Monthly Archives: July 2024

In terms of being hard-to-kill, few animals are more resilient than the tiny tardigrade. But the water bear isnt the planets only nearly indestructible, extremotolerant living organisman assuming desert moss known as Syntrichia caninervis can survive in some of the most inhospitable environments. Regardless of blistering heat, punishing cold, aridity, cloud cover, or radiation, S. caninervis can likely withstand the otherwise deadly conditions. And according to researchers, thats what makes the plant a perfect Martian transplant.

In a paper published June 1 in the journal The Innovation, a team at the Chinese Academy of Sciences (CAS) argues S. caninervis is a promising pioneer plant for colonizing extraterrestrial environments, especially in scenarios like establishing a permanent base on another planet.

[Related: How super resilient tardigrades can fix their radiation-damaged DNA.]

Many plans to establish human settlements on other planets focus on adapting crops to growth in controlled environments, arid ecology experts note in their paper abstract. However, these settlements will also require pioneer plants that can grow in the soils and harsh conditions found in extraterrestrial environments, such as those on Mars.

The arid ecology experts at CAS believe S. caninervis is an extremely promising nominee for one of these future pioneer plants. After obtaining both fully hydrated and dehydrated moss samples, the team put them through the ringerstoring them in -112 degree Fahrenheit freezers for 3-5 years, submerging them in a liquid nitrogen tank (-320 degrees Fahrenheit) for 15-30 days, and exposing them to upwards of 16,000 grays of gamma radiation at a time.

From there, S. caninervis samples were then moved into a simulated Martian environment, complete with UV radiation, atmospheric pressures, and low-oxygen levels consistent with the planets surface. Some moss fared better than others (plants dehydrated by as much as 98-percent bounced back more easily than fully hydrated ones, for example), but S. caninervis generally proved extremely capable of enduring Mars.

Researchers believe much of its resilience is owed to the evolutionary history of moss itself. Mosses are thought to be the very first embryophytes to spread across Earth on land, but in order to do that, the team writes these diminutive pioneer plants have evolved innate resistance to drought, UV radiation, and temperature fluctuations.

This is thanks to an intricate interplay of mosses physiological, morphological, and molecular adaptations. The twisting leaves of S. caninervis, for example, conserves water by reducing surface area and transpiration, while its cellular makeup is designed to handle extreme desiccation. At a molecular level, S. caninervis also contains high amounts of sucrose and maltose, even after intense stress. This helps it to maintain its cellular architecture under duress, with the sugars then offering the energy reserves needed to recover once conditions improve.

[Related: To create a small Mars colony, leave the jerks on Earth.]

Its important to note that even with all these impressive traits, its unlikely S. caninervis or most other mosses will ever become food staples for humans on Mars. That said, genetically engineering other plants to include these extremotolerant attributes may offer a promising way to strengthen them for Martian living. But even without any real nutrition value, moss like S. caninervis may help boost oxygen production, soil health, and carbon sequestration efforts, all of which will be necessary for humans to eventually thrive on Mars.

Although there is still a long way to go to create self-sufficient habitats on other planets, we demonstrated the great potential of S. caninervis, a model moss plant, as a pioneer plant for growth on Mars, the team writes.

Going forward, they hope to soon send S. caninervis samples to the moon, or even Mars, to begin testing real world tests.

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This inedible, indestructible moss may help humans thrive on Mars - Popular Science

In a meteor crater on the red planet, a solitary robot is moving about. Right now it is probably collecting soil samples with a drill and a robotic arm, as it has quite a habit of doing. NASA's Curiosity rover has been active on Mars as the extended arm of science for nearly 12 years, and it continues to make discoveries that surprise and challenge scientists' understanding of both Mars and our own world here on Earth.

Most recently, the discovery of sedimentary organic material with particular properties has had many researchers scratching their heads. The properties of these carbon-based materials, in particular the ratio of its carbon isotopes, surprised researchers.

Organic materials with such properties, if found on Earth, would typically be a sign of microorganisms, but they can also be the result of non-biological, chemical processes. The find obviously had researchers scrambling for a clear answer, but nothing seemed to fit.

However, for the research collaboration behind a new study published inNature Geoscience, there has been little hair scratching and much enthusiasm.

In fact, the discovery on Mars provided the missing piece that made everything fall into place for this group of researchers from the University of Copenhagen and the Tokyo Institute of Technology.

As co-author and chemistry professor Matthew Johnson puts it, it is "the smoking gun" needed to confirma decade-old theory of his about so-called photolysis in Mars' atmosphere.

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With the Curiosity sample, the new research is able to prove with reasonable certainty that the Sun broke down CO2in the Martian atmosphere billions of years agoas the old theory predicted. And that the resulting carbon monoxide gradually reacted with other chemicals in the atmosphere synthesizing complex moleculesand thus providing Mars with organic materials.

Such carbon-based complex molecules are the prerequisite of life, the building blocks of life one might say. So, this it is a bit like the old debate about which came first, the chicken or the egg. We show that the organic material found on Mars has been formed through atmospheric photochemical reactionswithout life that is. This is the 'egg', a prerequisite of life. It still remains to be shown whether or not this organic materialresulted in life on the Red Planet." said Johnson and continued:

Additionally because Earth, Mars, and Venus had very similar CO2-rich atmospheres long ago when this photolysis took place, it can also prove important for our understanding of how life began on Earth, said Professor Matthew Johnson from the Department of Chemistry at the University of Copenhagen.

12 years ago Johnson and two colleagues used simulations based on quantum mechanics to determine what happens when a CO2-rich atmosphere is exposed to the UV light of the Sun, in a process known as photolysis.

Basically, on Mars around 20 percent of the CO2 is split into oxygen and carbon monoxide. But carbon has two stable isotopes: carbon-12 and carbon-13. Usually, they are present in a ratio of one carbon-13 for every 99 carbon-12. However, photolysis works faster for the lighter carbon-12, so the carbon monoxide produced by photolysis has less carbon-13 (is depleted), and the leftover CO2 has more (is enriched).

Because of this, Johnson and his colleagues were able to make very precise predictions of the ratio of carbon isotopes after photolysis. And this gave them two distinctive fingerprints to look for. One of these was identified in a different Martian sample, years ago.

We actually have a piece of Mars here on Earth, which was knocked off that planet by a meteorite, and then became one itself, when it landed here on Earth. This meteorite, called Allan Hills 84001 for the place in Antarctica where it was found, contains carbonate minerals that form from CO2 in the atmosphere. The smoking gun here is that the ratio of carbon isotopes in it exactly matches our predictions in the quantum chemical simulations, but there was a missing piece in the puzzle. We were missing the other product of this chemical process to confirm the theory, and that's what we've now obtained," says Matthew Johnson.

The carbon in the Allan Hills meteorite is enriched in carbon-13, which makes it the mirror image of the depletion in carbon-13 that has now been measured in the organic material found by Curiosity on Mars.

The new study has thus linked data from two samples, which researchers believe have the same origin in Mars' childhood but were found more than 50 million kilometers apart.

There is no other way to explain both the carbon-13 depletion in the organic material and the enrichment in the Martian meteorite, both relative to the composition of volcanic CO2 emitted on Mars, which has a constant composition, similar as for Earths volcanos, and serves as a baseline, said Johnson

Because the organic material contains this isotopic fingerprint of where it came from, researchers are able to trace the source of the carbon in the organic material to the carbon monoxide formed by photolysis in the atmosphere. But this also reveals a lot about what happened to it in between.

This shows that carbon monoxide is the starting point for the synthesis of organic molecules in these kinds of atmospheres. So we have an important conclusion about the origin of lifes building blocks. Although so far only on Mars, said Matthew Johnson.

Researchers hope to find the same isotopic evidence on Earth, but this has yet to happen, and it could be a much bigger challenge because our geological development has changed the surface significantly compared to Mars, Johnson explains.

"It is reasonable to assume that the photolysis of CO2 was also a prerequisite for the emergence of life here on Earth, in all its complexity. But we have not yet found this smoking gun material here on Earth to prove that the process took place. Perhaps because Earth's surface is much more alive, geologically and literally, and therefore constantly changing. But it is a big step that we have now found it on Mars, from a time when the two planets were very similar," says Matthew Johnson.

- This press release was originally published on the University of Copenhagen - Faculty of Science website and has been edited for style and clarity

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Organic Material from Mars Reveals the Likely Origin of Lifes Building Blocks - Lab Manager Magazine

From strange rocks on Mars to interstellar visitors, the cosmos is filled with mysteries that captivate and confound scientists and stargazers alike.

Over the years, numerous odd and unexplained objects have been discovered across the universe, challenging our understanding of the world we live in.

One of the most recent finds is a peculiar rock on Mars, which has left researchers puzzled over its origin and composition.

This discovery adds to a growing list of cosmic conundrums, encouraging scientists to dig deeper into the unknown.

Here, The National explores some of the most intriguing discoveries that the universe has to offer.

Astronomers detected a bizarre object passing through the solar system in 2017.

Named 'Oumuamua, a Hawaiian word that translates to a messenger from afar arriving first, it was the first object confirmed to have visited from another solar system.

Its elongated shape and unusual trajectory prompted immediate interest. Unlike typical asteroids or comets found within the solar system, 'Oumuamua did not behave as expected.

It showed non-gravitational acceleration, meaning it moved more quickly than gravity alone could explain, with scientists speculating about its nature.

'Oumuamua is of great interest, said Dimitra Atri, an astrophysicist at New York University Abu Dhabi.

It had a very unusual shape about 400 metres long and about 40 to 50 metres wide, unlike anything that weve seen before.

It also got a speed boost while it was near the Sun, which was likely due to outgassing, sort of like a rocket thruster when material (most likely hydrogen ice) on the object evaporated from sunlight.

Initially, some researchers suggested that 'Oumuamua might be a fragment of a comet pushed out from another star system.

However, its lack of a visible coma the cloud of gas and dust that surrounds a comet's nucleus puzzled scientists.

Others proposed that it could be a piece of an interstellar asteroid, but its rapid rotation and unusual shape made this explanation less likely.

One of the most interesting theories came from astronomers at Harvard University, who speculated that 'Oumuamua might be a probe sent by an advanced extraterrestrial civilisation.

Nasas Dawn spacecraft arrived at Ceres, the largest object in the asteroid belt between Mars and Jupiter, in 2015.

As the spacecraft approached Ceres, it captured images of unusual bright spots on the dwarf planet's surface.

These bright areas, in the Occator Crater, stood out against Ceres' dark and rocky terrain.

Scientists initially thought that the bright spots might be ice deposits reflecting sunlight.

But detailed analysis revealed that the spots are made of sodium carbonate, a type of salt.

This discovery was surprising because it suggested that Ceres had experienced hydrothermal minerals that formed from hot liquids activity in the past.

The presence of these salts indicates that liquid water once existed beneath the surface, potentially providing a habitable environment for microbial life.

The exact origin of the bright spots is still being studied. Some scientists think they were formed by salty water erupting from inside Ceres, which then evaporated, leaving salt behind.

Others believe that asteroid or comet impacts might have caused the release of this underground salty water.

Saturn, the second largest planet in the solar system, is known for its stunning rings and moons.

But one of its most peculiar features is a massive hexagonal cloud pattern at its north pole.

First observed by the Voyager missions in the 1980s, this hexagonal storm has intrigued the science community for decades.

The hexagon is a vast structure, spanning nearly 32,000km across, and it rotates with the planet's atmosphere.

Unlike the more familiar circular storms seen on other planets, such as Jupiter's Great Red Spot, Saturn's hexagon maintains its six-sided shape with remarkable precision.

This geometric storm is composed of a strong jet stream, with wind speeds reaching up to 321kph.

Researchers have proposed several theories to explain the hexagon's formation.

One study suggests that the shape is due to atmospheric rotation speeds at various latitudes, creating an unusual wave pattern.

Nasas Viking 1 orbiter took a photo of a region on Mars called Cydonia in 1971.

In this area, one rock formation looked like a human face, which quickly sparked speculation.

Some social media users even thought it might be a monument built by an ancient Martian civilisation.

But, later missions, including Nasa's Mars Global Surveyor and the European Space Agency's Mars Express, took clearer pictures that showed the face was just a natural rock formation.

The original photo's lighting and shadows made it look like a face, but it was an illusion.

Last month, a strange rock was discovered on Mars by Nasas Perseverance rover.

It has a highly reflective surface that glitters under the Martian sun.

Studies showed that it might contain high concentrations of metals not commonly found on the Red Planet.

The rock's location, at the edge of a dried-up lake bed, suggests it might have been transported by ancient water flows.

Scientists are eager to study it in more detail, as it could offer clues on Marss geological history and water activity that took place long time ago.

Updated: July 03, 2024, 3:00 AM

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Mysteries of space: From a 'face' on Mars to a visitor from another solar system - The National

In the wake of being informed that Utah State University intends to terminate his employment, Aggies football coach Blake Anderson retained the services of college sports attorney Tom Mars, ESPNs Pete Thamel reported Tuesday afternoon.

In a statement to ESPN, Mars said that USU faces an uphill battle to fire Anderson with cause.

Stiffing a head coach by blaming him for what his supervisor was supposed to do is a novel approach, but that theory will never hold up in court, Mars told Thamel.

Utah State alleged Tuesday that an external investigation determined that Anderson committed actions in the spring of 2023 that violated both his employment agreement and university policy and that were grounds for termination with cause.

Deputy athletic director Jerry Bovee and USU football director of player development Austin Albrecht were also dismissed from USU for alleged violations of university policies related to the reporting of sexual and domestic violence and failures of professional responsibilities, as the Deseret News previously reported.

To comply with Utahs public records laws and Utah State University policies, the university noted that it cannot release any additional information until all opportunities (for Anderson) to respond and/or appeal have expired, which is a minimum of 14 days.

Mars is a nationally recognized attorney, with experience as a crisis consultant for companies, executives, and public officials, according to his website.

In the sports realm, Mars has dealt primarily with the NCAAs transfer rules, though he notably represented former Ole Miss football coach Houston Nutt during a suit Houston Nutt v. University of Mississippi in which Nutt alleged a breach of contract by the University of Mississippi. Nutt got an undisclosed settlement in that case, along with a public apology from Ole Miss.

Anderson has been the head football coach at Utah State since late in 2020, when he was hired by then athletic director John Hartwell to replace Gary Andersen.

Anderson led USU to a Mountain West Conference championship in his first year in 2021, then followed up that performance with back-to-back 6-7 campaigns.

USU president Elizabeth Cantwell and athletic director Diana Sabau released a statement to university faculty and staff about Andersons pending termination on Tuesday.

As leaders, we are responsible for ensuring allegations of USU policy violations are investigated. Todays actions are the result of a thorough external investigation, and we believe the evidence demands immediate action. Our job is to fearlessly hold ourselves and others accountable for their conduct and to make sure that, for the sake of our students and our community, we are living the values of our university.

While recognizing the impact of these decisions on our student-athletes and football program, we will continue to take the steps necessary to deliver a respectful, transparent and winning culture at Utah State University.

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Blake Anderson responds to allegations, pending termination - Deseret News

ESA has published a new image obtained by the Mars Express spacecraft. The centerpiece of the image is an amazing feature: a dark uneven scar cutting through the terrain at the foot of a giant volcano.

This scar is known as Aganippe Fossa. Its length is about 600 kilometers. It is a graben a lowered area relative to the surrounding terrain with steep walls on either side.

Aganippe Fossa crosses the foot of one of the largest volcanoes on Mars, Arsia Mons. It is located in the region of the Tharsis: a vast highland that is home to the Red Planets largest supervolcanoes.

Arsia Mons has a base diameter of 435 km and rises above the surrounding plains by more than 9 km. And if measurements are made relative to the zero altitude of Mars, it will be 19 km. In comparison, the highest dormant volcano on Earth, Ojos del Salado (it is located on the border of Argentina and Chile) reaches a height of less than 7 kilometers.

Scientists still dont know how and when the Aganippe Fossa originated. But it seemed likely that it was formed when magma beneath the colossal mass of volcanoes in the Tharsis caused the crust of Mars to stretch and crack.

The Mars Express image captures two different types of terrain: so-called hummocky terrain, consisting of many irregularly shaped hills and valleys clustered together, and lobate terrain, consisting of gentle cliffs and rocky debris.

These reliefs are characteristic of the ring-shaped aureole of Arsia Mons, a 100,000 km2 disk around the base of the volcano, possibly associated with ancient glaciers. Interestingly, the aureole only formed on the northwestern flank of the volcano, probably because prevailing winds from the opposite direction influenced where the ice settled over time.

Wind-blown dust and sand has also impacted this region of Mars, creating interesting zebra-like patterns. They occurred when dark material was deposited on lighter colored soil and vice versa. The surface also shows traces of lava flows formed during volcanic activity.

Earlier we told you about how the Mars Express photographed the inhabitants of Inca City.

According to ESA

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Mars Express photographs a snake-shaped structure on Mars - The Universe. Space. Tech

Close-up of S. caninervis. Credit: John Game/Wikimedia Commons

At first glance, Syntrichia caninervis looks like a dust bunny or a gray, low-lying shrub. But this humble moss is known for surviving harsh conditions that most plants find uninhabitable, like the aridity of Antarctica and the Mojave Desert. Inspired by the plant's resilience, researchers have pushed S. caninervis to its limits and found that it can endure extreme cold, drought, and high levels of radiationthe conditions a plant would need to withstand to grow food on Mars.

In a paper published Monday in the scientific journal The Innovation, researchers at the Chinese Academy of Sciences (CAS) write that S. caninervis is a "promising pioneer plant for colonizing extraterrestrial environments." The moss is considered extremotolerant, a term frequently applied to tardigrades to testify to their near-invincibility. While most mosses require shade and abundant moisture to flourish, S. caninervis does things differently. It's evolved to withstand 98% water loss, conduct photosynthesis while covered with snow, and survive extremely low and extremely high temperatures, placing it "among the most stress tolerant organisms."

It just so happens that researchers have spent the last decade or so eagerly searching for ways to grow plants in space. Whether by sowing seeds in lunar soil or farming inside a simulative Mars habitat, everyone from NASA and the European Space Agency to educational institutions and Elon Musk wants to make extraterrestrial agriculture happen. It can't be overstated that this is a tough thing to succeed at; while we know Mars and the Moon don't offer the nurturing conditions we enjoy here on Earth, finding (or producing) the right plant for the job is another task entirely.

But what about reverse-engineering a Mars-worthy plant? Recognizing how uniquely rugged S. caninervis can be, the arid ecology experts at CAS decided to see how much strain the moss could survive. First, they obtained S. caninervis samples, some of which were left fully hydrated while others were intentionally dehydrated. The researchers placed samples from both groups in a freezer at -80 degrees Celsius (-112 Fahrenheit) for three to five years, in a liquid nitrogen storage tank at -196 Celsius (-320 Fahrenheit) for 15 to 30 days, and 500 to 16,000 grays of gamma radiation. Then, they transferred the samples to a sandbox subjected to Mars-like pressures, gases, and UV radiation.

Credit: Li et al, The Innovation/DOI 10.1016/j.xinn.2024.100657

Samples from all three exposure groups (freezer, nitrogen storage, and gamma radiation) successfully generated new branches. While some groups thrived more easily than othersdehydrated plants had an easier time recovering than plants that started out fully hydratedS. caninervis proved capable of bouncing back after enduring extremely low temperatures and levels of radiation similar to those they'd experience on Mars. The researchers also noted that an extra two years of exposure to cold temperatures didn't significantly affect S. caninervis regeneration.

Make no mistake: Like most mosses, S. caninervis isn't tasty and wouldn't make it onto a Martian menu. But, as the CAS researchers point out, S. caninervis could drive efforts to genetically engineer edible plants resistant to the Red Planet's harsh environment. The moss also appears to be a "promising candidate" in contributing to oxygen production, carbon sequestration, and soil fertility on extraterrestrial landsthree pieces of the long-term Mars colonization puzzle.

"Although there is still a long way to go to create self-sufficient habitats on other planets, we demonstrated the great potential of S. caninervis, a model moss plant, as a pioneer plant for growth on Mars," the researchers write. "Looking to the future, we expect that this promising moss could be brought to Mars or the Moon to further test the possibility of plant colonization and growth in outer space."

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Desert Moss Could Hold the Key to Growing Plants on Mars - ExtremeTech

NASA has recently published two new white papers detailing specific areas of its Moon to Mars architecture efforts, providing insights into the agencys strategy for long-term human exploration of deep space.

The first white paper, titled Lunar Mobility Drivers and Needs, addresses the challenges and requirements for moving cargo and assets on the lunar surface. This includes considerations from landing sites to areas of use and factors that significantly impact mobility systems.

The paper outlines the need for robust mobility solutions to transport essential equipment, scientific instruments, and other assets across the rugged and varied terrain of the moon. It also discusses the importance of developing vehicles and technologies capable of withstanding the harsh lunar environment, including extreme temperatures and radiation.

The second paper, Lunar Surface Cargo, examines the projected needs and identifies current capability gaps for transporting cargo to the moons surface. This document delves into the logistical challenges of delivering large quantities of supplies, building materials, and other resources necessary for sustained human presence on the moon.

It highlights the importance of developing efficient and reliable cargo transport systems that can operate autonomously or with minimal human intervention. The paper also explores potential innovations in packaging, handling, and deploying cargo to ensure it reaches its intended destination safely and efficiently.

These white papers are part of NASAs ongoing efforts to communicate essential information to its stakeholders, including U.S. industry, academia, international partners, and the NASA workforce. Typically, NASA releases a series of technical documents at the end of its annual analysis cycle, but these mid-cycle releases provide timely insights into critical areas of interest.

By sharing these findings, NASA aims to foster collaboration and innovation across the space exploration community. The documents serve as a foundation for discussions on how to address the identified challenges and leverage emerging technologies and capabilities to achieve mission objectives.

Under NASAs Artemis campaign, the agency aims to establish a sustainable presence on the moon, including landing the first woman, the first person of color, and international partner astronauts on the lunar surface. These efforts are foundational for preparing human expeditions to Mars.

The Artemis program is designed to build a robust infrastructure on the moon that will support long-duration missions and serve as a testing ground for the technologies and procedures needed for Mars exploration. This includes the development of habitats, power systems, and life support technologies that can be scaled and adapted for use on Mars.

The release of these white papers highlights the ongoing work and planning required to achieve NASAs ambitious goals. Moving forward, NASA will continue to refine its strategies and address the identified capability gaps to ensure the success of future lunar and Martian missions.

The agency plans to leverage the latest advancements in robotics, artificial intelligence, and autonomous systems to enhance the efficiency and safety of space operations. Additionally, NASA will focus on developing sustainable practices for resource utilization, such as in-situ resource utilization (ISRU) technologies, which enable the extraction and use of local materials to support human activities on the moon and Mars.

For more detailed information, the white papers can be accessed through NASAs official channels, providing a deeper understanding of the challenges and solutions proposed for lunar and Mars exploration. These documents offer valuable insights into the technical and operational considerations that will shape the future of human spaceflight. They also serve as a roadmap for the continued development of capabilities that will enable humanity to explore and settle new frontiers.

These white papers underscore NASA's commitment to advancing human space exploration and addressing the complex logistical challenges of establishing a sustainable presence on the moon and preparing for future missions to Mars. By identifying and addressing the critical needs for mobility and cargo transport, NASA is laying the groundwork for a new era of exploration that will expand our understanding of the universe and inspire future generations of explorers.

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NASA Releases New White Papers on Moon to Mars Architecture - The Daily Galaxy --Great Discoveries Channel

Scientists have found promising new evidence that could help make Mars eventually habitable for humans.

Alongside the Moon, Mars has had a lot of interest from scientists here on Earth.

While it's very unlikely that we'll ever live on the Moon, there are hopes that Mars will eventually be habitable for humans.

It won't be a long-term plan for humankind however as the Red Planet was recently deemed unsafe for us to live for longer than four years.

Despite the potential knock back, scientists are still testing theories that could help us eventually make a home on Mars and they've recently made a huge breakthrough.

Scientists from the Chinese Academy of Sciences say they have found Syntrichia caninervis - a common kind of moss that's able to grow in extreme desert environments - is able able to withstand Mars-like conditions, including drought, high levels of radiation and extreme cold.

While moss isn't something that's edible, it could prove hugely beneficial in making Mars' atmosphere more habitable.

Prof Stuart McDaniel, an expert on moss at the University of Florida but was not involved in the study, explained to The Guardian: "Cultivating terrestrial plants is an important part of any long-term space mission because plants efficiently turn carbon dioxide and water into oxygen and carbohydrates essentially the air and food that humans need to survive.

"Desert moss is not edible, but it could provide other important services in space."

As well as surviving Mars-like conditions, the moss was said to have rapidly recovered from almost complete dehydration.

Other moss samples were placed in a 80C (112F) freezer for three or five years and a 196C (-321F) liquid nitrogen storage tank for 15 or 30 days before being moved over to sterilized sand for recovery, IFL Science reports.

Remarkably the plants recovered quite well from being exposed to such harsh conditions and had a reintegration rate of around 95 percent that of control plants.

The moss was also exposed to the kind of extreme radiation it would face on the red planet as well, which the samples survived.

There are now hopes that the moss will be one day be tested on Mars or the Moon to look into possibility of plant colonisation and growth in outer space.

While the study doesn't confirm that the moss could definitely survive on the Red Planet, it's certainly a step in the right direction.

"This extremotolerant moss could be a promising pioneer plant for Mars colonisation," Prof Edward Guinan of Villanova University shared.

Noting that more research is needed, he went on: "We have a long way to go, but this lowly desert moss offers hope for making small portions of Mars habitable for humankind in the future."

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Scientists discover plant that could grow on Mars and pave the way for human life on the planet - UNILAD