Lasers can make roads to the Moon and sweep orbital trajectories.

 Lasers can make roads to the Moon and sweep orbital trajectories. 

ESA (European Space Administration) created a model where lasers turn moon dust into glass. Developers can use that system to make roads to the Moon. Lasers can melt moondust and transform it into glass, which allows vehicles to travel on it. The moon glass can be used as other structures on the Moon. The system puts dust in a mold and then the laser melts it. 

In some other versions, the pressure systems will blow dust to certain points, and laser rays melt that dust. That kind of system can create the 3D printing technology that is used to create structures for the Moon. But the other thing is that. It's possible to use this technology can also on Earth for the same purposes. 

The laser systems can melt dust on Earth. In 3D printers, lasers can melt dust like plastic. And that allows to create 3D printers that can print glass. 3D printers can use silicone dust for ceramic structures. By using this technology, a 3D printing system can print ceramic structures. And lasers can also be used to create airfields on sand. The workers must only equalize the surface. And then lasers will turn the sand into glass. 

"ESA’s PAVER project investigated the creation of paved surfaces on the Moon, such as roads and landing pads, through melting of lunar regolith. A carbon dioxide laser was used for terrestrial testing, but on the Moon a Fresnel lens would be employed to focus sunlight. Credit: PAVER consortium/LIQUIFER Systems Group" (ScitechDaily.com/Lunar Highways: How Lasers Can Transform Moon Dust Into Roads)

Above:) Laser satellites can use their lasers in multiple missions. The difference between data transmission lasers and lasers that destroy targets is only the power. That the laser uses. Lasers can use sunlight to create laser rays. The laser's flashlight tube can get its energy from solar panels. Or mirrors can focus sunlight on laser elements. (Image ESA)

Laser satellites are multipurpose tools. They can act as communication platforms. They can search for pollution from the atmosphere. And laser satellites can sweep orbital trajectories. The same satellite can make all those missions. In some visions around the Earth will be a large swarm of small laser satellites. The purpose of those satellites determines what power they use in each mission. 

If the laser satellite drills a hole in the other satellite's fuel tank, that turns the fuel or gas tank into a rocket that pushes the satellite away from the trajectory. And if the laser satellite is at a higher altitude than the target satellite, that effect pushes the target into the atmosphere.

Those AI-controlled laser satellite swarms can combine their data-handling capacity and aim their lasers at one target or they can push small debris to the atmosphere separately. The problem with laser systems is that they should not break the satellite. The laser satellite swarm can search for debris by using Lidars. Those satellites can used as the ASAT or ABM weapons. 

The AI-controlled lasers can sweep orbital trajectories from space junk. In visions, laser satellites can push other satellites. And especially space debris back into the atmosphere. When a laser ray hits metal it vaporizes it. And that acts like a rocket. The laser satellites can be the answer for small-size space debris that dangers satellites. The AI-controlled laser satellite swarm can also push large-size space junk into the atmosphere. And when those satellites combine their force, that system can act as killer satellites in ABM or ASAT missions. 

https://www.esa.int/Applications/Connectivity_and_Secure_Communications/A_world_first_Data_transmission_between_European_satellites_using_laser_light

https://scitechdaily.com/ai-powered-lasers-a-modern-solution-to-space-debris/

https://scitechdaily.com/lunar-highways-how-lasers-can-transform-moon-dust-into-roads/