Solders have given the designer of modern consumer, commercial, and military electronic systems a remarkable flexibility to interconnect electronic components. The properties of solder have facilitated broad assembly choices that have fueled creative applications to advance technology. Solder is the electrical and me chanical "glue" of electronic assemblies. This pervasive dependency on solder has stimulated new interest in applica tions as well as a more concerted effort to better understand materials properties. We need not look far to see solder being used to interconnect ever finer geo metries. Assembly of micropassive discrete devices that are hardly visible to the unaided eye, of silicon chips directly to ceramic and plastic substrates, and of very fine peripheral leaded packages constitute a few of solder's uses. There has been a marked increase in university research related to solder. New electronic packaging centers stimulate applications, and materials engineering and science departments have demonstrated a new vigor to improve both the materials and our understanding of them. Industrial research and development continues to stimulate new application, and refreshing new packaging ideas are emerging. New handbooks have been published to help both the neophyte and seasoned packaging engineer.

This book presents a systematic approach in performing reliability assessment of solder joints using Finite Element (FE) simulation. Essential requirements for FE modelling of an electronic package or a single reflowed solder joint subjected to reliability test conditions are elaborated. These cover assumptions considered for a simplified physical model, FE model geometry development, constitutive models for solder joints and aspects of FE model validation. Fundamentals of the mechanics of solder material are adequately reviewed in relation to FE formulations. Concept of damage is introduced along with deliberation of cohesive zone model and continuum damage model for simulation of solder/IMC interface and bulk solder joint failure, respectively. Applications of the deliberated methodology to selected problems in assessing reliability of solder joints are demonstrated. These industry-defined research-based problems include solder reflow cooling, temperature cycling and mechanical fatigue of a BGA package, JEDEC board-level drop test and mechanisms of solder joint fatigue. Emphasis is placed on accurate quantitative assessment of solder joint reliability through basic understanding of the mechanics of materials as interpreted from results of FE simulations. The FE simulation methodology is readily applicable to numerous other problems in mechanics of materials and structures.

The European Union’s directive banning the use of lead-based (Pb) solders in electronic consumer products has created an urgent need for research on solder joint behavior under various driving forces in electronic manufacturing, and for development of lead-free solders. This book provides a comprehensive examination of advanced materials reliability issues related to copper-tin reaction and electromigration in solder joints, and presents methods for preventing common reliablity problems.

Solder Joint Reliability Prediction for Multiple Environments will provide industry engineers, graduate students and academic researchers, and reliability experts with insights and useful tools for evaluating solder joint reliability of ceramic area array electronic packages under multiple environments. The material presented here is not limited to ceramic area array packages only, it can also be used as a methodology for relating numerical simulations and experimental data into an easy-to-use equation that captures the essential information needed to predict solder joint reliability. Such a methodology is often needed to relate complex information in a simple manner to managers and non-experts in solder joint who work with computer server applications as well as for harsh environments such as those found in the defense, space, and automotive industries.

Looks at how solder joint reliability is influenced by flux reactions, solder paste, reflow methods, wave soldering, and cleaning. Explores failure mechanisms and includes practical methods for testing, analysis, and life prediction of solder joints subjected to conditions of fatigue, creep, stress relaxation, shock, and vibration. For engineers and designers involved in electronics packaging. Annotation copyrighted by Book News, Inc., Portland, OR

The explosive growth of high-density packaging has created a tremendous impact on the electronic assembly and manufacturing industry. Ball grid array (BGA), chip-scale package (CSP), and solder-bumped flip chip technologies are taking the lead in this advanced manufacturing process. Many major equipment makers and leading electronic companies are now gearing up for these emerging and advanced packaging technologies. For these technologies, solder is the electrical and mechanical "glue," and thus solder joint reliability is one of the most critical issues in the development of these technologies. This book is a one-stop guide to the state of the art of solder joint reliability problem-solving methods, or choose a creative, high-performance, robust, and cost-effective design and high-yield manufacturing process for their interconnect systems will be able to do so with this unique sourcebook. It meets the reference needs of design, material, process, equipment, manufacturing, quality control, product assurance, reliability, component, packaging, vendor, marketing, and system engineers, and technical managers working in electronic packaging and interconnection. This book is structured to provide readers with the necessary know-how for practical, on-the-job problem-solving guidance. The book covers the solder joint reliability of BGA, CSP, flip chip, and FPT assemblies completely, proceeding from the theoretical basics to applications. Specific areas covered include: Definition of reliability, life distribution, failure rate, mean time to failure, etc.; Some well-known life distributions; Accelerated testing; Parameter estimation of life distributions; Acceleration factors for solders;Solder mechanics: plasticity, creep, and constitutive equations; Design, material, and manufacturing processes of BGA, CSP, flip chip, and FTP; Failure analysis and root cause of failure for BGA, CSP, flip chip, and FPT solder joints; Design for reliability of BGA, CSP, flip chip and FPT solder joints; Solder joint reliability of CBGA, PBGA, DBGA, and TBGA assemblies under thermal fatigue, mechanical bending and twisting, and shock and vibration conditions; solder joint reliability of flip chip (e.g., high-temperature and eutectic solder bumped flip chips on ceramic and PCB) assemblies under thermal fatigue, mechanical pulling, shearing, bending and twisting, and shock and vibration conditions; Solder joint reliability of CSP (e.g., LG Semicon's, Mitsubishi's, Motorola's, Tessera's, NEC's, nitto Denko's and Toshiba's) assemblies under thermal fatigue and mechanical bending conditions; Solder joint reliability of PQFP and TSOP assemblies under thermal fatigue, mechanical bending and twisting, and vibration conditions.

Lead-free solders are used extensively as interconnection materials in electronic assemblies and play a critical role in the global semiconductor packaging and electronics manufacturing industry. Electronic products such as smart phones, notebooks and high performance computers rely on lead-free solder joints to connect IC chip components to printed circuit boards. Lead Free Solder: Mechanics and Reliability provides in-depth design knowledge on lead-free solder elastic-plastic-creep and strain-rate dependent deformation behavior and its application in failure assessment of solder joint reliability. It includes coverage of advanced mechanics of materials theory and experiments, mechanical properties of solder and solder joint specimens, constitutive models for solder deformation behavior; numerical modeling and simulation of solder joint failure subject to thermal cycling, mechanical bending fatigue, vibration fatigue and board-level drop impact tests.