Your search keyword '"Caughman, J. B. O."' showing total 146 results

1. Power transport efficiency during O-X-B 2nd harmonic electron cyclotron heating in a helicon linear plasma device

Author

Marin, J. F. Caneses, Lau, C. L., Goulding, R. H., Bigelow, T., Biewer, T., Caughman, J. B. O., and Rapp, J.

Subjects

Physics - Plasma Physics

Abstract

The principal objective of this work is to report on the power coupled to a tungsten target in the Proto-MPEX device during oblique injection of a microwave beam (< 70 kW at 28 GHz) into a high-power (~100 kW at 13.56 MHz) over-dense (n_e>1E10^19 m^(-3)) deuterium helicon plasma column. The experimental setup, electron heating system, electron heating scheme, and IR thermographic diagnostic for quantifying the power transport is described in detail. It is demonstrated that the power transported to the target can be effectively controlled by adjusting the magnetic field profile. Using this method, heat fluxes up to 22 MWm-2 and power transport efficiencies in the range of 17-20% have been achieved using 70 kW of microwave power. It is observed that most of the heat flux is confined to a narrow region at the plasma periphery. Ray-tracing calculations are presented which indicate that the power is coupled to the plasma electrons via an O-X-B mode conversion process. Calculations indicate that the microwave power is absorbed in a single pass at the plasma periphery via collisions and in the over-dense region via 2nd harmonic cyclotron resonance of the electron Bernstein wave. The impact of these results is discussed in the context of MPEX., Comment: Peer-reviewed paper

Published

2021

2. Investigation of Materials for Radio Frequency Antenna Plasma Facing Components

Author

Caughman, J. B. O., primary, Butler, K., additional, Curreli, D., additional, Donovan, D., additional, Easley, D. C., additional, Gonzalez-Galvan, A., additional, Johnson, C. A., additional, Meredith, L., additional, and Unterberg, E. A., additional

Published

2024

3. Electron Bernstein waves emission in the TJ-II Stellarator

Author

García-Regaña, J. M., Cappa, Á., Castejón, F., Caughman, J. B. O, Tereshchenko, M., Ros, A., Rasmussen, D. A., and Wilgen, J. B.

Subjects

Physics - Plasma Physics

Abstract

Taking advantage of the electron Bernstein waves heating (EBWH) system of the TJ-II stellarator, an electron Bernstein emission (EBE) diagnostic was installed. Its purpose is to investigate the B-X-O radiation properties in the zone where optimum theoretical EBW coupling is predicted. An internal movable mirror shared by both systems allows us to collect the EBE radiation along the same line of sight that is used for EBW heating. The theoretical EBE has been calculated for different orientations of the internal mirror using the TRUBA code as ray tracer. A comparison with experimental data obtained in NBI discharges is carried out. The results provide a valuable information regarding the experimental O-X mode conversion window expected in the EBW heating experiments. Furthermore, the characterization of the radiation polarization shows evidence of the underlying B-X-O conversion process., Comment: 21 pages, 14 figures

Published

2010

4. Final Design of the Material Plasma Exposure eXperiment

Author

Rapp, J., Lumsdaine, A., Aaron, A., Biewer, T. M., Bigelow, T. S., Boyd, T., Caughman, J. B. O., Curry, D., Duckworth, R. C., Goulding, R. H., Hussain, A., Kaufman, M., and Lau, C. H.

Abstract

AbstractThe Material Plasma Exposure eXperiment (MPEX) has completed its design phase. MPEX will be a unique facility to investigate plasma material interactions (PMIs) under fusion prototypic divertor conditions in steady state. This includes plasma exposure conditions expected in a fusion reactor divertor. Materials to be investigated will include solids, liquids, and neutron pre-irradiated materials. Electron and ion heating will allow for a large operational domain ranging from erosion-dominated PMI conditions to deposition-dominated PMI conditions. An overview of the final design for all MPEX systems is given. In particular, it is shown how mission-driven project requirements have led to detailed design choices with innovative solutions. Examples are the water-cooled helicon window, the electron cyclotron heating launcher, the target holder and manipulator, and the autonomous decouplers.

Published

2023

5. Power transport efficiency during O-X-B 2nd harmonic electron cyclotron heating in a helicon linear plasma device 1

Author

Marin, J F Caneses, primary, Lau, C L, additional, Goulding, R H, additional, Bigelow, T, additional, Biewer, T M, additional, Caughman, J B O, additional, and Rapp, J, additional

Published

2021

6. RF sheath induced sputtering on Proto-MPEX part 2: Impurity transport modeling and experimental comparison

Author

Beers, C. J., primary, Lau, C., additional, Rapp, J., additional, Younkin, T. R., additional, Biewer, T. M., additional, Bigelow, T., additional, Caneses, J. F., additional, Caughman, J. B. O., additional, Green, D. L., additional, Meyer, H., additional, Myra, J. R., additional, and Zinkle, S. J., additional

Published

2021

7. Characterizing the plasma-induced thermal loads on a 200 kW light-ion helicon plasma source via infra-red thermography

Author

Caneses Marin, J F, primary, Beers, C J, additional, Chakraborty Thakur, S, additional, Simmonds, M J, additional, Goulding, R H, additional, Lau, C, additional, Caughman, J B O, additional, Biewer, T M, additional, Meitner, S, additional, Rapp, J, additional, and Tynan, George, additional

Published

2021

8. Development of the materials analysis and particle probe for Proto-MPEX

Author

Beers, C. J., primary, Jaramillo, C., additional, Reid, N. C., additional, Schamis, H., additional, Allain, J. P., additional, Caughman, J. B. O., additional, Meitner, S. J., additional, Rapp, J., additional, and Zinkle, S. J., additional

Published

2021

9. Heat Flux Analysis From IR Imaging on Proto-MPEX

Author

Lau, Cornwall, primary, Caneses, J. F., additional, Piotrowicz, P. A., additional, Showers, Melissa A., additional, Beers, Clyde Joshua, additional, Biewer, Theodore M., additional, Bigelow, T. S., additional, Caughman, J. B. O., additional, Goulding, R. H., additional, Kafle, N., additional, and Rapp, J., additional

Published

2020

10. The Materials Plasma Exposure eXperiment: Status of the Physics Basis Together With the Conceptual Design and Plans Forward

Author

Rapp, J., primary, Lau, C., additional, Lumsdaine, A., additional, Beers, C. J., additional, Bigelow, T. S., additional, Biewer, T. M., additional, Boyd, T., additional, Caneses, J. F., additional, Caughman, J. B. O., additional, Duckworth, R., additional, Goulding, R. H., additional, Hicks, W. R., additional, Kafle, N., additional, Piotrowicz, P. A., additional, and West, D., additional

Published

2020

11. Effect of magnetic field ripple on parallel electron transport during microwave plasma heating in the Proto-MPEX linear plasma device

Author

Caneses, J F, primary, Spong, D A, additional, Lau, C, additional, Biewer, T M, additional, Goulding, R H, additional, Bigelow, T S, additional, Caughman, J B O, additional, Kafle, N, additional, and Rapp, J, additional

Published

2020

12. Characterizing the plasma-induced thermal loads on a 200 kW light-ion helicon plasma source via infra-red thermography.

Author

Marin, J F Caneses, Beers, C J, Thakur, S Chakraborty, Simmonds, M J, Goulding, R H, Lau, C, Caughman, J B O, Biewer, T M, Meitner, S, Rapp, J, and Tynan, George

Subjects

PLASMA sources, THERMOGRAPHY, PLASMA confinement, PLASMA devices, HEAT flux, MAGNETIC flux

Abstract

The light-ion helicon plasma source of the Proto-MPEX linear plasma device has been recently upgraded to enable pulsed (0.5–1 s) operation up to 200 kW. The main objective of this work is to report on the plasma-induced surface heat fluxes incident on the helicon window during high power operation (60–150 kW net power) for the purpose of the design of the upcoming material plasma exposure eXperiment (MPEX). The IR imaging system and associated physics models for the extraction of surface heat fluxes are presented. Experimental results demonstrate that the control of the plasma strike point via magnetic flux mapping and the use of dedicated limiters is effective at reducing the heat loads on the dielectric window. Moreover, it is found that the flux mapping must create a gap between the plasma and the dielectric window of at least the plasma radial decay length. Extrapolated to 200 kW net RF power, this mode of operation can reduce the power lost to the dielectric window by 33%. The results presented have direct application to the design of high-powered helicon plasma sources that operate in a steady state. Examples include linear divertor simulators such as MPEX, electric thrusters, negative ion sources for NBI and linear plasma–material interaction test stands. [ABSTRACT FROM AUTHOR]

Published

2021

13. Results of Ion Cyclotron Heating Experiments on Proto-MPEX Utilizing a Movable Stainless Steel Target

Author

Goulding, R. H., primary, Piotrowicz, P. A., additional, Beers, C. J., additional, Biewer, T. M., additional, Caneses, J. F., additional, Caughman, J. B. O., additional, Kafle, N., additional, Lindquist, E. G., additional, Ray, H. A., additional, Rapp, J., additional, and Showers, M. A., additional

Published

2019

14. Computational investigation of ion cyclotron heating on Proto-MPEX

Author

Piotrowicz, P. A., primary, Goulding, R. H., additional, Caneses, J. F., additional, Green, D. L., additional, Caughman, J. B. O., additional, Lau, C., additional, Rapp, J., additional, and Ruzic, D. N., additional

Published

2019

15. Differential pumping requirements for the light-ion helicon source and heating systems of Proto-MPEX

Author

Caneses, J. F., primary, Piotrowicz, P. A., additional, Biewer, T. M., additional, Caughman, J. B. O., additional, Goulding, R. H., additional, Kafle, N., additional, and Rapp, J., additional

Published

2018

16. Helicon normal modes in Proto-MPEX

Author

Piotrowicz, P A, primary, Caneses, J F, additional, Green, D L, additional, Goulding, R H, additional, Lau, C, additional, Caughman, J B O, additional, Rapp, J, additional, and Ruzic, D N, additional

Published

2018

17. Direct measurement of the transition from edge to core power coupling in a light-ion helicon source

Author

Piotrowicz, P. A., primary, Caneses, J. F., additional, Showers, M. A., additional, Green, D. L., additional, Goulding, R. H., additional, Caughman, J. B. O., additional, Biewer, T. M., additional, Rapp, J., additional, and Ruzic, D. N., additional

Published

2018

18. Plasma flow measurements in the Prototype-Material Plasma Exposure eXperiment (Proto-MPEX) and comparison with B2.5-Eirene modeling

Author

Kafle, N., primary, Owen, L. W., additional, Caneses, J. F., additional, Biewer, T. M., additional, Caughman, J. B. O., additional, Donovan, D. C., additional, Goulding, R. H., additional, and Rapp, J., additional

Published

2018

19. Power accounting of plasma discharges in the linear device Proto-MPEX

Author

Showers, M, primary, Piotrowicz, P A, additional, Beers, C J, additional, Biewer, T M, additional, Caneses, J, additional, Canik, J, additional, Caughman, J B O, additional, Donovan, D C, additional, Goulding, R H, additional, Lumsdaine, A, additional, Kafle, N, additional, Owen, L W, additional, Rapp, J, additional, and Ray, H, additional

Published

2018

20. Helicon plasma ion temperature measurements and observed ion cyclotron heating in proto-MPEX

Author

Beers, C. J., primary, Goulding, R. H., additional, Isler, R. C., additional, Martin, E. H., additional, Biewer, T. M., additional, Caneses, J. F., additional, Caughman, J. B. O., additional, Kafle, N., additional, and Rapp, J., additional

Published

2018

21. Progress in the Development of a High Power Helicon Plasma Source for the Materials Plasma Exposure Experiment

Author

Goulding, R. H., primary, Caughman, J. B. O., additional, Rapp, J., additional, Biewer, T. M., additional, Bigelow, T. S., additional, Campbell, I. H., additional, Caneses, J. F., additional, Donovan, D., additional, Kafle, N., additional, Martin, E. H., additional, Ray, H. B., additional, Shaw, G. C., additional, and Showers, M. A., additional

Published

2017

22. The Development of the Material Plasma Exposure Experiment

Author

Rapp, Juergen, primary, Biewer, T. M., additional, Bigelow, T. S., additional, Caughman, J. B. O., additional, Duckworth, R. C., additional, Ellis, R. J., additional, Giuliano, D. R., additional, Goulding, R. H., additional, Hillis, D. L., additional, Howard, R. H., additional, Lessard, T. L., additional, Lore, J. D., additional, Lumsdaine, A., additional, Martin, E. J., additional, McGinnis, W. D., additional, Meitner, S. J., additional, Owen, L. W., additional, Ray, H. B., additional, Shaw, G. C., additional, and Varma, V. K., additional

Published

2016

23. Utilization of O-X-B mode conversion of 28 GHz microwaves to heat core electrons in the upgraded Proto-MPEX.

Author

Biewer, T. M., Lau, C., Bigelow, T. S., Caneses, J. F., Caughman, J. B. O., Goulding, R. H., Kafle, N., Kaufman, M. C., and Rapp, J.

Subjects

MICROWAVES, ELECTRON density, ELECTRON temperature, MAGNETIC fields, MICROWAVE materials, ELECTRONS

Abstract

The magnetic geometry of the Prototype Material Plasma Exposure eXperiment (Proto-MPEX) was recently modified to enable more effective utilization of 28 GHz microwave auxiliary power, specifically: (1) to heat plasma electrons in the radial core of the device and (2) to deliver the heated plasma to the target plate of the device. To achieve this goal, the microwave launcher geometry and placement were significantly re-engineered, guided by previous experimental results and computational modeling. The core electron temperature in the launcher region is observed to increase from 3 eV to 11 eV with 30 kW of auxiliary power after the improvements, and an increase from 3 eV to 6 eV is concurrently measured in the target region (∼1 m from the launcher) at electron density above O-mode cutoff. Radially resolved measurements in the launcher region exhibit a strong dependence on the magnetic geometry. The results of a magnetic field scan reinforce the effectiveness of the intended O-X-B mode conversion scenario that is currently planned for microwave heating of the Material Plasma Exposure eXperiment (MPEX). [ABSTRACT FROM AUTHOR]

Published

2019

24. Evidence of electron heating at different radial locations on Proto-MPEX.

Author

Lau, C., Caneses, J. F., Bigelow, T. S., Biewer, T. M., Caughman, J. B. O., Goulding, R. H., Piotrowicz, P. A., Rapp, J., Ray, H. B., and Showers, M.

Subjects

PLASMA density, ELECTRONS, PLASMA production, HEAT flux, ELECTRON temperature, ELECTRON density

Abstract

This paper reports on the observation of controlled underdense electron heating for high heat flux applications in the Prototype Material Plasma Exposure eXperiment. The goal of this experiment is to demonstrate the source and heating concepts to create a high intensity plasma at material targets to study plasma-material interactions in similar plasma conditions to magnetic fusion divertors. A 80 kW helicon source at 13.56 MHz is used for the plasma density production and a 15 kW microwave source at 28 GHz is used for electron heating. For electron densities ∼5 × 1018 m−3, the electron temperature at the target location increases from 2 eV to 5 eV and the core heat flux increases by a factor of 5. It is shown that the radial profile of the heat flux delivered at the target can be controlled by either the background plasma density or the magnetic field. Analysis suggests that the electron heating is due to heating near the upper-hybrid resonance layer and that this heating scenario may scale up to divertor-relevant electron densities ∼5 × 1019 m−3 by increasing the microwave driving frequency to 105 GHz. [ABSTRACT FROM AUTHOR]

Published

2019

25. Solidification and Acceleration of Large Cryogenic Pellets Relevant for Plasma Disruption Mitigation

Author

Combs, S. K., primary, Meitner, S. J., additional, Gebhart, T. E., additional, Baylor, L. R., additional, Caughman, J. B. O., additional, Fehling, D. T., additional, Foust, C. R., additional, Ha, T., additional, Lyttle, M. S., additional, Fisher, J. T., additional, and Younkin, T. R., additional

Published

2016

26. Applications of Doppler-free saturation spectroscopy for edge physics studies (invited)

Author

Martin, E. H., primary, Zafar, A., additional, Caughman, J. B. O., additional, Isler, R. C., additional, and Bell, G. L., additional

Published

2016

27. Heat flux estimates of power balance on Proto-MPEX with IR imaging

Author

Showers, M., primary, Biewer, T. M., additional, Caughman, J. B. O., additional, Donovan, D. C., additional, Goulding, R. H., additional, and Rapp, J., additional

Published

2016

28. A temporally and spatially resolved electron density diagnostic method for the edge plasma based on Stark broadening

Author

Zafar, A., primary, Martin, E. H., additional, Shannon, S. C., additional, Isler, R. C., additional, and Caughman, J. B. O., additional

Published

2016

29. Cryogenic considerations for superconducting magnet design for the material plasma exposure experiment

Author

Duckworth, R C, primary, Demko, J A, additional, Lumsdaine, A, additional, Rapp, J, additional, Bjorholm, T, additional, Goulding, R H, additional, Caughman, J B O, additional, and McGinnis, W D, additional

Published

2015

30. Latest Results from Proto-MPEX and the Future Plans for MPEX

Author

Rapp, J., Lumsdaine, A., Beers, C. J., Biewer, T. M., Bigelow, T. S., Caneses, J. F., Caughman, J. B. O., Goulding, R. H., Kafle, N., Lau, C. H., Lindquist, E., Piotrowicz, P. A., Ray, H., and Showers, M.

Abstract

AbstractThe Prototype Material Plasma Exposure eXperiment (Proto-MPEX) is being used to qualify the plasma source and heating systems for the Material Plasma Exposure eXperiment (MPEX). The MPEX will address important and urgent research needs on plasma material interactions for future fusion reactors. In MPEX, plasma-facing components (nonirradiated and a priori neutron irradiated) will be exposed to plasma conditions as they are expected in future fusion reactors. The MPEX, a steady-state device enabled by superconducting magnets, will be able to break into new ground by assessing plasma-facing materials and components at an ion fluence level in the range of 1030to 1031 m−2. To achieve the relevant plasma conditions, high-density plasmas (>4 × 1019 m−3) are produced with a high-power helicon source. The so-produced low-temperature helicon plasma is then additionally heated with waves in the ion cyclotron resonance frequency and electron cyclotron resonance frequency domains. Proto-MPEX has achieved all key parameters (source ne, source Te, source Ti, target Te, target Ti, target ion flux, and target heat flux) within a factor of 2 of the design requirements of MPEX, albeit not simultaneously. These parameters were achieved with a total installed heating power of 330 kW, which is less than half of the planned heating power in the MPEX (800 kW). An overview of the latest results from Proto-MPEX is given. These results are shown in relationship to the MPEX system goals. Remaining necessary research and development tasks are discussed. The MPEX is currently in the conceptual design phase. The status of the design and an overview of the system requirements are presented.

Published

2019

31. Electric field measurements of the LH wave and ICRF near-field utilizing non-perturbative spectroscopic techniques

Author

Martin, E. H., primary, Caughman, J. B. O., additional, Klepper, C. C., additional, Goniche, M., additional, Isler, R. C., additional, Hillairet, J., additional, and Bottereau, C., additional

Published

2015

32. Massive pellet and rupture disk testing for disruption mitigation applications

Author

Combs, S. K., Meitner, S. J., Baylor, L. R., Caughman, J. B. O., Commaux, N., Fehling, D. T., Foust, C. R., Jernigan, T. C., McGill, J. M., Parks, P. B., and Rasmussen, D. A.

Abstract

n/a

Published

2009

33. Results from Laboratory Testing of a New Four-Barrel Pellet Injector for the TJ-II Stellarator

Author

Combs, S. K., primary, Foust, C. R., additional, McGill, J. M., additional, Caughman, J. B. O., additional, McCarthy, K. J., additional, Baylor, L. R., additional, Chamorro, M., additional, Fehling, D. T., additional, Garciab, R., additional, Harris, J. H., additional, Hernández Sánchez, J., additional, Hidalgo, C., additional, Meitner, S. J., additional, Rasmussen, D. A., additional, and Unamunob, R., additional

Published

2013

34. Experimental measurements of the dynamic electric field topology associated with magnetized RF sheaths in hydrogen and helium discharges

Author

Martin, E. H., primary, Shannon, S. C., additional, and Caughman, J. B. O., additional

Published

2012

35. Experimental measurements of the dynamic electric field topology associated with magnetized RF sheaths

Author

Martin, E. H., primary, Caughman, J. B. O., additional, Isler, R. C., additional, Klepper, C. C., additional, and Shannon, S.C., additional

Published

2011

36. Calculation of rf field characteristics using non-perturbative optical diagnostics with a generalized dynamic Stark effect model

Author

Martin, E. H., primary, Caughman, J. B. O., additional, Isler, R. C., additional, Klepper, C. C., additional, and Shannon, S.C., additional

Published

2011

37. A new four-barrel pellet injection system for the TJ-II stellarator

Author

Combs, S. K., primary, Foust, C. R., additional, McGill, J. M., additional, Baylor, L. R., additional, Caughman, J. B. O., additional, Fehling, D. T., additional, Harris, J. H., additional, Meitner, S. J., additional, Rasmussen, D. A., additional, McCarthy, K. J., additional, Chamorro, M., additional, Garcia, R., additional, Hidalgo, C., additional, Medrano, M., additional, Mirones, E., additional, Olivares, J., additional, and Unamuno, R., additional

Published

2011

38. Electron Bernstein waves emission in the TJ-II stellarator

Author

García-Regaña, J M, primary, Cappa, Á, additional, Castejón, F, additional, Caughman, J B O, additional, Tereshchenko, M, additional, Ros, A, additional, Rasmussen, D A, additional, and Wilgen, J B, additional

Published

2011

39. Operation of the ORNL High Particle Flux Helicon Plasma Source

Author

Goulding, R. H., primary, Biewer, T. M., additional, Caughman, J. B. O., additional, Chen, G. C., additional, Owen, L. W., additional, Sparks, D. O., additional, Phillips, Cynthia K., additional, and Wilson, James R., additional

Published

2011

40. Initial Electron Bernstein Wave Emission Measurements on the TJ-II Stellarator

Author

Caughman, J. B. O., primary, Fernández, Á., additional, Cappa, Á., additional, Castejón, F., additional, Garcia-Regaña, J. M., additional, Rasmussen, D. A., additional, and Wilgen, J. B., additional

Published

2010

41. Massive pellet and rupture disk testing for disruption mitigation applications

Author

Combs, S. K., primary, Meitner, S. J., additional, Baylor, L. R., additional, Caughman, J. B. O., additional, Commaux, N., additional, Fehling, D. T., additional, Foust, C. R., additional, Jernigan, T. C., additional, McGill, J. M., additional, Parks, P. B., additional, and Rasmussen, D. A., additional

Published

2009

42. ELECTRON BERNSTEIN WAVE EMISSION STUDIES ON THE TJ-II STELLARATOR

Author

CAUGHMAN, J. B. O., primary, FERNÁNDEZ, A., additional, CAPPA, A., additional, CASTEJÓN, F., additional, RASMUSSEN, D. A., additional, and WILGEN, J. B., additional

Published

2009

43. Characterization of Electron Bernstein Wave Emission from the TJ-II Stellarator

Author

Caughman, J. B. O., primary, Cappa, Á., additional, Garcia-Regaña, J. M., additional, Castejón, F., additional, Fernández, A., additional, Rasmussen, D. A., additional, Wilgen, J. B., additional, Bobkov, Volodymyr, additional, and Noterdaeme, Jean-Marie, additional

Published

2009

44. Design of a high particle flux hydrogen helicon plasma source for used in plasma materials interaction studies

Author

Goulding, R. H., primary, Chen, G., additional, Meitner, S., additional, Baity, F. W., additional, Caughman, J. B. O., additional, Owen, L., additional, Bobkov, Volodymyr, additional, and Noterdaeme, Jean-Marie, additional

Published

2009

45. Design Concepts For A Long Pulse Upgrade For The DIII-D Fast Wave Antenna Array

Author

Ryan, P. M., primary, Baity, F. W., additional, Caughman, J. B. O., additional, Goulding, R. H., additional, Hosea, J. C., additional, Greenough, N. L., additional, Nagy, A., additional, Pinsker, R. I., additional, Rasmussen, D. A., additional, Bobkov, Volodymyr, additional, and Noterdaeme, Jean-Marie, additional

Published

2009

46. A compact flexible pellet injector for the TJ-II stellarator

Author

McCarthy, K. J., primary, Combs, S. K., additional, Baylor, L. R., additional, Caughman, J. B. O., additional, Fehling, D. T., additional, Foust, C. R., additional, McGill, J. M., additional, Carmona, J. M., additional, and Rasmussen, D. A., additional

Published

2008

47. Pellet Dropper Device for ELM Control on DIII-D*

Author

Combs, S. K., primary, Baylor, L. R., additional, Foust, C. R., additional, McGill, J. M., additional, Caughman, J. B. O., additional, Fehling, D. T., additional, Hansink, M. J., additional, Jernigan, T. C., additional, and Rasmussen, D. A., additional

Published

2007

48. Study of RF Breakdown Mechanisms Relevant to an ICH Antenna Environment

Author

Caughman, J. B. O., primary, Castano-Giraldo, C., additional, Aghazarian, M., additional, Baity, F. W., additional, Rasmussen, D. A., additional, Ruzic, D. N., additional, Ryan, Philip M., additional, and Rasmussen, David, additional

Published

2007

49. Technique for measuring D2 pellet mass loss through a curved guide tube using two microwave cavity detectors

Author

Combs, S. K., primary, Caughman, J. B. O., additional, and Wilgen, J. B., additional

Published

2006

50. Operation of the ORNL High Particle Flux Helicon Plasma Source.

Author

Goulding, R. H., Biewer, T. M., Caughman, J. B. O., Chen, G. C., Owen, L. W., and Sparks, D. O.

Subjects

PLASMA gases, RADIO frequency, HYDROGEN plasmas, HELIUM plasmas, NUCLEAR facilities, PLASMA heating, ANTENNAS (Electronics)

Abstract

A high power, high particle flux rf-based helicon plasma source has been constructed at ORNL and operated at power levels up to 30 kW. High-density hydrogen and helium plasmas have been produced. The source has been designed as the basis for a linear plasma materials interaction (PMI) test facility that will generate particle fluxes Γp1023 m-3 s-1, and utilize additional ion and electron cyclotron heating to produce high parallel (to the magnetic field) heat fluxes of ∼10 MW/m2. An rf-based source for PMI research is of interest because high plasma densities are generated with no internal electrodes, allowing true steady state operation with minimal impurity generation. The ORNL helicon source has a diameter of 15 cm and to-date has operated at a frequency f = 13.56 MHz, with magnetic field strength |B| in the antenna region up to ∼0.15 T. Maximum densities of 3×1019 m-3 in He and 2.5×1019 m-3 in H have been achieved. Radial density profiles have been seen to be dependent on the axial |B| profile. [ABSTRACT FROM AUTHOR]

Published

2011