Melt Processable Novolac Cyanate Ester/Biphenyl Epoxy Copolymer Series with Ultrahigh Glass-Transition Temperature

Li, Jiaxiong; Ren, Chao; Sun, Zhijian; Ren, Yanjuan; Lee, Haksun; Moon, Kyoung‐Sik; Wong, Ching‐Ping

doi:10.1021/acsami.0c20537

Cited by 34 publications

(14 citation statements)

References 61 publications

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“…The high T g (above 200 °C) signifies that the polymer network of oxidized MC EDB is in glassy state and the chain segmental motion is not active at 200 °C, which imposes dynamic constraints on the diffusion of oxygen, the propagation of free radicals, and the volatilization of chain scission products. [ 9 ] As for the oxidized MC EDB (5/1.5/11) sample, the external oxygen can easily invade the polymer network from the defects, thus leading to an aggravated thermal‐oxidative degradation.…”

Section: Resultsmentioning

confidence: 99%

Development of Molding Compounds Based on Epoxy Resin/Aromatic Amine/Benzoxazine for High‐Temperature Electronic Packaging Applications

Gou

Bao

Huang

et al. 2022

Macro Materials & Eng

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Heat-resistant molding of compounds is an indispensable part in encapsulating future electronic power devices. Herein, it is used for polyfunctional epoxy resin (EP) and diamine-phenol benzoxazine (BOZ) as resin matrix, 4,4'-diaminodiphenylmethane (DDM) as curing agent, and iron acetylacetonate (Fe(acac) 3 ) as curing accelerator, as well as inorganic fillers and other auxiliaries, to prepare heat-resistant molding compounds. The curing behavior, processability and thermal performance of the EP/DDM/BOZ (EDB) resin blends containing different contents of DDM, BOZ, and Fe(acac) 3 are first systematically investigated. The EDB molding compounds (MC EDB ) with suitable BOZ content show good processability, and the molding process can be compatible with that of commercial epoxy molding compounds (EMC). With increasing the BOZ content, the glass transition temperature of cured MC EDB is greatly enhanced to a maximum of 261 °C determined by dynamic mechanical analyzer, owing to the hydrogen-bond interaction generated after polymerization of BOZ increasing the rigidity of network chains. Moreover, the cured MC EDB also exhibits higher thermal decomposition stability, better high-temperature (200 °C) mechanical properties, and lower water absorption compared to the cured EMC. After high-temperature (200 °C) aging for 500 h, the cured MC EDB with suitable BOZ content still maintains outstanding performance. This study provides a promising strategy for preparing heat-resistant electronic packaging molding compounds.

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Section: Resultsmentioning

confidence: 99%

Development of Molding Compounds Based on Epoxy Resin/Aromatic Amine/Benzoxazine for High‐Temperature Electronic Packaging Applications

Gou

Bao

Huang

et al. 2022

Macro Materials & Eng

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“…A more fundamental estimation of cross-link density was calculated by the following equation in the epoxy's rubbery region: 49,50 where X is the estimated cross-link density, R is the ideal gas constant ( R = 8.314 J (mol K) −1 , E ′ is the storage modulus at T ′, and T ′ is 30 °C higher than T g . With the ratio of bisA to cresol novolac epoxy decreasing, the calculated cross-link density is increased.…”

Section: Resultsmentioning

confidence: 99%

Melamine–graphene epoxy nanocomposite based die attach films for advanced 3D semiconductor packaging applications

et al. 2022

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“…Over these years, a lot of works has been done to modify epoxy by inorganic fillers. Yue et al 11 found the T g of epoxy increased from 257 to 275°C with a BN content of 30 wt% 10 . Chen et al 12 reported that the T g of epoxy increased from 103.5 to 132.1°C containing 20 wt% micro‐AlN particles and 3 wt% nano‐AlN particles.…”

Section: Introductionmentioning

confidence: 99%

“…Yue et al 11 found the T g of epoxy increased from 257 to 275 C with a BN content of 30 wt%. 10 Chen et al 12 reported that the T g of epoxy increased from 103.5 to 132.1 C containing 20 wt% micro-AlN particles and 3 wt% nano-AlN particles. Guo et al discovered that ZnO could increased T g of epoxy from 191.7 to 201.96 C when the filling rate is 50 wt%.…”

Section: Introductionmentioning

confidence: 99%

High heat‐resistant (250°C) epoxy resin composites with excellent dielectric properties

Wang

Feng

Zhang

et al. 2022

J of Applied Polymer Sci

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Insulated gate bipolar transistor (IGBT) is the core of electric energy conversion and circuit control, which is widely used in the field of electric vehicles. Higher service temperature, higher power density, and higher operating voltage are the tendency for IGBT in which packing materials have to possess more stable temperature resistance and better insulating properties. In this work, cyanate ester (CE) and polyhedral oligomeric silsesquioxanes (POSS) are introduced into epoxy with various filling ratio to improve the dielectric and thermal properties. The curing process of every system is determined by non‐isothermal differential scanning calorimetry (DSC). N and Si element distribution mappings indicate that there are good compatibility between POSS, CE, and epoxy. The dielectric test shows that the dielectric constant decreases from 4.34 to 2.84 at 1 MHz and from 4.76 to 2.93 at 1 kHz when the filling ratio is 60 wt%. Meanwhile, the DC breakdown strength increases from 172.7 to 286.4 kV/mm. Furthermore, the glass transition temperature (Tg) increases from 180 to 263°C and the yield of residual carbon increases from 6.2% to 23.7%. A new packing material, which can endure 250°C of operating temperature and has excellent dielectric properties has been synthesized.

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Melt Processable Novolac Cyanate Ester/Biphenyl Epoxy Copolymer Series with Ultrahigh Glass-Transition Temperature

Cited by 34 publications

References 61 publications

Development of Molding Compounds Based on Epoxy Resin/Aromatic Amine/Benzoxazine for High‐Temperature Electronic Packaging Applications

Development of Molding Compounds Based on Epoxy Resin/Aromatic Amine/Benzoxazine for High‐Temperature Electronic Packaging Applications

Melamine–graphene epoxy nanocomposite based die attach films for advanced 3D semiconductor packaging applications

High heat‐resistant (250°C) epoxy resin composites with excellent dielectric properties

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