If we were to make the Red Planet Earth-like enough to host life, we would probably have to use tiny bonds of iron and aluminum to raise the temperature. In this article, we will discuss the issue that Landing Mars may be easier than scientists think.
Landing Mars may be easier than scientists think
One of the classic subjects of science fiction stories is the terraforming of the planet Mars; It means to warm this cold world of our neighbor so that it can support human civilization. A recent study published in the journal Science Advances suggests that this idea may not be so far-fetched.
Researchers have found that injecting tiny particles into the Martian atmosphere could warm the planet by more than 10 degrees Celsius in a matter of months, enough to sustain liquid water. The plan proposed by scientists requires almost two million tons of particles per year, But they can be produced from materials found in Mars dust.
Although water is thought to have flowed on Mars billions of years ago, today a small amount of it remains frozen in the polar ice caps and underground. The Red Planet, with its thin atmosphere and little light received from the sun, has an average temperature of about minus 62 degrees Celsius and is colder than most places on Earth. As a result, making Mars suitable for growing agricultural crops, maintaining liquid water, and of course, the permanent presence of humans, requires a significant increase in temperature.
Injecting tiny particles into the atmosphere of Mars can heat the planet by more than 10 degrees Celsius within a few months.
Contrary to expectations, researchers think they can transform the Red Planet using the same mechanism that causes global warming on Earth. “The general idea is to artificially create a greenhouse,” says Samaneh Ansari, a doctoral student at Northwestern University and lead author of the study. Scientists are trying to find a substance that, when injected into the atmosphere in large quantities, traps heat like water vapor and carbon dioxide on Earth.
In a previous study, researchers had suggested releasing chlorofluorocarbons, or ozone-destroying compounds that were once used in spray cans like hair spray, into the atmosphere. Another study suggested placing tiles of silica aerogel, a clear, lightweight solid, on the surface of Mars to trap heat in the planet’s soils while blocking harmful ultraviolet rays.
But the main obstacle in both approaches will be the cost. Dispersing chlorofluorocarbons on the surface of Mars and silica gels require human production processes, and large quantities of each material must be transported from Earth to Mars, which is almost impossible with today’s rockets.
On the other hand, Ansari and his colleagues wanted to test the capacity of one of the abundant Martian materials, dust, to trap heat. Martian dust is rich in iron and aluminum, which gives it its iconic red color; But the microscopic size and almost spherical shape of dust particles are not suitable for absorbing radiations or reflecting them to the surface.
As a result, the researchers explored a different option: using the iron and aluminum found in the soil to make 9-micrometer-long bonds that are almost twice the size of Martian dust particles and smaller than commercially available wreaths.
Ansari designed a simulation to test how theoretical particles interact with light, and found “big unexpected results” in how infrared radiation is absorbed from the surface and scattered by Mars. Absorption and scattering are key factors that determine whether an airborne particle is capable of causing a greenhouse effect.
Ansari’s colleagues at the University of Chicago and the University of Central Florida then fed the theoretical particles into computer models of the Martian climate. They investigated the effect of annual injection of two million tons of grafted particles at a height of 10 to 100 meters above the surface. Particles at these altitudes are carried to higher distances by turbulent winds and leave the atmosphere 10 times slower than natural Martian dust.
The researchers found that despite the need for five thousand times less materials compared to other proposed plans, Mars can be heated by approximately 10 degrees Celsius within a few months. Two million tons of particles is still the size of almost 6 Empire State Buildings and nearly 0.1% of the industrial metals mined in the earth per year; But since the raw materials for bonds are on Mars, people can mine them on the Red Planet, eliminating the need for transportation from Earth.
Rising temperatures are not a “magic switch” to make Mars habitable
“Raising the temperature is just one of the things we have to do to live unaided on Mars,” said Juan Aldi, a planetary science researcher at the Open University in England who was not involved in the study. For example, the amount of oxygen in the atmosphere of Mars is only 0.1%, while it is 21% on Earth. The pressure on Mars is 150 times lower than on Earth, which makes human blood boil.
Mars also has no ozone layer; This means that there is no protection against the harmful ultraviolet rays of the sun. Additionally, even after warming, Martian soils may still be too salty or toxic to grow crops. In other words, rising temperatures aren’t “some kind of magic key” that will make Mars habitable.
But the mentioned obstacles do not stop Ansari and his colleagues from investigating further. Next, they hope to build and test their proposed links in the lab, while also investigating the effects of shapes, sizes, and other materials such as carbon and magnetite.
Researchers admit that they are unlikely to perform planetary-scale climate engineering on Mars anytime soon; But Edwin Kite, a planetary scientist at the University of Chicago and one of the authors of the study, said: “Earth formation studies also show how important it is to study Earth. “Can we understand climate and ecosystems well enough to build them elsewhere?”