Li Fu-Li

Quantum-information transfer with nitrogen-vacancy centers coupled to a whispering-gallery microresonator

We propose an efficient scheme for the realization of quantum information transfer and entanglement with nitrogen-vacancy (N-

Implementation of holonomic quantum computation through engineering and manipulating the environment

V

Controlling thermal radiation by photonic quantum well structure with zero-averaged-refractive-index gap

) centers coupled to a high-

Controlled generation of field squeezing with cold atomic clouds coupled to a superconducting transmission line resonator

Q

Entangling two single-mode Gaussian states by use of a beam splitter

whispering-gallery mode (WGM) microresonator. We show that based on the effective dipole-dipole interaction between the N-

Surface Plasmon-Assisted Excitation of Atomic Visible Light Spectral Lines in the Impact of Highly Charged Ions 126Xeq + on Solid Surfaces

V

Information Transferring between a Photon's Orbital Angular Momentum and Frequency

centers mediated by the WGM, quantum information can be transferred between the N-

Engineering squeezed states of microwave radiation with circuit quantum electrodynamics

V

Calculation of Ion Equilibrium Temperature in Ultracold Neutral Plasmas

centers through Raman transitions combined with laser fields. This protocol may open up promising possibilities for quantum communications with the solid-state quantum electrodynamic cavity system.

Guiding of Highly Charged Ions through PC Nanocapillaries

We consider an atom-field coupled system in which two pairs of four-level atoms are respectively driven by laser fields and trapped in two distant cavities that are connected by an optical fiber. First, we show that an effective squeezing reservoir can be engineered under appropriate conditions. Then, we show that a two-qubit geometric controlled-PHASE (CPHASE) gate between the atoms in the two cavities can be implemented through adiabatically manipulating the engineered reservoir along a closed loop. This scheme that combines an engineering environment with decoherence-free space and geometric phase quantum computation together has the following remarkable feature: a CPHASE gate with arbitrary phase shift is implemented by simply changing the strength and relative phase of the driving fields.