TY - GEN
T1 - The ITER radial neutron camera detection system
AU - Marocco, D.
AU - Belli, F.
AU - Bonheure, G.
AU - Esposito, B.
AU - Kaschuck, Y.
AU - Petrizzi, L.
AU - Riva, M.
PY - 2008
Y1 - 2008
N2 - A multichannel neutron detection system (Radial Neutron Camera, RNC) will be installed on the ITER equatorial port plug 1 for total neutron source strength, neutron emissivity/ion temperature profiles and nt/n d ratio measurements [1]. The system is composed by two fan shaped collimating structures: an ex-vessel structure, looking at the plasma core, containing tree sets of 12 collimators (each set lying on a different toroidal plane), and an in-vessel structure, containing 9 collimators, for plasma edge coverage. The RNC detecting system will work in a harsh environment (neutron fiux up to 108-109n/cm2s, magnetic field >0.5T or in-vessel detectors), should provide both counting and spectrometric information and should be flexible enough to cover the high neutron flux dynamic range expected during the different ITER operation phases. ENEA has been involved in several activities related to RNC design and optimization [2,3]. In the present paper the up-to-date design and the neutron emissivity reconstruction capabilities of the RNC will be described. Different options for detectors suitable for spectrometry and counting (e.g. scintillators and diamonds) focusing on the implications in terms of overall RNC performance will be discussed. The increase of the RNC capabilities offered by the use of new digital data acquisition systems will be also addressed.
AB - A multichannel neutron detection system (Radial Neutron Camera, RNC) will be installed on the ITER equatorial port plug 1 for total neutron source strength, neutron emissivity/ion temperature profiles and nt/n d ratio measurements [1]. The system is composed by two fan shaped collimating structures: an ex-vessel structure, looking at the plasma core, containing tree sets of 12 collimators (each set lying on a different toroidal plane), and an in-vessel structure, containing 9 collimators, for plasma edge coverage. The RNC detecting system will work in a harsh environment (neutron fiux up to 108-109n/cm2s, magnetic field >0.5T or in-vessel detectors), should provide both counting and spectrometric information and should be flexible enough to cover the high neutron flux dynamic range expected during the different ITER operation phases. ENEA has been involved in several activities related to RNC design and optimization [2,3]. In the present paper the up-to-date design and the neutron emissivity reconstruction capabilities of the RNC will be described. Different options for detectors suitable for spectrometry and counting (e.g. scintillators and diamonds) focusing on the implications in terms of overall RNC performance will be discussed. The increase of the RNC capabilities offered by the use of new digital data acquisition systems will be also addressed.
KW - ITER
KW - Radial neutron camera
UR - http://www.scopus.com/inward/record.url?scp=42449135699&partnerID=8YFLogxK
U2 - 10.1063/1.2905083
DO - 10.1063/1.2905083
M3 - Conference contribution
AN - SCOPUS:42449135699
SN - 9780735405073
T3 - AIP Conference Proceedings
SP - 291
EP - 294
BT - Burning Plasma Diagnostics - An International Conference
T2 - International Conference on Burning Plasma Diagnostics
Y2 - 24 September 2007 through 28 September 2007
ER -