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Dr. Suzanne Gildert presentation on “Building large-scale quantum computers” Part 1 of 6:

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“According to the quantum theory, everything vibrates,” theoretical physicist Michio Kaku tells NPR’s Guy Raz. Kaku is a frequent guest on the Science and Discovery channels. “When two electrons are placed close together, they vibrate in unison. When you separate them, that’s when all the fireworks start.”

This is where quantum entanglement — sometimes described as “teleportation” — begins. “An invisible umbilical cord emerges connecting these two electrons. And you can separate them by as much as a galaxy if you want. Then, if you vibrate one of them, somehow on the other end of the galaxy the other electron knows that its partner is being jiggled.”

This process happens even faster than the speed of light, physicists say.

Quantum entanglement isn’t a new idea — Einstein once famously referred to it as “spooky action at a distance” — but it wasn’t until the past 30 years that scientists were first able to observe this process.

It could one day lead to new types of computers, and some even think entanglement may explain things like telepathy. Scientists aren’t quite ready to beam up Scotty yet, but this is the technology that one day may lead to such a feat.

Mirrors and lenses direct lasers at atoms to catalyze entanglement.

The work is being pioneered at places like the Joint Quantum Institute at the University of Maryland. In a basement lab, scientist Christopher Monroe has successfully managed to “entangle” two atoms approximately one meter away from each other.

“It’s fun being on the fringe,” Monroe says. “This discipline, we don’t know where it’s going. And that drives me every day.”

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Previous experiments led by Graham Fleming, a physical chemist holding joint appointments with Berkeley Lab and UC Berkeley, pointed to quantum mechanical effects as the key to the ability of green plants, through photosynthesis, to almost instantaneously transfer solar energy from molecules in light harvesting complexes to molecules in electrochemical reaction centers. Now a new collaborative team that includes Fleming have identified entanglement as a natural feature of these quantum effects. When two quantum-sized particles, for example a pair of electrons, are “entangled,” any change to one will be instantly reflected in the other, no matter how far apart they might be. Though physically separated, the two particles act as a single entity.

The results of this study hold implications not only for the development of artificial photosynthesis systems as a renewable non-polluting source of electrical energy, but also for the future development of quantum-based technologies in areas such as computing – a quantum computer could perform certain operations thousands of times faster than any conventional computer.

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Quantum computers promise superfast calculations that precisely simulate the natural world, but physicists have struggled to design the brains of such machines. Some researchers have focused on designing precisely engineered materials that can trap light to harness its quantum properties. To work, scientists have thought, the crystalline structure of these materials must be flawlessly ordered — a nearly impossible task.

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One approach to quantum computing relies on entangling photons and atoms, or binding their quantum states so tightly that they can influence each other even across great distances. Once entangled, a photon can carry any information stored in the atom’s quantum state to other parts of the computer. To get that entangled state, physicists pin light in tiny cavities to increase the likelihood of quantum interaction with neighboring atoms.

Lodahl and his colleagues didn’t set out to trap light. They wanted to build a waveguide, a structure designed to send light in a particular direction, by drilling carefully spaced holes in a gallium arsenide crystal. Because the crystal bends light much more strongly than air does, light should have bounced off the holes and traveled down a channel that had been left clear of holes.

But in some cases, the light refused to move. It kept getting stuck inside the crystal.

“At first we were scratching our heads,” Lodahl says. “Then we realized it was related to imperfections in our structures.” If imperfect materials could trap light, Lodahl thought, then physicists could couple light and matter with much less frustration.

To see if disorder could help materials trap light, Lodahl and colleagues built a new waveguide, this time deliberately placing the holes at random intervals. They also embedded quantum dots, tiny semiconductors that can emit a single photon at a time, in the waveguide as a proxy for atoms that could become entangled with the photons.

quantum_peaksAfter zapping the quantum dots with a laser to make them emit photons, the researchers found that 94 percent of the photons stayed close to their emitters, creating spots of trapped light in the crystal. That’s about as good as previous results using more precisely ordered materials. Intuitively, physicists expect light to scatter in the face of disorder, but in this case colliding light waves built each other up and collected in the material.

Read More at Wired Science

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