In an achievement that could help enable fast quantum computers, University of Michigan physicists have built a better Rydberg atom trap. Rydberg atoms are highly excited, nearly ionized giants that can be thousands of times larger than their ground-state counterparts. As a result of their size, interactions between Rydberg atoms can be roughly 1 million times stronger than between regular atoms. This is why they could serve as faster quantum circuits, said Georg Raithel, associate chairman and professor in the department of physics. Quantum computers could solve problems too complicated for conventional computers. Many scientists believe that the future of computation lies in the quantum realm. An artist's interpretation of Rydberg atom trapping in an optical lattice. (Image: Kelly Younge) The research will be presented in Houston at the American Physical Society's Division of Atomic, Molecular and Optical Physics meeting in late May. Raithel's team trapped the atoms in what is called an optical lattice — a crate made of interfering laser beams. "The optical lattice is better than any other Rydberg atom trap for quantum information processing or high-precision spectroscopy," Raithel said. "Compared with other traps, optical lattices minimize energy level shifts in the atoms, which is important for these applications." Raithel and physics doctoral students Kelly Younge and Sarah Anderson started with ground-state atoms of the soft metal rubidium. At room temperature, the atoms whiz around at the speed of sound, about 300 m/s. The researchers hit them with lasers to cool and slow them to 10 cm/s. "That's about the speed of a mosquito," Younge said. "Cooling lasers combined with a magnetic field allows us to trap the ground-state atoms. Then we excite the atoms into Rydberg states." In a rubidium atom, just one electron occupies the outer valence shell. With precisely tuned lasers, the researchers excited this electron so that it moved 100 times farther away from the nucleus of the atom, which classified it as a Rydberg atom. That valence electron in this case is so far away from the nucleus that it behaves almost as if it is a free electron. To trap the Rydberg atoms, the researchers took advantage of what is called the "ponderomotive force," which allowed them to secure a whole atom by holding fast to one electron — the sole valence shell particle in the rubidium Rydberg atoms. The optical lattice, formed with intense, interfering laser beams, is what provides the ponderomotive force. "The laser field holds on to the electron, which behaves almost as if it were free, but the residual weak atomic binding force still holds the atom together. In effect, the entire atom is trapped by the lasers," Raithel said. The physicists used a technique called "microwave spectroscopy" to determine how the lattice affected the Rydberg atoms and, in general, how the atoms behaved in the trap. "Essentially, we could track the motion of the atoms during the experiment. We could tell if the atoms were sitting in the bottom of a well in the electromagnetic field or if they were roaming over many wells. In this way, we could optimize the performance of the trap," Younge said. The research was funded by the National Science Foundation and the National Defense Science and Engineering Graduate Fellowship Program. For more information, visit: www.umich.edu