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Why do just one experiment at a time when you can do ten? Researchers have developed an automated system, which allows them to research catalysts, electrodes, and reaction conditions for CO2 electrolysis up to ten times faster. The system is complemented by an open-source software for data analysis.

Why do just one experiment at a time when you can do ten? Researchers have developed an automated system, which allows them to research catalysts, electrodes, and reaction conditions for CO2 electrolysis up to ten times faster. The system is complemented by an open-source software for data analysis.

Researchers have developed a tiny robot replicating the aerial dance of falling maple seeds. In the future, this robot could be used for real-time environmental monitoring or delivery of small samples even in inaccessible terrain such as deserts, mountains or cliffs, or the open sea. This technology could be a game changer for fields such as search-and-rescue, endangered species studies, or infrastructure monitoring.

Researchers have developed a tiny robot replicating the aerial dance of falling maple seeds. In the future, this robot could be used for real-time environmental monitoring or delivery of small samples even in inaccessible terrain such as deserts, mountains or cliffs, or the open sea. This technology could be a game changer for fields such as search-and-rescue, endangered species studies, or infrastructure monitoring.

The majority of stars in our galaxy are home to planets. The most abundant are the sub-Neptunes, planets between the size of Earth and Neptune. Calculating their density poses a problem for scientists: depending on the method used to measure their mass, two populations are highlighted, the dense and the less dense. Is this due to an observational bias or the physical existence of two distinct populations of sub-Neptunes? Recent work argues for the latter.

Structural formulas are a source of dread for many students, but they're an essential tool in biology lessons. A study has now shown that the stress levels of students working with chemical formulas are significantly reduced if they are given simple tips on how to deal with these formulas.

Chemists have successfully synthesized Ruddlesden-Popper nitrides for the first time, opening the door to new materials with unique properties.

A more accurate way to scan for tuberculosis (TB) has been developed, using positron emission tomography (PET). The team has developed a new radiotracer, which is taken up by live TB bacteria in the body. Radiotracers are radioactive compounds which give off radiation that can be detected by scanners and turned into a 3D image. The new radiotracer, called FDT, enables PET scans to be used for the first time to accurately pinpoint when and where the disease is still active in a patient's lungs.

Just four per cent of talented teen academy prospects make it to the top tier of professional football, a new study has shown. A sample of nearly 200 players, aged between 13-18, also revealed only six per cent of the budding ballers even go on to play in lower leagues.

Researchers have developed a deep-learning model, called PepFlow, that can predict all possible shapes of peptides -- chains of amino acids that are shorter than proteins, but perform similar biological functions. Peptides are known to be highly flexible, taking on a wide range of folding patterns, and are thus involved in many biological processes of interest to researchers in the development of therapeutics.

The term aromaticity is a basic, long-standing concept in chemistry that is well established for ring-shaped carbon compounds. Aromatic rings consisting solely of metal atoms were, however, heretofore unknown. A research team recently succeeded in isolating such a metal ring and describing it in full.

Transmission electron microscopy (TEM) has long been the gold standard for detecting asbestos fibers in air samples drawn at construction sites. But researchers have found that a cheaper, less labor-intensive method, scanning electron microscopy (SEM), can work just as well in most cases. The new finding could help reduce the estimated $3 billion spent on asbestos remediation in this country every year.

By restricting radiant heat flows between buildings and their environment to specific wavelengths, coatings engineered from common materials can achieve energy savings and thermal comfort that goes beyond what traditional building envelopes can achieve.

Harnessing nanoparticles to deliver drugs precisely to a surgically repaired tendon is a promising new approach that reduced scar tissue formation and improved mechanical function.

If there's one thing we humans are good at, it's producing heat. Significant amounts, and in many cases most of the energy we generate and put into our systems we lose as heat, whether it be our appliances, our transportation, our factories, even our electrical grid.

Researchers have discovered a new way to drive chemical reactions that could generate a wide variety of azetidines -- four-membered nitrogen heterocycles that have desirable pharmaceutical properties.

Synthetic biology combines principles from science, engineering and social science, creating emerging technologies such as alternative meats and mRNA vaccines; Deconstructing synthetic biology across scales gives rise to new approach to uniting traditional disciplines; Case studies offer a modular, accessible approach to teaching at different institutions.

Trilobites are one of the most common fossils we know, but normally only their hard exoskeleton is preserved. Now, researchers have discovered a site that was buried by a Pompeii-style volcanic eruption, leaving the arthropods outlined in exquisite detail

Utilizing regolith on the Moon or Mars, especially to refill propellant for rockets to get back off the surface, is a common theme in the more engineering-minded space exploration community. There have been plenty of proof-of-concept technologies that could move us toward that goal. One of the best supported was the Regolith Advanced Surface Systems Operations Robot (RASSOR). Let’s take a look at what made this project unique.

It was initially conceived at Swamp Works, NASA’s version of Skunk Works, the famous Lockheed Martin development facility that worked on the SR-71 Blackbird and F-117 stealth plane. So far, it has gone through two iterations, known as 1.0 and 2.0, released in 2013 and 2016, respectively. 

RASSOR consists of a chassis, a drive train, and two large bucket drum excavators. The excavating elements are on opposing sides of the rover, allowing the system to cancel out any horizontal forces caused by the excavating activity. On Earth, those horizontal forces would be offset by the physical weight of the digging machinery. Since weight is a precious commodity on space missions, this force-canceling technology is arguably the most crucial innovation in the system.

Video showing testing of the RASSOR 2.0 prototype.
Credit – NASA Video Collection YouTube Channel

The RASSOR 2.0 prototype had several design goals, but it’s probably most helpful to walk through a use-case scenario. According to the soil samples collected by Curiosity and other rovers, around 2% of the regolith on Mars is water, even in the relatively “dry” regions outside the poles. Collecting that water could help refuel rockets and supply settlements with drinking water, radiation shielding, or water for agriculture.

NASA commonly uses a mission structure involving four astronauts on a journey to Mars. In a paper describing the 2.0 version of the robot back in 2016, the authors, including Robert Mueller, the founder of the Swamp Works facility and a doyen of ISRU research, describe a mission structure that would see RASSOR mining 1,000,000 kg of Martian regolith per year and supplying 10,000 kilograms of oxygen to the mission.

To do so, it would utilize a lander with processing capabilities for separating the useful parts from the chaff and would trek from the lander site to the regolith collection site about 35 times a day. With a charging cycle that would take about 8 hours a day, that would leave upwards of 16 hours to continuously mine the surface of Mars for these valuable materials.

Fraser describes how to live off the land in space using ISRU.

The paper goes on to describe the design process for the RASSOR’s various subsystems, including the powerful actuators that make up the majority of the weight of the system. They also used 3D-printed titanium to make the bucket drum excavating tools, which required some ingenious machining by Swamp Work’s machinists. 

But in the end, they did make a working prototype. They tested it with improvements like a 50% drop in weight and an autonomous mode that utilizes simple stereo-vision cameras. The team believes this project is ready to move on to the next phase, taking a step closer to making it a reality.

That paper, however, was published eight years ago. A relatively detailed internet search doesn’t produce any results for RASSOR 3.0 other than a brief mention at the end of the 2.0 paper. So, for now, it seems the project is on hold. However, another NASA project, the Lunabotics Challenge, keeps university teams working toward effectively mining regolith for us in ISRU systems. Maybe one of those teams will pick up where the RASSOR team left off – or come up with a completely new design. We’ll have to wait and see.

Learn More:
Mueller et al. – Design of an Excavation Robot: Regolith Advanced Surface Systems Operations Robot (RASSOR) 2.0
UT – Japan Tests Robotic Earth-Moving Equipment in a Simulated Lunar Jobsite
UT – NASA Wants to Learn to Live Off the Land on the Moon
UT – What is ISRU, and How Will it Help Human Space Exploration?

Lead Image:
CAD model of the RASSOR 2.0 excavating robot.
Credit – Mueller et al.

The post A Single Robot Could Provide a Mission To Mars With Enough Water and Oxygen appeared first on Universe Today.

A genetic study of woolly mammoths found on an isolated Arctic island shows they reached a stable population that lasted millennia, so were probably wiped out by a random event rather than inbreeding