A low-complexity 62-GHz f(T) SiGe heterojunction bipolar transistor process using differential epitaxy and in situ phosphorus-doped poly-Si emitter at very low thermal budget

Grahn JV; Fosshaug H; Jargelius M; Jonsson P; Linder M; Malm BG; Mohadjeri B; Pejnefors J; Radamson HH; Sanden M; Wang YB; Landgren G; Ostling M

Solid-State Electronics, Vol.44, No.3, 549-554, 2000

DOI10.1016/S0038-1101(99)00266-X Export Citation

A low-complexity 62-GHz f(T) SiGe heterojunction bipolar transistor process using differential epitaxy and in situ phosphorus-doped poly-Si emitter at very low thermal budget

Grahn JV, Fosshaug H, Jargelius M, Jonsson P, Linder M, Malm BG, Mohadjeri B, Pejnefors J, Radamson HH, Sanden M, Wang YB, Landgren G, Ostling M

A low-complexity SiGe heterojunction bipolar transistor process based on differential epitaxy and in situ phosphorus doped polysilicon emitter technology is described. Silane-based chemical vapor deposition at reduced pressure was used for low-temperature SiGe epitaxy. Following SiGe epitaxy, the process temperature budget was kept very low with 900 degrees C for 10 s as the highest temperature step. A very high current gain of almost 2000 and cut off frequency of 62 GHz were achieved for a uniform 12% Ge profile. The breakdown voltage BVCEO and forward Early voltage were equal to 2.9 and 6.5 V, respectively.