2026-05-17T07:35:08Z https://rodare.hzdr.de/oai2d

oai:rodare.hzdr.de:1601 2024-08-12T07:31:08Z openaire_data user-matter user-rodare user-mu2e user-elbe user-γelbe

Price, Joseph Müller, Stefan Ferrari, Anna Knodel, Oliver Voigt, Martin Keshavarzi, Alexander Motuk, Erdem Judson, Daniel Koltick, David Miller, James Plesniak, Pawel Edmonds, Andrew Ufer, Robert Huang, Shihua Chen, Jijun Chislett, Rebecca Lancaster, Mark Rachamin, Reuven Tickle, Steven Alvarez, Claudia Ginther, George Harkness-Brennan, Laura 2022-05-05 These data were taken to characterize the performance and test the data acquisition system of two detectors to be used to monitor the stopping target for the forth-coming Mu2e experiment at Fermilab; the High Purity Germanium (HPGe) and Lanthanum Bromide (LaBr) Detectors, in the presence of the pulsed gamma beam at ELBE. This measurement is crucial for the normalisation of the Mu2e experiment. The corresponding beamtime was carried out at the gELBE bremsstrahlung beamline of HZDR's ELBE radiation facility from April 21 to April 25, 2022 (GATE ID: 21202619-ST). The data sets represent the data taken with the LaBr detector by means of an ORTEC DSPEC 50 and a Lecroy/Teledyne HDO4104 oscilloscope. https://rodare.hzdr.de/record/1601 10.14278/rodare.1601 oai:rodare.hzdr.de:1601 eng doi:10.17815/jlsrf-2-58 doi:10.58065/24020 handle:20.500.12865/HZDR.Projects.2022.FWCC.Project.74 url:https://www.hzdr.de/publications/Publ-34624 doi:10.14278/rodare.1600 url:https://rodare.hzdr.de/communities/elbe url:https://rodare.hzdr.de/communities/matter url:https://rodare.hzdr.de/communities/mu2e url:https://rodare.hzdr.de/communities/rodare url:https://rodare.hzdr.de/communities/γelbe info:eu-repo/semantics/restrictedAccess dataset detector HPGe LaBr3 Stopping target Monitor (STM) Mu2e gELBE Data Mangement DAQ muon conversion Test of the detector system for the Stopping Target Monitor of the Mu2e experiment in the presence of a high flux gamma background info:eu-repo/semantics/other dataset

oai:rodare.hzdr.de:2807 2025-10-02T06:04:31Z openaire_data user-hzdr user-fwk user-health user-rodare user-elbe user-γelbe user-oncoray

García Rivas, Iris Fernández Prieto, Antonio Kögler, Toni Römer, Katja Hueso González, Fernando 2024-04-16 This repository contains raw experimental data acquired during the gELBE beam time performed in October 2023 under proposal number 23203137-ST, at Helmholtz-Zentrum Dresden - Rossendorf. In this setup, a bremsstrahlung beam of up to 12.5 MeV energy in 13 MHz pulses irradiates a CeBr3 scintillation detector (by Hilger®) of Ø 1'' x 1'', coupled to a Hamamatsu® R13408-100 PMT, custom voltage divider and shaping electronics, and a commercial digitizer (SFMC01+SIS1160) by Struck®, containing an AD9689 chip that supports a data sampling rate of 2.5 Gsps and 14-bits. This detector is developed in the context of the coaxial prompt gamma-ray monitoring method [1], where very high count rates are expected [2]. The dead-time-free data acquisition is programmed in-house using ROOT [3]. In addition, a plastic scintillation detector (paddle) was placed inbetween the beam and the CeBr3 crystal to serve as reference beam monitor. An Arduino is used to monitor the high-voltage supply for the PMT and active divider electronics in terms of current, voltage and temperature. A Comet Systems® T7310 is used to monitor ambient temperature, humidity and pressure. The published data consist of the raw signal waveforms acquired during ~450 measurements. Each measurement is stored in a separate folder, its name being the acquisition time start, and lasts between 3 and 20 seconds (16 GiB up to 100 GiB). The data format is little-endian binary. Each sample uses two bytes, being the 14 first bits the digitized signal in a 1.7 Vpp range, and the 15th bit the (negated) logic status of the reference beam monitor (paddle). Samples are stored consecutively, without headers. Sample time separation is 0.4 ns (2.5 Gsps). The digitizer is phase-locked to the accelerator radiofrequency (RF), so that each 2500 stored samples correspond to 13 consecutive periods of 13 MHz. The data can be directly opened using the open-source pulse visualization software (PulseSurfer) available in this link: https://igit.ific.uv.es/ferhue/pulse-surfer/, with ROOT as a dependency. One just needs to run: root -l test_gui.cpp+(\"/path-to-folder/chA.bin\") and then set 192.307692307692307696 in the "Cycle" box. Use the slider in the bottom to navigate across different consecutive frames. To visualize the paddle counter (negated) logic status, change the "Mask" box from 3FFF to 4000. There is also a checkbox to activate the baseline subtraction. In addition to the raw waveform data (chA.bin), each folder contains following metadata: log.root a ROOT file storing all the measurement and hardware settings as TObjString. It also contains the T7310 monitoring as a TTree ("pth") chA.root a ROOT file storing a TTree that benchmarks the readout speed of the DAQ for this channel zdt.log a text file storing the output printed by the DAQ software to terminal gui.png Screenshot of the DAQ window hv.txt a test file storing the monitoring of the high-voltage supply and electronics This activity has received funding from the European Union's 2020 research and innovation programme under grant agreement No 101008126, corresponding to the RADNEXT project. Also we received funding from the Conselleria de Educación, Investigación, Cultura y Deporte (Generalitat Valenciana) under grant number CDEIGENT/2019/011 In addition we received funding from the: Industrial Doctorates Program of the Xunta de Galicia (Consellería de Cultura, Educación, Formación Profesional e Universidades), the CONSOLIDACIÓN 2022 GRC GI-1490 - Grupo de Física de Altas Enerxías - GAES -- ED431C 2022/30 and the Studying Leptopic Flavour Universality and nuclear structure with the enhanced LHCb experiment -- PID2019-110378GB-I00 and from the PTCOG Project Funding 2024 - Physics https://rodare.hzdr.de/record/2807 10.14278/rodare.2807 oai:rodare.hzdr.de:2807 eng doi:10.58065/24020 doi:10.17815/jlsrf-2-58 doi:10.1016/j.nima.2022.166701 doi:10.1016/j.nima.2018.09.062 doi:10.1016/j.sna.2023.114859 doi:10.1109/TRPMS.2019.2930362 doi:10.1088/1361-6560/ab176d doi:10.1109/JSEN.2021.3062428 url:https://www.hzdr.de/publications/Publ-39098 url:https://www.hzdr.de/publications/Publ-41810 doi:10.14278/rodare.2806 url:https://rodare.hzdr.de/communities/elbe url:https://rodare.hzdr.de/communities/fwk url:https://rodare.hzdr.de/communities/health url:https://rodare.hzdr.de/communities/hzdr url:https://rodare.hzdr.de/communities/oncoray url:https://rodare.hzdr.de/communities/rodare url:https://rodare.hzdr.de/communities/γelbe info:eu-repo/semantics/openAccess https://creativecommons.org/licenses/by/4.0/legalcode Proton Therapy Range Verification High-count rate photon detection high speed digitizers pile-up deconvolution High-count rate photon detection with scintillators coupled to photomultiplier tubes and fast digitizers info:eu-repo/semantics/other dataset