Mission design of the Phoenix Mars Scout mission

Guinn, J.; Garcia, Mark; Talley, Kevin P.

doi:10.1029/2007je003038

Cited by 13 publications

(10 citation statements)

References 4 publications

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“…Information such as compositional estimates, detection of impurities, such as biomolecules, and potentially the relationship between the biomolecules and the geologic material can in theory be determined. Coupling mass spectral techniques such as those used in the thermal and evolved gas analyzer (TEGA) (Boynton et al, 2001) that is being used on the surface of Mars as part of the Phoenix mission (Guinn et al, 2008) would allow researchers to identify the gases evolved during heat treatment to positively identify combustion gases that are due to organic matter (i.e., CO 2 , CH 4 , and NH 4 ). Investigations such as these and others conducted on other mineral groups of interest (Stalport et al, 2005) could provide the framework necessary to interpret the thermal analysis results should sterilization continue to be a criteria for planetary protection.…”

Section: Discussionmentioning

confidence: 99%

“…Thermal analysis techniques (Wendlandt, 1986), although destructive, can provide valuable information while heating the samples to temperatures within the sterilization range (up to 500 1C). Thermal analysis has been shown to differentiate biotic and abiotic minerals by changes in onset temperatures (Stalport et al, 2005(Stalport et al, , 2007, and thermal analysis techniques were recently used on the Phoenix Mission that landed in the martian arctic (Banks, 2008;Guinn et al, 2008). Combining sterilization with thermal analysis techniques could therefore provide a reasonable compromise between planetary protection and scientific payoff.…”

Section: Introductionmentioning

confidence: 98%

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Laboratory simulations of prebiotic molecule stability in the jarosite mineral group; end member evaluation of detection and decomposition behavior related to Mars sample return

Kotler

Hinman

Richardson

et al. 2009

Planetary and Space Science

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 98%

Laboratory simulations of prebiotic molecule stability in the jarosite mineral group; end member evaluation of detection and decomposition behavior related to Mars sample return

Kotler

Hinman

Richardson

et al. 2009

Planetary and Space Science

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“…Comparison between the pitching moment coefficients for the heat shield case obtained by numerical simulations using FINFLO numerical code developed by Finflo Ltd and from LA. Chicarro et al, 1993;Chicarro, 1994;Merrihew et al, 1996;Haberle and Catling, 1996;Linkin et al, 1998;Harri et al, 1999Harri et al, , 2007. A spatially wide and comprehensive network alone would provide a significant leap in spatial and temporal (from diur-nal to seasonal and up to interannual scales) characterisation of the global circulation patterns and the major climatological cycles of dust, H 2 O and CO 2 (Savijärvi et al, 2005;Harri et al, 2014b, a;Savijärvi et al, 2016).…”

Section: Atmospheric Observation Networkmentioning

confidence: 99%

The MetNet vehicle: A lander to deploy environmental stations for local and global investigations of Mars

Harri¹,

Pichkadze²,

Zeleny³

et al. 2016

Preprint

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Investigations of global and related local phenomena on Mars such as atmospheric circulation patterns, boundary layer phenomena, water, dust and climatological cycles and investigations of the planetary interior would benefit from simultaneous, distributed in situ measurements. Practically, such an observation network would require low-mass landers, with a high packing density, so a large number of landers could be delivered to Mars with the minimum number of launchers.The Mars Network Lander (MetNet Lander; MNL), a small semi-hard lander/penetrator design with a payload mass fraction of approximately 17 %, has been developed, tested and prototyped. The MNL features an innovative Entry, Descent and Landing System (EDLS) that is based on inflatable structures. The EDLS is capable of decelerating the lander from interplanetary transfer trajectories down to a surface impact speed of 50-70 m s −1 with a deceleration of < 500 g for < 20 ms. The total mass of the prototype design is ≈ 24 kg, with ≈ 4 kg of mass available for the payload.The EDLS is designed to orient the penetrator for a vertical impact. As the payload bay will be embedded in the surface materials, the bay's temperature excursions will be much less than if it were fully exposed on the Martian surface, allowing a reduction in the amount of thermal insulation and savings on mass.The MNL is well suited for delivering meteorological and atmospheric instruments to the Martian surface. The payload concept also enables the use of other environmental instruments. The small size and low mass of a MNL makes it ideally suited for piggy-backing on larger spacecraft. MNLs are designed primarily for use as surface networks but could also be used as pathfinders for high-value landed missions.

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“…The trajectory includes six planned course maneuvers designed to put Phoenix on an entry path to land in the northern plains on 25 May 2008. A mission description is given by Guinn et al [2008].…”

Section: Missionmentioning

confidence: 99%

Introduction to special section on the Phoenix Mission: Landing Site Characterization Experiments, Mission Overviews, and Expected Science

et al. 2008

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Phoenix, the first Mars Scout mission, capitalizes on the large NASA investments in the Mars Polar Lander and the Mars Surveyor 2001 missions. On 4 August 2007, Phoenix was launched to Mars from Cape Canaveral, Florida, on a Delta 2 launch vehicle. The heritage derived from the canceled 2001 lander with a science payload inherited from MPL and 2001 instruments gives significant advantages. To manage, build, and test the spacecraft and its instruments, a partnership has been forged between the Jet Propulsion Laboratory, the University of Arizona (home institution of principal investigator P. H. Smith), and Lockheed Martin in Denver; instrument and scientific contributions from Canada and Europe have augmented the mission. The science mission focuses on providing the ground truth for the 2002 Odyssey discovery of massive ice deposits hidden under surface soils in the circumpolar regions. The science objectives, the instrument suite, and the measurements needed to meet the objectives are briefly described here with reference made to more complete instrument papers included in this special section. The choice of a landing site in the vicinity of 68°N and 233°E balances scientific value and landing safety. Phoenix will land on 25 May 2008 during a complex entry, descent, and landing sequence using pulsed thrusters as the final braking strategy. After a safe landing, twin fan‐like solar panels are unfurled and provide the energy needed for the mission. Throughout the 90‐sol primary mission, activities are planned on a tactical basis by the science team; their requests are passed to an uplink team of sequencing engineers for translation to spacecraft commands. Commands are transmitted each Martian morning through the Deep Space Network by way of a Mars orbiter to the spacecraft. Data are returned at the end of the Martian day by the same path. Satisfying the mission's goals requires digging and providing samples of interesting layers to three on‐deck instruments. By verifying that massive water ice is found near the surface and determining the history of the icy soil by studying the mineralogical, chemical, and microscopic properties of the soil grains, Phoenix will address questions concerning the effects of climate change in the northern plains. A conclusion that unfrozen water has modified the soil naturally leads to speculation as to the biological potential of the soil, another scientific objective of the mission.

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Mission design of the Phoenix Mars Scout mission

Cited by 13 publications

References 4 publications

Laboratory simulations of prebiotic molecule stability in the jarosite mineral group; end member evaluation of detection and decomposition behavior related to Mars sample return

Laboratory simulations of prebiotic molecule stability in the jarosite mineral group; end member evaluation of detection and decomposition behavior related to Mars sample return

The MetNet vehicle: A lander to deploy environmental stations for local and global investigations of Mars

Introduction to special section on the Phoenix Mission: Landing Site Characterization Experiments, Mission Overviews, and Expected Science

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