano silver paste; (b) preparation of proposed anti-ECM nano-Ag-SiOx composite paste; (c) preparation of ECM samples; (d) schematic of the sintering process and ECM test.
Figure 1. (a) Preparation process of nano silver paste; (b) preparation of proposed anti-ECM nano-Ag-SiOx composite paste; (c) preparation of ECM samples; (d) schematic of the sintering process and ECM test.
Applsci 12 04748 g001
Figure 2. Fabrication process of the DSC demonstration and verification of electrochemical migration resistance for a DSC device using sintered nano-Ag-SiOx as die attachment.
Figure 2. Fabrication process of the DSC demonstration and verification of electrochemical migration resistance for a DSC device using sintered nano-Ag-SiOx as die attachment.
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Figure 3. (a) Microstructures of as-sintered nano-Ag-SiOx; (b) the corresponding magnified image; (c) the thermal impedance of sintered nano-Ag-SiOx variation with the number of thermal shocking cycles.
Figure 3. (a) Microstructures of as-sintered nano-Ag-SiOx; (b) the corresponding magnified image; (c) the thermal impedance of sintered nano-Ag-SiOx variation with the number of thermal shocking cycles.
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Figure 4. (ad) Microstructures and (eh) porosity comparisons of sintered nano-Ag and sintered nano-Ag-SiOx before and after the thermal shocking test.
Figure 4. (ad) Microstructures and (eh) porosity comparisons of sintered nano-Ag and sintered nano-Ag-SiOx before and after the thermal shocking test.
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Figure 5. (a) Schematic diagram of DSC device, (b) metallographic micrograph of the DSC device after ECM failure, and (c) the corresponding magnified image.
Figure 5. (a) Schematic diagram of DSC device, (b) metallographic micrograph of the DSC device after ECM failure, and (c) the corresponding magnified image.
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Table 1. ECM testing conditions and lifetime comparisons.
Table 1. ECM testing conditions and lifetime comparisons.
Temperature (K)Electrode Spacing (mm)Voltage (V)Lifetime (min)
Sintered Nano-AgSintered Nano-Ag-SiOx
6730.5200332512
6730.5260294477
6730.5300236412
7730.5200134341
7730.526081244
7730.530074208
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Ding, Z.; Wang, Z.; Zhang, B.; Lu, G.-Q.; Mei, Y.-H. A Reliable Way to Improve Electrochemical Migration (ECM) Resistance of Nanosilver Paste as a Bonding Material. Appl. Sci. 2022, 12, 4748. https://doi.org/10.3390/app12094748

AMA Style

Ding Z, Wang Z, Zhang B, Lu G-Q, Mei Y-H. A Reliable Way to Improve Electrochemical Migration (ECM) Resistance of Nanosilver Paste as a Bonding Material. Applied Sciences. 2022; 12(9):4748. https://doi.org/10.3390/app12094748

Chicago/Turabian Style

Ding, Zikun, Zhichao Wang, Bowen Zhang, Guo-Quan Lu, and Yun-Hui Mei. 2022. "A Reliable Way to Improve Electrochemical Migration (ECM) Resistance of Nanosilver Paste as a Bonding Material" Applied Sciences 12, no. 9: 4748. https://doi.org/10.3390/app12094748

APA Style

Ding, Z., Wang, Z., Zhang, B., Lu, G. -Q., & Mei, Y. -H. (2022). A Reliable Way to Improve Electrochemical Migration (ECM) Resistance of Nanosilver Paste as a Bonding Material. Applied Sciences, 12(9), 4748. https://doi.org/10.3390/app12094748

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