Gauge fields

Interviewed by
David Zierler
Interview date
Location
Video conference
Abstract

In this interview, David Zierler, Oral Historian for AIP, interviews Thomas Appelquist, Eugene Higgins Professor of Physics at Yale University. Appelquist recounts his upbringing in rural Iowa and then Indiana, where he attended Catholic high school. He describes his undergraduate experience at Illinois Benedictine College and explains his attraction to attend a small school for college. Appelquist discusses his decision to attend Cornell for his PhD, and recalls that, relative to others in his cohort who went to larger schools, he had the most catching up to do in quantum mechanics. He explains the development of his thesis topic under the direction of Don Yennie, which focused on aspects of renormalization theory using the Feynman parametric approach. Appelquist contextualizes some of the broader questions in quantum field theory and quantum electrodynamics at this time, and he describes the opportunities that led him to SLAC for his postdoctoral research. He describes his interests there as focused on theories of the weak interactions, and he describes his initial faculty appointment at Harvard where he joined the particle theory group led by Shelly Glashow and Sidney Coleman. Appelquist discusses his close collaboration with Helen Quinn on how to renormalize Yang-Mills theories, and he explains his decision to take a tenured position at Yale in consideration of the culture at Harvard, where the prospects of tenure were minimal. He describes the revolutionary discoveries of asymptotic freedom, QCD, and the “November Revolution” at SLAC and Brookhaven at the time. Appelquist describes his research and administrative activities to advance the particle theory group at Yale, and his overall efforts to improve the department as chair and in particular building up the condensed matter theory group. He discusses his tenure as Dean of the Graduate School and his long-term involvement with the Aspen Center. At the end of the interview, Appelquist describes his current interests in lattice gauge theory and explains why he expects that physics will see double beta decay in the next generation of experiments.

Interviewed by
David Zierler
Interview date
Location
Video conference
Abstract

Interview with Berndt Müller, James B. Duke Professor of Physics at Duke University. The interview begins with Müller discussing his current work on quark-gluon plasma physics and the connections between nuclear physics and cosmology. Müller then recounts his family history in Germany during and after WWII, as well as his childhood in West Germany. He recalls his undergraduate studies at Goethe University Frankfurt, where it was the inspiring lectures that catalyzed his enthusiasm for physics. Müller explains the heavy ion research he was involved in at the time, as well as his master’s thesis on the Dirac equation. He recounts his first visit to Berkeley Lab in 1972 and his subsequent acceptance of a postdoc at University of Washington and a fellowship at Yale. Müller then returned to Frankfurt as an associate professor and explains how he got involved in quark-gluon plasma research. Müller talks about the creation of the RHIC and how that led him to pursue his next job in the US, landing at Duke. He discusses his involvement with the Institute of Nuclear Theory at the University of Washington, as well as his work at Brookhaven over the years. Müller recalls the pros and cons of the administrative side of academia, which he experienced as the Chair of the Faculty of Physics and then Dean of the Faculty of Natural Sciences at Duke. The interview concludes with Müller’s reflections on winning the Feshbach Prize and his predictions for the future of theoretical nuclear physics.

Interviewed by
David Zierler
Interview dates
July 27 & August 2, 2020
Location
Video conference
Abstract

In this interview, Peter McIntyre, Mitchell-Heep professor of experimental physics at Texas A&M University, and president of Accelerator Technology Corporation discusses his career and achievements as a professor. McIntyre recounts his childhood in Florida, and he explains his decision to pursue physics as an undergraduate at the University of Chicago and the influence of his longtime hero Enrico Fermi. He discusses his interests in experimental physics and he explains his decision to stay at Chicago for graduate school, where he worked with Val Teledgi, during a time he describes as the last days of bubble chamber physics. McIntyre conveys his intense opposition to the Vietnam War and the extreme lengths he took to avoid being drafted, and his dissertation work on the Ramsey resonance in zero field. He describes Telegdi’s encouragement for him to pursue postdoctoral research at CERN where he worked with Carlo Rubbia on the Intersecting Storage Rings project. He describes his time as an assistant professor at Harvard and his work at Fermilab, and the significance of his research which disproved Liouville’s theorem. McIntyre describes the series of events leading to his tenure at Texas A&M, and he explains how his hire fit into a larger plan to expand improve the physics program there. He discusses the completion of the Tevatron at Fermilab and the early hopes for the discovery of the mass scale of the Higgs boson, and he describes the origins of the SSC project in Texas and the mutually exclusive possibility that Congress would fund the International Space Station instead. McIntyre describes the key budgetary shortfalls that essentially doomed the SSC from the start, his efforts in Washington to keep the project viable, and the technical shortcomings stemming from miscommunication and stove-piping of expertise. He describes his involvement in the discovery of the top quark and the fundamental importance of the CDF, DZero, and ATLAS collaborations. McIntyre discusses his achievements as a teacher to undergraduates and a mentor to graduate students, and he assesses the current and future prospects for ongoing discovery in high energy physics. At the end of the interview, McIntyre describes his current wide-ranging research interests, including his efforts to improve the entire diagnostic infrastructure in screening and early detection of breast cancer.