Electrical Transport and Power Dissipation in Aerosol-Jet-Printed Graphene Interconnects

This paper reports the first known investigation of power dissipation and electrical breakdown in aerosol-jet-printed (AJP) graphene interconnects. The electrical performance of aerosol-jet printed (AJP) graphene was characterized using the Transmission Line Method (TLM). The electrical resistance decreased with increasing printing pass number (n); the lowest sheet resistance measured was 1.5 k Omega/sq. for n = 50. The role of thermal resistance (R-TH) in power dissipation was studied using a combination of electrical breakdown thermometry and infrared (IR) imaging. A simple lumped thermal model (T = P x R-TH) and COMSOL Multiphysics was used to extract the total R-TH, including interfaces. The R-TH of AJP graphene on Kapton is similar to 27 times greater than that of AJP graphene on Al2O3 with a corresponding breakdown current density 10 times less on Kapton versus Al2O3.