Horizontal Current Bipolar Transistor DC Performance at Cryogenic Temperatures
IEEE Electron Device Letters(2023)
Abstract
The DC current gain (
$\beta {)}$
of Si bipolar junction transistors (BJTs) reported so far decreases at cryogenic temperatures (CT), or shows a very limited improvement at best. For temperatures above 90 K, the Horizontal Current Bipolar Transistor (HCBT) behaves comparably to other published Si BJTs. However, cryogenic measurements of HCBT devices show a steep
$\beta $
increase at temperatures below 90 K. We report a current gain of 85 at 300 K, a minimum
$\beta $
of 31 at 90 K and an increase of
$\beta $
to 66 at 17 K. The collector-emitter breakdown voltage (
${\textit {BV}}_{\textit {CEO}}{)}$
measured around the peak
$\beta $
varies only within 0.2 V over the examined temperature range. Additionally, the Early voltage (
${V}_{A}{)}$
increases for temperatures below 50 K, improving the
$\beta {V}_{A}$
product at 20 K by 2.2x as compared to 300 K, which makes the HCBT a potentially attractive technology for deep cryogenic applications. TCAD simulations of an equivalent Si BJT structure show that such considerable increase of
$\beta $
at CT can be attributed to the interplay between incomplete ionization (II) of acceptors in the base and bandgap narrowing (BGN) in the emitter in a specific range of HCBT doping profiles.
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Key words
Cryogenics, bipolar junction transistor, low-temperature device performance, low-temperature device modeling, horizontal current bipolar transistor, quantum computing, low noise amplifier, radio frequencytransistors
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