|August 25||Bob Svoboda
|WATCHMAN: Neutrino Physics and Nuclear Non-Proliferation – Oh . . . Really?||Tom Handler|
|September 8||Jaideep Singh
Technische Universität München
|Trapping Atoms the "Old-Fashioned" Way: New Results & Opportunities||Nadia Fomin|
|September 15||Peng Xiong
Florida State University
WATCHMAN: Neutrino Physics and Nuclear Non-Proliferation – Oh . . . Really?
Monitoring nuclear non-proliferation treaties is a challenging technological problem. Since the “fast lane” to nuclear weapons is the production of plutonium in small nuclear reactors, an important (but difficult) problem is how to monitor reactors built for research to ensure they are not being used for weapons production. Recent experiments in neutrino physics and dedicated demonstration projects at commercial nuclear plants have shown that it may be possible to use neutrinos to determine the operational cycle of such reactors from moderately distant locations. At the same time, the particle physics community is developing technology that may make such monitoring both feasible and cost effective. The WATCHMAN Project is a collaborative effort between scientists and engineers that will not only advance neutrino detector technology, but also demonstrate the ability to effectively monitor nuclear reactors for weapons production.
Trapping Atoms the "Old-Fashioned" Way: New Results & Opportunities
Inert gases frozen at cryogenic temperatures have been used to trap and study atoms and molecules for over 60 years. In particular, noble gas solids (NGS) are a promising medium for the capture, detection, and manipulation of atoms and nuclear spins. They provide stable, chemically inert, & efficient confinement for a wide variety of guest species. Because NGS are transparent at optical wavelengths, the guest species can be probed using lasers. Longitudinal and transverse nuclear spin relaxation times of a guest species can be made very long under well understood and feasible conditions. Potential applications include measurements of rare nuclear reactions and tests of fundamental symmetries.
In this talk, I will present the results of our optical spectroscopic study of ytterbium atoms embedded in a frozen neon matrix, which includes the first experimental determination of the 23 second lifetime of the metastable atomic state of Yb-171 that is used for next generation atomic clocks. I will conclude with our efforts to demonstrate (1) optical single atom detection for studying rare nuclear reactions and (2) optical pumping of Yb-171 nuclei in solid neon for a test of time-reversal symmetry.
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