South Pole Safety Designing the NASA Lunar Rescue System Competition

In the unforgiving lunar environment, the possibility of an astronaut crewmember becoming incapacitated due to unforeseen circumstances (injury, medical emergency, or a mission-related accident) is a critical concern, starting with the upcoming Artemis III mission, where two astronaut crewmembers will explore the Lunar South Pole. The Moon’s surface is littered with rocks ranging from 0.15 to 20 meters in diameter and craters spanning 1 to 30 meters wide, making navigation challenging even under optimal conditions. The low gravity, unique lighting conditions, extreme temperatures, and availability of only one person to perform the rescue, further complicate any rescue efforts.

Among the critical concerns is the safety of astronauts during Extravehicular Activities (EVAs). If an astronaut crewmember becomes incapacitated during a mission, the ability to return them safely and promptly to the human landing system is essential. A single crew member should be able to transport an incapacitated crew member distances up to 2 km and a slope of up to 20 degrees on the lunar terrain without the assistance of a lunar rover.

This pressing issue opens the door for innovative solutions. We are looking for a cutting-edge design that is low in mass and easy to deploy, enabling one astronaut crewmember to safely transport their suited (343 kg (~755lb)) and fully incapacitated partner back to the human landing system. The solution must perform effectively in the Moon’s extreme South Pole environment and operate independently of a lunar rover.

Your creativity and expertise could bridge this critical gap, enhancing the safety measures for future lunar explorers. By addressing this challenge, you have the opportunity to contribute to the next “giant leap” in human space exploration.

Guidelines
Background
NASA’s Artemis campaign marks a new chapter in lunar exploration, aiming to land the first woman, first person of color, and first international partner crewmember at the Lunar South Pole. Artemis III, scheduled for no earlier than 2026, is the first crewed surface mission under this campaign. The objectives of Artemis III are to conduct experiments and collect samples to advance our understanding of lunar geology and resources, test new technologies and systems that will enable a long-term human presence on the Moon and gather data to support subsequent missions.

This ambitious endeavor presents significant challenges. Unlike future missions that will be equipped with a Lunar Terrain Vehicle (scheduled for delivery no earlier than Artemis V) and Pressurized Rover (scheduled for delivery no earlier than Artemis VII), the Artemis III and IV crews will not have access to a rover. This limitation necessitates that all equipment and safety protocols be carried and managed by the crewmembers themselves, emphasizing the need for solutions with minimal mass and volume impact.

The Spacesuit
For the Artemis III mission, crewmembers will be equipped with the next-generation Axiom Extravehicular Mobility Unit (AxEMU) spacesuit, developed by Axiom Space. This advanced suit represents a significant leap forward in spacesuit technology, designed to support the demanding objectives of lunar exploration at the Moon’s South Pole.

The AxEMU serves as a personal spacecraft for each EVA crewmember, providing a flexible, adjustable fit and life-sustaining environment amidst the vacuum of space and the Moon’s harsh conditions. The suit’s life support system is engineered for extended missions, featuring regenerable carbon dioxide scrubbing and robust thermal regulation. This system enables crewmembers to conduct spacewalks for durations of 4-8 hours. The Artemis missions currently expect 2-5 EVAs of this duration, each. The AxEMU suit is outfitted with four attachment points located on the front waist area and top of the Spacesuit. (See Axiom Suit Images in the Resources tab for additional details)

The Lunar Environment
The Lunar South Pole presents an environment of stark extremes and formidable challenges, shaping every aspect of the Artemis missions. Understanding this environment is crucial for ensuring the safety of the crewmembers and the success of their objectives. Temperature extremes are among the most significant challenges. Due to the Moon’s lack of atmosphere and minimal axial tilt, temperatures can vary dramatically. Sunlit areas can reach scorching highs of approximately 130°F (54°C), while areas in permanent shadow can plunge to frigid lows of about -334°F (-203°C). Equipment and suits must be able to operate effectively across this vast temperature range, and thermal regulation for crewmembers is a constant challenge.

Lighting conditions at the South Pole are uniquely challenging. The Sun hovers near the horizon, creating long shadows that obscure surface features and make terrain navigation difficult. Some regions are in near-permanent darkness, while others experience extended periods of daylight. The low-angle lighting can impair depth perception, increasing the risk of tripping or stumbling over unseen obstacles.

The terrain itself is rugged and uneven, characterized by a multitude of geological features, including:

Rocks (Blocks): The surface is strewn with rocks ranging from approximately 0.15 meters to 20 meters in diameter, with a height-to-diameter ratio of 0.5. These blocks can impede movement and create hazardous conditions for traversal.
Craters: Craters vary in size from 1 meter to 30 meters in diameter, with a depth-to-diameter ratio of 0.12. Navigating around or across these craters requires careful planning and significant physical effort.
Slopes: up to 20 degrees (up, down, or cross slopes)
(See Design Specification for Natural Environments (DSNE) in the Resources tab for additional details)

Lunar gravity: Approximately one-sixth that of Earth’s, the Moon’s gravitational pull affects how crewmembers move and handle objects. While the reduced gravity allows for lifting heavier loads than on Earth, it also means that inertia is a concern; once an object is in motion, it is harder to stop, impacting both walking and the manipulation of tools and equipment. Regolith, or lunar dust, is composed of fine, sharp particles that can cling to surfaces due to electrostatic charging. It can interfere with equipment functionality, degrade seals and joints, and pose safety and health risks (if ingested or inhaled) – though spacesuits are designed to minimize exposure. The Moon’s lack of an atmosphere exposes the surface to solar radiation and the threat of micrometeoroid impacts.

These environmental factors necessitate strong consideration for equipment materials, crewmember transport and use, deployment and operational procedures, and system durability.

Lunar Surface Extravehicular Activities (EVAs)
EVAs are pivotal for scientific discovery, technological advancement, and paving the way for sustained human presence on the Moon. Lunar spacewalks will enable the crew to explore the Lunar South Pole, a region of immense scientific interest due to its unique environmental conditions and the potential presence of water ice in permanently shadowed regions.

The mission will involve a multi-day journey to lunar orbit, followed by a descent to the Moon’s surface near the South Pole – a region unexplored by humans to date. During their mission, crewmembers will conduct EVAs, venturing up to 2 kilometers away from their landing site to explore and conduct scientific research.

“Consumables” in the context of a lunar EVA refer to the limited life support resources crewmember carries in their spacesuit. These resources include oxygen for breathing, water for cooling, and power for the suit’s systems, such as communication and life support. Consumables are essential to maintaining the crewmember’s ability to survive and function throughout the entire lunar EVA. The amount of consumables carried is designed to support the crewmember for a specific duration, with a contingency reserve for emergencies.

During early Artemis missions, there will only be two crewmembers on the surface of the Moon. Safety protocols dictate that all EVAs be performed with two crewmembers, working closely together. This requirement ensures mutual support and increases safety in the challenging lunar environment. However, it also presents a critical challenge: in the event that one crewmember becomes incapacitated due to injury, medical emergency, or equipment malfunction, the other must be prepared to assist and, if necessary, transport their partner back to the human landing system.

The Problem
The Lunar South Pole poses formidable challenges: treacherous terrain strewn with rocks and craters, extreme temperature fluctuations, unique lighting conditions, and the reduced gravity of the Moon. In this harsh environment, the possibility of a crewmember becoming incapacitated due to injury, health issues, or equipment failure is a serious concern.

Artemis explorers would benefit from a lightweight, easily deployable solution that allows a single crewmember to transport a 343 kg (~755lb) fully incapacitated crewmember over distances of up to 2 kilometers (and lunar terrain slopes up to 20 degrees) without the assistance of a lunar rover.

We are seeking innovative solutions to this challenge. By developing a design that is low in mass, easily transportable by the crewmember throughout the duration of the nominal EVA, easy to deploy, and capable of functioning effectively under the extreme conditions of the Lunar South Pole, you can play a vital role in enhancing the safety measures for our future lunar explorers.

The Challenge
Are you ready to make a tangible impact on the future of space exploration and claim your share of the $45,000 prize purse? This is your opportunity to contribute to crewmember safety on early lunar missions. We invite you to design an innovative solution that enables a single crewmember to safely transport a fully incapacitated crewmember back to the human landing system from up to 2 kilometers away during a lunar EVA, without relying on a lunar rover. Your concept should be low in mass, easy to deploy, transportable by the crewmember throughout the duration of the EVA, and capable of operating under the extreme conditions of the Lunar South Pole.

We are seeking comprehensive technical design concepts that showcase your ingenuity and problem-solving skills. Your proposal should detail how your solution works, explaining the mechanics that enable one crewmember to transport another safely across the challenging lunar terrain. It should address the specific requirements of the mission, and address all challenge judging criteria. Your design should demonstrate how it overcomes environmental hurdles, functioning effectively in low gravity, unique lighting conditions, extreme temperatures, and in the presence of abrasive lunar dust. Visual illustrations, such as diagrams, sketches, are required while preliminary CAD models are highly encouraged, to bring your idea to life and help us understand its practicality and feasibility. AI-generated images shall not be submitted.

In your proposal, provide key technical specifications and details that effectively communicate your design. Offer realistic estimates of your solution’s total mass and volume, aiming for less than 23 kilograms (~50 pounds), and minimal volume, to ensure practicality for lunar transport and use. Specify the materials you plan to use, ensuring they are suitable for the harsh lunar environment and capable of withstanding extreme temperatures, vacuum conditions, and Regolith.

Explain how your solution can be quickly and easily deployed by a single crewmember. Detail how your design can be transported, and functions once deployed, discussing aspects like stability, control, speed of movement, and how it navigates the challenging lunar terrain. Safety is paramount; describe how your design ensures the safety of both the incapacitated crewmember and the rescuer, outlining any risk mitigation strategies and highlighting how your solution avoids introducing new hazards to either crewmember. Emphasize the practicality of your design in an emergency scenario, ensuring it can be deployed rapidly and effectively when needed most.

Performance Criteria

The following factors should be considered in the design of your solution:

Must-Have Requirements

To be considered for the prize, your design must meet these essential requirements:

Low Mass and Minimal Volume: Aim for total mass no greater than 23 kilograms (~50 pounds). The lighter the design solution, the better. Design should also minimize stowed volume for ease of transport.
Effectiveness in Safe Transportation: enable a single crewmember to transport an incapacitated crewmember over a distance of up to 2 kilometers on up to 20 degrees lunar terrain slope. Facilitate a prompt return to the entry point of the lunar lander, considering limited EVA consumables (oxygen, battery life).
Ease of Deployment and Use: Deployable and operable by one crewmember wearing the AxEMU spacesuit. Can be deployed rapidly in an emergency situation with limited dexterity.
Compatibility with Lunar Environment: Use materials that can withstand extreme temperatures, lunar dust, and vacuum conditions. Capable of functioning through rugged terrain (up to 20 deg up/down/cross lunar terrain slope), including rocks and craters as specified in the lunar terrain data.
Safety and Reliability: Does not introduce additional risks during deployment or operation. Functions consistently without failure or hazards under expected lunar conditions.
Minimal Impact on Suit Design: Should require minimal to no modifications to the AxEMU spacesuit. Use of the attachment points on the Spacesuit is acceptable.
Nice-to-Have Features

While not mandatory, the following features will enhance your submission:

Collapsibility and Storage Efficiency: The solution can be collapsed or folded for efficient storage during transport to the Moon.
Adaptability: Can accommodate various incapacitation scenarios and adjust to different mission requirements.
Anthropometric Accommodation: Accommodates crewmembers across a broad range of body sizes and shapes (1st to 99th percentile).
Ease of Manufacturing: Utilizes materials and manufacturing processes that are practical and cost-effective with current technology.
Multi-functionality: The design serves other purposes beyond casualty evacuation, adding value to the mission.
. Out of Scope for This Challenge

Please note that the following aspects are out of scope and should not be included in your submission:

Medical Treatment: Providing medical attention or life support to the incapacitated crew member beyond safe transportation.
Suit Modifications: Any design requiring significant changes to the existing AxEMU spacesuit.
Lunar Rover Use: Solutions that rely on the use of rovers
Complex Integrations: Designs that require significant integration with other systems or have substantial impacts on mission mass, volume, or power resources beyond acceptable limits.
We are seeking solutions that push the boundaries of current technology and thinking. Highlight what makes your concept unique and how it represents a novel approach to this critical challenge. By contributing your expertise and creativity, you have the chance to play a vital role in enhancing crewmember safety during lunar missions, be part of a historic endeavor as humanity returns to the Moon, gain recognition from NASA and the global space exploration community, and win a portion of the $45,000 prize purse. Click Solve This Challenge to begin now!

Awards:-

$45,000 purse distributed through five prizes: