Mass Spectrometer for Planetary Exploration


The MAss SPectrometer for Planetary EXploration is a mass spectrometer capable of high-resolution and high-sensitivity that allows the determination of a wide variety of chemical compounds in complex mixtures. This instrument will fly on board the planned Europa Clipper orbiter to explore Jupiter's moon Europa. This astrobiology mission will analyse the composition of Europa's surface while in orbit, and will directly assess its internal ocean habitability by flying through Europa's tenuous atmosphere.
On 27 May 2016 it was announced that MASPEX was selected to fly on the mission. The launch is planned for approximately 2025. The instrument has also been proposed to fly on three Discovery program missions: Enceladus Life Finder, comet Hartley 2, and to the main belt comet Read. It also has applications for probes, landers, and sample return missions. The Principal Investigator is Jack Waite, and the Technical Lead is Tim Brockwell, from the Southwest Research Institute.

Overview

MASPEX is a next generation spectrometer with significantly improved performance over existing instruments, that was developed over 10 years by the Southwest Research Institute. Development of the MASPEX was born out of the need to separate and analyze the unexpectedly rich volatile mixtures discovered by the Cassini INMS instrument at Titan and Enceladus. The instrument is a high-resolution, high-sensitivity mass spectrometer developed for planetary applications. Its high-resolution allows the unambiguous determination of volatile isotopes of methane, water, ammonia, carbon monoxide, molecular nitrogen, carbon dioxide, and small organic compounds in complex mixtures. MASPEX can also measure compounds in trace amounts, including the noble gases argon, krypton, xenon, and their isotopes.
The MASPEX can operate in a heavy radiation environment, and can be baked to 300 °C for planetary protection against forward biological contamination in case the probe impacts any potentially habitable moon of Jupiter. MASPEX can observe spatial features as small as 400 km of orbital track at high scan rates, and can operate at 5 kHz across full mass range. Other areas of enhanced performance over existing instruments include:
ParameterPerformance
Extended mass range
for heavy organic molecules
>1000 amu
Enhanced mass resolution>30,000 M/dM
Enhanced dynamic range109 in a 1s period
Improved sensitivitybetter than 1ppt with cryotrapping
High throughput>5000 samples/s
Length and mass40 cm and < 8 kg