SPIDER, the Negative Ion Source Prototype for ITER: Overview of Operations and Cesium Injection
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R. Zagórski | E. Gaio | M. Bigi | A. Luchetta | G. Manduchi | D. Aprile | G. Chitarin | V. Toigo | M. Brombin | R. Cavazzana | M. Zuin | F. Fellin | M. Spolaore | G. Serianni | R. Pasqualotto | L. Grando | D. Marcuzzi | C. Taliercio | P. Zaccaria | B. Zaniol | L. Zanotto | P. Agostinetti | M. Barbisan | M. Boldrin | R. Delogu | A. Maistrello | M. Pavei | N. Pilan | M. Recchia | A. Rizzolo | E. Sartori | A. Muraro | G. Croci | O. McCormack | A. Shepherd | M. Dan | G. Berton | A. Pimazzoni | R. Agnello | M. Cavenago | S. Cristofaro | S. Denizeau | T. Patton | N. Marconato | N. Cruz | R. Milazzo | F. Lunardon | P. Jain | C. Poggi | M. Fadone | B. Segalini | M. Zaupa | S. Dal Bello | M. Dalla Palma | M. De Muri | M. Siragusa | M. Ugoletti | M. Agostini | A. Ferro | P. Veltri | I. Mario | R. Casagrande | V. Candeloro | C. Cavallini | A. Rigoni-Garola | M. De Nardi | F. Santoro | B. Duteil | C. Gasparrini
[1] M. Agostini,et al. SPIDER Beam Homogeneity Characterization Through Visible Cameras , 2022, IEEE Transactions on Plasma Science.
[2] M. Bigi,et al. On the Effectiveness of SPIDER RF System Improvements , 2022, IEEE Transactions on Plasma Science.
[3] G. Serianni,et al. Initial Results From the SPIDER Beamlet Current Diagnostic , 2022, IEEE Transactions on Plasma Science.
[4] N. Pomaro,et al. Langmuir Probes as a Tool to Investigate Plasma Uniformity in a Large Negative Ion Source , 2022, IEEE Transactions on Plasma Science.
[5] E. Gaio,et al. Radio Frequency Generators Based on Solid State Amplifiers for the NBTF and ITER Projects , 2022, IEEE Transactions on Plasma Science.
[6] G. Serianni,et al. Development of a Triple Langmuir Probe for Plasma Characterization in SPIDER , 2022, IEEE Transactions on Plasma Science.
[7] N. Marconato,et al. Numerical and Experimental Assessment of the New Magnetic Field Configuration in SPIDER , 2022, IEEE Transactions on Plasma Science.
[8] M. Brombin,et al. Spatially resolved diagnostics for optimization of large ion beam sources. , 2022, The Review of scientific instruments.
[9] R. Zagórski,et al. First operations with caesium of the negative ion source SPIDER , 2022, Nuclear Fusion.
[10] M. Spolaore,et al. Negative ion density in the ion source SPIDER in Cs free conditions , 2022, Plasma Physics and Controlled Fusion.
[11] A. Maistrello,et al. Power supply system for large negative ion sources: Early operation experience on the SPIDER experiment , 2021 .
[12] G. Serianni,et al. First results from beam emission spectroscopy in SPIDER negative ion source , 2021, Plasma Physics and Controlled Fusion.
[13] M. Brombin,et al. Development of a set of movable electrostatic probes to characterize the plasma in the ITER neutral beam negative-ion source prototype , 2021 .
[14] M. Brombin,et al. First tests and commissioning of the emittance scanner for SPIDER , 2021, Fusion Engineering and Design.
[15] N. Marconato,et al. Co-extracted electrons and beam inhomogeneity in the large negative ion source SPIDER , 2021, Fusion Engineering and Design.
[16] G. Serianni,et al. SPIDER Cs Ovens functional tests , 2021 .
[17] B. Heinemann,et al. First direct comparison of whole beam and single beamlet divergences in a negative ion source with simultaneous BES and CFC tile calorimetry measurements , 2021 .
[18] Emanuele Sartori,et al. Simulation-Based Quantification of Alkali-Metal Evaporation Rate and Systematic Errors From Current–Voltage Characteristics of Langmuir–Taylor Detectors , 2020, IEEE Transactions on Instrumentation and Measurement.
[19] K. Watanabe,et al. Achievement of high power and long pulse negative ion beam acceleration for JT-60SA NBI. , 2020, The Review of scientific instruments.
[20] P. Sonato,et al. First operation in SPIDER and the path to complete MITICA. , 2020, The Review of scientific instruments.
[21] R. Pasqualotto,et al. Laser absorption spectroscopy studies to characterize Cs oven performances for the negative ion source SPIDER , 2019, Journal of Instrumentation.
[22] P. Sonato,et al. SPIDER in the roadmap of the ITER neutral beams , 2019, Fusion Engineering and Design.
[23] G. Serianni,et al. Improving the transported negative ion beam current in NIO1 , 2018 .
[24] M. Brombin,et al. Final design of the diagnostic calorimeter for the negative ion source SPIDER , 2017 .
[25] V. Toigo,et al. The PRIMA Test Facility: SPIDER and MITICA test-beds for ITER neutral beam injectors , 2017 .
[26] B. Heinemann,et al. Towards large and powerful radio frequency driven negative ion sources for fusion , 2017 .
[27] W Kraus,et al. Ways to improve the efficiency and reliability of radio frequency driven negative ion sources for fusion. , 2014, The Review of scientific instruments.
[28] B. Chaudhury,et al. Physics of a magnetic filter for negative ion sources. II. E × B drift through the filter in a real geometry , 2012 .
[29] P. Zaccaria,et al. Physics and engineering design of the accelerator and electron dump for SPIDER , 2011 .
[30] Andrea Rizzolo,et al. Detail design of the beam source for the SPIDER experiment , 2010 .
[31] C. Rotti,et al. Diagnostic neutral beam for ITER - Concept to engineering , 2009, 2009 23rd IEEE/NPSS Symposium on Fusion Engineering.
[32] V. Toigo,et al. The ITER full size plasma source device design , 2009 .
[33] V Antoni,et al. Status of the ITER neutral beam injection system. , 2008, The Review of scientific instruments.
[34] U. Fantz,et al. A novel diagnostic technique for H−(D−) densities in negative hydrogen ion sources , 2006 .
[35] C. Martens,et al. Overview of the RF source development programme at IPP Garching , 2006 .
[36] R. S. Hemsworth,et al. Design of neutral beam system for ITER-FEAT , 2001 .
[37] Ian G. Brown,et al. The Physics and technology of ion sources , 1989 .
[38] V. Dudnikov,et al. A powerful injector of neutrals with a surface-plasma source of negative ions , 1974 .