Your search keyword '"Jeremy Lore"' showing total 3 results

1. The Development of the Material Plasma Exposure Experiment

Author

W. D. McGinnis, Dominic R Giuliano, Ronald James Ellis, E. J. Martin, Arnold Lumsdaine, Juergen Rapp, Richard H. Howard, D. L. Hillis, T. M. Biewer, R. H. Goulding, Timothy Lessard, H. Ray, Larry W Owen, Jeremy Lore, Steven J. Meitner, Venugopal Koikal Varma, John Caughman, T.S. Bigelow, G.C. Shaw, and Robert C. Duckworth

Subjects

Nuclear and High Energy Physics, Dense plasma focus, Materials science, Divertor, Nuclear engineering, Cyclotron, Superconducting magnet, Plasma, Fusion power, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, law.invention, Helicon, law, 0103 physical sciences, Nuclear fusion, Atomic physics, 010306 general physics

Abstract

The availability of future fusion devices, such as a fusion nuclear science facility or demonstration fusion power station, greatly depends on long operating lifetimes of plasma facing components in their divertors. ORNL is designing the Material Plasma Exposure eXperiment (MPEX), a superconducting magnet, steady-state device to address the plasma material interactions of fusion reactors. MPEX will utilize a new high-intensity plasma source concept based on RF technology. This source concept will allow the experiment to cover the entire expected plasma conditions in the divertor of a future fusion reactor. It will be able to study erosion and redeposition for relevant geometries with relevant electric and magnetic fields in-front of the target. MPEX is being designed to allow for the exposure of a priori neutron-irradiated samples. The target exchange chamber has been designed to undock from the linear plasma generator such that it can be transferred to diagnostics stations for more detailed surface analysis. MPEX is being developed in a staged approach with successively increased capabilities. After the initial development step of the helicon source and electron cyclotron heating system, the source concept is being tested in the Proto-MPEX device. Proto-MPEX has achieved electron densities of more than $4 \times 10^{19}~\text{m}^{-3}$ with a large diameter (13 cm) helicon antenna at 100 kW power. First heating with microwaves resulted in a higher ionization represented by higher electron densities on axis, when compared with the helicon plasma only without microwave heating.

Published

2016

2. Overview of Design and Analysis Activities for the W7-X Scraper Element

Author

D. McGinnis, Joris Fellinger, H. Neilson, Arnold Lumsdaine, J. Boscary, Kivanc Ekici, E. Clark, Peter Titus, T. Bjorholm, H. Hölbe, Jeremy Lore, J. H. Harris, J. Tretter, and G. A. Wurden

Subjects

Nuclear and High Energy Physics, Computer science, Nuclear engineering, Divertor, Fusion power, Condensed Matter Physics, 01 natural sciences, Finite element method, 010305 fluids & plasmas, Bootstrap current, law.invention, Scraper site, Heat flux, law, 0103 physical sciences, Limiter, 010306 general physics, Stellarator

Abstract

The Wendelstein 7-X stellarator is in final stages of commissioning, and will begin operation in late 2015. In the first phase, the machine will operate with a limiter, and will be restricted to low power and short pulse. But in 2019, plans are for an actively cooled divertor to be installed, and the machine will operate in steady state at full power. Recently, plasma simulations have indicated that, in this final operational phase, a bootstrap current will evolve in certain scenarios. This will cause the sensitive ends of the divertor target to be overloaded beyond their qualified limit. A high heat flux scraper element (HHF-SE) has been proposed in order to take up some of the convective flux and reduce the load on the divertor. In order to examine whether the HHF-SE will be able to effectively reduce the plasma flux in the divertor region of concern, and to determine how the pumping effectiveness will be affected by such a component, it is planned to include a test divertor unit scraper element (TDU-SE) in 2017 during an earlier operational phase. Several U.S. fusion energy science laboratories have been involved in the design, analysis (structural and thermal finite element, as well as computational fluid dynamics), plasma simulation, planning, prototyping, and diagnostic development around the scraper element program (both TDU-SE and HHF-SE). This paper presents an overview of all of these activities and their current status.

Published

2016

3. Design and Analysis of Divertor Scraper Elements for the W7-X Stellarator

Author

Joseph B. Tipton, Arnold Lumsdaine, D. McGinnis, J. Geiger, A.T. Peacock, Jeremy Lore, S. A. Bozhenkov, Tamara Andreeva, H. Hoelbe, J. H. Harris, and J. Boscary

Subjects

Physics, Nuclear and High Energy Physics, Field line, Nuclear engineering, Divertor, Plasma, Condensed Matter Physics, 7. Clean energy, Magnetic field, Bootstrap current, law.invention, Heat flux, law, Atomic physics, Engineering design process, Stellarator

Abstract

A set of new water-cooled divertor components is being designed for the Wendelstein 7-X stellarator to protect the edges of the primary plasma facing components during the bootstrap current evolution (~ 40 s). These new components, referred to as scraper elements (SEs), will intercept field lines and associated heat flux that would otherwise overload the main target edges in certain operational scenarios. The SEs are calculated to experience peak heat fluxes ~15-16 MW/m2 and will be constructed from carbon fiber reinforced composite monoblocks of a type that has been qualified for ITER. The heat flux distribution and magnitude is calculated from field line following in a 3-D magnetic field that includes the contribution from plasma currents. The heat flux calculations are coupled with an engineering design in an iterative process to generate SEs that meet the design criteria while reducing the geometric complexity of the elements.

Published

2014