Statements (131)
| Predicate | Object |
|---|---|
| gptkbp:instance_of |
gptkb:Mars_Rover
gptkb:scientific_experiments gptkb:designers |
| gptkbp:aims_to_improve |
future human missions
|
| gptkbp:analysis |
ongoing
|
| gptkbp:application |
supporting human missions to Mars
|
| gptkbp:average_temperature |
around 800 degrees Celsius
|
| gptkbp:can_transform_into |
CO2 to O2
|
| gptkbp:capacity |
about 0.5 cubic meters
|
| gptkbp:challenges |
harsh Martian conditions
|
| gptkbp:collaboration |
international space agencies
|
| gptkbp:collaborations |
collaborative research
|
| gptkbp:collaborator |
gptkb:MIT
|
| gptkbp:collection |
performance metrics
|
| gptkbp:community |
engaged
|
| gptkbp:community_engagement |
high interest
|
| gptkbp:community_impact |
inspiration for future generations
|
| gptkbp:community_outreach |
gptkb:educational_programs
|
| gptkbp:components |
gptkb:Oxygen_Generation_System
|
| gptkbp:contributes_to |
gptkb:Mars_exploration
future human missions |
| gptkbp:data_transmission |
transmits data to Earth
|
| gptkbp:design |
applied physics
compact and lightweight |
| gptkbp:designed_for |
sustaining human life on Mars
|
| gptkbp:developed_by |
gptkb:MIT
gptkb:NASA |
| gptkbp:development |
ongoing research
|
| gptkbp:duration |
several months
|
| gptkbp:engineering_success |
demonstrated feasibility
|
| gptkbp:environment |
gptkb:Martian_atmosphere
|
| gptkbp:environmental_impact |
low
|
| gptkbp:first_operation_date |
April 20, 2021
|
| gptkbp:first_successful |
oxygen production on another planet
|
| gptkbp:full_name |
gptkb:Mars_Oxygen_In-Situ_Resource_Utilization_Experiment
|
| gptkbp:funding |
NASA budget
|
| gptkbp:future_goals |
enhanced oxygen production
|
| gptkbp:future_prospects |
improving efficiency
|
| gptkbp:goal |
produce oxygen from Martian CO2
|
| gptkbp:has_component |
solid oxide electrolysis cell
|
| gptkbp:has_limitations |
limited by Martian resources
|
| https://www.w3.org/2000/01/rdf-schema#label |
MOXIE
|
| gptkbp:impact_on_exploration |
critical for future missions
|
| gptkbp:innovation |
pioneering technology
|
| gptkbp:involved_technology |
commercial applications
|
| gptkbp:is |
a focus of scientific research
a prototype for future systems a part of the future of space exploration a technology demonstration a part of the Artemis program a project that could pave the way for future human exploration of Mars a part of the broader goals of NASA's Mars exploration program a project that showcases international collaboration in space exploration a technology that could support life support systems on Mars a critical component for human survival on Mars a critical technology for space exploration a demonstration of resource utilization a demonstration of sustainable technology a key element for sustainable living on Mars a key to future Mars habitats a model for future Mars missions a part of the Mars 2020 mission objectives a potential lifesaver for astronauts a project under NASA's Jet Propulsion Laboratory a significant achievement in aerospace technology a step towards colonization of Mars a step towards making Mars habitable a technology that could enable long-term missions an example of advanced engineering an experiment in planetary science a demonstration of the potential for using local resources in space missions a demonstration of the feasibility of oxygen production on Mars a technology that could reduce the need for resupply missions from Earth a project that highlights the importance of innovation in space technology |
| gptkbp:is_analyzed_in |
atmospheric composition
|
| gptkbp:is_tested_for |
Mars atmosphere
Mars surface demonstration phase |
| gptkbp:launch_date |
February 18, 2021
|
| gptkbp:launched |
gptkb:NASA
|
| gptkbp:location |
gptkb:Mars
|
| gptkbp:mission |
gptkb:Mars_2020
|
| gptkbp:notable_mission |
gptkb:Mars_Sample_Return
|
| gptkbp:objective |
study Martian atmosphere
|
| gptkbp:operated_by |
gptkb:NASA
solar energy |
| gptkbp:operates_in |
gptkb:Mars
|
| gptkbp:operates_under |
high temperatures
|
| gptkbp:operational_since |
February 2021
|
| gptkbp:operational_status |
operational
|
| gptkbp:operational_use |
NASA engineers
|
| gptkbp:oxygen_produced |
approximately 5 grams per hour
|
| gptkbp:part_of |
gptkb:Mars_2020_Perseverance_rover
gptkb:Perseverance_rover |
| gptkbp:partnerships |
academic institutions
|
| gptkbp:powers |
300 watts
|
| gptkbp:produced |
oxygen
|
| gptkbp:produced_oxygen_amount |
up to 10 grams per hour
|
| gptkbp:produces |
oxygen
|
| gptkbp:project |
advanced life support systems
planned for several years |
| gptkbp:provides |
data for future technologies
|
| gptkbp:provides_information_on |
open access
|
| gptkbp:public_interest |
high
|
| gptkbp:publications |
gptkb:academic_journals
|
| gptkbp:research_focus |
sustainable human presence on Mars
|
| gptkbp:research_output |
validates oxygen production technology
|
| gptkbp:safety_measures |
redundant systems
|
| gptkbp:significance |
demonstrates in-situ resource utilization
|
| gptkbp:success |
produced oxygen
|
| gptkbp:success_rate |
high
|
| gptkbp:uses |
carbon dioxide
Martian CO2 |
| gptkbp:uses_electrolysis |
to separate oxygen
|
| gptkbp:uses_technology |
solid oxide electrolysis
|
| gptkbp:was_a_demonstration_of |
gptkb:in-situ_resource_utilization
oxygen production technology |
| gptkbp:weight |
about 17 kilograms
|
| gptkbp:bfsParent |
gptkb:Mars_Perseverance_Rover
gptkb:Perseverance_Rover gptkb:Mars_Rover gptkb:Mars_Rover_missions gptkb:Perseverance_rover gptkb:Mars_Rover_Missions gptkb:Mars_2020_mission gptkb:Mars_Perseverance_rover gptkb:Mars_Rover_Perseverance gptkb:Mars_2020 gptkb:Perseverance gptkb:Mars_2020_Perseverance_Rover |
| gptkbp:bfsLayer |
4
|