Highly Thermally Conductive and Light Weight Copper/Graphene Film Laminated composites for Cooling Applications
Paper i proceeding, 2018

A light-weight, robust and highly thermal conductive copper/graphene film laminated structure was developed as novel heat spreading materials for thermal management applications. The advantages of the copper/graphene film laminated structure lie in its ability to combine both good mechanical properties of metals and excellent thermal properties of graphene film. Graphene films (GFs) were fabricated via self-assembly of graphene oxide (GO) sheets and post-treated by high temperature graphitization and mechanical pressing. The resulted GFs show excellent flexibility and greatly improved tensile strength which is over 3 times higher than commercial PGS. The successful lamination between copper and GFs was realized by indium bonding. Thin indium layers can provide complete physical contact between copper and GFs, and thereby, minimize the contact resistance induced by surface roughness. The measured contact thermal resistance between copper and GFs bonded by indium is in the range of 2-5 Kmm(2)/W for a working temperature between 20 degrees C to 100 degrees C. This value is orders magnitude lower than other bonding methods, including direct hot pressing of copper and GFs, tape bonding and thermal conductive adhesive (TCA) bonding. By tailoring the thickness of GFs, desirable laminated composites with optimized thermal conductivity can be obtained, which offers an efficient heat dissipation solution for power driven systems.

Graphene film

Light-weight

Thermal resistance

Lamination

Författare

Nan Wang

SHT Smart High-Tech

Shujing Chen

Shanghai University

Amos Nkansah

SHT Smart High-Tech

Christian Chandra Darmawan

SHT Smart High-Tech

Lilei Ye

SHT Smart High-Tech

Johan Liu

Chalmers, Mikroteknologi och nanovetenskap (MC2), Elektronikmaterial och system

Shanghai University

2018 19TH INTERNATIONAL CONFERENCE ON ELECTRONIC PACKAGING TECHNOLOGY (ICEPT)

1588-1592

19th International Conference on Electronic Packaging Technology (ICEPT)
Shanghai, China,

Kolbaserat höghastighet 3D GaN elektroniksystem

Stiftelsen för Strategisk forskning (SSF), 2014-03-01 -- 2019-06-30.

Ämneskategorier

Bearbetnings-, yt- och fogningsteknik

Materialkemi

Annan materialteknik

DOI

10.1109/ICEPT.2018.8480614

ISBN

9781538663868

Mer information

Senast uppdaterat

2019-03-18