A cold electron-impact ion source driven by a photo-cathode – New opportunities for the delivery of radioactive molecular beams?

Article
Report number	arXiv:2110.00651
Title	A cold electron-impact ion source driven by a photo-cathode – New opportunities for the delivery of radioactive molecular beams?
Related title	A cold electron-impact ion source driven by a photo-cathode -- New opportunities for the delivery of radioactive molecular beams?
Author(s)	Ballof, Jochen (CERN ; Mainz U.) ; Au, Mia (CERN ; Mainz U.) ; Barbero, Ermanno (CERN) ; Chrysalidis, Katerina (CERN) ; Düllmann, Christoph E. (Mainz U. ; Darmstadt, GSI ; Helmholtz Inst., Mainz) ; Fedosseev, Valentin (CERN) ; Granados, Eduardo (CERN) ; Heinke, Reinhard (CERN) ; Marsh, Bruce A. (CERN) ; Owen, Michael (CERN) ; Rothe, Sebastian (CERN) ; Stora, Thierry (CERN) ; Yakushev, Alexander
Publication	2022
Imprint	2021-10-01
Number of pages	8
In:	J. Phys. : Conf. Ser. 2244 (2022) 012072
In:	19th International Conference on Ion Sources (ICIS 2021), Vancouver, BC, Canada, 20 - 24 Sep 2021, pp.012072
DOI	10.1088/1742-6596/2244/1/012072
Subject category	physics.ins-det ; Detectors and Experimental Techniques
Accelerator/Facility, Experiment	CERN ISOLDE
Abstract	The thick-target ISOL (Isotope mass Separation OnLine) method provides beams of more than 1000 radionuclides of 74 elements. The method is well established for elements with sufficiently high volatility at ca. 2000 {\deg}C. To extract non-volatile elements the formation of a volatile molecule is required. While successful in some cases (e.g. carbon or boron), most of these elements are not yet available as ISOL beam. A variety of volatile carrier molecules has been proposed for all elements produced in the target material, but their probability of survival during the extraction and ionization process is often limited by the high temperatures required for isotope diffusion in the thick targets and for ion source operation. While cold target concepts have already been proposed, the normal mode of operation of the typically used Versatile Arc Discharge Ion Source (VADIS) with a hot cathode is not well suited. Here, we report about first measurements with an electron-impact ion source operated at ambient temperature using electrons that were liberated via the photo-electric effect from a copper cathode.
Copyright/License	preprint: (License: arXiv nonexclusive-distrib 1.0) CC-BY-3.0

$(left) Dependence of anode drain current and \textsuperscript{84}Kr ion current on the anode voltage for different settings of the target magnet at a laser power and center wavelength of \SI{8(1)}{\milli\watt} and \SI{215}{\nano\meter}, respectively. Connecting lines were added to guide the eye. (right) Time structure of electron, laser and ion pulses. A photo-diode was used to assess the laser time structure. Laser and electron pulse shape were estimated by measurement of the voltage drop over a \SI{50}{\ohm} resistor. The curve shapes were redrawn from an oscilloscope photograph. The offset between electron and laser pulses was not measured. The ion time structure was obtained with a MagneToF detector and is given relative to the laser pulse.$ $Dependence of anode drain current and \textsuperscript{84}Kr ion current on laser power for different anode voltages and magnet currents. The electron current measurement does not differentiate between electrons impinging on the grid and electrons entering the anode volume. The ion currents for \SI{500}{\volt} and \SI{200}{\volt} at \SI{0}{\ampere} magnet current were indistinguishable, and only the data for \SI{500}{\volt} are shown.$ Show more plots

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