Sentences with phrase «laser beam at»
Aiming a laser beam at an aircraft in California can be charged as a misdemeanor or a felony.
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Again, this language helps to protect individuals who shine a laser beam at an unoccupied aircraft.
Use the dozens of awesome objects including explosives, balls, portals, elevators, magnets, blocks and more in a realistic physics environment to direct your laser beam at the target.
Grunty shoots a laser beam at Banjo's house.
When they shone a multi-wavelength laser beam at the open end of the gilded waveguide, a trapped rainbow formed inside.
Meanwhile the researchers aimed a laser beam at the smoke behind the bats and took pictures of the illuminated smoke particles.
This is a schematic of the BIC laser: a high frequency laser beam (blue) powers the membrane to emit a laser beam at telecommunication frequency (red).
Those proteins let him turn a set of cells on or off just by shining the right kind of laser beam at the cells.
When they shone a multi-wavelength laser beam at the open end of this waveguide, a trapped rainbow formed inside.
It is The Nature of Love (2010) where Oord shines most brightly in aiming a laser beam at the power of divine love.
The team pointed four laser beams at the photoresist film.
He and his collaborators trapped a rubidium atom and aimed two different laser beams at it: one for probing, or transmitting, and the other one for switching.
Fossilized corals, lasers beamed at a receding moon, Chinese artifacts, and other evidence have revealed that over the ages the length of time it takes Earth to spin once on its axis has increased significantly
In the second level of the game you are going through space and your character turns into a spaceship that shoots laser beams at enemies.
As a result of the Documenta 6 (1977), Kassel became the first town in the world to be illuminated by laser beams at night (Laserscape, by artist Horst H. Baumann).
Not exact matches
At Oakley, Jannard had thrown himself into the creative engineering process, enlisting technologies such as liquid laser prototyping and electron - beam gun - vapor deposition in his quest to make state - of - the - art sunglasses.
The Word of God is not like a laser beam, directed only at a few people whom God knows are ready to receive it.
A LIGO installation specialist checks the alignment of a laser test beam system at the far end of a LIGO arm.
LIGO detects gravitational waves by splitting a powerful infrared laser beam in two, then sending the beams at right angles through tunnels to mirrors 2.5 miles away.
This cosmic paperweight is handmade by an artist who uses laser beams to make tiny stars: Each laser pulse passes through the glass except at its focal point, where the concentrated energy creates a bright star.
In the 1970s, researchers at Lawrence Livermore National Laboratory (LLNL) in California focused on the former, boosting laser energy by routing beams through additional lasing crystals made of glass doped with neodymium.
This was made of silica glass and powered by a commercial laser beam, at the SLAC laboratory in the USA.
Scientists at the Helmholtz - Zentrum Dresden - Rossendorf (HZDR) together with colleagues from the Helmholtz - Zentrum Berlin (HZB) and the University of Virginia in Charlottesville, USA have found a way to write and delete magnets in an alloy using a laser beam — a surprising effect.
When the gravitational waters of spacetime are calm, the beams recombine at the junction and cancel each other out — the troughs of one beam's 1,064 - nanometer waves of laser light completely negate the crests of the second beam's waves.
These have been used to create laser beams made of atoms that etch precise patterns on surfaces, and might one day lead to superconductors that work at room temperature.
Using a laser beam, it will measure fluctuations in the distance between mirrors at each end.
Holonyak's team at the University of Illinois at Urbana - Champaign devised a transistor that is also an ultratiny laser, producing a narrow beam of light simultaneously with electrical current.
Strogatz explores dozens of strange synchronous phenomena, from hands clapping in unison to the rhythmic flashing of fireflies to laser beams produced by trillions of atoms emitting light waves in phase at the same frequency.
To generate an accurate picture of the temperature profile within the Earth's centre, scientists can look at the melting point of iron at different pressures in the laboratory, using a diamond anvil cell to compress speck - sized samples to pressures of several million atmospheres, and powerful laser beams to heat them to 4000 or even 5000 degrees Celsius.
In taking the next step, Eugene Polzik and his colleagues at the Niels Bohr Institute in Copenhagen shined a strong laser beam onto a cloud of room - temperature cesium atoms whose spins were all pointing in the same direction and fluctuating according to their given quantum state.
The results from the quantum - optics labs at the TU Vienna could give a new twist to research concerned with longitudinally oscillating light waves in very different scientific fields: Even a focused laser beam in free space has a longitudinal component.
He's done so by precisely focusing infrared laser light to selectively ionize, or steal the electrons from, air molecules at the beam's focal point, generating a flash of bluish - white plasma.
Earlier, the Laboratory of Gas Lasers at Lebedev demonstrated that such lasers can be used for many different tasks, from the etching of diamonds to medical operations, as beams concentrated into fine filaments enable more precise interactions with different mateLasers at Lebedev demonstrated that such lasers can be used for many different tasks, from the etching of diamonds to medical operations, as beams concentrated into fine filaments enable more precise interactions with different matelasers can be used for many different tasks, from the etching of diamonds to medical operations, as beams concentrated into fine filaments enable more precise interactions with different materials.
At the center of LIGO's equal - length, L - shaped arms sit a laser source and a device that splits the beam in two, sending the light racing toward mirrors at the end of each arAt the center of LIGO's equal - length, L - shaped arms sit a laser source and a device that splits the beam in two, sending the light racing toward mirrors at the end of each arat the end of each arm.
The new research has shown the even transparent plates made of quartz glass can significantly alter the laser filaments, an effect that leads to an improvement in the precision of material processing or a correction to the distance at which the power of the laser beam is delivered.
At each of the facilities, a laser shoots a 35 - watt infrared beam through a Faraday isolator, which directs and polarizes the light.
Developed by the US Department of Defense's Missile Defense Agency (MDA), the ABL aims to focus a beam of laser energy in the megawatt range for several seconds onto a missile at a...
It also lies at the heart of two quintessential modern technologies: lasers that radiate beams of staggering purity and intensity and optical fibers that direct those beams to telephones, televisions, and computers around the world.
Inside each arm a laser beam bounces back and forth between mirrors at each end of a vacuum tube, resonating like sound in an organ pipe.
Kept at minus 456 degrees Fahrenheit, a temperature at which niobium conducts electricity without losses, these cavities will power a highly energetic electron beam that will create up to 1 million X-ray flashes per second — more than any other current or planned X-ray laser.
The world's most powerful x-ray laser, known as the Linac Coherent Light Source, sits at the end of a linear particle accelerator and converts the particle beam into an x-ray beam.
By looking at their images, the researchers were able to discern which laser beams, or tweezers, were holding atoms and which were not.
The researchers focused the smaller laser beams through the cloud of ultracold atoms and found that each beam's focus — the point at which the beam's intensity was highest — attracted a single atom, essentially picking it out from the cloud and holding it in place.
Lasers have long been at the heart of modern telecommunications because their intense light beams can be chopped up to represent digital currency's 1s and 0s and can travel through optical cables at light speed.
The material is exposed and hardened at the focus point of the laser beam.
But a laser can set up a quantum - mechanical interference that blocks the electrons from making the jump, allowing a second beam at the normally absorbed wavelength to zip through.
Using X-ray beams and lasers, researchers studied how a new promising class of solar cell materials, called hybrid perovskites, behaves at the nanoscale level during operation.
An infrared laser beam is split in two; one half travels down one two - and - a-half-mile vacuum tunnel, and the other half travels down a second tunnel at a right angle to the first.
Laser beams fired at LAGEOS were not sensitive enough to pinpoint variations in orbit smaller than a centimeter or so and were too imprecise to pick out the subtler differences in gravity.
The patent (EP 562 742) describes a pair of spectacles that direct a laser beam onto the retina of the wearer's eye, creating the illusion of looking at a screen.