NASA Testing Advanced Capabilities for Moon, Mars Rovers

On a bleak stretch of the Colorado Desert in Southern California, a compact four-wheeled rover recently trundled about 16 miles (26 kilometers) with minimal intervention from the team of engineers trailing it. Called ERNEST (Exploration Rover for Navigating Extreme Sloped Terrain), this prototype is being used by NASA to advance both robotic autonomy and the ability to traverse challenging landscapes.

Developed at NASA’s Jet Propulsion Laboratory in Southern California, ERNEST is 4 feet (1.2 meters) long. Not only can it lift each of its mesh wheels to get past obstacles that would stymie Curiosity and Perseverance, NASA’s six-wheeled Mars rovers, but the prototype also has enhanced independent decision-making capabilities. These mobility and autonomy advances could be infused into future missions that will venture to previously inaccessible areas of the Red Planet or the Moon.

ERNEST serves as a testbed for a potential future lunar rover mission requiring high speeds and extreme distances. In a recent field test, the prototype traveled 16 miles over the course of 37 hours, going an order of magnitude above the top speed at which NASA’s current Mars rovers can navigate. Credit: NASA/JPL-Caltech

In the field, ERNEST served as a testbed for a potential future lunar mission requiring higher speeds and much greater mileage than can be accomplished by current rovers. This technology could be used to inform future designs for exploration efforts on the Moon and beyond.

“This testing is helping us refine the mobility hardware and autonomy software to navigate extreme distances across a wide range of terrain and lighting conditions anticipated on the Moon,” said Issa Nesnas, a principal technologist at JPL who led the recent testing as head of autonomy for a NASA mission concept for a potential future long-range lunar rover.

Engineers from JPL set up illuminators after transporting ERNEST for a pre-sunrise test during a seven-day desert field campaign.

NASA/JPL-Caltech

Nesnas’ team is using ERNEST to demonstrate it is possible to build a rover that’s twice as big as the prototype and capable of a long-distance Moon mission. During the recent campaign, ERNEST traveled at speeds up to 0.6 mph (1 kph) over 37 hours of driving, across seven days of intermittent testing. That’s an order of magnitude above the top speed Perseverance and Curiosity can navigate.

“You could do a science road trip across the Moon — or Mars — with this vehicle,” said James Keane, a JPL planetary scientist working on lunar missions.

The initial goal of the team that developed ERNEST was mechanical: to design a relatively simple, low-cost rover that advances the trusted rocker-bogie suspension system featured on every Mars rover since NASA’s Sojourner. This passive system keeps relatively constant weight on all six wheels, thanks to pivot points and struts that enable each one to adapt to the changing surface.

The mobility and autonomy advances developed at JPL for the ERNEST prototype rover could be infused into future NASA missions to previously inaccessible areas of the Red Planet or the Moon. Credit: NASA/JPL-Caltech

On ERNEST, the active suspension lets the rover manage weight distribution among its wheels. Two powered joints in front articulate a gimbal that allows the rover to drive using different gaits like squirming, wheel-walking, and obstacle-climbing. With a clutch mechanism, it can switch between active and passive suspension, which is less terrain capable but more energy efficient. With four steerable wheels, it can drive in any direction, including sideways.

“We started by postulating that we could do better in designing a planetary surface robotic mobility system,” said Hari Nayar, a JPL principal technologist leading the ERNEST team. “While the rocker-bogie system has been very successful over the past 30 years, there’s been a lot of research in that time on mobility and understanding terrain interaction.”

Before arriving at today’s version of ERNEST, the team built two earlier prototypes, each about 2 feet (0.6 meters) long, to test 11 active suspension configurations. In a trailer filled with lunar regolith simulant, they ran experiments at different slope angles over several months before landing on a final design.

Then the team scaled up, including adding a rectangular head mounted on a 4.5-foot-tall (1.4-meter-tall) mast. The hardware was completed in September 2024, but the rover still needed a human operator to joystick it, sending commands to instruct the rover on how to move over obstacles.

In order to train the rover to think on its own, the ERNEST team turned to reinforcement learning, a type of artificial intelligence where the robot learns by interacting with its environment. The Dynamics and Real-Time Simulation Laboratory at JPL developed a high-fidelity virtual testing environment that replicates the rover’s behavior. The team fed the simulator data collected by engineers who documented the response of the actual rover hardware to a variety of terrain types. On a high-performance computing cluster, the team ran many simulations at once, sometimes completing thousands of hours of tests over a single weekend.

After months of virtual training, the ERNEST team was ready to see if the rover could use its new autonomous algorithms to figure out how to drive over terrain features that would halt a passive-suspension rover. They set up an obstacle course with sand ripples, rubble piles, steps, and steep slopes in JPL’s Mars Yard, an outdoor terrain proving ground. Then they watched as the rover maneuvered the terrain on its own. Since then, ERNEST has completed many such courses.

Nayar’s team is starting a new autonomy project which involves integrating the rover’s ability to determine when and how to use its active suspension with longer-range intelligent navigation. The goal is to enable ERNEST to plan an efficient path so that it can tackle surmountable obstacles and circumnavigate hazardous ones. These capabilities could contribute to potential future rover missions encountering formidable landscapes on Mars or more rugged areas of the Moon.

Work on ERNEST began in 2022 was initially supported by JPL internal research and development funds. It is currently funded by NASA’s Mars Exploration Program and the agency’s Exploration Science Strategy and Integration Office in its Science Mission Directorate at NASA Headquarters in Washington. Caltech in Pasadena, California, manages JPL for NASA. 

Source: NASA Testing Advanced Capabilities for Moon, Mars Rovers - NASA

Wet coffee grounds turned into high-grade solid fuel in just 90 seconds - Engineering - Energy & Green Tech

Atmospheric-pressure flame plasma system. Credit: Chemical Engineering Journal (2026). DOI: 10.1016/j.cej.2026.176452

A research team at the Korea Institute of Geoscience and Mineral Resources (KIGAM) has developed a technology that converts wet spent coffee grounds directly into high-quality biochar in just 90 seconds, with no drying or oil removal required. The breakthrough offers a fast, energy-efficient path to turning high-moisture organic waste into valuable fuel and carbon materials. The study, led by Dr. Taejun Park in collaboration with GodTech Co., Ltd., was published in the Chemical Engineering Journal, one of the world's leading journals in chemical engineering.

Addressing a growing waste challenge

Every year, global coffee consumption generates more than 10 million tons of spent coffee grounds, most of which end up in landfills or are incinerated, releasing greenhouse gases and polluting the environment.

Spent coffee grounds hold real energy potential, but their high moisture content has long been a barrier. Converting them into fuel or carbon products typically requires energy-intensive predrying, making large-scale resource recovery economically impractical.

World-first flame plasma pyrolysis technology

To overcome this challenge, the KIGAM team developed Flame Plasma Pyrolysis (FPP), a process that directly treats biomass containing approximately 55% moisture under atmospheric-pressure plasma conditions.

The system generates plasma flames at temperatures of approximately 800–900°C (1,472–1,652°F) through the combustion of liquefied petroleum gas (LPG) and compressed air. Unlike conventional pyrolysis technologies, the process eliminates the need for any predrying treatment.

During processing, the intense thermal energy rapidly vaporizes moisture trapped inside the biomass particles. The resulting pressure buildup triggers microscopic explosions known as the "popcorn effect," which simultaneously enhance carbonization and create highly porous structures. Rather than acting as a barrier, moisture itself becomes a steam-activation agent that accelerates reactions and improves product quality.

The process proceeding in a clean manner, with almost no smoke or oil observed during treatment. Credit: Korea Institute of Geoscience and Mineral Resources(KIGAM)

Anthracite-level fuel performance

Under optimized conditions, the researchers achieved complete conversion within 90 seconds, with a mass reduction of 83.3%.

The resulting biochar exhibited a heating value of 29.0 MJ/kg, approximately 33% higher than the original coffee grounds (21.8 MJ/kg) and comparable to that of anthracite coal.

Additional performance improvements included:

• a nearly threefold increase in fixed carbon content (from 15.6% to 46.2%)
• complete removal of sulfur compounds, preventing sulfur oxide (SOx) emissions during combustion
• an increase in specific surface area from 1.5 to 115.4 m²/g, indicating potential use as an activated carbon precursor or adsorption material
• minimal formation of secondary pollutants such as smoke and tar

These characteristics make the biochar suitable not only as a renewable solid fuel but also as a high-value carbon material for environmental and industrial applications.

(a) SEM images at different exposure times. (b) Schematic illustrating the transformation from non-porous raw SCG to peak porosity and eventual collapse with extended treatment. Credit: Korea Institute of Geoscience and Mineral Resources(KIGAM)

Dramatically faster than existing technologies

The new process offers substantial advantages in both processing speed and energy efficiency.

Compared with hydrothermal carbonization (HTC), which typically requires one to six hours, the FPP process is 40 to 240 times faster. It also reduces treatment time by more than 20-fold compared with torrefaction, which generally requires at least 30 minutes.

Because the system relies on combustion-generated plasma rather than electricity-intensive plasma devices, it lowers overall energy consumption while maintaining high processing performance.

The researchers emphasize that the ability to directly process wet feedstocks without predrying represents one of the technology's most significant economic and environmental advantages.

Potential for distributed waste-to-energy systems

Beyond coffee waste, the technology could potentially be applied to a wide range of high-moisture organic wastes, including food waste, sewage sludge and agricultural residues.

Its compact process design and ultrafast treatment capability make it particularly attractive for decentralized, onsite waste-to-energy facilities, where transportation and drying costs often limit resource recovery efforts.

The study demonstrates a new approach for transforming wet organic waste into valuable energy resources while advancing carbon-neutral waste management strategies.

"This technology presents a new paradigm in which waste is no longer viewed as a disposal problem but as a valuable energy resource," said Park. "We plan to expand the technology to various types of high-moisture organic waste and further optimize the process for industrial-scale commercialization." 

Provided by National Research Council of Science and Technology 

by National Research Council of Science and Technology

edited by Gaby Clark, reviewed by Robert Egan 

Source: Wet coffee grounds turned into high-grade solid fuel in just 90 seconds