Complementary junction field-effect transistor logic gate operational at 300$^\circ$C with 1.4 V supply voltage

TL;DR

This paper demonstrates that SiC complementary JFET logic gates can operate reliably at 300°C with a low supply voltage of 1.4 V, enabling high-temperature electronics with predictable behavior and circuit simulation capabilities.

Contribution

The authors present the first SiC CJFET logic gates functioning at 300°C with low supply voltage, supported by an analytical model for circuit design and simulation.

Findings

Operated at 300°C with 1.4 V supply voltage

Logic threshold voltage shift of 0.2 V from room temperature to 300°C

Analytical model accurately explains temperature dependencies

Abstract

Integrated circuits (ICs) that can operate at high temperature have a wide variety of applications in the fields of automotive, aerospace, space exploration, and deep-well drilling. Conventional silicon-based complementary metal-oxide-semiconductor (CMOS) circuits cannot work at higher than 200 $^\circ$C, leading to the use of wide bandgap semiconductor, especially silicon carbide (SiC). However, high-density defects at an oxide-SiC interface make it impossible to predict electrical characteristics of SiC CMOS logic gates in a wide temperature range and high supply voltage (typically ${\geqq 15}$ V) is required to compensate their large logic threshold voltage shift. Here, we show that SiC complementary logic gates composed of p- and n-channel junction field-effect transistors (JFETs) operate at 300 $^\circ$C with a supply voltage as low as 1.4 V. The logic threshold voltage shift of the complementary JFET (CJFET) inverter is 0.2 V from room temperature to 300 $^\circ$C. Furthermore, temperature dependencies of the static and dynamic characteristics of the CJFET inverter are well explained by a simple analytical model of SiC JFETs. This allows us to perform electronic circuit simulation, leading to superior designability of complex circuits or memories based on SiC CJFET technology, which operate within a wide temperature range.