2012, Gopal, A., May, T., Herzer, S., Reinhard, A., Minardi, S., Schubert, M., Dillner, U., Pradarutti, B., Polz, J., Gaumnitz, T., Kaluza, M.C., Jäckel, O., Riehemann, S., Ziegler, W., Gemuend, H-P., Meyer, H-G., Paulus, G.G.

We report the first experimental observation of terahertz (THz) radiation from the rear surface of a solid target while interacting with an intense laser pulse. Experimental and two-dimensional particle-in-cell simulations show that the observed THz radiation is mostly emitted at large angles to the target normal. Numerical results point out that a large part of the emission originates from a micron-scale plasma sheath at the rear surface of the target, which is also responsible for the ion acceleration. This opens a perspective for the application of THz radiation detection for on-site diagnostics of particle acceleration in laser-produced plasmas.

2015, Lindenfelser, F., Keitch, B., Kienzler, D., Bykov, D., Uebel, P., Schmidt, M.A., Russell, P.St.J., Home, J.P.

We demonstrate a surface-electrode ion trap fabricated using techniques transferred from the manufacture of photonic-crystal fibres. This provides a relatively straightforward route for realizing traps with an electrode structure on the 100 micron scale with high optical access. We demonstrate the basic functionality of the trap by cooling a single ion to the quantum ground state, allowing us to measure a heating rate from the ground state of 787 ± 24 quanta/s. Variation of the fabrication procedure used here may provide access to traps in this geometry with trap scales between 100 μm and 10 μm