The effects of alumina nanoparticle on the properties of an epoxy resin system

Omrani, Abdollah; Simon, Leonardo C.; Rostami, Abbas Ali

doi:10.1016/j.matchemphys.2008.08.090

Cited by 138 publications

(92 citation statements)

References 21 publications

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“…It is well known that the most important factors that influence their performance are the molecular architecture, the ratio between the epoxide and the hardener, and the cure conditions, frequently at a high temperature, which determine the final properties of the material. The influence of the filler particles on the curing is still a subject of study and clearly depends on the nature of the particles [1][2][3][4][5]. Epoxy matrix composites find new applications every day in several areas of engineering and technology.…”

mentioning

confidence: 99%

A micro-Raman study of Cu-particulate-filled epoxy matrix composites

Tognana¹,

Salgueiro²,

Valcarce³

2014

Express Polym. Lett.

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Epoxy resins are used in structural applications ranging from high-performance composites for aerospace applications to encapsulants for the microelectronics industry because of their high thermal resistance, high tensile strength and modulus, and good chemical resistance. It is well known that the most important factors that influence their performance are the molecular architecture, the ratio between the epoxide and the hardener, and the cure conditions, frequently at a high temperature, which determine the final properties of the material. The influence of the filler particles on the curing is still a subject of study and clearly depends on the nature of the particles [1][2][3][4][5]. Epoxy matrix composites find new applications every day in several areas of engineering and technology. For example, copper-filled composites have a high possibility of being used in microelectronics because the high thermal conductivity of copper allows the composite to be a good heat dissipator, which serves as protection to electronic devices [6,7]. The matrix-particle interphases also play an important role. The physical properties of the polymeric composites can be significantly influenced by their thermal history; in fact, internal stresses are developed during the fabrication process and further thermal treatments. Abstract. A micro-Raman study is carried out to investigate the influence of the filler on the curing process of bisphenol A diglycidyl ether (DGEBA)-based epoxy matrix composites. The composites are cured (14 h at 393 K) with an anhydride (methyl tetrahydro phthalic anhydride, MTHPA, 100:90 pbw), catalyzed with a tertiary amine (0.7 pbw) and filled with a 30% volume of Cu particles of approximately 75 !m in diameter. The experimental results are compared with those obtained for the same epoxy resin unfilled and for the same composite with Cu filler but not catalyzed. The micro-Raman experimental technique is used to search for information on the curing process in different regions of the matrix, near to and far from the copper filler, taking into account the results of differential-scanning-calorimetry measurements performed on the same composites. The results provide information on the influence of the copper filler on the curing process of the epoxy matrix. Differences were observed in the peaks associated with the epoxy ring and the ester group as a function of the distance to the nearest copper particle, but no differences were observed between the different composites.

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mentioning

confidence: 99%

A micro-Raman study of Cu-particulate-filled epoxy matrix composites

Tognana¹,

Salgueiro²,

Valcarce³

2014

Express Polym. Lett.

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“…Some authors [39,40] have commented alteration on curing evolution of thermosetting composites systems, even when natural fibers are used as reinforcement. Musaceae fiber bundles could introduces the variations on the interfacial interactions respect to the matrix and introduce a catalytic effect on curing process and polymer chain network formation [41,42] . This phenomenon could introduce topological restrictions that reduce the impact of the evolution of the global convertion of the double bonds still present on composite samples after tribological test.…”

Section: Resultsmentioning

confidence: 99%

Influence of tribological test on the global conversion of natural composites

et al. 2017

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“…그렇지만, 나노 콤포지트의 특성은 필러와 매트릭스 사이 계면의 상호작용만큼 나노필러의 형상과 종류에 의존한다 [10]. 요구된 응용을 위한 에폭시수지를 보강하는 일반 적인 방법은 나노클레이, 나노알루미나 그리고 나노실 리카와 같은 유기와 무기필러 그리고 마이크로와 나노 의 조합이다 [11][12][13] …”

Section: 에폭시 나노콤포지트는 전기적 열적 그리고 기계적 스트레스를 억제할 수 있기 때문에 다방면의 절연재료unclassified

Mechanical Properties of Epoxy Alumina Multi-Composites

Park¹

2016

Journal of the Korean Institute of Electrical and Electronic Ma

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Abstract:In order to develop an electrical insulation material for gas GIS (insulation switch gear) spacer, 4 types of epoxy/micro-alumina (40, 50, 60, 70 wt%) composites and 9 types of epoxy/nano-alumina (1, 3, 5 g)/micro-alumina (40, 50, 60, 70 wt%) composites were prepared and tensile test was carried out. In here, nano-alumina was previously surface-treated with GDE (glycerol diglycidyl ether). As micro-alumina and GDE-treated nano-alumina contents increased, tensile strength increased and the highest value was shown in the system with 3 g GDE-treated nano-alumina.

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The effects of alumina nanoparticle on the properties of an epoxy resin system

Cited by 138 publications

References 21 publications

A micro-Raman study of Cu-particulate-filled epoxy matrix composites

A micro-Raman study of Cu-particulate-filled epoxy matrix composites

Influence of tribological test on the global conversion of natural composites

Mechanical Properties of Epoxy Alumina Multi-Composites

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