On the Performance Limits of Cryogenically Operated SiGe HBTs and Its Relation to Scaling for Terahertz Speeds

The goal of achieving terahertz (THz) transistors within the silicon material system has generated significant recent interest. In this paper, we use operating temperature as an effective way of gaining a better understanding of the performance limits of SiGe HBTs and their ultimate capabilities for...

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Bibliographic Details
Published in:IEEE transactions on electron devices 2009-05, Vol.56 (5), p.1007-1019
Main Authors: Jiahui Yuan, Cressler, J.D., Krithivasan, R., Thrivikraman, T., Khater, M.H., Ahlgren, D.C., Joseph, A.J., Jae-Sung Rieh
Format: Article
Language:English
Subjects:
Applied sciences
Cooling
Cryogenic temperature
Cryogenic temperatures
Cryogenics
device scaling
Devices
Electronics
Exact sciences and technology
Feasibility
heterojunction bipolar transistor (HBT)
Heterojunction bipolar transistors
Lithography
Microelectronic fabrication (materials and surfaces technology)
Microwave and submillimeter wave devices, electron transfer devices
Noise
noise figure
Operating temperature
Performance evaluation
Semiconductor devices
Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices
Silicon germanides
Silicon germanium
silicon-germanium (SiGe)
Temperature
terahertz (THz)
Transistors
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Summary:The goal of achieving terahertz (THz) transistors within the silicon material system has generated significant recent interest. In this paper, we use operating temperature as an effective way of gaining a better understanding of the performance limits of SiGe HBTs and their ultimate capabilities for achieving THz speeds. Different approaches for vertical profile scaling and reduction of parasitics are addressed, and three prototype fourth-generation SiGe HBTs are compared and evaluated down to deep cryogenic temperatures, using both dc and ac measurements. A record peak f T /f max of 463/618 GHz was achieved at 4.5 K using 130-nm lithography (309/343 GHz at 300 K), demonstrating the feasibility of reaching half-THz f T and f max simultaneously in a silicon-based transistor. The BV CEO of this cooled SiGe HBT was 1.6 V at 4.5 K (BV CBO = 5.6 V), yielding a record f T times BV CEO product of 750 GHzldrV (510 GHzldrV at 300 K). These remarkable levels of transistor performance and the associated interesting device physics observed at cryogenic temperatures in these devices provide important insights into further device scaling for THz speeds at room temperature. It is predicted in a new scaling roadmap that f T /f max of room-temperature SiGe HBTs could potentially achieve 782/910 GHz at a BV CEO of 1.1 V at the 32-nm lithographic node.
ISSN:0018-9383
1557-9646
DOI:10.1109/TED.2009.2016017