Conveners
Applications II
- Paul Greenlees
Thierry Stora
(CERN)
27/11/2013, 11:00
Invited
About 50% of the 1.4GeV CERN’s protons are sent onto targets to produce radioactive beams by online mass separation at ISOLDE, for a wide range of studies. As reported at the last Isolde users workshop, CERN-MEDICIS is a spin-off dedicated specifically to R&D in life sciences and medical applications. It is located in an extension of the Class A building presently under construction. It will...
Lars Hemmingsen
(U)
27/11/2013, 11:30
Submitted
Application of perturbed angular correlation (PAC) of γ-rays spectroscopy in coordination chemistry and biochemistry is well established [1]. Over the past few years we and our collaborators have applied this technique to elucidate structure and dynamics at metal sites in proteins. In addition, we have applied quantum chemical methods to explore how the spectroscopic properties are affected by...
Dr
Attila Jancso
(University of Szeged (HU))
27/11/2013, 11:50
Submitted
Metalloregulatory proteins are key elements of bacterial metal homeostasis and resistance regulating the metal ion transport/storage/detoxification systems at a transcriptional level. The copper-efflux regulator CueR belongs to the MerR protein family the members of which are dimers and all possess a characteristic short metal binding domain close to the C-terminus of each monomer. The...
Johannes Lehnert
(Experimentalphysik, Universität des Saarlandes, 66123 Saarbrücken, Germany)
27/11/2013, 12:10
Submitted
Radiotracer experiments are the most sensitive tool for the study of diffusion phenomena in solids. At ISOLDE/CERN diffusion experiments have been performed using 111-Ag delivered for implantation by ISOLDE.
It has been shown that in CdTe 111-Ag exhibits the phenomenon of uphill diffusion, which under suitable conditions (800 K, 60 min, Cd-pressure) results in the formation of symmetric...
Monika Stachura
(CERN)
27/11/2013, 12:30
Submitted
The planned upgrade of the RB0 line at ISOLDE, currently hosting the ASPIC apparatus, will be presented. The newly designed UHV beam line – reborn as the VITO experiment – will have three end stations allowing for carrying out versatile and multidisciplinary experiments: the ASPIC end station, the β -NMR end station and at a later stage an open station for traveling experiments. The major...
