Home | Department of Physics

Awardees at Physics Department annual
research poster exhibit, April 24, 2019.
Prof. Dame Jocelyn Bell Burnell,
Discovery of Binary Pulsars
23rd Annual Katzenstein Lecture
University of Connecticut
November 8, 2019
Prof. Bell Burnell with UConn Women in Physics, November 2019
Annual awards event honoring outstanding teaching assistants
Introductory Physics applies hands-on approach to learning
Annual department hike up Mt. Monadnock, October 2019

UConn seismometer detects Puerto Rico event

January 7, 2020

The Geophysics research group (Prof. Vernon Cormier and students) operate a seismic wave station that continuously monitors vibrations in the earth’s crust, many of which arise from seismic events that happen far away. These waves travel through the deep earth, and eventually make their way to the surface where they are detected. The above […]

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Professor Donna Strickland , Katzenstein Distinguished Lecturer, March 13, 2020

December 4, 2019

The University of Connecticut, Department of Physics, is proud to announce that on March 13, 2020, Professor Donna Strickland of the Department of Physics and Astronomy at the University of Waterloo will be presenting the 2020 Distinguished Katzenstein Lecture. Prof. Strickland is one of the recipients of the 2018 Nobel Prize in Physics for developing […]

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Insight from APS: Careers in Physics

November 16, 2019

What is a Bachelors of Science degree in Physics good for? What kinds of jobs are available to graduates who complete a 4-year degree in physics, but decide not to pursue an advanced degree? How does a physics degree stack up against other STEM fields in terms of employment options in today’s highly competitive job […]

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Ron Mallett Featured on NBC Connecticut

November 15, 2019

Could traveling into the past be part of our future? Quite possibly, says Ron Mallett, a UConn emeritus professor of physics who has studied the concept of time travel for decades. Earlier this month, he spoke with NBC Connecticut reporter Kevin Nathan about his life and work as a theoretical physicist, and discussed how time […]

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UConn Today: A New Phase for the Gant Science Complex

November 11, 2019

The UConn Today published an article highlighting the state of 10-year renovation of the Gant Science Complex. The Complex was first constructed between 1974 and 1978 and was home to the departments of mathematics and physics for several decades. The renovation to this 285,00 square-foot campus landmark is part of Next Generation Connecticut, the initiative […]

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Feb 28 Graduate Student Seminar12:15pm

Graduate Student Seminar

Friday, February 28th, 2020

12:15 PM - 01:15 PM

Storrs Campus
GS-119

Prof. M. Gai, Department of Physics, University of Connecticut

The Big Bang

The Big Bang theory is one of the most fundamental theory of nature. In particular Big Bang Nucleosynthesis (BBN) is a parameter free theory, that gave one of the first and strongest evidence for the Big Bang theory. Current observation of primordial elements (that were produced during BBN), that are measured in some cases with an accuracy nearing 1%, are predicted at the same level of accuracy, with excellent agreement with observation. But one nagging problem remains: the production of 7Li in BBN is approximately a factor 3 and close to 5 sigma smaller than the prediction of BBN. This problem has been known over the last forty years as the "Primordial 7Li Problem".

We will review the Big Bang theory and BBN and describe an attempt to solve the lithium problem in the Master work of Emily Kading at UConn. We conclude that currently, there is still no standard solution to the lithium problem.

Contact Information: Prof. V. Kharchenko
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Mar 6 Physics Colloquium (Dr. Ali Kaya)3:30pm

Physics Colloquium (Dr. Ali Kaya)

Friday, March 6th, 2020

03:30 PM - 04:30 PM

Storrs Campus
BPB-131

Dr. Ali Kaya, Department of Physics, Harvard University

Challenging the initial condition prescriptions in quantum cosmology

Determining the initial state of the universe is a challenging problem in quantum cosmology and there are popular suggestions like the no boundary (Hawking & Hartle) and the tunneling (Vilenkin) prescriptions.

After briefly reviewing the problem, we argue that the quantum theory of gravity must resolve the big-bang singularity either by yielding a regular past eternal evolution or by a smooth finite beginning; in both cases the initial state can in principle be totally arbitrary that need not to be restricted by any ad-hoc principle. We illustrate this point in a minisuperspace toy model where there is a smooth beginning of the universe provided by the matter Hamiltonian degenerating to the zero operator. This simple model also illustrates how quantum gravity may resolve the big-bang singularity.

Contact Information: Prof. Necmi Biyikli (ECE)
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Mar 10 Condensed Matter Physics Seminar2:00pm

Condensed Matter Physics Seminar

Tuesday, March 10th, 2020

02:00 PM - 03:00 PM

Storrs Campus
GS 119

Dr. A. B. Belonoshko,
Department of Physics, Royal Institute of Technology, Sweden

Iron under extreme conditions

I will report the latest theoretical data on the iron phase diagram. A particular emphasis will be on the stabilization of the high-PT body-centered cubic (bcc) Fe under conditions of the Earth Inner Core [1] and how its stabilization interfere in the interpretation of iron melting curve and resolution of related enigmatic questions.

The mechanism of the high-PT bcc Fe phase stabilization is quite unique. The atoms in this structure move at times as in a liquid [2]. Therefore, the mean square displacement never saturates and the diffusion coefficient and the viscosity of the bcc Fe are similar to those in very viscous liquid [3].

Recently, our theoretical prediction of the stability of high-PT bcc Fe phase [1,4] was confirmed by diamond anvil cell experiments [5]. Interesting, that when a number of the experimental studies analyzed with the knowledge of the physics of the bcc Fe phase, those experiments confirm the stability of the new phase rather than contradict it.

I will show how the X-ray diffraction pattern of the bcc Fe looks like and discuss whether similar XRD patterns have already been observed in Fe high-PT melting experiments. I will demonstrate that the stabilization of the bcc phase was at times misinterpreted as melting.

The similarity of the bcc and liquid iron under extreme conditions of pressure and temperature revives the speculations on the existence of the critical solid-liquid point.

Acknowledgments: This work was supported by the Swedish Research Council.

[1] A. B. Belonoshko, T. Lukinov, J. Fu, J. Zhao, S. Davis, S. I. Simak Nature Geoscience 10, 312 (2017).

[2] https://www.youtube.com/watch?v=s5Rl7mtxiEY

[3] A. B. Belonoshko, J. Fu, T. Bryk, S. I. Simak, M. Mattesini, Nature Communications 10, 1-7 (2019).

[4] A. B. Belonoshko, R. Ahuja, B. Johansson, Nature 424, 1032 (2003).

[5] R. Hrubiak, Y. Meng, G. Shen, arXiv:1804.05109 Experimental evidence of a body centered cubic iron at the Earth's core conditions.

Contact Information: Prof. A. Balatsky.
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Mar 13 24th Annual Katzenstein Distinguished Lecture4:00pm

24th Annual Katzenstein Distinguished Lecture

Friday, March 13th, 2020

04:00 PM - 05:00 PM

Storrs Campus
Student Union Theater

Presented by the UConn Physics Department, the Katzenstein Distinguished Lecture series continues this spring. This year's program features Professor Donna Strickland of the University of Waterloo, 2018 Nobel Prize winner in Physics for co-inventing chirped pulse amplification, a technique for creating high-intensity ultrashort optical pulses. More information about Professor Strickland can be found: https://physics.uconn.edu/2019/12/04/professor-donna-strickland-katzenstein-distinguished-lecturer-march-13-2020/

Contact Information: caroline.cichocki@uconn.edu
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Mar 17 Condensed Matter Physics Seminar2:00pm

Condensed Matter Physics Seminar

Tuesday, March 17th, 2020

02:00 PM - 03:00 PM

Storrs Campus
GS 119

Dr. J. Nathan Hohman,
Institute of Materials Science and the Department of Chemistry, University of Connecticut

Self-Assembly of Low-Dimensional Nanomaterials in Crystalline Ensemble

When reduced in size to the nanoscale, materials express compelling new phenomena. For example, a single layer abstracted from graphite leads to fantastic new properties in graphene, or a nanocrystal of gold takes on new optical properties as a nanoparticle. Making materials very small or very thin has been an easy way to prepare exciting new materials—for example, the 2D transition metal dichalcogenides (TMDCs) have a long history of investigation prior to the recent interest in their monolayers for applications in photovoltaics, electrocatalysts, and spintronic materials. 2D phases have been uncovered for a number of elements and binary semiconductors, although many compounds do not share the same propensity to form 2D structures. Through the use of hybrid materials like hybrid perovskites and metal organic chalcogenide assemblies (MOCHAs), low-dimensional nanostructures can be prepared that are part of a crystalline ensemble, unlocking new portions of the period table to the exploration of low-dimensional phases. Importantly, hybrid materials combine organic components which enables structural and electronic direction at the molecular scale. Here, we consider the structure and organization of mithrene- silver benzeneselenolate- a self-assembling layered hybrid structure, and examine its optoelectronic properties in the context of a 2D-like material. Synthetic manipulation of dimensionality and topology is used to prepare a family of related crystalline polymer systems, and the role of intermolecular forces and molecular geometry on the inorganic phases are considered in the context of transitions between 1D, 2D, and 3D coordination polymer systems.

Contact Information: Prof. B. Wells
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Charles Reynolds Distinguished Lecture, Charles Reynolds Distinguished Lecture (Prof. Peter Abbamonte, U. of Illinois)3:30pm 2/21

Charles Reynolds Distinguished Lecture, Charles Reynolds Distinguished Lecture (Prof. Peter Abbamonte, U. of Illinois)

Friday, February 21st, 2020

03:30 PM - 04:30 PM

Storrs Campus
BPB-131

Charles Reynolds Distinguished Lecture

"Bose Condensation of Excitons in a Transition Metal Dichalcogenide"

Professor Peter Abbamonte
University of Illinois
Urbana, IL

Bose condensation has shaped our understanding of macroscopic quantum phenomena, having been realized in superconductors, atomic gases, and liquid helium. Excitons are bosons that have been predicted to condense into either a superfluid or an insulating electronic crystal. But definitive evidence for a thermodynamically stable exciton condensate has never been achieved. In this talk I will describe our use of momentum-resolved electron energy-loss spectroscopy (M-EELS) to demonstrate the existence of an exciton condensate in the transition metal dichalcogenide semimetal, 1T‐TiSe2. This phase of matter was predicted in the 1960's and nicknamed "excitonium" by Halperin and Rice, but not realized for certain until now. I will discuss the experimental signature of exciton condensation, a plasmon that disperses to zero energy at the transition temperature, and latest results on its stability against carrier doping and hydrostatic pressure.

Contact Information: Prof. Jason Hancock
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Dr. Evan Philip, Department of Physics & Astronomy, Stony Brook University, "Chiral Photocurrents and Terahertz Emission in Dirac/Weyl Semimetals", Condensed Matter Physics Seminar2:00pm 2/19

Dr. Evan Philip, Department of Physics & Astronomy, Stony Brook University, "Chiral Photocurrents and Terahertz Emission in Dirac/Weyl Semimetals", Condensed Matter Physics Seminar

Wednesday, February 19th, 2020

02:00 PM - 03:00 PM

Storrs Campus
GS 119

Dr. Evan Philip, Department of Physics & Astronomy, Stony Brook University

Chiral Photocurrents and Terahertz Emission in Dirac/Weyl Semimetals

I will start with an introduction to Dirac/Weyl semimetals and chiral anomaly. We will then look at a new mechanism for photocurrents in Dirac/Weyl semimetals that relies on the chiral anomaly. I will also discuss terahertz emission from the Weyl semimetal TaAs induced by a near-infrared laser, where Weyl fermions play a central role. We will conclude with remarks on some potential applications of these works.

Contact Information: Prof. A. Balatsky
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Dr. I. Zaliznyak, Brookhaven National Laboratory, "Entropic elasticity and negative thermal expansion in crystalline solids", Condensed Matter Physics Seminar2:00pm 2/18

Dr. I. Zaliznyak, Brookhaven National Laboratory, "Entropic elasticity and negative thermal expansion in crystalline solids", Condensed Matter Physics Seminar

Tuesday, February 18th, 2020

02:00 PM - 03:00 PM

Storrs Campus
GS 119

Dr. I. Zaliznyak, Brookhaven National Laboratory

Entropic elasticity and negative thermal expansion in crystalline solids

While most solids expand when heated, some materials show the opposite behavior: negative thermal expansion (NTE). NTE is common in polymers and biomolecules, where it stems from the entropic elasticity of an ideal, freely-jointed chain. The origin of NTE in solids had been widely believed to be different, with phonon anharmonicity and specific lattice vibrations that preserve geometry of the coordination polyhedra -- rigid unit motions (RUMs) -- as leading contenders for explaining NTE. Our neutron scattering study of a simple cubic NTE material, ScF3, overturns this consensus [1]. We observe that the correlation in the positions of the neighboring fluorine atoms rapidly fades on warming, indicating an uncorrelated thermal motion, which is only constrained by the rigid Sc-F bonds. These experimental findings lead us to a quantitative, quasi-harmonic theory of NTE in terms of entropic elasticity of a Coulomb floppy network crystal, which is applicable to a broad range of open framework solids featuring floppy network architecture [2]. Our theory is in remarkable agreement with experimental results in ScF3, accurately describing NTE, phonon frequencies, entropic compressibility, and structural phase transition governed by entropic stabilization of criticality. We thus find that NTE in a family of insulating ceramics stems from the same simple and intuitive physics of entropic elasticity of an under-constrained floppy network that has long been appreciated in soft matter and polymer science, but broadly missed by the "hard" condensed matter community.

Our results reveal the formidable universality of the NTE phenomenon across soft and hard matter [1,2].

[1] D. Wendt, et al., Sci. Adv. 5: eaay2748. (2019).

[2] A. V. Tkachenko, I. A. Zaliznyak. arXiv:1908.11643 (2019).

Contact Information: Prof. I. Sochnikov
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Dr. Andrey Sadofyev, Los Alamos National Laboratory, "Spin polarization of gauge bosons in rotating plasma", Particle, Astrophysics, and Nuclear Physics Seminar2:00pm 2/17

Dr. Andrey Sadofyev, Los Alamos National Laboratory, "Spin polarization of gauge bosons in rotating plasma", Particle, Astrophysics, and Nuclear Physics Seminar

Monday, February 17th, 2020

02:00 PM - 03:00 PM

Storrs Campus
GS-413E

Dr. Andrey Sadofyev, Los Alamos National Laboratory

Spin polarization of gauge bosons in rotating plasma

I will show that the chiral vortical effect (CVE) known to take place for massless fermions in a rotating system can be, in fact, generalized to particles of arbitrary spin. These effects are particularly interesting since they describe the polarization of quarks, gluons, and photons in rotating QGP produced in heavy-ion collisions. For gauge bosons the local polarization current is not gauge invariant making it harder to use this object on practice. This issue can be resolved if one focuses on a class of gauge-invariant but non-canonical polarization currents of gauge bosons known as zilches. I will further show that CVE for gauge bosons has a counterpart in the general zilch current - zilch vortical effect (ZVE) and discuss how ZVE arises in a simple theoretical setup.

Contact Information: Prof. L. Jin
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Prof. G. Dunne, Department of Physics, University of Connecticut, "Scientific Communication: Preparing a Talk, a Proposal, or a Paper", Graduate Student Seminar12:15pm 2/14

Prof. G. Dunne, Department of Physics, University of Connecticut, "Scientific Communication: Preparing a Talk, a Proposal, or a Paper", Graduate Student Seminar

Friday, February 14th, 2020

12:15 PM - 01:15 PM

Storrs Campus
GS-119

Prof. G. Dunne, Department of Physics, University of Connecticut

Scientific Communication: Preparing a Talk, a Proposal, or a Paper

An important part of the work of a scientist is to communicate clearly the results of their work, in a way that can be understood by the appropriate audience: scientific, political or general. In this talk I discuss some tips for preparing a paper, a seminar or a proposal, and encourage you to think carefully about this aspect of your work. The good news is that with a little dedicated effort it is a sure way to stand out from the pack and have your work recognized.

Contact Information: Prof. V. Kharchenko
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Prof. Lorenzo Sorbo, Department of Physics, University of Massachusetts Amherst, "Particle production during inflation: a case study", Particle, Astrophysics, and Nuclear Physics Seminar2:00pm 2/10

Prof. Lorenzo Sorbo, Department of Physics, University of Massachusetts Amherst, "Particle production during inflation: a case study", Particle, Astrophysics, and Nuclear Physics Seminar

Monday, February 10th, 2020

02:00 PM - 03:00 PM

Storrs Campus
GS-413E

Prof. Lorenzo Sorbo, Department of Physics, University of Massachusetts Amherst

Particle production during inflation: a case study

In this talk I will quickly review primordial inflation. After arguing that axion-like inflatons are especially well motivated, I will discuss how a derivative coupling of a pseudoscalar inflaton to vector and to fermions fields can amplify significantly the mode functions of those degrees of freedom which, in their turn, can lead to a very rich phenomenology.

Contact Information: Prof. L. Jin
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Prof. Reynold E. Silber, Department of Geology and Geophysics, Yale University, "Transport properties of liquid transition metals at extreme conditions: a lesson from metallic glasses with the forbidden symmetry", Physics Colloquium (Prof. Reynold Silber)3:30pm 2/7

Prof. Reynold E. Silber, Department of Geology and Geophysics, Yale University, "Transport properties of liquid transition metals at extreme conditions: a lesson from metallic glasses with the forbidden symmetry", Physics Colloquium (Prof. Reynold Silber)

Friday, February 7th, 2020

03:30 PM - 04:30 PM

Storrs Campus
BPB-131

Prof. Reynold E. Silber, Department of Geology and Geophysics, Yale University

Transport properties of liquid transition metals at extreme conditions: a lesson from metallic glasses with the forbidden symmetry

The Earth's core is a giant heat engine that supports the existence of life on our planet by providing heat to drive mantle convection, plate tectonics and volcanism. The convection of a liquid iron (Fe) alloy in the outer core generates the Earth's magnetic field. However, transport properties of liquid Fe-alloys (e.g., electrical, thermal and viscous transport properties) at extreme core conditions are some of the least constrained parameters. The high pressure experimental measurements of the transport properties are extremely challenging and a general theoretical understanding of the structures of liquid transition metals is still incomplete. Recent successful electrical resistivity measurements of liquid Fe, Ni and Fe-Si alloy at pressures up to 24 GPa show the invariant electrical resistivity along the melting boundaries. It was demonstrated that the Icosahedral Short Range Order (ISRO) structures in liquid transition metals and alloys strongly modulate transport properties at extreme conditions. Supporting evidence for the presence of the ISRO in the Earth's and other terrestrial outer cores comes from the recently discovered quasi-crystalline phases in natural metallic glasses with the forbidden symmetry, previously considered impossible to exist in nature. However, the existence of forbidden fivefold symmetry is not possible without super-cooling of metallic glass forming liquids that contain ISRO structures. Thus, metallic glasses represent one of the convergence points between planetary science and materials science. Here, I first discuss a new paradigm imposed by the ISRO structures on the transport properties of the outer cores of terrestrial planetary bodies. The discussion is then extended toward the important role ISROs play in formation of metallic glasses with exotic properties. Furthermore, I examine the potential application of high pressures toward manufacturing of metallic glasses with customizable concentration of structures with ISRO or any other forbidden symmetry. Considering the important role of metallic glasses in the high tech industry, this research has significant cross-disciplinary implications.

Contact Information: Prof. Vernon Cormier
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Prof. I. Sochnikov, Department of Physics, University of Connecticut, "Quantum sensing and imaging of materials", Graduate Student Seminar12:15pm 1/31

Prof. I. Sochnikov, Department of Physics, University of Connecticut, "Quantum sensing and imaging of materials", Graduate Student Seminar

Friday, January 31st, 2020

12:15 PM - 01:15 PM

Storrs Campus
GS-119

Prof. I. Sochnikov, Department of Physics, University of Connecticut

Quantum sensing and imaging of materials

I will describe our recent discoveries of fascinating emergent phenomena in several quantum materials, including high temperature and low temperature superconductors. I will provide details of our state-of-the-art experimental systems with a focus on quantum sensing and mesoscopic imaging.

Additionally, I will present my view of what a successful doctorate in experimental physics includes, as well as, what you might expect from our Ph.D. program and how to be successful in it.

Contact Information: Prof. V. Kharchenko
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