Aluminum-Graded-Base PNp AlGaAs/GaAs Heterojunction Transistor with 37 GHz Cut-Off Frequency

Atsushi KAMEYAMA  Alan MASSENGALE  Changhong DAI  James S. HARRIS, Jr.  

IEICE TRANSACTIONS on Electronics   Vol.E79-C   No.4   pp.518-523
Publication Date: 1996/04/25
Online ISSN: 
Print ISSN: 0916-8516
Type of Manuscript: Special Section PAPER (Special Issue on Ultra-High-Speed LSIs)
HBT,  Pnp,  AlGaAs/GaAs,  complementary circuit,  graded base,  

Full Text: PDF>>
Buy this Article

The base transit time of an Aluminum-graded-base PNp AlGaAs/GaAs heterojunction bipolar transistor (HBT) was studied in order to clarify the effect of aluminum grading in the base. Theoretical analysis using a classical drift diffusion model with velocity saturation at the base-collector junction and a high base quasielectric field (58 keV/cm) created by 20%-aluminum linear grading in a 400 base, leads to a base transit time (τb) of 0.9 ps. The base transit time is reduced by four times, compared to the base transit time of 3.6 ps without aluminum grading in the base. In order to demonstrate this advantage, we fabricated aluminum-graded-base PNp AlGaAs/GaAs heterojunction transistor which employs a 20%-aluminum linear graded 400 -wide base. The device with a 2 µm 10 µm emitter showed high RF performance with a cut-off frequency (ft) of 37 GHz and a maximum oscillation frequency (fmax) of 30 GHz at a collector current density of 3.4 104 A/cm2. Further analysis using direct parameter extraction of a small signal circuit model under the collector current density of 1.1-9.9104 A/cm2 indicated the intrinsic transit time, which is the sum of the base transit time and the collector depletion layer transit time (τSC), was as low as 2.3 ps under lowinjection level. Subtracting the collector depletion-layer transit time from the intrinsic time leads to a base transit time of 1.1 ps, which is close to the theoretical base transit time and is the shortest value ever reported. The structure is very attractive for pnp-type AlGaAs HBTs combined with Npn HBTs for complementary applications.