Moore A L, Shi L. Emerging challenges and materials for thermal management of electronics[J]. Materials Today, 2014, 17(4):163-174.
|
Razeeb K M, Dalton E, Cross G L W, et al. Present and future thermal interface materials for electronic devices[J]. International Materials Reviews, 2018, 63(1):1-21.
|
Cui T, Li Q, Xuan Y, et al. Multiscale simulation of thermal contact resistance in electronic packaging[J]. International Journal of Thermal Sciences, 2014, 83(Supplement C):16-24.
|
Hansson J, Nilsson T M J, Ye L, et al. Novel nanostructured thermal interface materials:A review[J]. International Materials Reviews, 2018, 63(1):22-45.
|
Wang Y, Cao Y, Zhou K, et al. Assessment of self-assembled monolayers as high-performance thermal interface materials[J]. Advanced Materials Interfaces, 2017, 4(15):1700355.
|
Huang Y, Hu J, Yao Y, et al. Manipulating orientation of silicon carbide nanowire in polymer composites to achieve high thermal conductivity[J]. Advanced Materials Interfaces, 2017, 4(17):1700446.
|
Zhang P, Zeng J, Zhai S, et al. Thermal properties of graphene filled polymer composite thermal interface materials[J]. Macromolecular Materials and Engineering, 2017, 302(9):1700068.
|
Cai D, Neyer A. Large scale silicone-rubber-based optical interconnect packaged with FR4[J]. Journal of Microelectromechanical Systems, 2010, 19(6):1362-1369.
|
Bhanushali S, Ghosh P C, Simon G P, et al. Copper nanowire-filled soft elastomer composites for applications as thermal interface materials[J]. Advanced Materials Interfaces, 2017, 4(17):1700387.
|
Chen H, Wei H, Chen M, et al. Enhancing the effectiveness of silicone thermal grease by the addition of functionalized carbon nanotubes[J]. Applied Surface Science, 2013, 283:525-531.
|
Raza M A, Westwood A, Brown A, et al. Characterisation of graphite nanoplatelets and the physical properties of graphite nanoplatelet/silicone composites for thermal interface applications[J]. Carbon, 2011, 49(13):4269-4279.
|
Zhang Q, Feng J. Difunctional olefin block copolymer/paraffin form-stable phase change materials with simultaneous shape memory property[J]. Solar Energy Materials and Solar Cells, 2013, 117:259-266.
|
Ma S, Song G, Li W, et al. UV irradiation-initiated MMA polymerization to prepare microcapsules containing phase change paraffin[J]. Solar Energy Materials and Solar Cells, 2010, 94(10):1643-1647.
|
Yang W, Zhang L, Guo Y, et al. Novel segregated-structure phase change materials composed of paraffin@graphene microencapsules with high latent heat and thermal conductivity[J]. Journal of Materials Science, 2018, 53(4):2566-2575.
|
Huang Y R, Chuang P H, Chen C L. Molecular-dynamics calculation of the thermal conduction in phase change materials of graphene paraffin nanocomposites[J]. International Journal of Heat and Mass Transfer, 2015, 91:45-51.
|
Yuan K, Wang H, Liu J, et al. Novel slurry containing graphene oxide-grafted microencapsulated phase change material with enhanced thermo-physical properties and photo-thermal performance[J]. Solar Energy Materials and Solar Cells, 2015, 143:29-37.
|
Mehrali M, Latibari S T, Mehrali M, et al. Shape-stabilized phase change materials with high thermal conductivity based on paraffin/graphene oxide composite[J]. Energy Conversion and Management, 2013, 67(Supplement C):275-282.
|
Li Y F, Liu Y Z, Chen S, et al. Self-templating synthesis nitrogen and sulfur co-doped hierarchical porous carbons derived from crab shells as a high-performance metal-free oxygen electroreduction catalys[J]. Materials Today Energy, 2018, 10:388-395.
|
Lai L, Chen L, Zhan D, et al. One-step synthesis of NH2-graphene from in situ graphene-oxide reduction and its improved electrochemical properties[J]. Carbon, 2011, 49(10):3250-3257.
|
Liu C, Chen M, Zhou D, et al. Effect of filler shape on the thermal conductivity of thermal functional composites[J]. Journal of Nanomaterials, 2017, 2017:1-15.
|