一项新的研究基于好奇号探测器收集的数据，分析了盖尔陨石坑中富含碳的矿物质的同位素组成，为火星古代气候环境提供了新的见解。研究发现，这些矿物质的同位素组成表明，盖尔陨石坑经历了一系列交替的湿润和干旱时期，或存在着含盐冰的条件，这些环境可能不适合地表生命存在，但可能存在地下生物圈或在碳酸盐形成之前存在的地表生物圈。研究人员认为，火星古代气候环境可能不适合生命存在，但存在着地下生物圈或在碳酸盐形成之前存在的地表生物圈的可能性。

🤔 **碳同位素分析：揭示盖尔陨石坑古代气候环境** 这项研究利用好奇号探测器收集的数据，分析了盖尔陨石坑中富含碳的矿物质的同位素组成。研究发现，这些矿物质的同位素组成表明，盖尔陨石坑经历了一系列交替的湿润和干旱时期，或存在着含盐冰的条件。这种环境可能不适合地表生命存在，因为大多数水会被冻结，无法用于化学或生物过程，而且存在极高的盐度，对生命很不利。 研究人员通过对样本进行加热，分析释放的气体来进行同位素测量。结果显示，样本中的重同位素值远高于地球上碳酸盐矿物质的重同位素值，而且是所有火星材料中最高的碳和氧同位素值。这表明，这些矿物质可能是在经历了大量蒸发的情况下形成的，这进一步支持了盖尔陨石坑经历了交替的湿润和干旱时期或存在着含盐冰的条件。

🧐 **火星古代生命存在的可能性：地下生物圈和早期地表生物圈** 尽管研究结果表明盖尔陨石坑的古代环境可能不适合地表生命存在，但研究人员并没有完全排除生命存在的可能性。他们认为，可能存在着地下生物圈或在碳酸盐形成之前存在的地表生物圈。 地下生物圈可能存在于火星的深层洞穴中，这些洞穴由古代火山喷发形成，可能存在液态水，以及长期死亡的细菌或真菌，甚至可能存在现存的微生物生命。地球上的洞穴中存在着复杂的生态系统，其中栖息着以岩石为食并将其转化为生命能量的极端微生物。因此，许多天体生物学家希望探索火星的洞穴，以寻找生命的迹象。

🚀 **火星生命探索的未来方向：洞穴探测和样本返回** 这项研究结果进一步表明，火星的古代环境可能比之前认为的更加极端，但这并不意味着生命就不可能存在。未来，科学家将继续探索火星，寻找生命的迹象，包括对洞穴进行探测，以及将样本返回地球进行分析。 火星探测任务将继续进行，包括洞穴探测和样本返回，以进一步探索火星的奥秘，寻找生命的迹象。科学家们希望通过这些任务，能够揭开火星生命之谜，并为人类探索宇宙提供新的启示。

Cold, dry, and barren: Mars doesn't look like it could be a haven for life — at least not the kind humans are familiar with. 

Despite the Red Planet's appearance, scientists have wondered for decades about the possibility of microbial life inhabiting Mars in the distant past. Now a new study, based on data collected by NASA's Curiosity rover, is peeling back another layer of the mystery. For the first time, researchers measured the isotopic composition of carbon-rich minerals found in Gale Crater, a region laced with dried rivers and gullies and being explored by the rover.

The findings Curiosity beamed millions of miles back to Earth were not optimistic, at least in terms of the potential for life above ground. 

"Our samples are not consistent with an ancient environment with life (biosphere) on the surface of Mars," said David Burtt, lead author of the study, in a statement, "although this does not rule out the possibility of an underground biosphere or a surface biosphere that began and ended before these carbonates formed."

The new paper, published in the National Proceedings of the National Academy of Sciences on Monday, suggests two possible ways carbon-rich minerals could have formed at Gale crater: a series of alternating wet and dry periods at the site or salty-ice conditions. These two different ancient climate scenarios could be summed up as bleak and bleaker when it comes to supporting life. 

In an environment that swings like a pendulum from wet to dry, the region would intermittently shift from more habitable to less habitable, said Jennifer Stern, a co-author. In frigid temperatures near the planet's equator, the environment would be hostile for living things because most water would be frozen and inaccessible for chemistry or biology.

"And what is there is extremely salty and unpleasant for life," she added in a statement.

This isn't the first time scientists have theorized these possible climate scenarios for ancient Mars. Computer modeling of the planet, based on the presence of certain minerals and rock formations, have led scientists down this path before, but this is the first time they've had isotopic evidence from Martian rocks to bolster those ideas. 

Scientists have sought life on Mars since the first spacecraft touched down on its surface in 1976. Mounting evidence from robotic explorers, especially from Curiosity and its twin Perseverance, has shown the Red Planet to have once been warmer and wetter, perhaps more than 3 billion years ago. 

The rover pair had a highly productive summer, including Perseverance's discovery of a spotted rock with the most compelling signs of ancient dead Martian life yet, though a sample would need to be shipped back to Earth for confirmation. A research team also recently published more evidence of a vast ocean of water below the planet’s surface. And where there's water on Earth, there's often life.

Scientists are interested in Mars' carbon-rich rocks because they are like climate time capsules. Their minerals can hold onto clues about the environments in which they formed, such as the temperature and acidity of the water, and the ingredients within the water and air. Curiosity made the isotope measurements by heating the samples to over 1,600 degrees Fahrenheit and analyzing the released gasses. 

Isotopes are versions of an element with different masses. As water evaporates, light versions of carbon and oxygen are more likely to escape into the atmosphere, while heavier versions tend to remain and get incorporated into rocks. 

The isotope values of the sampled materials indicate lots of evaporation, the team says, suggesting that they probably formed in a climate that could only support transient liquid water — that is, water that comes from melted ice when temperatures rise and the surface pressure is right. 

The heavy isotope values in the samples are much higher than what’s seen on Earth for carbonate minerals. Furthermore, they are the heaviest carbon and oxygen isotope values recorded for any Martian materials. Although evaporation can cause oxygen isotope changes on Earth, the changes measured in the Martian samples were two to three times greater, Burtt said. 

"The fact that these carbon and oxygen isotope values are higher than anything else measured on Earth or Mars points towards a process (or processes) being taken to an extreme," he said. 

But this doesn't discount the possibility of life. The Red Planet appears to have a network of deep caves formed by ancient volcanic vents. Within them could be liquid water, traces of long-deceased bacteria or fungi, or, some scientists believe, perhaps even existing microbial life. 

Caves can host complex ecosystems, inhabited by extremophiles that munch on rocks and convert the material into energy for life. Because of this, many astrobiologists want nothing more than to go spelunking on Mars.