Fuel Cycle Research Thrust Using A Full Fusion Nuclear Environment

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Presentation transcript:

Fuel Cycle Research Thrust Using A Full Fusion Nuclear Environment Brad Patton Grady Yoder Martin Peng Korsah Kofi Presented at the Fusion Power Workshop March 2, 2009

Major Tritium Flows Fusion Nuclear Science Facility (FNSF) Fuel Injection System Plasma Vacuum System Tritium Removal Plasma Vacuum System Tritium Purification Tritium Production and Recovery Liquid Breeder Blanket Tritium Purification Waste Tritium Production and Recovery Solid Breeder Blanket Tritium Purification Waste Tritium Storage 2

Required FNS R&D Capabilities of a Full Fusion Nuclear Environment Fusion neutron fluxes ranging from ~0.01 – 2 MW/m2 Continuous operational durations that can be increased from 103 s progressively toward 106 s Safe remote handling of test components Instrumentation of these components to measure in-situ physical properties of interest to Fuel Cycle 3

Enabled R&D Detection techniques to measure and manage tritium under the high temperatures, high neutron flux, and high gamma field in a full fusion environment do not exist and may not be practical to develop Understanding the tritium consumption, production, material interactions, and permeation mechanisms in the full fusion environment and modeling these mechanisms are essential to managing the flow of tritium in Demo in the absence of direct measurement Although the tritium nuclear and chemical reactions and transport models can be initially developed in a laboratory and engineering environment, the validation of the models in a Demo relevant environment is essential FNFS will provide the highly instrumented test environment to validate these essential fusion fuel cycle models 4

Tritium Measurement R&D Although a number techniques exist for measurement of tritium in grab samples and bulk storage geometries, real-time tritium measurements are extremely challenging in the full fusion environment Real-time tritium concentration in gas and liquid streams and tritium profiles in solid material would be invaluable in establishing operational control, tritium accountability, and material radiation degradation effects Successful R&D in the tritium monitoring area would provide significant contribution to success of Demo Advances in tritium monitoring are essential to understanding the fuel cycle phenomena on the path to Demo and also to address the sensitivities of the public to tritium accountability and releases It is recommended an aggressive R&D effort be directed at measurement of tritium in a full fusion environment 5

Enabling Tritium Measurement R&D in a Full Fusion Environments For each area/component/matrix, the conditions need to be understood to frame the tritium measurement R&D effort Neutron Flux Gamma Field Alpha Field Beta Field Tritium Concentration Temperature 6

Backups 7

Closing a Research Gap to Fusion Demo Solid/Liquid breeders Issues: What is the tritium distribution in breeder and surrounding systems? What is the tritium concentration in the breeder as function of operation conditions and operating duration? How is the concentration measured/predicted for operational control? What is the permeation rate and distribution of tritium in the breeder containment system? What is the tritium transport rate through the containment to the coolant? 8

Closing a Research Gap to Fusion Demo (cont.) Tritium Recovery Issues: Do surrogate tritium streams used in testing recovery processes outside a full fusion environment represent the streams in the Demo environment? What are the impurities introduced in a full fusion environment that may impact the recover systems performance? Are there radiation enhanced properties that may impact recovery system performance in a full fusion nuclear environment? 9

Closing a Research Gap to Fusion Demo (cont.) Tritium processing Issues: What is needed to adequately perform tritium accountability and nuclear facility operations for Demo What are the transient and steady state inventories of tritium in the plasma facing components, breeder blanket and containment material? How is the inventory of tritium held up in materials affected by the operating neutron flux, the temperature and its gradient, the defects, and the tritium gradients? Are there synergistic effects among these parameters? Is it necessary to have on-line tritium hold-up detection or can predictive modeling techniques based on integrated parametric experiments provide adequate accountability? Can tritium detection technology be developed to measure tritium “on-line” in the full fusion environment? 10