1. Introduction
Neutral beams are widely used in the experimental magnetic fusion devices (Hemsworth & Inoue Reference Hemsworth and Inoue2005; Takeiri et al. Reference Takeiri2010; Hopf et al. Reference Hopf, Starnella, den Harder and Fantz2021). Over the last three decades the Budker Institute of Nuclear Physics (BINP) has developed and produced neutral beam injectors for plasma diagnostics, auxiliary heating, plasma rotation and current drive for medium-size tokamaks, mirror machines, field-reversed configurations and other magnetic fusion devices in the research centres of Russia, Europe and the USA (Belchenko et al. Reference Belchenko2018).
Charge-exchange injectors are based on acceleration of positive hydrogen (or deuterium) ions with subsequent neutralization in a gas target. The injectors of this type developed at BINP produce neutral beams with energy from 8 to 80 keV; the beam power ranges from hundreds of kilowatts for diagnostic beams to several megawatts for heating beams. The diagnostic injectors produce focused neutral beams with very small angular divergence of elementary beamlets, high atomic flux at the focal spot, and time modulation. The high-power injectors (up to 2 MW) producing focused beams with small width in the focal region are used for plasma heating in devices with narrow ports or for injection into a desired plasma region.
A typical injector scheme is shown in figure 1. Its main components are an ion source, ion beam accelerator, beam neutralizer and a separator of residual ions with a beam dump (Brown Reference Brown2004). The ion source includes a plasma chamber, where a hydrogen or deuterium plasma is produced, and a multiaperture ion-optical system (IOS), which extracts and forms an ion beam. The extracted beam has different species, including the molecular ones. After neutralization of the accelerated molecular ions, species with full, one-half and one-third energy are formed. A bending magnet deflects the residual ions into the ion dump. The neutral beam is transported along a beam duct and finally passes through a port in a vacuum vessel of a plasma device towards the confined plasma. The injector has a high-speed pumping system. The beam dump is equipped with an array of thermocouples used for conditioning of the ion source and measuring the parameters of the beam.
Figure 1. Schematic of a neutral beam injector.
Plasma is created using a radio-frequency (RF) or an arc discharge. Most BINP injectors use cold cathode arc discharge through a washer stack channel with subsequent plasma expansion in a chamber surrounded by a multipole magnetic field. This discharge produces a plasma with high proton content and good spatial homogeneity. High thermal loads and erosion of the arc channel imply that the arc generators are mainly used in injectors with a short active pulse ($\max 1$
s). In the RF discharge, on the other hand, erosion of the discharge chamber is negligible, therefore the RF emitter can operate without maintenance in injectors with multisecond pulse lengths. The disadvantage for the diagnostic injectors is that the content of the beam fraction with the total energy is 20 % smaller than from the injectors based on arc plasma generators.
The ion source has a three- or four-electrode (or grid) IOS. The first grid (also called a plasma grid) faces the plasma, the second grid extracts the ions from the plasma, the third grid accelerates the ions and the fourth grid is grounded. To suppress electron backstreaming, the acceleration grid is biased negatively with respect to ground. The ion sources for the diagnostic injectors have four grids, which allows formation of the beams with very small angular divergence. The three-grid systems (without the extraction grid) are mainly used in the ion sources for heating injectors with a higher initial ion current density of the extracted beams.
Finite ion temperature in the plasma source results in inherent angular divergence of elementary beamlets formed in the apertures of the grids. The beamlet current density at the grid surface is assumed to depend on the angle $\theta$
from the beamlet axis as $\exp (-\theta ^2/\theta _0^2)$
, where $\theta _0$
is the divergence. For a long slit aperture, the divergence in the direction along the slit is determined by the ion temperature. The divergence in the direction across the slits is always larger due to aberrations in the extraction system. Individual beamlets from the grids are directed to one point and merge there, which is called focusing (Brown Reference Brown2004).
The neutralization efficiency of positive ions in a gas target decreases rapidly with ion energy, so in a positive ion-based injector the injection energy is limited to approximately 120 keV. Such beam energies are sufficient for most existing plasma experiments. New fusion devices (ITER and the next generation) with high density and large plasma radius require neutral beams with an increased energy of 0.5–1 MeV. The neutralization efficiency of negative ions in this energy range is approximately 60 % (Hemsworth & Inoue Reference Hemsworth and Inoue2005), so the new generation of high-energy neutral injectors based on neutralization of accelerated negative ions (${\rm H}^-/{\rm D}^-$
) is under development for large tokamaks and stellarators (Speth et al. Reference Speth2006; Takeiri et al. Reference Takeiri2010; Heinemann et al. Reference Heinemann, Fantz, Kraus, Schiesko, Wimmer, Wünderlich, Bonomo, Fröschle, Nocentini and Riedl2017; Hemsworth et al. Reference Hemsworth2017; Singh et al. Reference Singh, Boilson, Polevoi, Oikawa and Mitteau2017; Hiratsuka et al. Reference Hiratsuka, Kashiwagi, Ichikawa, Umeda, Saquilayan, Tobari, Watanabe, Kojima and Yoshida2020; Inoue Reference Inoue2023). Most of the powerful high-energy neutral injectors for fusion devices use the surface plasma method of negative hydrogen ion production, which was discovered and developed at BINP (Belchenko, Dimov & Dudnikov Reference Belchenko, Dimov and Dudnikov1974). At present a prototype of a powerful high-energy neutral beam injector is under development at the BINP (Sotnikov et al. Reference Sotnikov2021). An RF surface-plasma source produces a negative ion beam by conversion of the hydrogen plasma atoms on a caesium-coated plasma grid. The specific features include a low-energy ion transport path, energy enhancement using a single-aperture accelerating tube, and a plasma neutralizer. At present the experiments are underway to increase the beam energy to 500 keV with a current of 1.5 A and operation in a multisecond mode up to 100 s. Several improved versions of the RF plasma drivers were tested to increase the pulse length (Gavrisenko et al. Reference Gavrisenko, Shikhovtsev, Belchenko, Gorbovskiy, Kondakov, Sotnikov, Sanin, Vointsev and Finashin2023). The paper gives an overview of these and other studies devoted to the development of neutral beam injectors in recent years.
2. Neutral injectors for plasma diagnostics
The BINP has approximately 50 years of experience in developing the neutral beam injectors for plasma diagnostics (Belchenko et al. Reference Belchenko2018). A diagnostic neutral beam has energy in the range from 20 to 60 keV, equivalent beam current of 1–10 A and pulse length from 5 ms to 10 s. The beam is extracted from an RF or an arc-discharge plasma emitter and accelerated to the desired energy by a four-grid IOS. Relatively low emission current density of $110\unicode{x2013}130\ {\rm mA}\ {\rm cm}^{-2}$
allows formation of a beam with the initial angular divergence as small as 10 mrad. A spherical shape of the multiaperture grids provides ballistic focusing of the beam resulting in small dimensions of the focal spot of the diagnostic neutral beam in a plasma. In recent decades the BINP team has developed diagnostic injectors for various plasma devices, for example: the Wendelstein 7-X stellarator at IPP, Greifswald, Germany (Davydenko et al. Reference Davydenko, Deichuli, Ivanov, Stupishin, Kapitonov, Kolmogorov, Ivanov, Sorokin and Shikhovtsev2016); the C-2W facility at TAE, USA; the T-15MD tokamak at the Kurchatov Institute, Moscow, Russia (Stupishin et al. Reference Stupishin2016); the ST40 tokamak at Tokamak Energy Ltd, Abingdon, UK. The main parameters of these injectors are listed in table 1.
Table 1. Diagnostic injectors developed by BINP in recent years.
$^{a}$
The injector is scheduled for connection to the tokamak in 2024.
The injector for charge exchange recombination spectroscopy of impurity atoms and diagnostics of charge exchange neutrals in the Wendelstein 7-X stellarator was designed to operate under strict conditions of the radiation environment of a large fusion device. Its vacuum tank was made of the non-magnetic and low-cobalt special ASTM/AISI 316 LN (1.4429) stainless steel ($\mu < 1.02, {\rm Co} < 500\ {\rm ppm}$
). The neutral beam had to pass through a long port surrounded by a cryostat. Thus, the IOS was designed to have a large focal length of 6 m. Power supply systems were located in a radiation-protected room and the cable route was approximately 70 m long. The injector is presently located at a test stand (figure 2a) in Greifswald. The ion source (yellow) is tilted at an angle of $18^\circ$
. The chamber is pumped down by two closed cycle Leybold COOLVAC cryopumps with pumping speeds of $60\,000\ {\rm l}\ {\rm s}^{-1}$
and $30\,000\ {\rm l}\ {\rm s}^{-1}$
. A view of the molybdenum plasma grid of the four-electrode IOS with peripheral cooling is shown in figures 2(b) and 2(c). The accumulated beam-on time in the modulated regime is limited to 2.5 s for a 10 s pulse length, because the grids are cooled only at the periphery, and because the protective shield of the RF ion source is cooled by a single channel at one end. The design of the plasma chamber is similar to that of the heating injector (Sorokin et al. Reference Sorokin, Belov, Davydenko, Deichuli, Ivanov, Podyminogin, Shikhovtsev, Shulzhenko, Stupishin and Tiunov2010). An RF generator based on a radio tube operates at a rated power of 25 kW and a frequency of 4 MHz.
Figure 2. (a) Diagnostic injector for W7-X stellarator at test stand. (b,c) View of the plasma grid of the IOS.
The diagnostic beam injector for the C-2W facility (TAE, USA) forms a beam with an energy of 44 keV. High beam energy was chosen to ensure low beam attenuation in the plasma and to allow charge exchange recombination spectroscopy throughout the plasma column to measure the local ion temperature and the velocity of impurity ions (Nations et al. Reference Nations, Gupta, Sweeney, Frausto and Tobin2021) and of the main deuterium ion component (Gupta et al. Reference Gupta, Nations, Sweeney, Aviles, Leinweber and Marshall2021). The ion source is based on an arc plasma generator and its four-electrode IOS is made of chromium zirconium brass. This arc plasma generator is analogous to the one used for the C-2W heating beams and described in detail in Deichuli et al. (Reference Deichuli, Davydenko, Ivanov, Korepanov, Mishagin, Smirnov, Sorokin and Stupishin2015). The injector operates with fast 100 % beam modulation with a frequency of up to 1 kHz. Modulation is carried out by completely turning on/off a high-voltage power supply. For higher frequency up to 10 kHz the beam modulation is performed by rapidly reconnecting the arc discharge current in the plasma source from the anode to the plasma chamber. It changes the plasma generation and the extracted ion current density as well. The beam density modulation depth reaches ${\approx }60\,\%$
.
The diagnostic injector developed for the T-15MD tokamak forms a hydrogen beam with an energy of 60 keV and an equivalent current of 2.6 A (Stupishin et al. Reference Stupishin2016). Integrated beam-on time is maximally set to 1 s when the beam is operated in a 10 s pulse with modulation. The diagnostic injector is based on an arc discharge plasma source with a plasma expansion chamber. The spherical shape of the grids and a small angular divergence of 10 mrad provide the relatively small focal spot ${\approx }6$
cm in diameter in the plasma. The injector was tested at the BINP in 2016 and commissioned at the Kurchatov Institute in 2023. The layout of the injector with the cross-section of the T15-MD tokamak is shown in figure 3.
Figure 3. Cross-section of the T15-MD tokamak with the diagnostic neutral beam injector connected to the port.
The diagnostic injector for the ST40 tokamak is the upgraded injector made earlier for the TEXTOR tokamak (Listopad et al. Reference Listopad, Coenen, Davydenko, Ivanov, Mishagin, Savkin, Schweer, Shulzhenko and Uhlemann2012). Its plasma source has been replaced by an arc discharge plasma generator with a cold cathode (Stupishin et al. Reference Stupishin2016), which is more reliable and much easier to operate (although the pulse duration becomes shorter). All power systems were redesigned to work from storages based on supercapacitors due to the absence of a powerful electric network. New supply provides a 2 s injector pulse. A cryogenic system with helium filling has been replaced by an easier-to-operate system with cryocooler heads. A new injector control system uses a hardware platform consisting of an industrial computer with National Instruments modules integrated in LabVIEW.
3. Neutral beam injectors for plasma heating
In recent years the heating neutral beam injectors with a power of approximately 1 MW have been developed and commissioned on tokamaks at SPC, Lausanne, Switzerland (TCV), Ioffe Institute St. Petersburg, Russia (Globus-M2), Tokamak Energy Ltd, England (ST40), IPP, Prague, Czech Republic (COMPASS). The parameters of the injectors are listed in table 2.
Table 2. Parameters of neutral beam injectors for plasma heating.
The injectors with an increased power and an energy of 15 keV were designed and manufactured in 2014 (Deichuli et al. Reference Deichuli, Davydenko, Ivanov, Korepanov, Mishagin, Smirnov, Sorokin and Stupishin2015), and the injectors with a tuneable beam energy were made in 2019 (Brul et al. Reference Brul2021). The initial beam energy was set to 15 keV and could be subsequently increased to 40 keV during the beam pulse, so that the fast ion orbits would agree with the controlled external magnetic field ramp-up of the C-2W device (Gota et al. Reference Gota2021). The energy rise time could be varied from 0.2 ms to several milliseconds, and the total pulse length was 30 ms. Thus, the neutral beam power increased from 1.7 MW to 3.5 MW. A particular feature of these injectors was that the ion beam current was kept constant at 150 A during a change in the beam energy. It was achieved by switching the operating mode of the IOS – it worked as a three-electrode system at an energy of 15 keV and was turned to a four-electrode system for an energy of 40 keV.
The heating injector for the Globus-M2 tokamak has a design similar to the injector for C2 (Sorokin et al. Reference Sorokin, Belov, Davydenko, Deichuli, Ivanov, Podyminogin, Shikhovtsev, Shulzhenko, Stupishin and Tiunov2010) with minor changes in the IOS to operate with a deuterium beam at an energy of 50 keV (Shchegolev et al. Reference Shchegolev2023). The first experiments on plasma heating by two neutral beams demonstrated the increase in ion temperature at the plasma axis up to $\sim$
4 keV at the electron density of $5\times 10^{19}\ {\rm m}^{-3}$
(Kurskiev et al. Reference Kurskiev2023).
Two heating injectors delivering D/H beams with a power of 1 MW each and energies of 25 and 51 keV operate at the TCV tokamak (Karpushov et al. Reference Karpushov2017, Reference Karpushov2023). Radio-frequency generators with power up to 60 kW at a frequency of 4 MHz are used for plasma production in the ion sources. A multiaperture IOS consists of three spherically shaped slitted grids made of chromium zirconium brass. It provides ballistic beam focusing, and produces a sufficiently narrow beam with an angular divergence of $14\times 5$
mrad. The grids are cooled at the periphery, and the plasma grid is additionally cooled in the centre, which allows extension of the beam pulse to 2 s. The injectors are operated in a modulated mode forming the beams with varying energy and power during the pulse according to a preset sequence or using a real-time feedback signal. General views of the second injector and its ion source are shown in figure 4 and in the photographs in figure 5.
Figure 4. (a) Layout of the ion source of the second TCV injector: 1, gas puffing valve; 2, inner electrostatic screen; 3, outer magnetic screen; 4, RF plasma box; 5, IOS insulation unit; 6, IOS grids; 7, neutralizer tube. (b) Three-dimensional model of the second TCV injector: 1, outer magnetic screen of ion source; 2, RF plasma box; 3, IOS, 4, bending magnet;5, cryocooler head; 6, neutral beam; 7, calorimeter; 8, cryopump panels; 9, ion dump; 10, neutralizer; 11, alignment unit.
Figure 5. (a) Ion source, (b) plasma grid of the IOS and (c) injector at the TCV tokamak.
The main parameters of the injectors were studied at the BINP test stands and at plasma devices. Beam profiles were measured by a set of secondary emission sensors mounted in the form of a cross at a distance of 3.3 m from the IOS (Sorokin et al. Reference Sorokin, Akhmetov, Brul, Davydenko, Ivanov, Karpushov, Mishagin and Shikhovtsev2020). The widths of the 27 keV beam at the 1/e level in the directions along and across the grid slits versus the ion beam current for the first injector after its upgrade are shown in figure 6(a). At the optimal ion beam current minimizing the width across the slits, the dimensions of the neutral beam are $4 \times 8$
cm. The molecular fractions of the neutral beam were determined using the Doppler optical emission diagnostics. The Doppler-shifted spectra of the hydrogen emission lines shown in figure 6(b) (Tec 2020) illustrate the ratio of the atoms with energies $E$
, $E/2$
, $E/3$
in the beam. The neutral beam comprises $75\,\%$
atoms with full energy (left-hand peak in figure 6b). The beam dimensions were also inferred from measurement of the temperature distribution over the surface of a tungsten tile heated by the beam (Karpushov et al. Reference Karpushov2023). The local temperature rise was proportional to the local beam power density. The focal length, calculated from measuring the beam profiles at various distances from the IOS, is ${\approx }380/400$
cm (across/along the slits). The inherent beamlet divergence angle is defined as a ratio of the beam half-width in the focal plane to the focal length. For the first and the second injectors, the measured divergence was $1.35^\circ /0.57^\circ$
and $0.79^\circ /0.3^\circ$
(across/along the slits).
Figure 6. (a) Change of 27 keV beam sizes across and along the slits versus ion beam current. (b) Doppler-shifted spectra of deuterium 27 keV beam of H-$\alpha$
emission line.
The BINP heating injector of a deuterium beam with an energy of 55 keV and a power of 1 MW is one of the two injectors on the ST40 tokamak (McNamara et al. Reference McNamara2023). An injector tank with a cryogenic pumping system based on the Sumitomo cool heads is the same as for the TCV injectors. A high-voltage power system (manufactured by JEMA) and an RF system are supplied from storages based on supercapacitors. The IOS geometry is different from the one in the injector for the TCV tokamak. The tokamak port is round and large enough with a diameter of 320 mm. The ion source produces a beam with a circular initial cross-section 250 mm in diameter. A set of 5 mm holes fills the emission area of the plasma grid forming a hexagonal structure with a transparency of $32\,\%$
. The nominal current density of a beam extracted from an elementary cell is $190\ {\rm mA}\ {\rm cm}^{-2}$
. The measured angular divergence of the beam is 13 mrad.
Two 300 kW, 40 keV heating injectors of deuterium and hydrogen atoms have been operated since 2011 at IPP in Prague (Deichuli et al. Reference Deichuli2012). The new heating neutral beam was commissioned in 2021 and tested at nominal parameters (80 keV, 1 MW deuterium beam) at the COMPASS tokamak before the shutdown of the latter. This injector is a prototype for the new COMPASS-U tokamak.
4. High energy negative ion-based injector
A high-energy injector based on negative ion acceleration is under development at the BINP (Ivanov et al. Reference Ivanov2013). It includes several innovative components: a RF negative ion source with thermal stabilization of electrodes and directed deposition of caesium vapour to the plasma electrode (Belchenko et al. Reference Belchenko, Abdrashitov, Deichuli, Ivanov, Gorbovsky, Kondakov, Sanin, Sotnikov and Shikhovtsev2016); a low-energy beam transport (LEBT) section needed to purify the beam from parasitic particles leaving the ion source and to protect the source from particles backstreaming from the accelerator; an accelerator, separated from the source with LEBT; a plasma neutralizer of accelerated negative ions.
Negative ion beam formation, acceleration and transport are studied at a high-voltage acceleration test stand, schematically shown in figure 7. An intense 120 keV negative ion beam, produced by a surface-plasma negative ion source is directed to the LEBT vacuum tank, equipped with cryopumps and a pair of immersed dipole magnets. The LEBT bending magnets shift the beam axis between the source and the high-voltage accelerator. This beam shift and high pumping speed of the LEBT tank reduce the flux of the accompanying harmful species moving from the source to the acceleration tube and prevents positive ions and neutrals from backstreaming into the ion source. It increases the high-voltage strength of the accelerator. The acceleration tube has a wide aperture, which provides better tube pumping, thus reducing beam losses and production of secondary particles, and increasing the high-voltage strength of the tube. The accelerated beam passes through a high-energy beam transport line (HEBT) with quadrupole lenses towards a calorimeter. A separation magnet is installed before the calorimeter to bend the accelerated beam to the recuperator tube (not shown in figure 7). The trajectories of ${\rm H}^-$
ions in the LEBT, the acceleration tube and the HEBT calculated by COMSOL are shown in figure 7 by the red lines. Figure 7 demonstrates that $\sim$
60 %–70 % of the negative ion beam extracted from the source with an initial divergence of 30 mrad enter the accelerator through a 260 mm diameter input diaphragm, and the acceleration tube provides 100 % beam passage. The beam losses during its transport through the LEBT tank were caused by the beam divergence and by the ${\rm H}^-$
ion stripping in the vacuum tank. These losses agreed well with the calculations (Sotnikov et al. Reference Sotnikov2021) using the ion optical code IBSimu (Kalvas et al. Reference Kalvas, Tarvainen, Ropponen, Steczkiewicz, Ärje and Clark2010). The accelerated H$^-$
beam is focused by the quadrupole lenses. The profile and intensity of the beam are measured by a calorimeter at a 10 m distance from the ion source.
Figure 7. High-voltage acceleration test stand. Red lines show calculated ion trajectories for 30 mrad initial divergence and 85 keV energy.
A schematic diagram of the negative ion source and its photograph are shown in figure 8. The plasma produced in the RF driver (figure 8b) flows through an expansion chamber with a multipole magnetic wall confining the plasma towards the plasma grid with the dipole magnetic filter. The dipole field suppresses transverse electron diffusion and decreases the electron temperature and density in the region of negative ion production and extraction close to the plasma grid. The negative ions are generated at the plasma grid surface by conversion of the plasma particles. This surface conversion is significantly enhanced due to caesium coverage of the plasma grid. Caesium is supplied from heated caesium distribution galleries located at the plasma grid periphery (figure 8c). The plasma grid is biased positively with respect to the expansion chamber in order to collect the plasma electrons and reduce the flow of electrons extracted together with the negative ions. The acceleration grid is electrically connected to the ground grid, so effectively a three-electrode multiaperture IOS is used for negative ion beam formation. The emission apertures of the plasma grid with the internal diameter of 16 mm and conical chamfers for better extraction of the negative ions are arranged in a rectangular array on the grid surface. Experiments were carried out with 21 open apertures (figure 8c).
Figure 8. (a) Schematic of the 1.5 A ion source: Faraday shield (FS); expansion chamber (EC); magnetic filter (MF); plasma grid (PG); caesium (Cs); extraction grid (EG); correction magnet (CM); acceleration grid (AG); ground grid (GG). (b) The RF ion source attached to the LEBT tank. (c) View from the RF driver side to the surface of plasma grid with 21 emission apertures and two caesium distribution tubes.
At the RF power of 37 kW the extracted beam has a current of 1 A and 100 keV energy in a 10 s pulse, and the emission current density is $240\unicode{x2013}260\ {\rm A}\ {\rm m}^{-2}$
. The prepared upgrade of the RF power supply to 70 kW will allow achieving the design ion beam current of 1.5 A. The RF plasma driver is studied in detail in Gavrisenko et al. (Reference Gavrisenko, Shikhovtsev, Belchenko, Gorbovskiy, Kondakov, Sotnikov, Sanin, Vointsev and Finashin2023).
A schematic of the acceleration tube with electric connections and calculated beam trajectories is shown in figure 9. The accelerated beam is compressed by the electrostatic lenses formed in the first accelerating gaps. It is clear that the acceleration tube with the voltage above 35 kV at each gap provides focusing of a 85 keV beam and its full passage through the acceleration tube when the diameter of the input diaphragm is less than 260 mm.
Figure 9. Cross-section of the acceleration tube and electrode connections to the power supply. Currents in the electrode circuit are measured by $I_{{P}}$
and $I_{\text {HV}}$
. Green lines show the calculated equipotential lines for all gaps powered up to 35 kV each. Red lines show the calculated trajectories for the beam with an initial energy of 85 keV and divergence at the source of 30 mrad (Sotnikov et al. Reference Sotnikov2021).
As seen in the high-voltage circuit of figure 9, the total accelerated current $I_{{P}}$
is the current flowing from the high-voltage platform, and the current $I_{\text {HV}}$
in the circuit of the last high-voltage electrode is the current leaving the acceleration tube. Their difference $I_{{P}} - I_{\text {HV}}$
corresponds to the current of charged particles intercepted by the accelerating electrodes. The accelerated current $I_{{P}}$
of approximately 0.6 A was achieved in the experiments with the source beam current of 0.86 A, and the voltage of 117 keV. The measured current of intercepted particles in this case was $I_{{P}} - I_{\text {HV}} \approx 0.1\ \text {A} \approx 0.16 I_{{P}}$
. This relatively high value of interception was mainly caused by the low voltage (<35 kV) at each of the first accelerating gaps and by poor alignment of the ion beam with the acceleration tube axis. The 100 % passage of the accelerated beam was demonstrated, when the diameter of the input diaphragm was decreased to 200 mm (Sotnikov et al. Reference Sotnikov2021).
The ion source with a negative ion beam current of 9 A, a beam energy up to 120 keV and a pulse duration up to 100 s was designed and manufactured at BINP (Sotnikov et al. Reference Sotnikov2021). It includes four RF plasma drivers and uses a four-grid IOS with 145 apertures for beam extraction. Additional pumping is provided at the IOS sides. Thermal stabilization of the IOS grids will be provided by circulating a coolant through internal channels. An IOS insulator unit with an expansion chamber and a plasma grid are shown in figures 10(a) and 10(b), respectively. A four-channel RF power supply system has been manufactured. Installation of the RF drivers and assembly of the high-voltage power supply system will complete the RF system.
Figure 10. (a) Photograph of the 9 A ion source attached to the LEBT tank. (b) View onto the plasma grid with 145 apertures.
5. Conclusion
The BINP has developed and produced more than 50 neutral beam injectors for plasma heating and diagnostics over the last 30 years. The current and future activities are focused on the development of ion sources and injectors with power up to 10 MW and continuous operation. These studies are supported by national scientific programs aimed at constructing new plasma devices and developing innovative plasma technologies (Belchenko et al. Reference Belchenko, Burdakov, Davydenko, Gorbovskii, Emelev, Ivanov, Sanin and Sotnikov2021). The scientific program on creation of a new generation of magnetic mirror devices for plasma confinement is directly related to the BINP (Skovorodin et al. Reference Skovorodin2023).
Acknowledgements
Editor C. Forest thanks the referees for their advice in evaluating this article.
Funding
The work was partially supported by the Ministry of Science and Higher Education of the Russian Federation.
Declaration of interests
The authors report no conflict of interest.
