Blowing dust to cool fusion plasmas by Staff Writers Washington DC (SPX) Mar 09, 2022
Future tokamak fusion power reactors will generate heat beyond what current materials can withstand. Scientists have proposed various methods for cooling the edge of the magnetically confined fusion fuel, or plasma, to protect the walls of the surrounding tokamak. One approach is injecting impurities in the form of gases to help radiate away excess heat. However, there is a limited range of gases that can be injected, and some gases react poorly with hydrogen fusion fuel. A new approach uses impurities in powder form. This allows researchers to introduce a considerable amount of material directly into the exhaust system, far more than with any gas injection technique. This leads to a promising scenario that reduces peak heat fluxes that reach the tokamak wall.
The Impact This cools the plasma edge, creating a protective gas cushion that helps spread heat and particles uniformly across the divertor. The use of powders in place of gases expands the range of possible impurities that can be injected into a tokamak. Powders can also be delivered in higher purity than gases, reducing the dilution of fuel and allowing better control of the fusion plasma. However, powder delivery is still relatively slow, and researchers will need to improve these methods to react to changes in plasma conditions. Future work will combine powder injection for exhaust control with optimization of fusion performance in the plasma core. These steps will help fusion scientists demonstrate how these methods would operate in a working fusion reactor.
Summary A research team working at the DIII-D National Fusion Facility, a Department of Energy (DOE) user facility, experimented with the injection of boron, boron nitride, and lithium powders. Lithium in particular is attractive due to its potential use as a candidate for proposed liquid metal walls in future tokamaks, which would allow heat to spread and be conducted away efficiently and safely. During the experiments, measurements showed increased light emission (radiation) and associated reductions in peak heat flux reaching the wall surfaces. At the same time, powder injection improved the wall conditions and reduced the fuel dilution through impurities. Both lithium and boron nitride caused a substantial increase in gas pressure at the divertor. The radiation features and distribution observed during powder injection were also seen in computer simulations modeling the experiment. The simulations showed that materials with smaller particle sizes tend to be ablated immediately at the injection location and migrate similar to a gas. Larger particles can travel longer distances before they are fully ablated and ionized. The simulations show that the choice of the material and particle size allows controlling the deposition and the location of the cooling location. Understanding this effect in the experiments and through computer simulations makes it possible to include this in reactor designs. Incorporating powder injection into future reactor designs may allow them to maintain high levels of fusion performance while increasing the lifetime of divertor surfaces.
Research Report: "3D modeling of boron transport in DIII-D L-mode wall conditioning experiments"
Selecting the right structural materials for fusion reactors Tokyo, Japan (SPX) Mar 04, 2022 Do two promising structural materials corrode at very high temperatures when in contact with "liquid metal fuel breeders" in fusion reactors? Researchers of Tokyo Tech, YNU and QST now have the answer. This high-temperature compatibility of reactor structural materials with the liquid breeder-a lining around the reactor core that absorbs and traps the high energy neutrons produced in the plasma inside the reactor-is key to the success of a fusion reactor design. Fusion reactors could be a powerful ... read more
|
|
The content herein, unless otherwise known to be public domain, are Copyright 1995-2024 - Space Media Network. All websites are published in Australia and are solely subject to Australian law and governed by Fair Use principals for news reporting and research purposes. AFP, UPI and IANS news wire stories are copyright Agence France-Presse, United Press International and Indo-Asia News Service. ESA news reports are copyright European Space Agency. All NASA sourced material is public domain. Additional copyrights may apply in whole or part to other bona fide parties. All articles labeled "by Staff Writers" include reports supplied to Space Media Network by industry news wires, PR agencies, corporate press officers and the like. Such articles are individually curated and edited by Space Media Network staff on the basis of the report's information value to our industry and professional readership. Advertising does not imply endorsement, agreement or approval of any opinions, statements or information provided by Space Media Network on any Web page published or hosted by Space Media Network. General Data Protection Regulation (GDPR) Statement Our advertisers use various cookies and the like to deliver the best ad banner available at one time. All network advertising suppliers have GDPR policies (Legitimate Interest) that conform with EU regulations for data collection. By using our websites you consent to cookie based advertising. If you do not agree with this then you must stop using the websites from May 25, 2018. Privacy Statement. Additional information can be found here at About Us. |