A Paul trap with sectored ring electrodes for experiments with two-dimensional ion crystals.

We have developed a trapped ion system for producing two-dimensional (2D) ion crystals for applications in scalable quantum computing, quantum simulations, and 2D crystal phase transition and defect studies. The trap is a modification of a Paul trap with its ring electrode flattened and split into eight identical sectors and its two endcap electrodes shaped as truncated hollow cones for laser and imaging optics access. All ten trap electrodes can be independently DC-biased to create various aspect ratio trap geometries.

Note: Single ion imaging and fluorescence collection with a parabolic mirror trap.

Efficient fluorescence collection is the most challenging part in remote entangled ion qubit state generation. To address this issue, we developed an ion trap consisting of a reflective parabolic surface and a needle electrode. This parabolic trap design covers a solid angle of 2π steradians and allows precise ion placement at the focal point of the parabola.

[Experimental study on the effect of low molecular DNA from salmon milt on hemopoiesis].

Biological activity of low molecular DNA isolated from salmon milt was studied. When administered subcutaneously to mice with with acute experimental radiation disease in a course dose of 10 mg/kg, it showed a therapeutic effect, stimulated hemopoiesis, increased the survival rate and the average life span of the animals. Moreover, its marked effect on the humoral immunity was observed.

Experimental Bell inequality violation with an atom and a photon.

We report the measurement of a Bell inequality violation with a single atom and a single photon prepared in a probabilistic entangled state. This is the first demonstration of such a violation with particles of different species. The entanglement characterization of this hybrid system may also be useful in quantum information applications.

Observation of entanglement between a single trapped atom and a single photon.

An outstanding goal in quantum information science is the faithful mapping of quantum information between a stable quantum memory and a reliable quantum communication channel. This would allow, for example, quantum communication over remote distances, quantum teleportation of matter and distributed quantum computing over a 'quantum internet'. Because quantum states cannot in general be copied, quantum information can only be distributed in these and other applications by entangling the quantum memory with the communication channel.