Eric Sembrat's Test Bonanza

Abstract

In 1937 Ettore Majorana introduced the concept of what are now fittingly called Majorana fermions -- fermionic particles that are their own antiparticles. Nowadays an active search for condensed-matter analogues of these elusive objects is well underway, motivated by both the prospect of revealing new facets of quantum mechanics and longer-term quantum computing applications. This talk will survey recent advances in this pursuit.

In particular, I will describe strategies for "engineering" Majorana platforms from simple building blocks, preliminary experimental successes, and future milestones that reveal foundational aspects of Majorana physics directly relevant for quantum computation.

Abstract

Detailed understanding of how conformational dynamics orchestrates function in allosteric regulation of recognition and catalysis at atomic resolution remains ambiguous. The three dimensional structure of protein is not always adequate to provide a complete understanding of protein function. We use atomistic molecular dynamics simulations to complement experiments to understand how protein conformational dynamics are coupled to allosteric function. We analyze multi-dimensional simulation trajectories by mapping key dynamical features within individual macrostates as residue-residue contacts.

In this talk, we will discuss computational studies and evolutionary analysis of members of a ubiquitous family of enzymes that regulate many sub-cellular processes. The effects of distal mutations and substrate binding are observed at locations far beyond the mutation and binding sites, implying their importance in allostery. The results provide insights into the general interplay between enzyme conformational dynamics and catalysis from an atomistic perspective that have implications for structure-based drug design and protein engineering.

ABSTRACT

Today, much of the very high energy Universe is directly accessible only with neutrinos.  The IceCube Neutrino Observatory at the South Pole has been able to detect an energetic cosmic neutrino flux.  More recently, together with other telescopes, more recently, evidence for cosmic neutrinos and gamma rays  from a distant galaxy was reported by IceCube and a number of other ground and space based telescopes.  This strategy, multimessenger astrophysics is seen as the most promising path to close in on a better understanding on some of the most energetic phenomena in the Universe.  In the meantime, preparations are underway for an upgrade of IceCube with optical and radio detectors.  

I will briefly describe the challenges of neutrino astronomy, the recent progress by IceCube and discuss the next generation upgrade at the South Pole.

ABSTRACT

Most populations are spread over spatial ranges much bigger than any one individual will explore in its lifetime. How does the simple fact of this spatial structure affect adaptive evolution and genetic diversity?

I will discuss when space can slow down or speed up adaptation, how adaptation in spatially structured populations restructures even the neutral genetic variation, and how we might be able to use sequencing data as a lens to watch organisms move.

ABSTRACT

Optical interferometry is at the heart of many precise measurements from gravitational wave searches to microscopy.  Generally one improves interferometer precision by increasing the light intensity, as well as by calming the many technical sources of noise that can perturb the mirrors or optical path.  However, at extreme levels of light strength where radiation forces are significant, a new and interesting disturbance should appear – the quantum shaking associated with random arrival of individual photons at a mirror of the interferometer.  This quantum backaction of light has been long foreseen and played a formative role in quantum optics theory.

In this talk I will discuss an experiment in which we used a particularly compliant micro-scale drum to observe backaction in an interferometer, and demonstrate how quantum correlations can improve measurement in the presence of backaction.  In this strong-light limit, interferometer mirrors can also be used as a nonlinear medium to manipulate light – for example to make squeezed light.  We may even be able to extract more complex quantum states from our interferometer by coupling superconducting microwave circuits to the moving mirror.

Abstract:

The Big Bang theory tells the story of the beginning of the Universe, our cosmic home for the last 13.8 billion years. But what is the story of its end? I’ll share what modern astrophysics tells us about the ultimate fate of the cosmos, and what each possibility would entail if there were people there to see it.

Biography:

Dr Katherine (Katie) Mack is a theoretical astrophysicist who studies a range of questions in cosmology, the study of the universe from beginning to end. She currently holds the position of Assistant Professor of Physics at North Carolina State University, where she is also a member of the Leadership in Public Science Cluster. Throughout her career she has studied dark matter, the early universe, galaxy formation, black holes, cosmic strings, and the ultimate fate of the cosmos. Alongside her academic research, she is an active science communicator and has been published in a number of popular publications such as Scientific American, Slate, Sky & Telescope, Time.com, and Cosmos Magazine, where she is a columnist. You can find her on Twitter as @AstroKatie.

Abstract:

The quantum laws governing atoms and other tiny objects seem to defy common sense, and information encoded in quantum systems has weird properties that baffle our feeble human minds. John Preskill will explain why he loves quantum entanglement, the elusive feature making quantum information fundamentally different from information in the macroscopic world.

By exploiting quantum entanglement, quantum computers should be able to solve otherwise intractable problems, with far-reaching applications to cryptology, materials, and fundamental physical science. Preskill is less weird than a quantum computer, and easier to understand.

Bio: 

John Preskill is the Richard P. Feynman Professor of Theoretical Physics at the California Institute of Technology, and Director of the Institute for Quantum Information and Matter at Caltech. Preskill received his Ph.D. in physics in 1980 from Harvard, and joined the Caltech faculty in 1983.  Preskill began his career in particle physics and cosmology, but in the 1990s he got excited about the possibility of solving otherwise intractable computational problems by exploiting quantum physics; he is especially intrigued by the ways our deepening understanding of quantum information and quantum computing can be applied to other fundamental issues in physics, such as the quantum structure of space and time. You can follow him on Twitter @preskill

About the Bold Ideas In Physics Lecture and Exhibit

The lecture series celebrates the life and work of David Ritz Finkelstein, the late School of Physics professor who was unafraid to challenge orthodoxy. The exhibit introduces Finkelstein's life, his work on gravational fields, space-time, quantum relativity, and quantum computations, as well as research by Georgia Tech faculty and students that continues some of his bold ideas. For more information, visit www.davidritzfinkelstein.com.

Abstract:

American Institute of Physics reports 16% decrease in the number of faculty hired for tenure track positions by Physics Departments from over 350 in 2006 to 300 in 2016. Meanwhile, NSF statistics suggests that the number of doctorate degrees awarded in Physics and Astronomy went up 48% from 1565 to 2321 for the same period of time. Among other reasons, the odds of landing a tenure track position can make industry an appealing alternative career choice for perspective graduates. But what if you are not ready to give up research? Fortunately, many companies are willing to invest in highly skilled scientists to drive their scientific endeavors. Daria Monaenkova, a former GA Tech postdoc, comes back to the School of Physics to talk about The Dow Chemical Company and her experience as new employee at Analytical Science organization. She will give an overview of the company, discuss its rich history, culture and priorities and how these priorities are reflected in Analytical Sciences R&D projects. By the way, did you know that Gel Permeation Chromatography, a technique utilized for polymer molecular weight analysis, has been invented at Dow? The presentation will conclude with Q&A session, where you will have a chance to ask about Dow hiring process, life in industry and how it is different from academia.

Bio:

Daria received her B.S./M.S. degree in Physics with specialization in fracture mechanics from Russian State Aviation Technological University in 2007 and her Ph.D. in Materials Science and Engineering from Clemson University in 2012.   In 2012 she joined Professor Daniel Goldman group at the Georgia Institute of Technology as a post-doc to study the interactions of living systems with surrounding environment. She was working on the integration of biological experiments, numerical simulations and robotics to understand and improve organization of complex systems in confined spaces.  In 2016 Daria has joined Analytical Sciences team at The Dow Chemical Company as a senior engineer.  The team focus is the development and implementation of next generation of analytical techniques for materials characterization. Daria is responsible for digital imaging and image analysis and contributes to multiple projects ranging from development of carbon-fiber based composites to plant health assessment in artificial growth substrates.