Compressive mechanical response of graphene foams and their thermal resistance with copper interfaces

Abstract

We report compressive mechanical response of graphene foams (GFs) and the thermal resistance (RTIM) between copper (Cu) and GFs, where GFs were prepared by the chemical vapor deposition (CVD) method. We observe that Young's modulus (EGF) and compressive strength (σGF) of GFs have a power law dependence on increasing density (GF) of GFs. The maximum efficiency of absorbed energy (ηmax) for all GFs during the compression is larger than ~0.39. We also find that a GF with a higher GF shows a larger ηmax. In addition, we observe that the measured RTIM of Cu/GFs at room temperature with a contact pressure of 0.25 MP applied increases from ~50 to ~90 mm2K/W when GF increases from 4.7 to 31.9 mg/cm3.