Evaluation of Anisotropic Conductive Films Based on Vertical Fibers for Post-CMOS Wafer-Level Packaging

In this paper, we investigate the mechanical and electrical properties of an anisotropic conductive film (ACF) on the basis of high-density vertical fibers for a wafer-level packaging (WLP) application. As part of the WaferBoard, a\ud reconfigurable circuit platform for rapid system prototyping,\ud ACF is used as an intermediate film providing compliant and\ud vertical electrical connection between chip contacts and a top surface of an active wafer-size large-area IC. The chosen ACF is first tested by an indentation technique. The results show that the elastic–plastic deformation mode as well as the Young’s modulus and the hardness depend on the indentation depth. Second, the efficiency of the electrical contact is tested using a uniaxial compression on a stack comprising a dummy ball grid array (BGA) board, an ACF, and a thin Al film. For three bump diameters, as the compression increases, the resistance values decrease before reaching low and stable values. Despite the BGA solder bumps exhibit plastic deformation after compression, no damage is found on the ACF film. These results show that vertical fiber ACFs can be used for nonpermanent bonding in a WLP application

Nanowires for 3d silicon interconnection – low temperature compliant nanowire-polymer film for z-axis interconnect

Semiconductor chip packaging has evolved from single chip packaging to 3D heterogeneous system integration using multichip stacking in a single module. One of the key challenges in 3D integration is the high density interconnects that need to be formed between the chips with through-silicon-vias (TSVs) and inter-chip interconnects. Anisotropic Conductive Film (ACF) technology is one of the low-temperature, fine-pitch interconnect method, which has been considered as a potential replacement for solder interconnects in line with continuous scaling of the interconnects in the IC industry. However, the conventional ACF materials are facing challenges to accommodate the reduced pad and pitch size due to the micro-size particles and the particle agglomeration issue. A new interconnect material - Nanowire Anisotropic Conductive Film (NW-ACF), composed of high density copper nanowires of ~ 200 nm diameter and 10-30 µm length that are vertically distributed in a polymeric template, is developed in this work to tackle the constrains of the conventional ACFs and serves as an inter-chip interconnect solution for potential three-dimensional (3D) applications

Development and Evaluation of Accelerated Environmental Test Methods for Products with High Reliability Requirements

Reliability testing of electronics is performed to ensure that products function as planned in specific conditions for a specified amount of time. This is usually both time-consuming and expensive and therefore test time acceleration is often required. The acceleration may be realized by using more severe stress levels or higher use cycle frequencies, but at the same time the risk increases of inducing failure mechanisms not relevant to the use conditions. As a consequence, the accelerated reliability testing of products with markedly long lifetimes and high reliability is frequently challenging. In this thesis different methods for test time acceleration for products with high reliability requirements and long service lives were studied. Both standard tests and modifications of these were used. The effect of the accelerated tests used on the failure modes and mechanisms observed was examined and the limitations of the test methods discussed. The research in this work was conducted at both interconnection level and at device level. The interconnection level testing focused on anisotropically conductive adhesive (ACA) flex-on-board (FOB) attachments. In addition to the effect of the curing process on the mechanical strength of ACA FOB attachments, their applicability and long-term performance in industrial applications was studied. According to the real-time resistance measurement the assembly tested was observed to be extremely resilient in thermal cycling and hygrothermal aging. However, a significant decrease in the mechanical strength of the FOB attachment was also seen. Hydrolysis and embrittlement of the flex material was also observed to limit the applicability of harsher hygrothermal aging conditions. Clear ACA joint failures were only observed with moisture condensation testing, but this may not be a suitable test method for applications that are not susceptible to such a stressor. The device level testing comprised reliability analysis of two frequency converter models. The older generation device and its field failure data were used as the starting point in the development of a test method that could be used to minimize testing time and to induce comparable failure modes to those occurring in the use conditions of the devices. The tests showed that only with the simultaneous use of stresses could a significant reduction in the testing time be achieved. However, the application of the same test method to the newer generation device proved challenging because of differences in materials, components and layouts. Although similar failure modes were observed in both devices, the combined effect of the stresses used on the failure mechanisms requires further study. In addition, knowledge of the service conditions, the environmental stresses and their severity is critical. The main disadvantage of simultaneous stress testing was observed to be the interpretation of the test results, especially due to the complexity of the devices tested. Moreover, the results obtained may be highly application specific. However, regardless of the difficulties in the lifetime estimation, the use of combined stresses was observed to be a practical method to study the weaknesses in a product

Development and reliability of a direct access sensor using flip chip on flex technology with anisotropic conductive adhesive

Technological developments in biomedical microsystems are opening up new opportunities to improve healthcare procedures. Swallowable diagnostic sensing capsules are an example of these. In none of the diagnostic sensing capsules, is the sensor’s first level packaging achieved via Flip Chip Over Hole (FCOH) method using Anisotropic Conductive Adhesive (ACA). In a capsule application with direct access sensor (DAS), ACA not only provides the electrical interconnection but simultaneously seals the interconnect area and the underlying electronics. The development showed that the ACA FCOH was a viable option for the DAS interconnection. Adequate adhesive formed a strong joint that withstood a shear stress of 120N/mm2 and a compressive stress of 6N required to secure the final sensor assembly in place before encapsulation. Electrical characterization of the ACA joint in a fluid environment showed that the ACA was saturated with moisture and that the ions in the solution actively contributed to the leakage current, characterized by the varying rate of change of conductance. Long term hygrothermal aging of the ACA joint showed that a thermal strain of 0.004 and a hygroscopic strain of 0.0052 were present and resulted in a fatigue like process. In-vitro tests showed that high temperature and acidity had a deleterious effect of the ACA and its joint. It also showed that the ACA contact joints positioned at around or over 1mm would survive the gastrointestinal (GI) fluids and would be able to provide a reliable contact during the entire 72hr of the GI transit time. A final capsule demonstrator was achieved by successfully integrating the DAS, the battery and the final foldable circuitry into a glycerine capsule. Final capsule soak tests suggested that the silicone encapsulated system could survive the 72hr gut transition

JTEC Panel report on electronic manufacturing and packaging in Japan

This report summarizes the status of electronic manufacturing and packaging technology in Japan in comparison to that in the United States, and its impact on competition in electronic manufacturing in general. In addition to electronic manufacturing technologies, the report covers technology and manufacturing infrastructure, electronics manufacturing and assembly, quality assurance and reliability in the Japanese electronics industry, and successful product realization strategies. The panel found that Japan leads the United States in almost every electronics packaging technology. Japan clearly has achieved a strategic advantage in electronics production and process technologies. Panel members believe that Japanese competitors could be leading U.S. firms by as much as a decade in some electronics process technologies

Développement de procédés avancés d'encapsulation de composants microélectroniques basés sur les techniques de thermocompression

L'un des grands défis de la recherche et développement est d'optimiser l'ensemble du cycle de fabrication d'un produit microélectronique, depuis sa conception jusqu’à sa tenue mécanique en service. Un objectif essentiel des entreprises était de réduire le temps de cycles d’assemblage afin de minimiser les coûts de production. La phase d’assemblage des composants microélectroniques est l'une des étapes clé qui doit être bien optimisée afin d’atteindre l’objectif de minimisation du temps de cycle. La méthode d'assemblage traditionnelle des puces par refusion (en anglais mass reflow MR) convenait généralement à une fabrication à grand volume, en particulier pour des puces à pas standard d'environ 150 μm. Cependant, la forte demande du marché pour des interconnexions à pas plus fin, pour permettre un nombre d'entrée/sortie (Input/Output : I/O) plus élevé dans un facteur de forme plus petit, a entraîné une transition du processus de la liaison MR conventionnel à l'assemblage par thermocompression (en anglais ThermoCompression Bonding TCB). Bien que le procédé TCB offre un assemblage de plus grande précision et permet l'utilisation des pas d'interconnexion plus fins, il présente également de nouveaux défis. L'un des problèmes majeurs de l'assemblage TCB est qu'il s'agit d'un processus assez long, dans lequel chaque puce doit être passée indépendamment à travers un cycle TCB complet, incluant le chauffage, le maintien de la température et le refroidissement. Cela entraîne une diminution significative de la productivité par rapport au MR. Le débit de production peut être amélioré en réduisant le temps nécessaire pour atteindre les températures de processus requises. Cependant, des variations thermiques peuvent se produire aux interfaces de liaison, entraînant une mauvaise uniformité de température sur la surface de la puce et conduisant à des régions où le point de fusion de la brasure n'est pas atteint. Ainsi, il est extrêmement important de prévoir et contrôler la température réelle à l'interface de liaison afin d’obtenir une bonne uniformité thermique et des joints de brasure sans défaut. C'est dans cette perspective que s'inscrit les travaux menés dans la première partie de la thèse. Le premier objectif de cette étude était donc de déterminer la durée minimum de temps de chauffe nécessaire assurant une uniformité de température optimal et par conséquent des joints de brasure de bonne qualité. Pour atteindre cet objectif, il fallait alors proposer et valider une nouvelle méthodologie pour estimer la température d'interface lors d'un processus TCB. Une évaluation de l'influence de différentes vitesses de chauffe sur la distribution de température à travers la surface de la puce, ainsi que sur la qualité de liaison résultante, a été réalisée à l’aide d’un capteur de type RTD (). Les résultats ont montré que les défauts de brasure observés aux interfaces de liaison peuvent éventuellement être liés à une mauvaise uniformité de température, liée à des vitesses de chauffe élevées. Des variations thermiques acceptables ont été trouvées à une faible vitesse de chauffage de 80°C/s. Par conséquent, pour surmonter les températures de processus élevées et leurs effets néfastes sur la productivité, le développement d'une nouvelle méthode d’assemblage TCB à basse température devient primordiale. Le développement d’une nouvelle méthode de liaison par thermocompression à l'état solide détecteur de température résistif, Resistance Temperature Detector en anglais était donc notre second objectif dans cette étude. Cette méthode est basée sur la création d'une liaison mécanique temporaire initiale au début du processus de packaging (en utilisant une pression à une température inférieure au point de fusion de la brasure). Les joints de iv brasure seront entièrement refondus à la fin du processus de packaging, lorsque les billes de brasure BGA (ball-grid-array) seront brasées au substrat. Cette nouvelle méthode peut surmonter les limitations associées au processus TCB conventionnel, notamment la température élevée, le processus d'assemblage lent et les contraintes mécaniques élevées. Une investigation a été menée pour déterminer les conditions d'assemblage appropriées à appliquer pendant ce processus. Des investigations supplémentaires ont été également menées pour explorer le mécanisme d'assemblage responsable de l’assemblage mécanique temporaire. Les résultats préliminaires de cette méthode sont prometteurs, montrant des joints de brasure de bonne qualité formés en un temps d'assemblage très court (6 secondes) et à des températures bien inférieures au TCB conventionnel (200°C)

JTEC panel on display technologies in Japan

This report is one in a series of reports that describes research and development efforts in Japan in the area of display technologies. The following are included in this report: flat panel displays (technical findings, liquid crystal display development and production, large flat panel displays (FPD's), electroluminescent displays and plasma panels, infrastructure in Japan's FPD industry, market and projected sales, and new a-Si active matrix liquid crystal display (AMLCD) factory); materials for flat panel displays (liquid crystal materials, and light-emissive display materials); manufacturing and infrastructure of active matrix liquid crystal displays (manufacturing logistics and equipment); passive matrix liquid crystal displays (LCD basics, twisted nematics LCD's, supertwisted nematic LCD's, ferroelectric LCD's, and a comparison of passive matrix LCD technology); active matrix technology (basic active matrix technology, investment environment, amorphous silicon, polysilicon, and commercial products and prototypes); and projection displays (comparison of Japanese and U.S. display research, and technical evaluation of work)

Proceedings of the 2018 Canadian Society for Mechanical Engineering (CSME) International Congress

Published proceedings of the 2018 Canadian Society for Mechanical Engineering (CSME) International Congress, hosted by York University, 27-30 May 2018

Proceedings /5th International Symposium on Industrial Engineering – SIE2012, June 14-15, 2012., Belgrade

editors Dragan D. Milanović, Vesna Spasojević-Brkić, Mirjana Misit

Proceedings /5th International Symposium on Industrial Engineering – SIE2012, June 14-15, 2012., Belgrade

editors Dragan D. Milanović, Vesna Spasojević-Brkić, Mirjana Misit