Transferred-substrate heterojunction bipolar transistor integrated circuit technology

Conference Proceedings. Eleventh International Conference on Indium Phosphide and Related Materials (IPRM'99) (Cat. No.99CH36362) Pub Date : 1999-05-16 DOI:10.1109/ICIPRM.1999.773661

M. Rodwell, Q. Lee, D. Mensa, J. Guthrie, Y. Betser, S. Martin, R.P. Smith, S. Jaganathan, T. Mathew, P. Krishnan, C. Serhan, S. Long

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引用次数: 15

Abstract

Using substrate transfer processes, we have fabricated heterojunction bipolar transistors with 0.4 /spl mu/m emitter-base and collector-base junctions, minimizing RC parasitics and increasing f/sub max/ to 820 GHz, the highest yet reported for a transistor. The process provides microstrip interconnects on a low-/spl epsiv//sub /spl tau// polymer dielectric with a electroplated copper ground plane and substrate. Substrate thermal resistance is reduced 5:1 over InP. Important wiring parasitics, including wiring capacitance, ground via inductance, and IC-package ground-return inductance, are substantially reduced. Demonstrated ICs include lumped and distributed amplifiers with bandwidths to 85 GHz, master-slave flip-flops operable at over 48 GHz, and 50 GHz AGC/limiting amplifiers. Current efforts include further improvement in bandwidth, development of power devices, and demonstration of more complex mixed-signal ICs.

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转移衬底异质结双极晶体管集成电路技术

利用衬底转移工艺，我们制造了具有0.4 /spl mu/m发射基和集电极基结的异质结双极晶体管，最大限度地减少了RC寄生，并将f/sub max/提高到820 GHz，这是迄今为止报道的最高晶体管。该工艺在低/spl epsiv//sub /spl tau//聚合物介质上提供微带互连，并具有电镀铜地平面和衬底。衬底热阻在InP上降低了5:1。重要的布线寄生，包括布线电容、经地电感和ic封装接地返回电感，大大降低。演示的ic包括带宽达85 GHz的集总和分布式放大器，可在48 GHz以上工作的主从触发器，以及50 GHz AGC/限制放大器。目前的工作包括进一步改进带宽，开发功率器件，以及演示更复杂的混合信号集成电路。

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Conference Proceedings. Eleventh International Conference on Indium Phosphide and Related Materials (IPRM'99) (Cat. No.99CH36362)

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