The Heat Flow and Physical Properties Package (HP3) for the InSight Mission

The Heat Flow and Physical Properties Package HP 3 for the InSight mission will attempt the first measurement of the planetary heat flow of Mars. The data will be taken at the InSight landing site in Elysium planitia (136  ∘ E, 5  ∘ N) and the uncertainty of the measurement aimed for shall be better...

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Bibliographic Details
Published in:Space science reviews 2018-08, Vol.214 (5), p.1-33, Article 96
Main Authors: Spohn, T., Grott, M., Smrekar, S. E., Knollenberg, J., Hudson, T. L., Krause, C., Müller, N., Jänchen, J., Börner, A., Wippermann, T., Krömer, O., Lichtenheldt, R., Wisniewski, L., Grygorczuk, J., Fittock, M., Rheershemius, S., Spröwitz, T., Kopp, E., Walter, I., Plesa, A. C., Breuer, D., Morgan, P., Banerdt, W. B.
Format: Article
Language:English
Subjects:
Aerospace Technology and Astronautics
Astrophysics and Astroparticles
Brightness temperature
Hammering
Heat conductivity
Heat flow
Heat transfer
Heat transmission
Mars
Mars landing
Mars surface
Physical properties
Physics
Physics and Astronomy
Plains
Planetology
Platinum
Regolith
Robot arms
Seismometers
Sensors
Shadows
Space Exploration and Astronautics
Space Sciences (including Extraterrestrial Physics
Surface brightness
Surface temperature
Temperature
Temperature gradients
Temperature measurement
Temperature sensors
The InSight Mission to Mars II
Thermal conductivity
Uncertainty
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Summary:The Heat Flow and Physical Properties Package HP 3 for the InSight mission will attempt the first measurement of the planetary heat flow of Mars. The data will be taken at the InSight landing site in Elysium planitia (136  ∘ E, 5  ∘ N) and the uncertainty of the measurement aimed for shall be better than ±5 mW m −2 . The package consists of a mechanical hammering device called the “Mole” for penetrating into the regolith, an instrumented tether which the Mole pulls into the ground, a fixed radiometer to determine the surface brightness temperature and an electronic box. The Mole and the tether are housed in a support structure before being deployed. The tether is equipped with 14 platinum resistance temperature sensors to measure temperature differences with a 1- σ uncertainty of 6.5 mK. Depth is determined by a tether length measurement device that monitors the amount of tether extracted from the support structure and a tiltmeter that measures the angle of the Mole axis to the local gravity vector. The Mole includes temperature sensors and heaters to measure the regolith thermal conductivity to better than 3.5% (1- σ ) using the Mole as a modified line heat source. The Mole is planned to advance at least 3 m—sufficiently deep to reduce errors from daily surface temperature forcings—and up to 5 m into the martian regolith. After landing, HP 3 will be deployed onto the martian surface by a robotic arm after choosing an instrument placement site that minimizes disturbances from shadows caused by the lander and the seismometer. The Mole will then execute hammering cycles, advancing 50 cm into the subsurface at a time, followed by a cooldown period of at least 48 h to allow heat built up during hammering to dissipate. After an equilibrated thermal state has been reached, a thermal conductivity measurement is executed for 24 h. This cycle is repeated until the final depth of 5 m is reached or further progress becomes impossible. The subsequent monitoring phase consists of hourly temperature measurements and lasts until the end of the mission. Model calculations show that the duration of temperature measurement required to sufficiently reduce the error introduced by annual surface temperature forcings is 0.6 martian years for a final depth of 3 m and 0.1 martian years for the target depth of 5 m.
ISSN:0038-6308
1572-9672
DOI:10.1007/s11214-018-0531-4