Mitsubishi Electric Develops World's First Multi-Cell GaN-HEMT Bonded Directly to Diamond Substrate
Mitsubishi Electric Corp. announced that in collaboration with the Research Center for Ubiquitous MEMS and Micro Engineering, National Institute of Advanced Industrial Science and Technology (AIST), it has developed a GaN-high electron mobility transistor (GaN-HEMT) in a multi-cell structure (multiple transistors cells arranged in parallel) bonded directly to a single-crystal diamond heat-dissipating substrate with high thermal conductivity. The direct bonding of a multi-cell GaN-HEMT to a single-crystal diamond substrate is believed to be the world's first. The new GaN on Diamond HEMT will improve the power-added efficiency of high-power amplifiers in mobile communication base stations and satellite communications systems, thereby helping to reduce power consumption. Mitsubishi Electric will refine the GaN on Diamond HEMT prior to its commercial launch targeted for 2025.
This research achievement was first announced at the International Conference on Solid State Devices and Materials (SSDM) being held at Nagoya University, Japan from September 2 to 5.
Mitsubishi Electric handled the design, manufacture, evaluation and analysis of the GaN on Diamond HEMT and AIST developed the direct bonding technology. A part of this achievement is based on results obtained from a project commissioned by the New Energy and Industrial Technology Development Organization (NEDO).
World's first GaN-HEMT with multi-cell structure directly bonded to diamond substrate. Most existing GaN-HEMTs that use a diamond substrate for heat dissipation are created using a GaN epitaxial layer foil from which silicon substrate has been removed and onto which diamond is deposited at high temperature. HEMTs are then fabricated on the diamond substrate of the flattened GaN wafer. However, because the thermal expansion coefficients of GaN and diamond are different, the wafer can warp greatly during the manufacturing process, making it difficult to fabricate large multi-cell GaN-HEMTs.
During this research a silicon substrate was removed from a multi-cell GaN-HEMT that was fabricated with a silicon substrate; the back surface of the GaN-HEMT was then polished to make it thinner and flatter, after which it was bonded directly onto a diamond substrate using a nano adhesion layer. A multi-cell structure was used for the parallel alignment of eight transistor cells of a type found in actual products. Finally, a multi-cell GaN on Diamond HEMT─the world's first─was fabricated using a substrate with high heat dissipation made of single-crystal diamond.
Improved output and power efficiency for expanded radio wave range and energy conservation, compared to an original GaN-HEMT with the same structure on a silicon substrate. Using a single-crystal diamond (thermal conductivity of 1900 W/mK) for superior heat dissipation suppresses temperature degradation, decreasing the temperature rise of the GaN-HEMT from 211.1°C to 35.7°C. This improves output per gate width from 2.8 to 3.1 W/mm as well as raising power efficiency from 55.6 percent to 65.2 percent, thereby realizing significant energy conservation.