{"title":"混合动力系统上焊接或环氧粘合片状电容器互连的可靠性","authors":"G. Dreyer, A. Koudounaris, I. Pratt","doi":"10.1109/TPHP.1977.1135212","DOIUrl":null,"url":null,"abstract":"The influence of capacitor chip-to-substrate assembly variables on interconnect reliability was evaluated using several conventional environmental tests. The variables investigated included: capacitor chip size, capacitor end metallization, substrate pad size, substrate metallization, different solders, and a nonconduetive and a conductive epoxy. Environmental tests consisted of mechanical shock, temperature cycling, and high temperature storage. The test specimens included three capacitor sizes: 0.050 X 0.080 in, 0.080 X 0.180 in, and 0.080 X 0.270 in, all 0.050 in high; and three end terminations: silver, palladium-silver, and an Sn60-Pb36-Ag4 solder coating. Substrate pad sizes were varied to represent large, medium, and small bonding areas. Capacitors having all three end terminations were reflow soldered on Sn10-Pb88-Ag2 or Sn96-Ag4 tinned pads, by reflowing Sn62-Pb-36-2Ag paste, or by Silver conductive epoxy bonding with Ablefilm 606-2 (commonly used for bonding active devices). Also, capacitors with palladium-silver end terminations were bonded with nonconductive epoxy, while the electrical interc0nnection from substrate to chip was made by thermocompression bonded gold wire. Two types of substrate metallization were used: a) thin film nichrome, nickel, gold;b) thick film platinum-gold. Testing consisted of the sequential exposure:· i) to 3000-G mechanical shock (5 pulses), ii) temperature cycling from -65 to 150°C (100 cycles), iii) 3000-G mechanical shock (5 pulses), and iv) high temperature exposure at 150°°C for one week (168 h). All chips were visually and electrically checked after each test. Capacitor attachment was more reliable when small chips were bonded to thick f'dm metallization and when the bonding pads were large. Snl0 solder or nonconductive epoxy were the most reliable inter, connect materials. When soldering, the best electrical and mechanical end terminations were palladium-silver; the appearance of silver end terminations changed during environmental testing, but solder coated or palladium-silver terminations were visually unaffected. When conductive epoxy bonding, no differences were noted between silver or palladium-silver terminations. Visual examination was of minimal value in detecting marginal chip attachments. The most effective environmental test combination was thermal cycling followed by mechanical shock.","PeriodicalId":387212,"journal":{"name":"IEEE Transactions on Parts, Hybrids, and Packaging","volume":"25 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"1977-09-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":"{\"title\":\"The Reliability of Soldered or Epoxy Bonded Chip Capacitor Interconnections on Hybrids\",\"authors\":\"G. Dreyer, A. Koudounaris, I. Pratt\",\"doi\":\"10.1109/TPHP.1977.1135212\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"The influence of capacitor chip-to-substrate assembly variables on interconnect reliability was evaluated using several conventional environmental tests. The variables investigated included: capacitor chip size, capacitor end metallization, substrate pad size, substrate metallization, different solders, and a nonconduetive and a conductive epoxy. Environmental tests consisted of mechanical shock, temperature cycling, and high temperature storage. The test specimens included three capacitor sizes: 0.050 X 0.080 in, 0.080 X 0.180 in, and 0.080 X 0.270 in, all 0.050 in high; and three end terminations: silver, palladium-silver, and an Sn60-Pb36-Ag4 solder coating. Substrate pad sizes were varied to represent large, medium, and small bonding areas. Capacitors having all three end terminations were reflow soldered on Sn10-Pb88-Ag2 or Sn96-Ag4 tinned pads, by reflowing Sn62-Pb-36-2Ag paste, or by Silver conductive epoxy bonding with Ablefilm 606-2 (commonly used for bonding active devices). Also, capacitors with palladium-silver end terminations were bonded with nonconductive epoxy, while the electrical interc0nnection from substrate to chip was made by thermocompression bonded gold wire. Two types of substrate metallization were used: a) thin film nichrome, nickel, gold;b) thick film platinum-gold. Testing consisted of the sequential exposure:· i) to 3000-G mechanical shock (5 pulses), ii) temperature cycling from -65 to 150°C (100 cycles), iii) 3000-G mechanical shock (5 pulses), and iv) high temperature exposure at 150°°C for one week (168 h). All chips were visually and electrically checked after each test. Capacitor attachment was more reliable when small chips were bonded to thick f'dm metallization and when the bonding pads were large. Snl0 solder or nonconductive epoxy were the most reliable inter, connect materials. When soldering, the best electrical and mechanical end terminations were palladium-silver; the appearance of silver end terminations changed during environmental testing, but solder coated or palladium-silver terminations were visually unaffected. When conductive epoxy bonding, no differences were noted between silver or palladium-silver terminations. Visual examination was of minimal value in detecting marginal chip attachments. 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引用次数: 1
摘要
通过几种常规环境试验,评估了电容器芯片-衬底组装变量对互连可靠性的影响。研究的变量包括:电容器芯片尺寸,电容器端金属化,衬底焊片尺寸,衬底金属化,不同的焊料,以及非导电和导电环氧树脂。环境试验包括机械冲击、温度循环和高温储存。测试样品包括三种电容器尺寸:0.050 X 0.080英寸,0.080 X 0.180英寸和0.080 X 0.270英寸,高均为0.050;以及三种末端端子:银、钯银和Sn60-Pb36-Ag4焊料涂层。衬底衬垫尺寸不同,以代表大、中、小的键合区域。具有所有三个末端的电容器回流焊在Sn10-Pb88-Ag2或Sn96-Ag4镀锡焊盘上,回流焊Sn62-Pb-36-2Ag浆料,或用Ablefilm 606-2(通常用于粘合有源器件)进行银导电环氧树脂粘合。此外,钯银端头的电容器用不导电的环氧树脂粘接,而基板与芯片的电气互连采用热压粘接金线。采用了两种类型的衬底金属化:a)薄膜镍、镍、金;b)厚膜铂金。测试包括顺序暴露:·i) 3000-G机械冲击(5个脉冲),ii)从-65°C到150°C的温度循环(100个循环),iii) 3000-G机械冲击(5个脉冲),iv) 150°C高温暴露一周(168小时)。每次测试后,所有芯片都进行了视觉和电气检查。当小芯片粘接在厚的f'dm金属层上时,当粘接垫很大时,电容器的附着更可靠。Snl0焊料或不导电环氧树脂是最可靠的互连材料。焊接时,最好的电气和机械端是钯银;银端子的外观在环境测试期间发生了变化,但焊料涂层或钯银端子在视觉上不受影响。当导电环氧键合时,银端或钯银端没有差别。目视检查在检测边缘芯片附着时价值最小。最有效的环境试验组合是热循环后机械冲击。
The Reliability of Soldered or Epoxy Bonded Chip Capacitor Interconnections on Hybrids
The influence of capacitor chip-to-substrate assembly variables on interconnect reliability was evaluated using several conventional environmental tests. The variables investigated included: capacitor chip size, capacitor end metallization, substrate pad size, substrate metallization, different solders, and a nonconduetive and a conductive epoxy. Environmental tests consisted of mechanical shock, temperature cycling, and high temperature storage. The test specimens included three capacitor sizes: 0.050 X 0.080 in, 0.080 X 0.180 in, and 0.080 X 0.270 in, all 0.050 in high; and three end terminations: silver, palladium-silver, and an Sn60-Pb36-Ag4 solder coating. Substrate pad sizes were varied to represent large, medium, and small bonding areas. Capacitors having all three end terminations were reflow soldered on Sn10-Pb88-Ag2 or Sn96-Ag4 tinned pads, by reflowing Sn62-Pb-36-2Ag paste, or by Silver conductive epoxy bonding with Ablefilm 606-2 (commonly used for bonding active devices). Also, capacitors with palladium-silver end terminations were bonded with nonconductive epoxy, while the electrical interc0nnection from substrate to chip was made by thermocompression bonded gold wire. Two types of substrate metallization were used: a) thin film nichrome, nickel, gold;b) thick film platinum-gold. Testing consisted of the sequential exposure:· i) to 3000-G mechanical shock (5 pulses), ii) temperature cycling from -65 to 150°C (100 cycles), iii) 3000-G mechanical shock (5 pulses), and iv) high temperature exposure at 150°°C for one week (168 h). All chips were visually and electrically checked after each test. Capacitor attachment was more reliable when small chips were bonded to thick f'dm metallization and when the bonding pads were large. Snl0 solder or nonconductive epoxy were the most reliable inter, connect materials. When soldering, the best electrical and mechanical end terminations were palladium-silver; the appearance of silver end terminations changed during environmental testing, but solder coated or palladium-silver terminations were visually unaffected. When conductive epoxy bonding, no differences were noted between silver or palladium-silver terminations. Visual examination was of minimal value in detecting marginal chip attachments. The most effective environmental test combination was thermal cycling followed by mechanical shock.
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