David Van Baak (B.S. Calvin College, 1973; M.A. 1975, Ph.D. 1979, Harvard University) is Professor of Physics at Calvin College. He has been teaching, and developing the advanced lab, at Calvin College since 1980. Anyone with an interest in atomic physics and optics is sure to encounter optical pumping, and David first saw the phenomenon in a 'home-built' apparatus as an undergraduate in the 1970‘s. Since then, his research interests in atomic physics, and his teaching in quantum mechanics, have reminded him of all the superb physics that can be illustrated in an apparently simple tabletop apparatus. Few experiments available to undergraduates offer more insight into the practical consequences of all those theoretical details of atomic and optical angular momentum that we can teach our students.
Professor David A. Van Baak, Department of Physics and Astronomy, Calvin College, 3201 Burton Street SE, Grand Rapids, MI 49546. Email: dvanbaak@calvin.edu. Telephone: 616-526-6275
The central theme of ‘optical pumping’ is the transfer of angular momentum. Circularly polarized light carries angular momentum, and resonant light can transfer this angular momentum to the atoms in a vapor sample. This technique, combined with the quantum-mechanical properties of atoms’ ground states, makes possible a host of applications of a deceptively simple optical technique.
Optical pumping is historically interesting for its ‘late’ discovery—this non-laser phenomenon could have been discovered in the 1930’s. But since its invention in the 1950’s, it has remained a technique of continuing interest for highly-sensitive magnetometry, and for atomic frequency standards. It’s also a fine tool for motivating students to appreciate the details of atomic fine- and hyperfine-structure.
This workshop will use the ‘optical bench’ topology of a TeachSpin apparatus to show in detail the instrumental requirements for this technique. Participants will learn how to set up, align, and optimize an optical-pumping apparatus. They will use it to detect driven radio-frequency quantum transitions in real time, and apply that capability to the measurement of weak magnetic fields. Participants need only bring along a lab notebook.