Soldatkina et al., 2022 - Google Patents
Electron beam-plasma discharge in GDT mirror trap: experiments on plasma start-up with electron gunSoldatkina et al., 2022
View PDF- Document ID
- 1327471044748213287
- Author
- Soldatkina E
- Pinzhenin E
- Korobeynikova O
- Maximov V
- Yakovlev D
- Solomakhin A
- Savkin V
- Kolesnichenko K
- Ivanov A
- Trunev Y
- Voskoboynikov R
- Shulzhenko G
- Annenkov V
- Volchok E
- Timofeev I
- Bagryansky P
- Publication year
- Publication venue
- Nuclear Fusion
External Links
Snippet
The paper describes experiments on the injection of an electron beam into a gas at the gas dynamic trap (GDT) and develops a technique for creating a starting plasma with parameters sufficient for its subsequent heating by neutral beams. It is found that a relatively thin …
- 210000002381 Plasma 0 title abstract description 143
Classifications
-
- G—PHYSICS
- G21—NUCLEAR PHYSICS; NUCLEAR ENGINEERING
- G21K—TECHNIQUES FOR HANDLING PARTICLES OR IONISING RADIATION NOT OTHERWISE PROVIDED FOR; IRRADIATION DEVICES; GAMMA RAY OR X-RAY MICROSCOPES
- G21K1/00—Arrangements for handling particles or ionizing radiation, e.g. focusing or moderating
- G21K1/14—Arrangements for handling particles or ionizing radiation, e.g. focusing or moderating using charge exchange devices, e.g. for neutralising or changing the sign of the electrical charges of beams
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Ivanov et al. | Gas-dynamic trap: an overview of the concept and experimental results | |
| Downer et al. | Diagnostics for plasma-based electron accelerators | |
| Lieberman et al. | From Fermi acceleration to collisionless discharge heating | |
| Benford et al. | Survey of pulse shortening in high-power microwave sources | |
| Soldatkina et al. | Electron beam-plasma discharge in GDT mirror trap: experiments on plasma start-up with electron gun | |
| EA011288B1 (en) | Method for containing plasma, contains electrons and ions, into a chamber | |
| Saitoh et al. | Efficient injection of an intense positron beam into a dipole magnetic field | |
| Chardin et al. | Proposal to measure the gravitational behaviour of antihydrogen at rest | |
| Postupaev et al. | Start of experiments in the design configuration of the GOL-NB multiple-mirror trap | |
| Nakajima | Laser-driven electron beam and radiation sources for basic, medical and industrial sciences | |
| Andreev et al. | Gyromagnetic autoresonance plasma bunches in a magnetic mirror | |
| Sarri et al. | Spectral and spatial characterisation of laser-driven positron beams | |
| Ji et al. | Ion acceleration in the ‘dragging field’of a light-pressure-driven piston | |
| Timofeev et al. | Electron beam–plasma discharge in GDT mirror trap: particle-in-cell simulations | |
| Eseev et al. | Traps for storing charged particles and antiparticles in high-precision experiments | |
| Maitrallain et al. | Parametric study of high-energy ring-shaped electron beams from a laser wakefield accelerator | |
| Gruse | Development of laser wakefield accelerators | |
| Blasi | Theoretical challenges in acceleration and transport of ultra high energy cosmic rays: A review | |
| Higginson | Optimisation and control of ion acceleration in intense laser-foil interactions | |
| Goodman | Optimisation of proton acceleration and synchrotron radiation in ultraintense laser-solid interactions | |
| Hinode et al. | Expected performance of a planar undulator designed for the terahertz source project at Tohoku University | |
| Svendsen | Applications of Laser-Plasma Acceleration | |
| Garnett | Active interrogation probe technologies | |
| Boom | Characterization of edge localized modes in tokamak plasmas | |
| Zhang et al. | Proton acceleration in plasma turbulence driven by high-energy lepton jets |