Neutron Science Laboratory

The NERS department previously managed and used the Ford Nuclear Reactor at the Phoenix Memorial Laboratory. The reactor provided an access to a neutron source for instructional and experimental use. In 2003, the Ford Nuclear Reactor was shut down and decommissioning operations began. A neutron source was still required for educational and research use. In 2004, the NERS Department purchased a DD neutron generator (Thermo Fisher Scientific, Model MP320, producing 2.45 MeV with a rate of 10⁶ n/s).

A decision was also made to have a dedicated facility for a neutron source, and in 2006, the first deliveries of components for a D711 DT neutron generator from Thermo Electron Corporation (USA) were made to the department. This generator was rated to produce up to 2×10¹⁰ n/s at 14.1 MeV, a useful flux for nuclear activation studies. Final installation and operation of the D711 neutron generator commenced in 2007. The original housing for the neutron generator consisted of a prefabricated concrete “cave”. The cave was about 3 m in length and 1.5 m wide and had windows on two sides. The walls were about 35 cm thick. By simulating the cave and surrounding room, it was determined that 2.5 cm of polyethylene lining added to the inside and outside of the cave would help thermalize the neutrons. In addition, another 60-cm thick wall was built of concrete blocks around the entirety of the cave. The floor was also lined with 5 cm of polyethylene to reduce scatter from the floor. This reduced the average dose on the surface of the cave below 10 mRem/hr. “Hotspots” still existed at the points closest to the source, but they were less than 50 mRem/hr, well within the 100 mRem/hr regulation.

In 2017, the D711 neutron generator was decommissioned and a new DT neutron generator (Thermo Fisher Scientific, Model P211, producing up to 10⁸ n/s at 100 Hz) was acquired with a goal to provide a pulsed neutron source with near-monoenergetic spectrum by operating the unit in open space, far from structural or shielding walls and floor. The NSL was redesigned and renovated to ensure that the dose rates around the laboratory stay within the permissible limits. The renovated NSL provides a convenient access to both monoenergetic (DD/DT) and broad-energy (²⁵²Cf) neutron sources to the faculty, staff, and students of University of Michigan. The laboratory also houses various radioisotope gamma sources, detectors, and supporting nuclear instrumentation.