Current research includes:
MA major research interest is Nuclear Data, more specifically Nuclear Data related to Nuclear Fission and Fusion applications. In these application neutrons play an important role in energy production.
In this research we try to answer questions like:
- How do neutrons interact with materials?
- What is the probability that a neutron will interact in a specific way? For example the neutron can be scattered, induce fission, or be absorbed.
- What are the products of neutron interactions?
- How accurate is the data used for neutron transport calculations?
- How can we improve the accuracy of our reactor calculation predictions?
Because neutron interactions are a complex process that is not completely understood, theory alone cannot provide the answer to these questions. Our research uses neutrons generated by the RPI LINAC to preform experiments that answer these questions. Specific experiments are conducted to answer each of the questions above. For example by passing a neutron beam through a sample material (such as U-238), and measuring the fraction of the beam that does not interact, the probability for neutron interaction can be determined. This probability is referred to as the total neutron interaction cross section.
Examples of experiments performed at the Gaerttner LINAC center include: Neutron transmission – measure the total interaction cross section
- Neutron Capture – measure the neutron capture yield (for a thin sample approximately the capture cross section)
- Neutron fission – measure the fission yield (for a thin sample approximately the fission cross section)
- Fission fragment yields – measure the fission fragment yield as a function of neutron energy.
- Neutron scattering – measures the probability of neutron scattering to different angles.
Sometimes we use experiments also to verify physics models used in different computational code. One such example as an experiment on neutron resonance scattering we performed with U-238. This experiment demonstrated that current model in different Monte Carlo codes under predicted back scattering by nearly a factor of 2.
The research in this area includes cross-section measurements with the RPI LINAC nd other facilities. The RPI LINAC is used to measure transmission, capture and fission cross-sections. The cross sections are measured with thermal and epithermal neutrons. The RPI enhanced thermal target was designed and constructed as part of my PhD. Thesis. This target is still used in today's measurements. The target is optimized to generate high thermal and sub-thermal neutron flux. RPI hosts the one of two slowing-down spectrometer in the USA and one of the few in the world. As part of the research the high flux in the lead spectrometer was used to measure cross section of nano-grams of short-half life isotopes. We are now exploring the possibility of using the lead slowing down spectrometer for measurements of capture cross sections.
The high energy electron beam or intense bremsstrahlung radiation produced by the LIANC can be used to produce medical isotope via the (gamma,x) reaction. Where x could be a neutron or proton for example. The reaction utilized the higher cross section near the peak of the giant dipole resonance which from most element is between 15-30 MeV.
This is a very effective to produce isotopes and often results in cleaner separation chemistry after irradiation. Isotopes studied at RPI include 99Mo, 111In, 67Cu, and 225Ac.
The objective of the experiment is to determine the production rate and compare to simulations. Such work can provide the data needed to design a medical isotope production facility.