Development of high pressure deuterium gas targets for the generation of intense mono-energetic fast neutron beams

• Published in: Nuclear instruments & methods in physics research. Section B, Beam interactions with materials and atoms Vol. 152; no. 4; pp. 515 - 526
• Main Authors: Guzek, J, Richardson, K, Franklyn, C.B, Waites, A, McMurray, W.R, Watterson, J.I.W, Tapper, U.A.S
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.06.1999
• ISSN: 0168-583X; 1872-9584
• DOI: 10.1016/S0168-583X(99)00122-6

Two different technical solutions to the problem of generation of mono-energetic fast neutron beams on the gaseous targets are presented here. A simple and cost-effective design of a cooled windowed gas target system is described in the first part of this paper. It utilises a thin metallic foil window and circulating deuterium gas cooled down to 100 K. The ultimate beam handling capability of such target is determined by the properties of the window. Reliable performance of this gas target system was achieved at 1 bar of deuterium gas, when exposed to a 45 μA beam of 5 MeV deuterons, for periods in excess of 6 h. Cooling of the target gas resulted in increased fast neutron output and improved neutron to gamma-ray ratio. The second part of this paper discusses the design of a high pressure, windowless gas target for use with pulsed, low duty cycle accelerators. A rotating seal concept was applied to reduce the gas load in a differentially pumped system. This allows operation at 1.23 bar of deuterium gas pressure in the gas cell region. Such a gas target system is free from the limitations of the windowed target but special attention has to be paid to the heat dissipation capability of the beam dump, due to the use of a thin target. The rotating seal concept is particularly suitable for use with accelerators such as radio-frequency quadrupole (RFQ) linacs that operate with a very high peak current at low duty cycle. The performance of both target systems was comprehensively characterized using the time-of-flight (TOF) technique. This demonstrated that very good quality mono-energetic fast neutron beams were produced with the slow neutron and gamma-ray component below 10% of the total target output.