TY - GEN
T1 - Nano-micro particle filled thermal interface materials
T2 - 2012 IEEE 62nd Electronic Components and Technology Conference, ECTC 2012
AU - Das, Rabindra N.
AU - Chenelly, Evan
AU - Kopp, Erich
AU - Alcoe, Dave
AU - Poliks, Mark D.
AU - Markovich, Voya R.
PY - 2012
Y1 - 2012
N2 - Thermal interface materials (TIM) used to improve the conductivity between mating components in an electronic assembly are discussed. A variety of materials including adhesives, gels, greases, fluids were used in this study. Both greases and pastes are considered, to improve the contact resistance of stress decoupling and stress coupling interfaces, respectively. Nanoparticles, micro particles, low melting point (LMP) fillers, and mixtures of nano-micro particles were combined to obtain both decreased interparticle thermal resistance and decreased bulk thermal resistance in thermal pastes. An evaluation of thermal grease filler materials was also conducted. A steady-state conductivity test was employed to measure conductivity. Adhesive materials were tested at various fixed bondline thicknesses and had thermal impedances ranging from 170 to 53 mm 2 K/W. The performance of greases varied from 70 to 11 mm 2 K/W at low bondline with a varied load. For thermal pastes, cross section measurements were used to measure particle dispersion throughout the interface. The paper also presents a nanoparticle dispersion approach to prepare temperature and time stable nanogels. Several nanogels were evaluated after three years post-preparation, using transmission electron microscopy (TEM), to check particle distribution in the nanogel.
AB - Thermal interface materials (TIM) used to improve the conductivity between mating components in an electronic assembly are discussed. A variety of materials including adhesives, gels, greases, fluids were used in this study. Both greases and pastes are considered, to improve the contact resistance of stress decoupling and stress coupling interfaces, respectively. Nanoparticles, micro particles, low melting point (LMP) fillers, and mixtures of nano-micro particles were combined to obtain both decreased interparticle thermal resistance and decreased bulk thermal resistance in thermal pastes. An evaluation of thermal grease filler materials was also conducted. A steady-state conductivity test was employed to measure conductivity. Adhesive materials were tested at various fixed bondline thicknesses and had thermal impedances ranging from 170 to 53 mm 2 K/W. The performance of greases varied from 70 to 11 mm 2 K/W at low bondline with a varied load. For thermal pastes, cross section measurements were used to measure particle dispersion throughout the interface. The paper also presents a nanoparticle dispersion approach to prepare temperature and time stable nanogels. Several nanogels were evaluated after three years post-preparation, using transmission electron microscopy (TEM), to check particle distribution in the nanogel.
UR - https://www.scopus.com/pages/publications/84866879512
U2 - 10.1109/ECTC.2012.6249026
DO - 10.1109/ECTC.2012.6249026
M3 - Conference contribution
SN - 9781467319669
T3 - Proceedings - Electronic Components and Technology Conference
SP - 1442
EP - 1447
BT - 2012 IEEE 62nd Electronic Components and Technology Conference, ECTC 2012
Y2 - 29 May 2012 through 1 June 2012
ER -