复合材料
材料科学
热膨胀
环氧树脂
电介质
热导率
复合数
填料(材料)
热传导
各向同性
陶瓷
负热膨胀
介电损耗
热的
电子包装
介电常数
电导率
均质化(气候)
复合环氧材料
聚四氟乙烯
纳米复合材料
导电体
作者
Xin Jin,Feiyu Qin,Hao Liu,Xin Yang,Yi Qin,Jun Sun,Xiangdong Ding,Lei Hu
摘要
ABSTRACT Low thermal expansion and high thermal conductivity are essential for advanced integrated circuit packaging materials. In this study, an isotropic negative thermal expansion fluoride, Ca 0.85 Sr 0.15 SnF 6 (CSSF), exhibiting a linear coefficient of thermal expansion, α l of −7.3 × 10 −6 /°C, is synthesized via a hydrothermal method. TEM results capture the diverse lattice distortion in CSSF, including attractive Moiré fringe, dislocations, and obvious lattice strain. Subsequently, CSSF is introduced into epoxy resin (EP) to design the unconventional CSSF/EP composites. Compared with the pure epoxy, the composite with 60 wt.% CSSF filler exhibits a significant reduction in α l , from 69.5 × 10 −6 /°C (glassy region) and 172.0 × 10 −6 /°C (rubbery region), down to 35.8 × 10 −6 /°C and 87.4 × 10 −6 /°C, respectively. Meanwhile, the thermal conductivity increases from 0.19 to 0.48 W·m −1 ·°C −1 . Moreover, a higher Shore hardness (93.3 HD) is achieved for the CSSF60/Epoxy composite. Furthermore, the composite demonstrates desirable dielectric properties, with a dielectric constant of 9.48 and a dielectric loss of 0.166 at 1 MHz. In particular, fracture surface analysis reveals that CSSF filler achieves strong interfacial adhesion with the epoxy matrix without surface treatment, which can be attributed to its isotropic nature. This unconventional strategy of incorporating NTE fluorides into EP presents a viable approach for advanced electronic packaging applications.
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