Microfabrication of a gadolinium-derived solid-state sensor for thermal neutrons

Abstract: Neutron sensing is critical in civilian and military applications. Conventional neutron sensors are limited by size, weight, cost, portability and helium supply. Here the microfabrication of gadolinium (Gd) conversion material–based heterojunction diodes for detecting thermal neutrons using electrical signals produced by internal conversion electrons (ICEs) is described. Films with negligible stress were produced at the tensile-compressive crossover point, enabling Gd coatings of any desired thickness by contr… Show more

“…The electrons resulting from neutron capture by gadolinium do not exceed the likely minimum detectable energy, and gadolinium is therefore excluded from our choice of converter layer. It is significant that the successful use of gadolinium as a neutron converter [34], [35] has been with silicon detectors (pulse heights ∼2× those in SiC) with thick active regions (encompassing the longer range of lighter reaction products and resulting in lower capacitance and lower detection thresholds, e.g. ∼20 keV).…”

Development of an Optimized Converter Layer for a Silicon-Carbide-Based Neutron Sensor for the Detection of Fissionable Materials

“…The electrons resulting from neutron capture by gadolinium do not exceed the likely minimum detectable energy, and gadolinium is therefore excluded from our choice of converter layer. It is significant that the successful use of gadolinium as a neutron converter [34], [35] has been with silicon detectors (pulse heights ∼2× those in SiC) with thick active regions (encompassing the longer range of lighter reaction products and resulting in lower capacitance and lower detection thresholds, e.g. ∼20 keV).…”

Development of an Optimized Converter Layer for a Silicon-Carbide-Based Neutron Sensor for the Detection of Fissionable Materials

Analysis of a neutron-induced conversion electron spectrum of gadolinium

Modelling Gd-diamond and Gd-SiC neutron detectors