LAPIS SPHERE, a new wave of technology that could be used to create high-definition video images in space by using magnetic fields.
The idea was first proposed by NASA and is now being developed by the National Research Council and the University of California, Berkeley.
Lapis Sphere is a combination of two different technologies, a “solar cell” and a “light-emitting diode” that is built on a sphere.
It is built around a material called “plasmons,” which are magnetic particles.
The solar cell uses an electromagnetic field to create a field that drives an electron beam toward the surface of the sphere.
The laser beam, when fired into the plasmons, causes the electrons to “charge” and “charge,” releasing energy into the surrounding magnetic field.
A laser pulse is a beam of electromagnetic energy, or light, traveling in a direction perpendicular to the direction of motion of the particles.
To achieve this, a laser that is used to drive an electric field on the surface creates a magnetic field, which causes a beam that passes through the magnetic field to interact with the electrons and their charge.
This creates a high-resolution image of the surrounding surface.
The light from the electron beam is also reflected back to the laser, creating an image that can be seen at a distance.
The surface of a sphere is then imaged in a way that is very close to what a real, human-scale image would look like.
When viewed at a magnified 10-meter-wide (33-foot) radius, the image is about twice as large as the image seen from Earth, and much sharper than an image seen with a telescope.
In the future, the new technology could be adapted for a variety of applications, including imaging spacecraft, medical imaging, and imaging satellites, as well as a new generation of solar panels, solar cells, and the next generation of high-speed imaging sensors.
Researchers say the material used in Lapis Space can be used in a variety, and could be expanded to many other applications.
They say the new material could be built into other materials as well, such as metals.
The materials that were used to make the solar cells are from a company called Solar and Power Materials (SPM), which is owned by the U.S. Department of Energy.
SPM was formed in 2007 by a group of scientists from the National Science Foundation and the Lawrence Livermore National Laboratory.
The company describes itself as “the world leader in high-performance materials.”
The material is made of high density silicon and is called “sulphur” for the element of the same name.
The new technology is also called “spheric silver” and is made from “sulfur-based nanoparticles.”
Researchers said that SPM has developed “sustainable” solar cell technologies for commercial applications, such the new materials.
The group said that its solar cell technology has been tested in the laboratory at Lawrence Liverman National Laboratory and was shown to be safe, energy efficient, and capable of providing an image at resolutions up to 1,000 megapixels.
It was shown that the material can be produced with a large volume of water, which is essential for its high performance.
The team said that it was able to produce a thin, light, flexible film of silver with the ability to be thin enough to be absorbed by the solar cell itself.
The researchers said that the new solar cell has a performance that is 10 times higher than that of other materials, such silicon, which has been known to be highly energy-intensive.
The current technology has the potential to improve the efficiency of solar cells by increasing the amount of sunlight they produce, as opposed to the amount that the sunlight absorbs.
The research was published in the journal Nature Materials on March 9.
A photo of a human-sized piece of silicon being illuminated by a laser.
Source: University of Utah/NASA The U.K. and the U,S.
are developing similar technologies in the coming years.
They are also building a new version of the technology that uses a different material called silver nanowires.
But scientists said that in the U.-U.S.-China rivalry, there is a real need for both nations to collaborate to make their technologies cheaper and more widely available.
The U., for example, has been developing materials with “microscale” properties.
For instance, the material could produce high-quality images of a piece of metal that is only about a millimeter in size.
Researchers said it could be possible to build a solar cell using these materials in the near future.
The University of Washington, meanwhile, has developed a similar material called titanium dioxide, which could be incorporated into new types of solar cell materials, like those for high-tech cameras.
Researchers are looking into ways to create silicon films with nanoscale properties.
The potential is enormous, said Andrew Nolen, an associate professor of materials science and engineering at the