The prolonged operation of semiconductor integrated circuits (ICs) needed for long-duration exploration of the surface of Venus has proven insurmountably challenging to date due to the ∼ 460 °C, ∼ 9.4 MPa caustic environment. Past and planned Venus landers have been limited to a few hours of surface operation, even when IC electronics needed for basic lander operation are protected with heavily cumbersome pressure vessels and cooling measures. Here we demonstrate vastly longer (weeks) electrical operation of two silicon carbide (4H-SiC) junction field effect transistor (JFET) ring oscillator ICs tested with chips directly exposed (no cooling and no protective chip packaging) to a high-fidelity physical and chemical reproduction of Venus’ surface atmosphere. This represents more than 100-fold extension of demonstrated Venus environment electronics durability. With further technology maturation, such SiC IC electronics could drastically improve Venus lander designs and mission concepts, fundamentally enabling long-duration enhanced missions to the surface of Venus.
While there have been numerous reports of short-term transistor operation at 500 °C or
above, these devices have previously not demonstrated sufficient long-term operational durability at
500 °C to be considered viable for most envisioned applications. This paper reports the
development of SiC field effect transistors capable of long-term electrical operation at 500 °C. A
6H-SiC MESFET was packaged and subjected to continuous electrical operation while residing in a
500 °C oven in oxidizing air atmosphere for over 2400 hours. The transistor gain, saturation current
(IDSS), and on-resistance (RDS) changed by less than 20% from initial values throughout the duration
of the biased 500 °C test. Another high-temperature packaged 6H-SiC MESFET was employed to
form a simple one-stage high-temperature low-frequency voltage amplifier. This single-stage
common-source amplifier demonstrated stable continuous electrical operation (negligible changes to
gain and operating biases) for over 600 hours while residing in a 500 °C air ambient oven. In both
cases, increased leakage from annealing of the Schottky gate-to-channel diode was the dominant
transistor degradation mechanism that limited the duration of 500 °C electrical operation.
This paper reports on the fabrication and testing of 6H-SiC junction field effect transistors
(JFETs) and a simple differential amplifier integrated circuit that have demonstrated 2000 hours of
electrical operation at 500 °C without degradation. The high-temperature ohmic contacts, dielectric
passivation, and packaging technology that enabled such 500 °C durability are briefly described. Key
JFET parameters of threshold voltage, on-state resistance, transconductance, and on-state current, as
well as the gain of the differential amplifier integrated circuit, exhibited less than 7% change over the
first 2000 hours of 500 °C operational testing.
Prolonged Venus surface missions (lasting months instead of hours) have proven infeasible to date in the absence of a complete suite of electronics able to function for such durations without protection from the planet's extreme conditions of ∼460 • C, ∼9.3 MPa (∼92 Earth atmospheres) chemically reactive environment. Here, we report testing data from a successful two-month (60-day) operational demonstration of two 175-transistor 4H-SiC junction field effect transistor (JFET) semiconductor integrated circuits directly exposed (no cooling and no protective chip packaging) to a high-fidelity physical and chemical reproduction of Venus surface atmospheric conditions in a test chamber. These results extend the longest reported duration of electronics operation in Venus surface atmospheric conditions almost threefold and were accomplished using prototype SiC JFET chips of more than sevenfold increased complexity. The demonstrated advancement marks a significant step toward realization of electronics with sufficient complexity and durability for implementing robotic landers capable of returning months of scientific data from the surface of Venus. INDEX TERMS Silicon carbide, high-temperature techniques, JFET integrated circuits, space technology.
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