High temperature potential of flip chip assemblies for automotive applications

Braun, T.; Becker, K.-F.; Sommer, J.-P.; Löher, Thomas; Schottenloher, K.; Kohl, Robert; Pufall, Reinhard; Bader, V.; Koch, Matthias; Aschenbrenner, R.; Reichl, H.

doi:10.1109/ectc.2005.1441293

Cited by 15 publications

(6 citation statements)

References 13 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Typical CTEs below glass transition temperature range from 8 to 14 10 K, Young's moduli range from 4 to 8 GPa. values are higher than 160 C. Regarding the long term behavior of these materials, investigations performed at IZM also prove the high thermal stability and media resistance of duromer materials [3], allowing them to be used as a base material also for demanding automotive applications. Fig.…”

Section: A Base Materialsmentioning

confidence: 99%

Duromer MID technology for system-in-package generation

Becker

Braun

Neumann

et al. 2005

IEEE Trans. Electron. Packag. Manufact.

Self Cite

View full text Add to dashboard Cite

The Duromer MID technology for realization of stackable SIPs is similar to conventional Molded Interconnect Device (MID) technology, which is usually realized using thermoplastic polymers, combining the functionality of housing and substrate into one device. Advantages of the conventional MID technology are the reduction of parts during assembly by integrating mechanical and electrical functionality into a device and the reduction of space, as MID allows a 3D integration of devices. Disadvantage of conventional technology, especially if combined with typical technical thermoplastics is the large mismatch in coefficient of thermal expansion (CTE) between substrate and advanced microelectronic components as CSP or flip chip. This is reducing the applicability of thermoplastic MID to moderate temperature ranges and/or to rather robust components. To overcome this disadvantage the use of low CTE duromer as Epoxy Molding Compounds (EMC) as base material for device assembly is proposed, generating a unique technology well adapted to SIP and MEMS packaging needs, the Duromer MID approach. The technological realization of Duromer MID uses conventional backend processes as IC bonding to flex, transfer molding using epoxy molding compounds, laser machining, metallization and structurization processes well known from PCB processing. The use of existing equipment allows both, a rather fast process implementation and a cost effective manufacturing of the components. Within this paper the investigations described previously [1] are driven further towards a description of a generic packaging technology integrating detailed analysis of metallization processes and assembly issues. Summarized this paper presents further process development and feasibility analysis of wafer level packaging technologies for SiP solutions based on a Duromer MID approach

show abstract

Section: A Base Materialsmentioning

confidence: 99%

Duromer MID technology for system-in-package generation

Becker

Braun

Neumann

et al. 2005

IEEE Trans. Electron. Packag. Manufact.

Self Cite

View full text Add to dashboard Cite

show abstract

“…The reason for this behavior is the nonlinear dependence of penetration time on concentration of zeolite. Additionally, the thermomechanical and adhesion properties of the encapsulant in the vicinity of the chip play an important role for the reliability [1][2][3]. For this reason, single-and multilayer encapsulation experiments have been designed, in which two types of fillers are distributed differently.…”

Section: Multi-layer Systemsmentioning

confidence: 99%

“…On the one hand, typically true for encapsulants, mechanical stresses are imposed on interconnects and on the other hand humidity can easily access the interface and can cause corrosion. Both effects have a negative influence on the reliability of the assembly [1,2]. Water in polymers can also lead to a softening and/or to a swelling of the material resulting in degraded thermo-mechanical properties and higher stresses in a package [3].…”

Section: Introductionmentioning

confidence: 99%

Enhancement of barrier properties of encapsulants for harsh environment applications

Braun

Bauer

Georgi

et al. 2012

2012 IEEE 62nd Electronic Components and Technology Conference

Self Cite

View full text Add to dashboard Cite

Medical devices with embedded highly miniaturized microsystems are used as implants in the human body or as non-invasive devices for sensor applications outside the body. Those devices bear quite a lot of economic opportunities but they also do offer unique challenges compared to consumer or automotive applications. Medical applications need to provide biocompatibility, highest miniaturization, rough treatment, autoclave sterilization and harsh environment e. g. humidity, wax, dust, blood or urine to be applicable. And microelectronics packaging needs to protect the functional elements of the microsystem against these rigid conditions. And, with a different set of media, packaging needs to fulfill the same task for automotive applications, where a growing number of control units and sensor systems under the hood in the transmission oil or petrol can be found. For both markets low cost packaging concepts with high media resistivity is needed. Polymer materials - mainly epoxy resins - are widely used in microelectronics packaging. They are established in microsystem manufacturing, for adhesives as die attach glues or for encapsulants as molding compounds, glob tops or underfill materials. Low cost and mass production capabilities are the main advantages of these materials. But like all polymers they cannot provide a hermetical sealing due to their permeability properties. The susceptibility to diffusion of liquids and gases through the polymer and along the interfaces is a drawback for polymer materials in general, as water or other media inside a microelectronic package might lead to softening of the material and to a decreasing adhesive strength and resulting delaminations close to solder bumps or wire bonds reducing package reliability by decreasing the package structural integrity. Therefore, plastic packaging materials with enhanced humidity resistance allowing the manufacturing of miniaturized microsystems for demanding applications as e. g. medical devices would increase package reliability during assembly and lifetime ideally without cost increase and with no changes in processing. As filler particles have an important influence on the final material properties of microelectronic encapsulants, they are well suited for material modifications. Typically micro-sized silica particles are incorporated into the polymer matrix as the thermo-mechanical properties could be well adapted to reliable packaging demands. However, there are a lot of nano- and micro-sized filler particles with potential to enhance the humidity barrier properties of encapsulants. Working principles of these particles may range from large surface impact of nano-particles, barrier functionality due to stacked layer formation (nano-clays), highly hydrophobic particle surface and molecular water catcher function. Micro-and nano-sized SiO2, bentonite, zeolites, Al2O3, carbon black and carbon nano tubes have been selected for a systematic study. To evaluate the potential of such additives concerning moisture resistance particles are mixed with a ...

show abstract

“…However, none have been proposed for 175°C. [66] A new polymer-based film, PIBO, has been proposed to address these issues. PIBO is a high temperature stable polyimide film with resistance to plasma degradation.…”

Section: Pc Boardsmentioning

confidence: 99%

Power Modulation Investigation for High Temperature (175-200 degrees Celcius) Automotive Application

McCluskey¹

2007

View full text Add to dashboard Cite

High temperature potential of flip chip assemblies for automotive applications

Cited by 15 publications

References 13 publications

Duromer MID technology for system-in-package generation

Duromer MID technology for system-in-package generation

Enhancement of barrier properties of encapsulants for harsh environment applications

Power Modulation Investigation for High Temperature (175-200 degrees Celcius) Automotive Application

Contact Info

Product

Resources

About