UMD CMNS Physics S1 Color


The Fall 2016 colloquia will be held in the lobby of the Physical Sciences Complex unless otherwise noted

Each week during the semester, the Department of Physics invites faculty, students and the local community to hear prominent scientists discuss intriguing physics research. The Fall 2016 colloquia will be held Tuesdays in the Physical Sciences Complex lobby at 4:00 p.m. (preceded by light refreshments at 3:30 p.m.)

Parking is available in the Regents Drive Parking Garage (PG2). An attendant will direct visitors within the garage. Additionally, a free ShuttleUM bus runs between the College Park Metro Station and Regents Drive at about eight-minute intervals.

For further information, please contact the Physics Department at 301-405-5946 or email This email address is being protected from spambots. You need JavaScript enabled to view it..

September 6
Carter Hall, University of Maryland

Down-to-earth searches for cosmological dark matter

Can we detect the Milky Way's dark matter halo in a laboratory experiment? If so, it would be a spectacular confirmation of modern cosmology, and would re-write the standard model of particle physics. A global campaign of such direct-detection experiments is rapidly exploring many theoretical models, and this talk will review where we stand and what may lie ahead, with emphasis on the LUX and LZ experiments.


September 20
Prange Prize Lecture
PHYS Room 1412
Frank Wilczek, MIT
Hosted by: Sankar Das Sarma

Some Intersections of Art and Science

There are profound reasons, rooted in the nature of human cognition and perception, why art and science have a lot to offer one another. Wilczek will display some important historical examples of their synergy, and point out some emerging opportunities. Several striking images are an integral part of the presentation.

September 27
Kaustubh Agashe, University of Maryland


October 4
Shih-I Pai Lecture
PHYS Room 1412
Carlos Bustamante, University of California, Berkeley
Hosted by: Chris Jarzynski

The Folding Cooperativity of a Protein is Controlled by the Topology of its Polypeptide Chain

Proteins are complex functional molecules that tend to segregate into structural regions. Throughout evolution, biology has harnessed this modularity to carry out specialized roles and regulate higher-order functions such as allostery. Cooperative communication between such protein regions is important for catalysis, regulation, and efficient folding; indeed, lack of domain coupling has been implicated in the formation of fibrils and other misfolding pathologies.  How domains communicate and contribute to a protein’s energetics and folding, however, is still poorly understood. Bulk methods rely on a simultaneous and global perturbation of the system (temperature or chemical denaturants) and can miss potential intermediates, thereby overestimating protein cooperativity and domain coupling.  I will show that by using optical tweezers it is possible to mechanically induce the selective unfolding of particular regions of single T4 lysozyme molecules and establish the response of regions not directly affected by the force.  In particular, I will discuss how the coupling between distinct domains in the protein depends on the topological organization of the polypeptide chain.  To reveal the status of protein regions not directly subjected to force, we determined the free energy changes during mechanical unfolding using Crooks’ Fluctuation Theorem. We evaluate the cooperativity between domains by determining the unfolding energy of topological variants pulled along different directions.  We show that topology of the polypeptide chain critically determines the folding cooperativity between domains and, thus, what parts of the folding/unfolding landscape are explored.  We speculate that proteins may have evolved to select certain topologies that increase coupling between regions to avoid areas of the landscape that lead to kinetic trapping and misfolding.

October 18
Peter Shawhan, University of Maryland

Probing physics and astrophysics with gravitational wave observations

The direct detection of gravitational waves by LIGO in 2015 was an amazing milestone. Our exquisitely constructed detectors have finally reached the sensitivity at which these exceedingly weak signals can be recorded and identified. LIGO detected two clear events, each from the merger of a pair of rather heavy black holes. Those events, plus a third candidate, are already informing us about stellar evolution and allowing us to test the general theory of relativity in detail. I will talk about the operational status of LIGO and Virgo and the prospects for capturing more events in the near future. Besides further binary black hole events, we are also eager to detect binaries containing neutron stars, and potentially other signals. I will outline the possibilities for detecting gamma-ray bursts and/or other electromagnetic signals associated with gravitational-wave events (with a possible hint already from the Fermi spacecraft).

THURSDAY, October 20
Democracy Then & Now Series
Tom Cohen, University of Maryland

American Democracy and Science

The philosophical movement known as the Enlightenment stressed the role of reason and in many deeps ways guided the development of modern science. In developing the political system of the United States, its founders were also profoundly influenced by the ideas of the Enlightenment. This talk explores the interactions between American democracy and science from their enlightenment beginnings to the present.

October 25
Paint Branch Lecture
PHYS Room 1412
Eli Yablonovitch, University of California, Berkeley
Hosted by: Tom Murphy



November 1
Laurens Molenkamp, University of Wurzburg
Hosted by: Mohammad Hafezi



November 8
Artur Ekert, University of Oxford
Hosted by: Charles Clark



November 22
Lisa Manning, Syracuse University
Hosted by: Chris Jarzynski



November 29
DST Lecture
Steven Anlage, University of Maryland

When Waves Meet Chaos: A Clash of Paradigms