Publications

Dr. Shahab Sanjari

Online version of this page with clickable links:

http://web-docs.gsi.de/~ssanjari/pages/publications.html


Contents:


Books

2022

  • Der Kalligraph von Lanzhou und andere Kurzgeschichten, M. S. Sanjari, 2022 ePubli Berlin / Frankfurt am Main ISBN-13: 978-3-7565-0892-1 (Fiction / short stories in German)

Software

2023

  • PyScript for scientific projects: an introduction, Quanchao Song and M. S. Sanjari. Zenodo, 7907143, (2023) DOI:10.5281/zenodo.7907143

  • iqtools: Collection of code for working with offline complex valued time series data in Python. M. S. Sanjari. Zenodo, 7615693, (2023) DOI:10.5281/zenodo.7615693

Journal and conference publications

2023

  • Determining neutron-induced reaction cross sections through surrogate reactions at storage rings, M. Sguazzin et al J. Phys.: Conf. Ser. 2586 012082 (2023) DOI:10.1088/1742-6596/2586/1/012082

  • Proton capture on stored radioactive 118Te ions, S. F. Dellmann et. al. EPJ Web of Conferences 279, 11018, (2023) DOI:10.1051/epjconf/202327911018

  • Indirect measurements of neutron-induced reaction cross sections at storage rings, M. Sguazzin et. al. EPJ Web of Conferences 279, 11006, (2023) DOI:10.1051/epjconf/202327911006

  • Storage, accumulation and deceleration of secondary beams for nuclear astrophysics, J. Glorius et. al., NIM-B, 541, pp 190-193 DOI:10.1016/j.nimb.2023.04.059

2022

  • X-ray emission associated with radiative recombination for Pb82+ ions at threshold energies, B. Zhu et. al., Phys. Rev. A 105, 052804 (2022) DOI:0.1103/PhysRevA.105.052804

  • Single and double K-shell vacancy production in slow Xe54+,53+-Xe collisions, P.-M. Hillenbrand et al., Phys. Rev. A 105, 022810 (2022) DOI:10.1103/PhysRevA.105.022810

2021

  • Electron-loss-to-continuum cusp in collisions of U89+ with N2 and Xe, P.-M. Hillenbrand et al., Phys. Rev. A 104, 012809 (2021) DOI:10.1103/PhysRevA.104.012809

2020

  • A 410 MHz resonant cavity pickup for heavy ion storage rings, M. S. Sanjari et. al. The Review of scientific instruments 91(8), pp. 083303 (2020) DOI:10.1063/5.0009094

  • Electron capture of Xe54+ in collisions with H2 molecules in the energy range between 5.5 and 30.9 MeV/u, F. M. Kröger et. al., Phys. Rev. A 102, 042825 (2020) DOI:10.1103/PhysRevA.102.042825

  • Software defined radio for Schottky analysis in storage rings, D. Dmytriiev et. al. 2020 J. Phys.: Conf. Ser. 1668 012014 DOI:10.1088/1742-6596/1668/1/012014

  • Radiative electron capture to the continuum in U89+ + N2 collisions: Experiment and theory, P.-M. Hillenbrand et al. Phys. Rev. A 101, 022708 (2020) DOI:10.1103/PhysRevA.101.022708

  • Position sensitive resonant Schottky cavities for heavy ion storage rings, D. Dmytriiev et. al., Nuclear Instruments and Methods in Physics Research, Section B: 463, pp. 320-323 (2020) DOI:10.1016/j.nimb.2019.04.074

  • Towards experiments with highly charged ions at HESR. R. Sanchez et. al. X-Ray Spectrometry 49(1), pp. 33-36 (2020) DOI:10.1002/xrs.3041

  • High‐resolution wavelength‐dispersive spectroscopy of K‐shell transitions in hydrogen‐like gold, T. Gassner et. al. X-Ray Spectrometry 49(1), pp. 204-208 (2020) DOI:10.1002/xrs.3098

2019

  • New test of modulated electron capture decay of hydrogen-like 142Pm ions: Precision measurement of purely exponential decay, F. C. Ozturk et. al., Phys. Let. B v 797, 134800 (2019) DOI:10.1016/j.physletb.2019.134800

  • Approaching the Gamow window with stored ions: Direct measurement of 124Xe(p,γ) in the ESR storage ring, J. Glorius et. al. Phys. Rev. Lett. 122, 092701 (2019) DOI:10.1103/PhysRevLett.122.092701

  • Position sensitive resonant Schottky cavities for heavy ion storage rings. D. Dmytriiev et. al. Proc. EMIS conf. (2019) DOI:10.1016/j.nimb.2019.04.074

2018

  • Wavelength-dispersive spectroscopy in the hard x-ray regime of a heavy highly-charged ion: the 1s Lamb shift in hydrogen-like gold, T. Gassner et. al. N. J. Phys 20 (2018) DOI:10.1088/1367-2630/aad01d

  • Electroweak Decays of Highly Charged Ions, R. S. Sidhu et. al. EPJ Web of Conferences 178, 01003 (2018) DOI:10.1051/epjconf/201817801003

2017

2016

2015

  • Accuracy improvement in the isochronous mass measurement using a cavity doublet. X. Chen et. al. Hyperfine Interactions 05-2015. DOI:10.1007/s10751-015-1183-3

  • Between atomic and nuclear physics: radioactive decays of highly-charged ions, Dinko Atanasov et. al. J. Phys. B: At. Mol. Opt. Phys. 48 (2015) 144024. DOI:10.1088/0953-4075/48/14/144024

  • Total projectile electron loss cross sections of U28+ ions in collisions with gaseous targets ranging from hydrogen to krypton, G. Weber et. al. Phys. Rev. STAB, 18, 034403 (2015) DOI:10.1103/PhysRevSTAB.18.034403

  • Experiments with Stored Highly Charged Ions at the Border between Atomic and Nuclear Physics, B. S. Gao et. al. Physics Procedia 66 (2015) pp 28. DOI:10.1016/j.phpro.2015.05.006

  • Radioactive decays of highly-charged ions, B. S. Gao et. al. EPJ Web of Conferences 93, 05003 (2015) DOI:10.1051/epjconf/20159305003

2014

  • Conceptual design of elliptical cavities for intensity and position sensitive beam measurements in storage rings. M. S. Sanjari et. al. 2015 Phys. Scr. 2015 T166 014060 DOI:10.1088/0031-8949/2015/T166/014060

  • A new data acquisition system for Schottky signals in atomic physics experiments at GSI’s and FAIR’s storage rings, Ch. Trageser et. al., Phys. Scr, 2015 T166 014062 DOI:10.1088/0031-8949/2015/T166/014062

  • Laser cooling of stored relativistic ion beams with large momentum spreads using a laser system with a wide scanning range, W. Wen et. al. J. Phys.: Conf. Ser. 488 122005 (2014). DOI:10.1088/1742-6596/488/12/122005

2013

2012

2011

  • A fast and sensitive resonant Schottky pick-up for heavy ion storage rings, F. Nolden et. al. Nuclear Instruments and Methods A, v. 659 No. 1 pp. 69–77 (2011). DOI:10.1016/j.nima.2011.06.058

  • Simulation and measurement of the resonant Schottky pickup, Y. D. Zang et. al. Chinese Physics C, v. 35 No. 12 p. 1124 (2011). DOI:10.1088/1674-1137/35/12/008

Other publications and scientific reports

2018

  • Progress of a variable sensitivity resonant Schottky pick-up cavity, M. S. Sanjari et. al. GSI Scientific Report RESEARCH-APPA-AP-25 (2017) DOI:10.15120/GSI-2017-01856

  • Mode-dependent loading of resonant pick-up cavities, D. Dmytriiev et. al. GSI Scientific Repor RESEARCH-APPA-AP-27 (2017) DOI:10.15120/GSI-2017-01856

  • Electron capture decay of hydrogen-like 142Pm ions: status of data analysis, F. C. Ozturk et. al. GSI Scientific Report RESEARCH-APPA-AP-30 (2017) DOI:10.15120/GSI-2017-01856

  • S. Litvinov et. al. Selection of β-decay daughters in the ESR, GSI Scientific Report ACCELERATOROPERATIONS-ESR-2 (2017) DOI:10.15120/GSI-2017-01856

2017

  • A continuous data logger for the ESR current transformer, M. S. Sanjari et. al. GSI Scientific Report, RESEARCH-APPA-AP-6 (2016) DOI:10.15120/GR-2017-1

  • Asymmetries of the electron cusp in heavy-ion atom collisions, P.-M. Hillenbrand et. al. GSI Scientific Report, RESEARCH-APPA-AP-2 (2016) DOI:10.15120/GR-2017-1

  • High-resolution wavelength-dispersive spectroscopy of K-shell transitions in hydrogen-like gold, T. Gassner et. al. GSI Scientific Report, RESEARCH-APPA-AP-3 (2016) DOI:10.15120/GR-2017-1

  • Proton and α capture studies for nuclear astrophysics at GSI storage rings, J. Glorius et. al. GSI Scientific Report, RESEARCH-APPA-AP-5 (2016) DOI:10.15120/GR-2017-1

  • ESR operation and development, C. Dimopoulou et. al. GSI Scientific Report, ACCELERATOROPERATIONS-ESR-1 (2016) DOI:10.15120/GR-2017-1

2016

  • Analysis of the revolution frequency stability in the ESR during the E82 experiment using resonant the Schottky pickup, M. S. Sanjari et. al. GSI Scientific report 2015. DOI:10.15120/GR-2016-1

  • Python code for Schottky analysis in storage ring experiments, M. S. Sanjari et. al. GSI Scientific report 2015. DOI:10.15120/GR-2016-1

  • Intensity-sensitive and position-resolving cavity for the CR: proof of principle, X. Chen et. al. GSI Scientific report 2015. DOI:10.15120/GR-2016-1

  • Schottky beam time “logbook” for laser spectroscopy of Bi82+ and Bi80+, C. Trageser et. al. GSI Scientific report 2015. DOI:10.15120/GR-2016-1

  • Many-electron projectile stripping cross section studies at the ESR gas target, G. Weber et. al. GSI Scientific report 2015. DOI:10.15120/GR-2016-1

2015

2014

  • Conceptual design of elliptical cavity beam position monitors for heavy ion storage rings, M. S. Sanjari, IBIC-2014: International Beam Instrumentation Conference, Monterey, Ca, USA. LINK 🔗

2013

  • Sensitivity measurements of the resonant pickup in the ESR, M. S. Sanjari et. al. GSI Scientific report PNI-ACC-03 (2012). LINK 🔗

  • Single Differential Cross Section dσ/dEelectron for Projectile Ionization of U28+ Ions at 30-50 AMeV measured in the ESR, S. Hagmann et. al. GSI Scientific report PNI-INHOUSE-EXP-03 (2012). LINK 🔗

  • Laser cooling of stored relativistic C3+ ions at the ESR, D. F. A. Winters et. al. GSI Scientific report PNI-IONS-EXP-05 (2012).LINK 🔗

  • FOCAL X-ray spectroscopy for QED in strong fields, H. F. Beyer et. al. GSI Scientific report PNI-IONS-EXP-02 (2012). LINK 🔗

2012

  • Bead-pull Measurement on the Resonator Pick-up at IMP, Lanzhou, M. S. Sanjari et. al. GSI Scientific report 2011. LINK 🔗

  • A new resonator Schottky pick-up for short-lived nuclear investigations, B. Sun et. al. GSI Scientific report 2011. LINK 🔗

  • Orbital electron capture of stored highly charged 122I ions, N. Winckler et. al. GSI Scientific report 2011. LINK 🔗

  • Long-lived nuclear and atomic states explored using dielectronic recombination, C. Brandau et. al. GSI Scientific report 2011. LINK 🔗

  • Mass measurements of neutron-rich 197Au projectile fragments at the ESR, D. Shubina et. al. GSI Scientific report 2011. LINK 🔗

  • Measurement of α-decay half-life of bare and H-like 213Fr ions, F. Farinon et. al. GSI Scientific Report 2011. LINK 🔗

2011

  • A Sensitive Resonant Schottky Pick-Up for the ESR Storage Ring at GSI, F. Nolden et. al. Proceedings of the 10th European Workshop on Beam Diagnostics and Instrumentation for Particle Accelerators (DIPAC-2011), Hamburg, Germany. LINK 🔗

  • A new resonant Schottky pickup for nuclear physics measurements of highly charged ions in storage rings, M. S. Sanjari, German Physical Society Spring Meeting 2011, Münster, Germany. LINK 🔗

  • Measurement of α-decay half-life of bare and H-like 213Fr ions, F. Farinon et. al. GSI Scientific Report 2010. LINK 🔗

  • Investigation of neutron-rich 197Au projectile fragments with Schottky mass spectrometry at the ESR, D. Shubina et. al.GSI Scientific Report 2010. LINK 🔗

  • Longitudinal momentum distribution of monoenergetic electron neutrinos from orbital electron capture decay, N. Winckler et. al. GSI Scientific Report 2010. LINK 🔗

  • ESR Operation and Development, C. Dimopoulou et. al. GSI Scientific Report 2010. LINK 🔗

  • A New Resonant Schottky Pickup for the ESR at GSI, F. Nolden et. al. GSI Scientific Report 2010. LINK 🔗

2010

  • A High-Speed Data Converter for Digital Control of Synchrotron RF Cavities, M. S. Sanjari et. al. GSI Scientific Report GSI-ACCELERATORS-07 (2009). LINK 🔗

2008

  • Digital Hilbert transformers for FPGA-based phase-locked loops, M. Kumm and M. S. Sanjari, International Conference on Field Programmable Logic and Applications FPL 2008, Heidelberg, Germany. DOI:10.1109/FPL.2008.4629940

2007

  • Realtime Communication Based on Optical Fibers for the Control of Digital RF Components, M. Kumm et. al. GSI Scientific Report GSI-ACCELERATORS-14 (2006). LINK 🔗

2005

  • Article about CAN Bus components for industrial electronic applications in CAN magazine, bibliographical information ist lost.

Academic Theses

2013

  • Resonant pickups for non-destructive single-particle detection in heavy-ion storage rings and first experimental results, M. S. Sanjari, PhD Thesis, Institute of Applied Physics, Goethe University, Frankfurt am Main, Germany. LINK 🔗

2009

  • Novel Diode Structures Based on Polar and Non-polar III-Nitride Semiconductors, M. S. Sanjari, Masters’ Thesis, Technische Universität Darmstadt, Germany. DOI:10.26083/tuprints-00023080

2006

  • Hardware and software implementation of a radio frequency high-speed data conversion unit for digital control systems, M. S. Sanjari, Bachelors’ Thesis, Technische Universität Darmstadt, Germany. DOI:10.26083/tuprints-00023078