SPIDER, the Negative Ion Source Prototype for ITER: Overview of Operations and Cesium Injection

An overview of the recent operations and the main results of cesium injection in the Source for the Production of Ions of Deuterium Extracted from Rf plasma (SPIDER) negative ion source are described in this contribution. In experiments without cesium injection, all SPIDER plants were tested to verify the basic expectations on the operational parameters (e.g., electron cooling effectiveness of magnetic filter field) and to determine its operational region. For beam properties, it was shown that the current density varies across the beam in the vertical direction. In preliminary cesium experiments, the expected increase of negative ion current and simultaneous decrease of co-extracted electrons were found, along with the influence of the control parameters (polarization of the plasma electrodes, magnetic filter field) on the SPIDER beam uniformity in the horizontal and vertical directions. It was shown that non-Gaussian tails can be identified in the angular distribution on the plane perpendicular to the beam propagation direction. Stray particles, nonhomogeneous beam and large divergence might result in unexpected heat and particle loads over ITER neutral beam injector (NBI) accelerator grids; it is the goal of SPIDER to assess and possibly to identify suitable methods for controlling these beam features. A major shutdown, planned for late 2021, to solve the issues identified during the operation and to carry out scheduled modifications, is outlined. Such improvements are expected to allow SPIDER to pursue the ITER requirements in terms of negative ion current, electron-to-ion ratio, and beam duration.

[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 .