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Transcript
Quantum Computation Using Optical Lattices Ben Zaks Victor Acosta Physics 191 Prof. Whaley UC-Berkeley Contents • • • • Standing Wave Light Field Egg Crate Potential Atom Cooling Gates and Qubits 1D Optical Lattice 2 Linearly Polarized Light Waves... y x z 1D Optical Lattice σ+ σ0 4 E 2 t 3 4 Cos k z …or 2 Circularly Polarized Standing Waves! Sin k z Atom in a Light Field: AC-Stark Shifts Electric Dipole Hamiltonian Time Dependent Schroedinger Equation Choose Rotating Frame: Unitary Transformation Finally Example: Two-Level System Example: J=1/2 J=3/2 Periodic Spatially-Varying Optical Trap -1 -2 -3 Cooling in Optical Lattices Optical Molasses and Magneto-Optical Traps • Six lasers tuned slightly below the resonance frequency of atoms being trapped • Atoms moving towards lasers see frequencies closer to resonance • Atoms moving towards lasers absorb more momentum • Magnetic field gradient creates Zeeman splitting to further trap atoms • Can cool to ~1 microKelvin Cooling in Optical Lattices Sisyphus Cooling • Atoms with enough energy can climb out of the well • Atoms will be optically pumped from the higher energy ground state (red line) • Spontaneous emission will drop the atom into the lower energy ground state (blue line) • The atom loses more energy than it gains, so it is cooled Quantum Computation An Array of Qubits • Optical lattices contain neutral atoms, ions or polar molecules as qubits • Electric dipoles of these particles are qubits aligned with or against an external field • Qubits are entangled by the dipole-dipole interaction • Need strong coupling between qubits but weak coupling with environment Quantum Computation Some Current Research • Prof. DeMille uses polar molecules as qubits at Yale • An electric field gradient allows for spectroscopic addressing of individual qubits • Microwave laser pulses can be used as single and twoqubit gates • Coupling effects can be eliminated by “refocusing” Quantum Computation Some Current Research • Prof. Deutsch et al. use neutral atoms in far-off resonance optical lattices as qubits at the University of New Mexico • Neutral atoms have weak dipole-dipole interactions but are also very weakly coupled to the environment • Polarization is rotated to bring atoms together • Once together, laser pulses set to specific resonances will only allow specific transitions, and these can be utilized as gates Thank you to the following websites for their resources • • • • • http://quaser.physics.lsa.umich.edu/projects/lattice/ http://web.arizona.edu/~lascool/research.html http://nobelprize.org/physics/laureates/1997/illpres/ http://www.yale.edu/physics/research/atomic.html http://physics.nist.gov/Divisions/Div842/Gp4/lattices.html
