Life on Mars: What do we need to do it? - 麻豆官网首页入口 Bitesize

Until the 20th Century, travelling to, let alone living in space was the domain of science fiction. Nowadays, life on Mars feels genuinely within our grasp.

The biggest challenge facing people who want to settle on the red planet has always been getting there in the first place. Any rocket launching from Earth needs to do so when both our planet and Mars are aligned in orbit, and therefore the distance to travel is at its shortest. But that doesn鈥檛 mean it鈥檒l be quick - the most recent rover to go to Mars, Perseverance, took seven months to get there.

2020 Mars Perseverance on surface of Mars — Image caption,
If we persevere just as this rover has, we may be able to live on Mars one day

But space travel is developing at such a pace that it鈥檚 possible human missions to Mars will start happening in the next few decades. So if and when we get there, what else do we need to think about if we want to make it our home? We spoke to two scientists to find out.

Blood, sweat and tears

The first thing that needs to be sorted when building a settlement on Mars is exactly that - building the settlement. As Dr Aled Roberts from the University of Manchester explains: 鈥淥ne of the big challenges to living on other planets and travelling in space is there's a lot of radiation.鈥�

Radiation is extremely damaging to your health. On Earth, we鈥檙e shielded from this radiation by our thick atmosphere and the planet鈥檚 magnetic field, but travellers to Mars will need to build things with thick enough walls to keep them safe.

Flying materials to Mars is too expensive, so any construction on the planet will need to be made out of things they can find there. Luckily, he says the dust that covers the surface of Mars is good at shielding from radiation, but without anything to bind it together, it鈥檚 pretty useless.

Inspiration struck when Dr Roberts was working on a different project, trying to make synthetic, protein-based glues. These kinds of glues have been made all throughout history, from egg whites, cheeses, and animal parts, including their blood.

Spider in the centre of its web — Image caption,
Spider silk isn't just sticky, it's strong too - gram for gram, it is actually stronger than steel!

Dr Roberts and the team were looking in particular at spider silk 鈥� a very strong material. They compared it to a common protein found in cow blood, which they weren鈥檛 expecting to be as sticky, but it turned out to be even more so.

Of course, as Dr Roberts explains, 鈥渋t's not really feasible to take cows to Mars.鈥� But he had an idea: why not try and get the protein from humans that are going to be there anyway? After mixing a protein in human blood with Mars dust, voila! Astro-Crete 鈥� a concrete-like substance that can be made on the Red Planet 鈥� was born.

The reason it鈥檚 so strong is because of the amount of it contains. The team later realised also has many hydrogen bonds, so they added that to Astro-Crete and made it even stronger.

However, Dr Roberts says that the health and safety risks in extracting the protein are too great to produce the material on a large scale. In its current form, he thinks it could be used as an emergency building material, if any future Martian settlement was damaged.

Food, glorious food

Food is another big issue that needs to be tackled. Earth has everything we need for food growth - soil, sunlight (but not too much), and rain. However, the conditions on Mars aren鈥檛 quite as friendly to crops, as planetary geologist Kevin Cannon explains: 鈥淭he main challenge is that nothing can be grown or produced outdoors because it鈥檚 simply too cold and the atmospheric pressure is too low. All food will have to be produced indoors in a heated and pressurized environment."

Hydroponics — Image caption,
While soil might be an issue, water shouldn't be - Cannon says the planet has lots of ice deposits that can be melted down and pumped from the ground

Our diets will also likely look a little different to what we鈥檙e used to, although Cannon says 鈥渨e should be able to produce most of the same foods we eat on Earth.鈥� For example, animals won鈥檛 be able to be reared for meat in the same way as they are on Earth, so any meat we eat will have to be lab grown. We might also be eating more insects, as they don鈥檛 take up nearly as much room and are very nutritious.

Soil is an other big challenge, as the surface of Mars is very different to Earth, and therefore doesn鈥檛 contain the same nutrients that plants we eat need. If we rely on soil, it would involve transporting a lot of it from Earth to Mars, which is time-consuming and expensive.

Instead, Cannon says he would look at soil-less solutions like , or growing plant tissues from cells as opposed to growing whole plants.