ISRO, IISc researchers develop a way to make bricks from Martian soil

[INDIAPOSITIVE]

In Ridley Scott’s 2015 sci-fi film, The Martian, botanist Mark Watney, who is trapped on the red planet, creates a garden using local soil and the crew’s bio-waste, as well as water from rocket fuel. While vegetable gardens on Mars are still a distant dream, building houses may not be a problem — should humans colonise the planet.

Researchers from the Indian Space Research Organisation (ISRO) and the Indian Institute of Science (IISc) have developed a way to make bricks from Martian soil with the help of bacteria and urea. These ‘space bricks’ can be used to construct building-like structures on Mars that could facilitate human settlement on the red planet, said IISc in a press release.

Their research was published in the peer-reviewed open access scientific journal, PLOSOne. The team first made the slurry by mixing Martian soil with guar gum, a bacterium called Sporosarcina pasteurii, urea and nickel chloride (NiCl 2). “This slurry can be poured into moulds of any desired shape, and over a few days the bacteria convert the urea into crystals of calcium carbonate. These crystals, along with biopolymers secreted by the microbes, act as cement holding the soil particles together,” stated the release.

This method ensures that the bricks are less porous, which was a problem with other methods used to make Martian bricks. “The bacteria seep deep into the pore spaces, using their own proteins to bind the particles together, decreasing porosity and leading to stronger bricks,” said Aloke Kumar, associate professor, Department of Mechanical Engineering at IISc, and one of the senior authors of the paper.

The slurry-casting method was developed with the help of Koushik Viswanathan, assistant professor in the Department of Mechanical Engineering, IISc.

In the past, the team had made bricks out of lunar soil using a similar method. However, the previous method could only produce cylindrical bricks, while the current slurry-casting method can also produce bricks of complex shapes, the release stated.

Another challenge was the composition of Martian soil, which has a lot of iron that causes toxicity to organisms. “In the beginning, our bacteria did not grow at all. Adding nickel chloride was the key step in making the soil hospitable to the bacteria,” said Kumar.

The team is now gearing up to investigate how the atmosphere in Mars combined with low gravity affects the ‘space bricks’. Martian atmosphere is a hundred times thinner than that of Earth’s, and contains over 95% carbon dioxide, which may significantly affect bacterial growth, stated the release. To recreate conditions on the red planet, researchers have constructed a device–MARS (Martian AtmospheRe Simulator).

As per the release, the team has also developed a lab-on-a-chip device that aims to measure bacterial activity in micro-gravity conditions. “The device is being developed keeping in mind our intention to perform experiments in micro-gravity conditions in the near future,” said Rashmi Dikshit, a DBT-BioCARe Fellow at IISc and first author of the study, who had also previously worked on the lunar bricks. With ISRO’s help, the team plans to send such devices into space, so that they can study the effect of low gravity on the bacterial growth.

https://www.thehindu.com/news/national/karnataka/isro-iisc-researchers-develop-way-to-make-bricks-from-martian-soil/article65338661.ece?utm_source=dlvr.it&utm_medium=twitter

https://twitter.com/x/status/1518530379158024192

 

[lcloo]

2. ISRO-IISc team developed a prototype for bricks made of Martian and lunar soil, using bacteria, nickel chloride, guar gum, and urea.

So Indians have managed to bring back Martian Soil and Moon Soil, and have already used them to made brick. Bravo!!!

 

[jamahir]

2. ISRO-IISc team developed a prototype for bricks made of Martian and lunar soil, using bacteria, nickel chloride, guar gum, and urea.

So Indians have managed to bring back Martian Soil and Moon Soil, and have already used them to made brick. Bravo!!!

Well, any source called "Rising Bharat" is bound to be stupid.

@INDIAPOSITIVE, please stop continuously embarrassing the rational people of India.

 

[Black Tornado]

Misleading title

ISRO-IISc team develops prototype of bacteria-infused bricks for Martian, lunar soil

New method is proof of concept for sustainable way to make bricks for construction on Mars & Moon using soil found on surface. Study published in PLOS One on 14 April.

theprint.in

 

[SMC]

Isn't Martian soil made from Indian soil?

 

[jamahir]

Misleading title

ISRO-IISc team develops prototype of bacteria-infused bricks for Martian, lunar soil

New method is proof of concept for sustainable way to make bricks for construction on Mars & Moon using soil found on surface. Study published in PLOS One on 14 April.

theprint.in

Additionally, Martian soil is rich in perchlorates, compounds made up of oxygen and chlorine that are highly toxic to humans. While recent studies have indicated that the level of perchlorates on the surface of Mars could be toxic even to bacteria when exposed to the ultraviolet radiation that the planet is bathed in, making the use of such bricks safe for human settlements is a challenge for materials engineers for future space missions.

So the bacteria will have to be engineered ones resistant to the percholate chemical when exposed to ultraviolet light. That implies that the first few crewed landings on Mars will have to bring back the soil samples to Earth be be experimented with or much better would be for geologists, biochemists and materials scientists to go Mars in those first missions. I also read on marsdaily.com about a chemical called superoxide that if is come in contact with the human body will cause "chemical burns".

@Bilal9

 

[Bilal9]

So the bacteria will have to be engineered ones resistant to the percholate chemical when exposed to ultraviolet light. That implies that the first few crewed landings on Mars will have to bring back the soil samples to Earth be be experimented with or much better would be for geologists, biochemists and materials scientists to go Mars in those first missions. I also read on marsdaily.com about a chemical called superoxide that if is come in contact with the human body will cause "chemical burns".

@Bilal9

Let me read up on this, so I can reply properly. Please remind me if I forget, interesting subject.

 

[Bilal9]

So the bacteria will have to be engineered ones resistant to the percholate chemical when exposed to ultraviolet light. That implies that the first few crewed landings on Mars will have to bring back the soil samples to Earth be be experimented with or much better would be for geologists, biochemists and materials scientists to go Mars in those first missions. I also read on marsdaily.com about a chemical called superoxide that if is come in contact with the human body will cause "chemical burns".

@Bilal9

According to NASA, a one way trip to Mars would take about 9 months, and waiting to catch the right trajectory, a total of 21 months for a round trip. However way you look at getting people there and back, it is a significant engineering challenge, if not a biological one.

During the first phase of colonizing Mars, they also have to think about growing food (using lichen) and terraforming. Huge challenges any way you look at them.

Terraforming of Mars - Wikipedia

en.wikipedia.org

 

[jamahir]

According to NASA, a one way trip to Mars would take about 9 months, and waiting to catch the right trajectory, a total of 21 months for a round trip. However way you look at getting people there and back, it is a significant engineering challenge, if not a biological one.

@Hamartia Antidote, didn't you once tell me that the SpaceX Starship can go higher speeds to Mars than the current robotic mission craft but the issue would be to brake the spaceship once arrival at Mars ?

Secondly Bilal bhai, there is the VASIMR propulsion engine in development for long by the Ad Astra Rocket Company founded by former NASA astronaut Franklin Chang Diaz :

The VASIMR engine can supposedly propel a craft to Mars in 39 days ! VASIMR is an electric engine essentially, creating plasma out of xenon or argon gas and expelling that plasma at high speed to create thrust, and to create that plasma it requires lot of continuous electricity for some time to electromagnetically charge the gas :

The issues with VASIMR are :

1. It does not produce enough thrust to propel a craft where there is no vacuum / zero gravity so it can't lift a craft off planetary bodies and hence is an in-space propulsion system so any craft using VASIMR should either have traditional chemical ( or nuclear ) rocket engines to first lift the craft into zero gravity space and then the VASIMR can be started. Or the VASIMR can be installed on a big spaceship that is assembled in space and never ascends from a planetary body or descends onto one, and to ascend or descend a rocket propulsion is used.

2. Once the in-space VASIMR engine is started and kept on for a while or kept pulsing regularly for a while it speeds up the craft to very high speeds and then the engine is stopped until the destination arrives at a sem-long distance and the craft is reversed and the VASIMR restarted to brake the craft so that it doesn't crash into the destination. But to keep the VASIMR on continuously or pulsed regularly it seems that solar panels won't provide that much electricity to supply to VASIMR so that it generates the high speed plasma so as per existing technology it would require a nuclear reactor to generate the electricity required :

Mars in 39 days​

In order to conduct an imagined crewed trip to Mars in 39 days,[32] the VASIMR would require an electrical power level far beyond anything currently possible.

On top of that, any power generation technology will produce waste heat. The necessary 200 megawatt reactor "with a power-to-mass density of 1,000 watts per kilogram" (Díaz quote) would require extremely efficient radiators to avoid the need for "football-field sized radiators" (Zubrin quote).[33]

The radiator statement may turn out to be exaggeration in practice but seems the craft would need an existing submarine's nuclear reactor if one has to build such a craft in the next three years.

Thirdly, remember the post about the MEGA drive propulsion system I tagged you in this post in the space travel thread ? The MEGA drive is an electo-mechanical propulsion system that uses alternating pushers and pullers to repel and pull on gravity. IIRC a large array of such alternating pullers and pushers will propel the craft and the chief designer Professor James Woodward says the propulsion system can propel the craft even from gravity-high planetary bodies like Earth so this can also mean the propulsion system can be used for taxis and buses on Earth and Mars. The beauty of this system is that it doesn't require any propellant gas or liquid. All it requires is electricity to switch the pushers and pullers on and off and secondly the system can propel the craft to light speed according to the professor but that travel speed will be have to be lowered to have precaution to not collide with passing space objects especially the minute ones which are hard to detect.

Fourthly, the MEGA drive and the VASIMR engine require electricity so that can be provided by the universal and ultimate form of device-level electricity generation : energy converters from the omnipresent and endless neutrino particles about which I have already posted to you.

During the first phase of colonizing Mars, they also have to think about growing food (using lichen) and terraforming. Huge challenges any way you look at them.

Terraforming of Mars - Wikipedia

en.wikipedia.org

Well, growing food for the first decade at least will have to be through closed cycle hydroponics-based vertical farming. But what do you mean by "growing food using lichen" ?

Secondly, the wiki is very interesting and this I liked a lot :

Magnetic shield at L1 orbit​

Magnetic shield on L1 orbit around Mars

During the Planetary Science Vision 2050 Workshop[15] in late February 2017, NASA scientist Jim Green proposed a concept of placing a magnetic dipole field between the planet and the Sun to protect it from high-energy solar particles. It would be located at the Mars Lagrange orbit L1 at about 320 R♂, creating a partial and distant artificial magnetosphere. The field would need to be "Earth comparable" and sustain 50 μT as measured at 1 Earth-radius. The paper abstract cites that this could be achieved by a magnet with a strength of 1–2 teslas (10,000–20,000 gauss).[65] If constructed, the shield may allow the planet to restore its atmosphere. Simulations indicate that within years, the planet would be able to achieve half the atmospheric pressure of Earth. Without solar winds stripping away at the planet, frozen carbon dioxide at the ice caps on either pole would begin to sublimate (change from a solid into a gas) and warm the equator. Ice caps would begin to melt to form an ocean. The researcher further argues that volcanic outgassing,[dubious – discuss] which to some degree balances the current atmospheric loss on Earth, would replenish the atmosphere over time, enough to melt the ice caps and fill 1⁄7 of Mars' prehistoric oceans.

 

[Hamartia Antidote]

@Hamartia Antidote, didn't you once tell me that the SpaceX Starship can go higher speeds to Mars than the current robotic mission craft but the issue would be to brake the spaceship once arrival at Mars ?

Yes, it you use X amount of fuel to increase your speed to Mars you will then need to turn around and use just as much fuel trying to slow down when you get there.

You have to get to zero speed one way or another.

 

[jamahir]

Yes, it you use X amount of fuel to increase your speed to Mars you will then need to turn around and use just as much fuel trying to slow down when you get there.

You have to get to zero speed one way or another.

Right, and you also said that Starship can go to Mars earlier than seven months, yes ?

 

[Hamartia Antidote]

Right, and you also said that Starship can go to Mars earlier than seven months, yes ?

If it refuels in space to a full tank it certainly can but then you have to weigh the costs vs the benefit.

SpaceX Mars program - Wikipedia

en.wikipedia.org

"The notional journeys outlined in the November 2016 talk would require 80 to 150 days of transit time,[52] with an average trip time to Mars of approximately 115 days (for the nine synodic periods occurring between 2020 and 2037)."

 

[Naofumi]

2. ISRO-IISc team developed a prototype for bricks made of Martian and lunar soil, using bacteria, nickel chloride, guar gum, and urea.

So Indians have managed to bring back Martian Soil and Moon Soil, and have already used them to made brick. Bravo!!!

Well, any source called "Rising Bharat" is bound to be stupid.

@INDIAPOSITIVE, please stop continuously embarrassing the rational people of India.

It probably means developed using materials that are known to be available on Mars in sufficient quantities.

Composition of Mars - Wikipedia

en.wikipedia.org

 

[jamahir]

It probably means developed using materials that are known to be available on Mars in sufficient quantities.

Composition of Mars - Wikipedia

en.wikipedia.org

Sure but the rovers analyze samples local to very very few locations because there's not a huge number of rovers all over the planet so it is not necessary that the sites where these rover have analyzed will end up being the sites chosen when the time comes to land crews.