Jiateng Huang , Feiyu Zhu , Wei Hu , Qiunan Xie , Xiaohan Li , Xiaoma Fei , Jingcheng Liu , Xiaojie Li , Wei Wei
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引用次数: 0
Abstract
Developing the packaging materials with superior high-temperature stability to meet the requirement of high-power devices is crucial. Herein, we synthesized 4-(4-aminophenoxy)phthalonitrile (APN) and blended it with polyfunctional epoxy resin (EP) to obtain the APN/EP (APNE) binary blends. Further, we employed the APNE as resin matrix to prepare a new high-temperature stable molding compound, aminophenoxyphthalonitrile epoxy molding compound (AEMC), aiming for high-power device packaging. Firstly, the curing behavior, reaction mechanism, thermal stability, and mechanical properties of the APNE system were systematically studied. Although the crosslinking density of the cured APNE decreased with increasing the APN content, the introduction of APN made the cured resins have the stable and rigid structures of isoindoline, triazine, and phthalocyanine. Thus, the cured APNE had the initial thermal decomposition temperature above 370 °C, the glass transition temperature (Tg) up to 306 °C, and the char yield at 800 °C up to 61.1 %, showing an excellent thermal performance. In addition, the flexural strength, flexural modulus, and impact strength of the cured APNE also increased with increasing the APN content. Such good properties of the APNE resin matrix endowed the AEMC with an attractive performance. The AEMC exhibited a good compatibility in molding process with the current epoxy molding compound (EMC). The Tg, thermal-aging resistance, intrinsic flame retardancy, dielectric properties, and thermal conductivity of the cured AEMC were all superior to those of the cured EMC. Therefore, the AEMC shows a good application prospect in the field of high-temperature electronic packaging.
期刊介绍:
Reactive & Functional Polymers provides a forum to disseminate original ideas, concepts and developments in the science and technology of polymers with functional groups, which impart specific chemical reactivity or physical, chemical, structural, biological, and pharmacological functionality. The scope covers organic polymers, acting for instance as reagents, catalysts, templates, ion-exchangers, selective sorbents, chelating or antimicrobial agents, drug carriers, sensors, membranes, and hydrogels. This also includes reactive cross-linkable prepolymers and high-performance thermosetting polymers, natural or degradable polymers, conducting polymers, and porous polymers.
Original research articles must contain thorough molecular and material characterization data on synthesis of the above polymers in combination with their applications. Applications include but are not limited to catalysis, water or effluent treatment, separations and recovery, electronics and information storage, energy conversion, encapsulation, or adhesion.