Hans Kraus

Calorimetric Detectors at Low Temperatures

Chapter in Low Temperature Detectors for Neutrinos and Dark Matter, Springer Nature (1987) 94-112

Authors:

F v. Feilitzsch, T Hertrich, H Kraus, L Oberauer, Th Peterreins, F Pröbst, W Seidel

High-Resolution X-Ray Detection with Superconducting Tunnel Junctions

EPL (Europhysics Letters) IOP Publishing 1:4 (1986) 161-166

Authors:

H Kraus, Th Peterreins, F Pröbst, FV Feilitzsch, RL Mössbauer, V Zacek, E Umlauf

Measuring the electric dipole moment of the neutron: The cryoEDM experiment

Proceedings of Science EPS-HEP 2009 376

Authors:

CA Baker, SN Balashov, V Francis, K Green, MGD van der Grinten, PS Iaydjiev, SN Ivanov, A Khazov, MAH Tucker, DL Wark, A Davidson, JR Grozier, M Hardiman, PG Harris, JR Karamath, K Katsika, JM Pendlebury, SJM Peeters, DB Shiers, PN Smith, CM Townsley, I Wardell, C Clarke, S Henry, H Kraus, M McCann, P Geltenbort, H Yoshiki

Abstract:

The cryoEDM experiment at the Institut Laue-Langevin in Grenoble will measure the electric dipole moment (EDM) of the neutron with unparalleled precision. A neutron EDM arises due to CP violation. The cryoEDM experiment is sensitive to levels of CP violation predicted by many “beyond the standard model” theories and the result will therefore constrain or support these theories. The current limit to the neutron EDM stands at d_n<2.9x 10^-26 e cm as measured with a room temperature experiment. By operating in superfluid helium below 0.9 K and collecting high densities of ultra cold neutrons, the cryoEDM experiment will improve on the existing limit or measure an EDM. High precision magnetometry is essential to reduce the systematic errors in the cryoEDM experiment originating from changes in the magnetic environment. We present the cryoEDM apparatus and technologies.

The influence of subwavelength geometry on extracting the electrical properties of semiconductors by terahertz spectroscopy

APL Photonics AIP Publishing LLC