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1. Influence of mechanical deformations on the performance of a coaxial shield for a cryogenic current comparator

Author

Marsic, Nicolas, Müller, Wolfgang F. O., Tympel, Volker, Stöhlker, Thomas, Stapelfeld, Max, Schmidl, Frank, Schmelz, Matthias, Zakosarenko, Vyacheslav, Stolz, Ronny, Haider, David, Sieber, Thomas, Schwickert, Marcus, and De Gersem, Herbert

Subjects
Physics - Accelerator Physics
Abstract

This paper studies the impact of mechanical deformations on the performance of a coaxial-type cryogenic current comparator (CCC). Such deformations may become a concern as the size of the CCC increases (e.g. when used as a diagnostic device in a particle accelerator facility involving beamlines with a large diameter). In addition to static deformations, this paper also discusses the effect of mechanical vibrations on the CCC performance., Comment: 9 pages, 10 figures

Published
2022
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2. Numerical analysis of a folded superconducting coaxial shield for cryogenic current comparators

Author

Marsic, Nicolas, Müller, Wolfgang F. O., De Gersem, Herbert, Schmelz, Matthias, Zakosarenko, Vyacheslav, Stolz, Ronny, Kurian, Febin, Sieber, Thomas, and Schwickert, Marcus

Subjects
Physics - Accelerator Physics, Physics - Instrumentation and Detectors
Abstract

This paper presents a new shield configuration for cryogenic current comparators (CCCs), namely the folded coaxial geometry. An analytical model describing its shielding performance is first developed, and then validated by means of finite element simulations. Thanks to this model, the fundamental properties of the new shield are highlighted. Additionally, this paper compares the volumetric performance of the folded coaxial shield to the one of a ring shield, the latter being installed in many CCCs for measuring particle beam currents in accelerator facilities., Comment: 13 pages, 15 figures

Published
2022
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6. Influence of Mechanical Deformations on the Performance of a Coaxial Shield for a Cryogenic Current Comparator

Author

Marsic, Nicolas, primary, Muller, Wolfgang F. O., additional, Tympel, Volker, additional, Stohlker, Thomas, additional, Stapelfeld, Max, additional, Schmidl, Frank, additional, Schmelz, Matthias, additional, Zakosarenko, Vyacheslav, additional, Stolz, Ronny, additional, Haider, David, additional, Sieber, Thomas, additional, Schwickert, Marcus, additional, and De Gersem, Herbert, additional

Published
2022
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7. The Cryogenic Current Comparator at CRYRING@ESR

Author

Crescimbeni, Lorenzo, De Gersem, Herbert, Haider, David, Marsic, Nicolas, Müller, Wolfgang, Reiter, Andreas, Schmelz, Matthias, Schmidl, Frank, Schwickert, Marcus, Sieber, Thomas, Stöhlker, Thomas, Stolz, Ronny, Tympel, Volker, and Zakosarenko, Vyacheslav

Subjects
06 Beam Charge and Current Monitors, Accelerator Physics
Abstract

The Cryogenic Current Comparator (CCC) at the heavy-ion storage ring CRYRING@ESR at GSI provides a calibrated non-destructive measurement of beam current with a resolution of 10 nA or better. With traditional diagnostics in storage rings or transfer lines a non-interceptive absolute intensity measurement of weak ion beams ( 1 µA) is already challenging for bunched beams and virtually impossible for coasting beams. Therefore, at these currents the CCC is the only diagnostics instrumentation that gives reliable values for the beam intensity independently of the measured ion species and without the need for tedious calibration procedures. Herein, after a brief review of the diagnostic setup, an overview of the operation of the CCC with different stored ion beams at CRYRING is presented. The current reading of the CCC is compared to the intensity signal of various standard instrumentations including a Parametric Current Transformer (PCT), an Ionization Profile Monitor (IPM) and the Beam Position Monitors (BPMs). It was shown that the CCC is a reliable instrument to monitor changes of the beam current in the range of nA., Proceedings of the 11th International Beam Instrumentation Conference, IBIC2022, Kraków, Poland

Published
2022
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8. Creation of the First High-Inductance Sensor of the New CCC-Sm Series

Author

Tympel, Volker, Crescimbeni, Lorenzo, Haider, David, Machalett, Frank, Schmelz, Matthias, Schmidl, Frank, Schönau, Thomas, Schwickert, Marcus, Seidel, Paul, Sieber, Thomas, Stöhlker, Thomas, Stolz, Ronny, and Zakosarenko, Vyacheslav

Subjects
06 Beam Charge and Current Monitors, Accelerator Physics
Abstract

Cryogenic Current Comparators (CCC) are presently used at CERN-AD (100 mm beamline diameter) and in the FAIR project at CRYRING (150 mm beamline diameter) for non-destructive absolute measurement of beam currents below 20 ’A (current resolution 10 nA). Both sensor versions (CERN-Nb-CCC and FAIR-Nb-CCC-XD) use niobium as superconductor for the DC-transformer and magnetic shielding. The integrated flux concentrators have an inductance of below 100 ’H at 4.2 Kelvin. The new Sm-series (smart small) is designed for a beamline diameter of 63 mm and uses lead for the superconducting shield. The first sensor (IFK-Pb-DCCC-Sm-200) has two core-based pickup coils (2x 100 µH at 4.2 K) and two SQUID units, to eliminate Barkhausen current jumps as part of the low frequency 1/f-noise. During the construction some basic experiments on noise behavior (fluctuation’dissipation theorem, white noise below 2 pA/sqrt(Hz)) and magnetic shielding (flux concentrator and shielding as LC circuit resonance , additional mu-metal shielding) were undertaken, the results of which are presented here. Finally, a current resolution of 500 pA could be achieved in the laboratory., Proceedings of the 11th International Beam Instrumentation Conference, IBIC2022, Kraków, Poland

Published
2022
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9. Commissioning of the Cryogenic Current Comparator (CCC) at CRYRING

Author

Haider, David, De Gersem, Herbert, Marsic, Nicolas, M��ller, Wolfgang, Reiter, Andreas, Schmelz, Matthias, Schwickert, Marcus, Sieber, Thomas, Stapelfeld, Max, St��hlker, Thomas, Stolz, Ronny, Tympel, Volker, Ucar, Furkan, and Zakosarenko, Vyacheslav

Subjects
Physics::Accelerator Physics, 06 Beam Charge and Current Monitors, Accelerator Physics
Abstract

Proceedings of the 10th International Beam Instrumentation Conference, IBIC2021, Pohang, Rep. of Korea 10th International Beam Instrumentation Conference, IBIC 2021, Pohang, Republic of Corea, 24 May 2021 - 28 May 2021; JACoW Publishing, Geneva, Switzerland 4 pages (2021). doi:10.18429/JACOW-IBIC2021-WEOB02, Accurate non-destructive measurement of the absolute intensity of weak ion beams ( 1 uA) in storage rings is often restricted to special beam conditions and, even then, is associated with large uncertainties and tedious calibration procedures. However, experiments with rare ions in particular depend on excellent current resolution. In order to make these beams accessible, the Cryogenic Current Comparator (CCC) monitors deviations of the DC beam current on a scale of nA and compares the signal to a calibrated reference current. At the heavy-ion storage ring CRYRING at GSI a CCC prototype for FAIR was installed and first results of the commissioning are reported here. Preceding the operation with beam, a careful design of the beamline helium cryostat was required to provide the stable cryogenic environment needed for CCC operation. Mechanical and electro-magnetic perturbations that interfere with measurement of the beam’s faint magnetic field are suppressed by the internal structure of the system and a superconducting magnetic shield, while the remaining interference can be filtered with adequate signal processing. In this way, a current resolution in the nA range was demonstrated., Published by JACoW Publishing, Geneva, Switzerland

Published
2021
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11. Versatile Beamline Cryostat for the Cryogenic Current Comparator (CCC) for FAIR

Author

Haider, David, De Gersem, Herbert, Golm, Jessica, Koettig, Torsten, Kurian, Febin, Marsic, Nicolas, Müller, Wolfgang, Schmelz, Matthias, Schwickert, Marcus, Sieber, Thomas, Stöhlker, Thomas, Stolz, Ronny, Tympel, Volker, Ucar, Furkan, Zakosarenko, Vyacheslav, Schaa, Volker RW (Ed.), Jansson, Andreas (Ed.), Shea, Thomas (Ed.), and Olander, Johan (Ed.)

Subjects
Physics::Instrumentation and Detectors, Physics::Accelerator Physics, Beam charge and current monitors, 7. Clean energy, Accelerators and Storage Rings, Accelerator Physics
Abstract

The Cryogenic Current Comparator (CCC) extends the measurement range of traditional non-destructive current monitors used in accelerator beamlines down to a few nano-amperes of direct beam current. This is achieved by a cryogenic environment of liquid helium around the beamline, in which the beam’s magnetic field is measured with a Superconducting Quantum Interference Device (SQUID), which is itself enclosed in a superconducting shielding structure. For this purpose, a versatile UHV-beamline cryostat was designed for the CCCs at FAIR and is currently in production. It is built for long-term autonomous operation with a closed helium re-liquefaction cycle and with good access to all inner components. The design is supported by simulations of the cryostat’s mechanical eigenmodes to minimize the excitation by vibrations in an accelerator environment. A prototype at GSI has demonstrated the self-contained cryogenic operation in combination with a 15 l/day re-liquefier. The cryostat will be used in CRYRING to compare the FAIR-CCC-X with newly developed CCC-types for 150 mm beamlines. Both which will supply a nA current reading during commissioning and for the experiments., Proceedings of the 8th International Beam Instrumentation Conference, IBIC2019, Malmö, Sweden

Published
2019

12. Comparative Measurement and Characterisation of Three Cryogenic Current Comparators Based on Low-Temperature Superconductors

Author

Tympel, Volker, De Gersem, Herbert, Fernandes, Miguel, Golm, Jessica, Haider, David, Kurian, Febin, Marsic, Nicolas, Müller, Wolfgang, Neubert, Ralf, Schmelz, Matthias, Schmidl, Frank, Schwickert, Marcus, Seidel, Paul, Sieber, Thomas, Stöhlker, Thomas, Stolz, Ronny, Tan, Jocelyn, Welsch, Carsten, and Zakosarenko, Vyacheslav

Subjects
Accelerators and Storage Rings
Abstract

A Cryogenic Current Comparator (CCC) is a non-destructive, metrological-traceable charged particle beam intensity measurement system for the nano-ampere range. Using superconducting shielding and coils, low temperature Superconducting Quantum Interference Devices (SQUIDs) and highly permeable flux-concentrators, the CCC can operate in the frequency range from DC to several kHz or hundreds of kHz depending on the requirement of the application. Also, the white noise level can be optimized down to 2 pA/sqrt(Hz) at 2.16 K. This work compares three different Pb- and Nb-based CCC-sensors developed at the Institute of Solid State Physics and Leibniz Institute of Photonic Technology at Jena, Germany: CERN-Nb-CCC, optimized for applica-tion at CERN Antiproton Decelerator (AD) in 2015 with a free inner diameter of 185 mm; GSI-Pb-CCC, designed for GSI-Darmstadt with a free inner diameter of 145 mm, 1996 completed, 2014 upgraded; GSI-Nb-CCC-XD, de-signed for the GSI/FAIR-project with a free inner diame-ter of 250 mm, 2017 completed. The results of noise, small-signal, slew-rate, and drift measurements done 2015 and 2018 in the Cryo-Detector Lab at the University of Jena are presented here.

Published
2019

13. en-usFirst Measurements of a New Type of Coreless Cryogenic Current Comparators (4C) for Non-Destructive Intensity Diagnostics of Charged Particles

Author

Tympel, Volker, Anders, Solveig, De Gersem, Herbert, Golm, Jessica, Haider, David, Kunert, Juergen, Marsic, Nicolas, Müller, Wolfgang, Schmelz, Matthias, Schmidl, Frank, Schwickert, Marcus, Schönau, Thomas, Seidel, Paul, Sieber, Thomas, Stapelfeld, Max, Stöhlker, Thomas, Stolz, Ronny, Tan, Jocelyn, Zakosarenko, Vyacheslav, Schaa, Volker RW (Ed.), Jansson, Andreas (Ed.), Shea, Thomas (Ed.), and Olander, Johan (Ed.)

Subjects
Beam charge and current monitors, Accelerator Physics
Abstract

The non-destructive and highly sensitive measurement of a charged particle beam is of utmost importance for modern particle accelerator facilities. A Cryogenic Current Comparator (CCC) can be used to measure beam currents in the nA-range. Therein, charged particles passing through a superconducting toroid induce screening currents at the surface of the toroid, which are measured via SQUIDs. Classical CCC beam monitors make use of a high magnetic permeability core as a flux-concentrator for the pickup coil. The core increases the pickup inductance and thus coupling to the beam, but unfortunately also raises low-frequency noise and thermal drift. In the new concept from the Leibniz Institute of Photonic Technology the Coreless Cryogenic Current Comparator (4C) completely omits this core and instead uses highly sensitive SQUIDs featuring sub-micron cross-type Josephson tunnel junctions. Combined with a new shielding geometry a compact and comparably lightweight design has been developed, which exhibits a current sensitivity of about 6 pA/sqrt(Hz) in the white noise region and a measured shielding factor of about 134 dB*.

Published
2019
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14. Different Versions of Cryogenic Current Comparators with Magnetic Core for Beam Current Measurements

Author

Golm, Jessica, De Gersem, Herbert, Fernandes, Miguel, Haider, David, Kurian, Febin, Marsic, Nicolas, Müller, Wolfgang, Neubert, Ralf, Schmelz, Matthias, Schmidl, Frank, Schwickert, Marcus, Seidel, Paul, Sieber, Thomas, Stöhlker, Thomas, Stolz, Ronny, Tan, Jocelyn, Tympel, Volker, Welsch, Carsten, Zakosarenko, Vyacheslav, Boland, Mark (Ed.), Tanaka, Hitoshi (Ed.), Button, David (Ed.), Dowd, Rohan (Ed.), Schaa, Volker RW (Ed.), and Tan, Eugene (Ed.)

Subjects
Physics::Accelerator Physics, Nuclear Experiment, Accelerators and Storage Rings, 7. Clean energy, Accelerator Physics, MC6: Beam Instrumentation, Controls, Feedback and Operational Aspects
Abstract

For more than 20 years Cryogenic Current Comparators (CCC) are used to measure the current of charged particle beams with low intensity (nA-range). The device was first established at GSI in Darmstadt and was improved over the past two decades by the cooperation of institutes in Jena, GSI and CERN. The improved versions differ in material parameters and electronics to increase the resolution and in dimensions in order to meet the requirements of the respective application. The device allows non-destructive measurements of the charged particle beam current. The azimuthal magnetic field which is generated by the beam current is detected by low temperature Superconducting Quantum Interference Device (SQUID) current sensors. A complex shaped superconductor cooled down to 4.2 K is used as magnetic shielding and a high permeability core serves as flux concentrator. Three versions of the CCC shall be presented in this work: (1) GSI-Pb-CCC which was running at GSI Darmstadt in a transfer line, (2) CERN-Nb-CCC currently installed in the Antiproton Decelerator at CERN and (3) GSI-Nb-CCC-XD which will be operating in the CRYRING at GSI 2019. Noise, signal and drift measurements were performed in the Cryo-Detector Lab at the University of Jena., Proceedings of the 10th Int. Particle Accelerator Conf., IPAC2019, Melbourne, Australia

Published
2019
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15. en-usNext Generation Cryogenic Current Comparator (CCC) for nA Intensity Measurement

Author

Sieber, Thomas, De Gersem, Herbert, Golm, Jessica, Haider, David, Marsic, Nicolas, Müller, Wolfgang, Reeg, Hansjörg, Schmelz, Matthias, Schmidl, Frank, Schwickert, Marcus, Seidel, Paul, Stöhlker, Thomas, Stolz, Ronny, Tan, Jocelyn, Tranquille, Gerard, Tympel, Volker, Zakosarenko, Vyacheslav, Boland, Mark (Ed.), Tanaka, Hitoshi (Ed.), Button, David (Ed.), Dowd, Rohan (Ed.), Schaa, Volker RW (Ed.), and Tan, Eugene (Ed.)

Subjects
Accelerators and Storage Rings, 7. Clean energy, Accelerator Physics, MC6: Beam Instrumentation, Controls, Feedback and Operational Aspects
Abstract

A Cryogenic Current Comparator (CCC) is an extremely sensitive DC-Beam Transformer based on superconducting SQUID technology. Recently, a CCC without a toroidal core and with an axially oriented magnetic shielding has been developed at the Institute of Photonic Technologies (IPHT) Jena/Germany. It represents a compact and lightweight alternative to the ’classical’ CCC, which was originally developed at PTB Braunschweig and is successfully in operation in accelerators at GSI and CERN. Excellent low-frequency noise performance was demonstrated with a prototype of this new CCC-type. Current measurements and further tests are ongoing, first results are presented together with simulation calculations for the magnetic shielding. The construction from lead as well as simplified manufacturing results in drastically reduced costs compared to formerly used Nb-CCCs. Reduced weight also puts less constraints on the cryostat. Based on highly sensitive SQUIDs, the new prototype device shows a current sensitivity of about 6 pA/Hz1/2 in the white noise region. The measured and calculated shielding factor is ~135 dB. These values, together with a significant cost reduction - resulting also from a compact cryostat design - opens up the way for widespread use of CCCs in modern accelerator facilities., Proceedings of the 10th Int. Particle Accelerator Conf., IPAC2019, Melbourne, Australia

Published
2019
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16. First Measurements of a New Type of Coreless Cryogenic Current Comparators (4C) for Non-Destructive Intensity Diagnostics of Charged Particles

Author

Tympel, Volker, Anders, Solveig, De Gersem, Herbert, Golm, Jessica, Haider, David, Kunert, Juergen, Marsic, Nicolas, Müller, Wolfgang, Schmelz, Matthias, Schmidl, Frank, Schwickert, Marcus, Schönau, Thomas, Seidel, Paul, Sieber, Thomas, Stapelfeld, Max, Stöhlker, Thomas, Stolz, Ronny, Tan, Jocelyn, and Zakosarenko, Vyacheslav

Subjects
Accelerators and Storage Rings
Abstract

The non-destructive and highly sensitive measurement of a charged particle beam is of utmost importance for modern particle accelerator facilities. A Cryogenic Current Comparator (CCC) can be used to measure beam currents in the nA-range. Therein, charged particles passing through a superconducting toroid induce screening currents at the surface of the toroid, which are measured via SQUIDs. Classical CCC beam monitors make use of a high magnetic permeability core as a flux-concentrator for the pickup coil. The core increases the pickup inductance and thus coupling to the beam, but unfortunately also raises low-frequency noise and thermal drift. In the new concept from the Leibniz Institute of Photonic Technology the Coreless Cryogenic Current Comparator (4C) completely omits this core and instead uses highly sensitive SQUIDs featuring sub-micron cross-type Josephson tunnel junctions. Combined with a new shielding geometry a compact and comparably lightweight design has been developed, which exhibits a current sensitivity of about 6 pA/sqrt(Hz) in the white noise region and a measured shielding factor of about 134 dB*.

Published
2019

17. en-usComparative Measurement and Characterisation of Three Cryogenic Current Comparators Based on Low-Temperature Superconductors

Author

Tympel, Volker, De Gersem, Herbert, Fernandes, Miguel, Golm, Jessica, Haider, David, Kurian, Febin, Marsic, Nicolas, Müller, Wolfgang, Neubert, Ralf, Schmelz, Matthias, Schmidl, Frank, Schwickert, Marcus, Seidel, Paul, Sieber, Thomas, Stöhlker, Thomas, Stolz, Ronny, Tan, Jocelyn, Welsch, Carsten, Zakosarenko, Vyacheslav, and Schaa, Volker RW (Ed.)

Subjects
Accelerator Physics, 2. Beam charge and current monitors
Abstract

A Cryogenic Current Comparator (CCC) is a non-destructive, metrological-traceable charged particle beam intensity measurement system for the nano-ampere range. Using superconducting shielding and coils, low temperature Superconducting Quantum Interference Devices (SQUIDs) and highly permeable flux-concentrators, the CCC can operate in the frequency range from DC to several kHz or hundreds of kHz depending on the requirement of the application. Also, the white noise level can be optimized down to 2 pA/sqrt(Hz) at 2.16 K. This work compares three different Pb- and Nb-based CCC-sensors developed at the Institute of Solid State Physics and Leibniz Institute of Photonic Technology at Jena, Germany: CERN-Nb-CCC, optimized for applica-tion at CERN Antiproton Decelerator (AD) in 2015 with a free inner diameter of 185 mm; GSI-Pb-CCC, designed for GSI-Darmstadt with a free inner diameter of 145 mm, 1996 completed, 2014 upgraded; GSI-Nb-CCC-XD, de-signed for the GSI/FAIR-project with a free inner diame-ter of 250 mm, 2017 completed. The results of noise, small-signal, slew-rate, and drift measurements done 2015 and 2018 in the Cryo-Detector Lab at the University of Jena are presented here.

Published
2019
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18. Beam Intensity Monitoring with nanoampere resolution - the cryogenic current comparator (CCC)

Author

Haider, David, De Gersem, Herbert, Fernandes, Miguel, Forck, Peter, Golm, Jessica, Kurian, Febin, Marsic, Nicolas, Schmelz, Matthias, Schmidl, Frank, Schwickert, Marcus, Seidel, Paul, Sieber, Thomas, Stöhlker, Thomas, Stolz, Ronny, Tan, Jocelyn, Tympel, Volker, Zakosarenko, Vyacheslav, and Schaa, Volker RW (Ed.)

Subjects
Physics::Instrumentation and Detectors, Physics::Accelerator Physics, Accelerators and Storage Rings, Accelerator Physics, 2. Beam charge and current monitors
Abstract

The storage of low current beams as well as the long extraction times from the synchrotrons at FAIR require non-destructive beam intensity monitoring with a current resolution of nanoampere. To fulfill this requirement, the concept of the Cryogenic Current Comparator (CCC), based on the low temperature SQUID, is used to obtain an extremely sensitive beam current transformer. During the last years, CCCs have been installed to do measurements of the spill structure in the extraction line of GSI SIS18 and for current monitoring in the CERN Antiproton Decelerator. From these experiences lessons can be learned to facilitate further developments. The goal of the ongoing research is to improve the robustness of the CCC towards external influences, such as vibrations, stray fields and He-pressure variations, as well as to develop a cost-efficient concept for the superconducting shield and the cryostat., Proceedings of the 7\textsuperscript{th} Int. Beam Instrumentation Conf., IBIC2018, Shanghai, China

Published
2018
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19. Optimization of the Cryogenic Current Comparator (CCC) for Beam Intensity Measurement

Author

Sieber, Thomas, De Gersem, Herbert, Fernandes, Miguel, Golm, Jessica, Jones, Robert, Kowina, Piotr, Kurian, Febin, Marsic, Nicolas, Neubert, Ralf, Reeg, Hansjörg, Schmelz, Matthias, Schmidl, Frank, Schwickert, Marcus, Seidel, Paul, Søby, Lars, Stöhlker, Thomas, Stolz, Ronny, Tan, Jocelyn, Tranquille, Gerard, Tympel, Volker, Welsch, Carsten, and Zakosarenko, Vyacheslav

Subjects
8 Charge Monitors and Other Instruments, Accelerators and Storage Rings, Accelerator Physics
Abstract

Triggered by the need for current measurement in the nA range for slow extracted beams and for the beams in the storage rings at FAIR and CERN, the idea of the CCC as a current transformer has been revitalized during the last ten years. Compared to the first prototype, developed at GSI in the 90s, the second generation of CCCs is based on the possibility of detailed simulation of superconducting magnetic shielding properties, new nano-crystalline materials for the magnetic ring-cores, and on superior commercially available SQUID systems. In 2014, nA resolution measurements at 2 kHz bandwidth demonstrated the possibility of spill analysis at slow extracted beams from GSI SIS18. In the following year, the first stand-alone CCC system, including a cryostat with separate He liquefier, started operation in the CERN AD. Although the existing systems show an outstanding current resolution, their cost efficiency and robustness, as well as noise and vibration sensitivity can still be improved, which is subject of ongoing research. In this contribution recent results of our CCC tests are shown and future developments are discussed., Proceedings of the 6th Int. Beam Instrumentation Conf., IBIC2017, Grand Rapids, MI, USA

Published
2018
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20. Cryogenic Current Comparators for 150 mm Beamline Diameter

Author

Tympel, Volker, Kurian, Febin, Neubert, Ralf, Schmelz, Matthias, Schmidl, Frank, Schwickert, Marcus, Seidel, Paul, Sieber, Thomas, Stöhlker, Thomas, Stolz, Ronny, and Zakosarenko, Vyacheslav

Subjects
8 Charge Monitors and Other Instruments, Accelerator Physics
Abstract

New versions of Cryogenic Current Comparator (CCC) sensors with eXtended Dimensions (CCC-XD) for beam line diameters up to 150 mm (necessary for the planned new Facility for Antiproton and Ion Research (FAIR) at GSI (Gesellschaft für Schwerionenforschung) have been realized. These non-destructive charged particle beam monitoring systems are able to measure intensities in the nA-range with a white noise level below 5 pA/sqrt(Hz). The systems are sensitive from DC to several hundred kHz and can be linked-up in a traceable way with national and international ampere-standards. In its present design, the base body consists of a highly-permeable, nano-crystalline core optimized for low-temperatures (ready for superfluid He-II applications) and a niobium shielding/pickup-coil unit. The flexible SQUID (Superconducting Quantum Interference Device) - cartridge allows for application tuning. Three cartridge versions (direct, balanced and enhanced) will be presented, discussed and results of electrical laboratory measurements of the noise behaviour and the frequency response will be given., Proceedings of the 6th Int. Beam Instrumentation Conf., IBIC2017, Grand Rapids, MI, USA

Published
2018
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21. A Cryogenic Current Comparators (CCC) Customized for FAIR-Project

Author

Golm, Jessica, Haider, David, Kurian, Febin, Neubert, Ralf, Schmelz, Matthias, Schmidl, Frank, Schwickert, Marcus, Seidel, Paul, Sieber, Thomas, Stöhlker, Thomas, Stolz, Ronny, Tympel, Volker, Zakosarenko, Vyacheslav, Satogata, Todd (Ed.), and Schaa, Volker RW (Ed.)

Subjects
T03 Beam Diagnostics and Instrumentation, Physics::Accelerator Physics, 06 Beam Instrumentation, Controls, Feedback, and Operational Aspects, Physics::Atomic Physics, Nuclear Experiment, 7. Clean energy, Accelerator Physics
Abstract

The principle of non-destructive measurement of ion beams by detection of the azimuthal magnetic field, using low temperature Superconducting Quantum Interference Device (SQUID) sensors, has been established at GSI already in the mid 90's. After more recent developments at Jena, GSI and CERN, a CCC was installed in the CERN Antiproton Decelerator (AD) and is operated there routinely as the first stand-alone CCC system. For the Facility for Antiproton and Ion Research (FAIR) a new version of the CCC with eXtended Dimensions (CCC-XD) - especially with a larger inner diameter and adapted parameters - was constructed and first lab tests have already been performed. In parallel, a concept for a dedicated UHV beamline cryostat has been worked out. The CCC-XD system - together with the new cryostat - will be ready for testing in the CRYRING at GSI before the end of 2018. In this contribution, experimental results for the resolution, frequency range, slew rate and pulse-signal obtained by electrical laboratory measurements with the CCC-XD are presented., Proceedings of the 9th Int. Particle Accelerator Conf., IPAC2018, Vancouver, BC, Canada

Published
2018
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22. Development of SQUID Amplifiers for Axion Search Experiments

Author

Uchaikin, Sergey, primary, Urade, Yoshiro, additional, Kono, Shingo, additional, Schmelz, Matthias, additional, Stolz, Ronny, additional, Nakamura, Yasunobu, additional, Matlashov, Andrei, additional, Lee, Doyu, additional, Chung, Woohyun, additional, Oh, Seon Jeong, additional, Semertzidis, Yannis, additional, Zakosarenko, Vyacheslav, additional, Kutlu, Caglar, additional, and van Loo, Arjan, additional

Published
2019
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24. Cryogenic Current Comparators for Larger Beamlines

Author

Seidel, Paul, primary, Tympel, Volker, additional, Neubert, Ralf, additional, Golm, Jessica, additional, Schmelz, Matthias, additional, Stolz, Ronny, additional, Zakosarenko, Vyacheslav, additional, Sieber, Thomas, additional, Schwickert, Marcus, additional, Kurian, Febin, additional, Schmidl, Frank, additional, and Stohlker, Thomas, additional

Published
2018
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26. Progress in passive submillimeter-wave video imaging

Author

Heinz, Erik, additional, May, Torsten, additional, Born, Detlef, additional, Zieger, Gabriel, additional, Peiselt, Katja, additional, Zakosarenko, Vyacheslav, additional, Krause, Torsten, additional, Krüger, André, additional, Schulz, Marco, additional, Bauer, Frank, additional, and Meyer, Hans-Georg, additional

Published
2014
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28. Development of passive submillimeter-wave video imaging systems

Author

Heinz, Erik, primary, May, Torsten, additional, Born, Detlef, additional, Zieger, Gabriel, additional, Peiselt, Katja, additional, Brömel, Anika, additional, Anders, Solveig, additional, Zakosarenko, Vyacheslav, additional, Krause, Torsten, additional, Krüger, André, additional, Schulz, Marco, additional, and Meyer, Hans-Georg, additional

Published
2013
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31. The next generation of cryogenic current comparators for beam monitoring

Author

Tympel, Volker, Golm, Jessica, Kurian, Febin, Neubert, Ralf, Schmelz, Matthias, Schwickert, Marcus, Seidel, Paul, Sieber, Thomas, Stöhlker, Thomas, Stolz, Ronny, and Zakosarenko, Vyacheslav

Subjects
Condensed Matter::Superconductivity, Physics::Accelerator Physics, Charge Monitors and Other Instruments, Accelerator Physics
Abstract

A new Cryogenic Current Comparator with eXtended Dimensions (CCC-XD) is currently under development for a non-destructive, highly sensitive monitoring of nA-intensities of beams for larger beamline diameters planned for the new FAIR accelerator facility at GSI. The CCC consists of a superconducting coil which is read out by a Superconducting Quantum Interference Device (SQUID), a flux concentrator and a superconducting shield. The new flux concentrator comprises of a specially designed, highly permeable core made of nanocrystalline material in order to assure a low-noise operation and a high system bandwidth of up to 200 kHz. The superconducting shielding of niobium has extended geometric dimensions and will suppress disturbing magnetic fields of the beamline environment effectively. New SQUID sensors with sub-μm-Josephson junctions enable extreme low-noise signals and high disturbance-suppression. The CCC-XD system and the new dedicated cryostat will be ready for testing in the CRYRING at GSI in 2017. Results from electrical measurements with the components of the new CCC-XD Setup will be presented in this work., Proceedings of the 5th Int. Beam Instrumentation Conf., IBIC2016, Barcelona, Spain

32. First Measurements of a New Type of Coreless Cryogenic Current Comparators (4C) for Non-Destructive Intensity Diagnostics of Charged Particles

Author

Tympel, Volker, Anders, Solveig, De Gersem, Herbert, Golm, Jessica, Haider, David, Kunert, Juergen, Marsic, Nicolas, Müller, Wolfgang, Schmelz, Matthias, Schmidl, Frank, Schwickert, Marcus, Schönau, Thomas, Seidel, Paul, Sieber, Thomas, Stapelfeld, Max, Stöhlker, Thomas, Stolz, Ronny, Tan, Jocelyn, and Zakosarenko, Vyacheslav

Subjects
Beam charge and current monitors, 7. Clean energy, Accelerator Physics
Abstract

The non-destructive and highly sensitive measurement of a charged particle beam is of utmost importance for modern particle accelerator facilities. A Cryogenic Current Comparator (CCC) can be used to measure beam currents in the nA-range. Therein, charged particles passing through a superconducting toroid induce screening currents at the surface of the toroid, which are measured via SQUIDs. Classical CCC beam monitors make use of a high magnetic permeability core as a flux-concentrator for the pickup coil. The core increases the pickup inductance and thus coupling to the beam, but unfortunately also raises low-frequency noise and thermal drift. In the new concept from the Leibniz Institute of Photonic Technology the Coreless Cryogenic Current Comparator (4C) completely omits this core and instead uses highly sensitive SQUIDs featuring sub-micron cross-type Josephson tunnel junctions. Combined with a new shielding geometry a compact and comparably lightweight design has been developed, which exhibits a current sensitivity of about 6 pA/sqrt(Hz) in the white noise region and a measured shielding factor of about 134 dB*., Proceedings of the 8th International Beam Instrumentation Conference, IBIC2019, Malmö, Sweden

33. Comparative Measurement and Characterisation of Three Cryogenic Current Comparators Based on Low-Temperature Superconductors

Author

Tympel, Volker, De Gersem, Herbert, Fernandes, Miguel, Golm, Jessica, Haider, David, Kurian, Febin, Marsic, Nicolas, Müller, Wolfgang, Neubert, Ralf, Schmelz, Matthias, Schmidl, Frank, Schwickert, Marcus, Seidel, Paul, Sieber, Thomas, Stöhlker, Thomas, Stolz, Ronny, Tan, Jocelyn, Welsch, Carsten, and Zakosarenko, Vyacheslav

Subjects
7. Clean energy, Accelerator Physics, 2. Beam charge and current monitors
Abstract

A Cryogenic Current Comparator (CCC) is a non-destructive, metrological-traceable charged particle beam intensity measurement system for the nano-ampere range. Using superconducting shielding and coils, low temperature Superconducting Quantum Interference Devices (SQUIDs) and highly permeable flux-concentrators, the CCC can operate in the frequency range from DC to several kHz or hundreds of kHz depending on the requirement of the application. Also, the white noise level can be optimized down to 2 pA/sqrt(Hz) at 2.16 K. This work compares three different Pb- and Nb-based CCC-sensors developed at the Institute of Solid State Physics and Leibniz Institute of Photonic Technology at Jena, Germany: CERN-Nb-CCC, optimized for applica-tion at CERN Antiproton Decelerator (AD) in 2015 with a free inner diameter of 185 mm; GSI-Pb-CCC, designed for GSI-Darmstadt with a free inner diameter of 145 mm, 1996 completed, 2014 upgraded; GSI-Nb-CCC-XD, de-signed for the GSI/FAIR-project with a free inner diame-ter of 250 mm, 2017 completed. The results of noise, small-signal, slew-rate, and drift measurements done 2015 and 2018 in the Cryo-Detector Lab at the University of Jena are presented here., Proceedings of the 7\textsuperscript{th} Int. Beam Instrumentation Conf., IBIC2018, Shanghai, China

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