Neutron source strength monitors for ITER
There are several goals for the neutron source strength monitor system for the International Thermonuclear Experimental Reactor. Desired is a stable, reliable, time-dependent neutron detection system ...
There are several goals for the neutron source strength monitor system for the International Thermonuclear Experimental Reactor. Desired is a stable, reliable, time-dependent neutron detection system ...
Feasibility of neutron spectrometry diagnostic for the fuel ion density in DT tokamak plasmas
The neutron wall emission (WE) background is a crucial element of neutron spectrometry as a fuel density diagnostic for burning deuterium-tritium fusion plasmas in tokamaks. WE spectra have been studi...
The neutron wall emission (WE) background is a crucial element of neutron spectrometry as a fuel density diagnostic for burning deuterium-tritium fusion plasmas in tokamaks. WE spectra have been studi...
Neutron activation for ITER
Rev. Sci. Instrum. 68, 577 (1997); doi:10.1063/1.1147657
Issue Date: January 1997
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There are three primary goals for the Neutron Activation system for ITER: to maintain a robust relative measure of fusion power with stability and wide dynamic range (seven orders of magnitude), allow an absolute calibration of fusion power production, and provide a flexible and reliable system for materials testing. The nature of the activation technique is such that stability and wide dynamic range can be intrinsic properties of the system. It has also been the technique that demonstrated (on JET and TFTR) the most accurate neutron measurements in DT operation. Since the detectors for assaying the radioactivity are not located on the tokamak and are therefore amenable to accurate characterization, and if the activation samples are placed very close to the ITER plasma with minimal scattering or attenuation, high overall accuracy in the fusion energy production (7%–10%) should be achievable on ITER. In the paper, a conceptual design is presented. A system is shown to be capable of meeting these three goals, and unresolved design issues are identified. ©1997 American Institute of Physics.
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KEYWORDS and PACS
ITER TOKAMAK,
POWER GENERATION,
MEASURING METHODS,
PLASMA DIAGNOSTICS,
MATERIALS TESTING,
RADIOACTIVATION,
NEUTRON ACTIVATION ANALYSIS,
NEUTRON DETECTION,
CALIBRATION,
Tokamak devices,
neutron spectrometers,
plasma toroidal confinement,
fusion reactor instrumentation,
fusion reactor ignition
- 52.70.Nc
Physics of plasmas and electric discharges Plasma diagnostic techniques and instrumentation Particle measurements - 52.55.Fa
Physics of plasmas and electric discharges Magnetic confinement and equilibrium Tokamaks - 52.55.Pi
Physics of plasmas and electric discharges Magnetic confinement and equilibrium Fusion products effects (e.g., alpha-particles, etc.) - 28.52.Lf
Nuclear engineering and nuclear power studies Fusion reactors Components and instrumentation - 28.52.Cx
Nuclear engineering and nuclear power studies Fusion reactors Fueling, heating and ignition - 29.40.-n
Experimental methods and instrumentation for elementary-particle and nuclear physics Radiation detectors - 29.30.Hs
Experimental methods and instrumentation for elementary-particle and nuclear physics Spectrometers and spectroscopic techniques Neutron spectroscopy - YEAR: 1996-97
RELATED DATABASES
PUBLICATION DATA
0034-6748 (print)
1089-7623 (online)
AIP
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