Home | Department of Physics

Grads kick off the new 2021-2 year with a hike to Wolf Rock in Storrs
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

UConn Physics showing strong at the 2023 APS March Meeting

March 28, 2023

This year, international conferences have begun to come back into their pre-pandemic form. For the American Physical Society’s annual March Meeting, it was bigger than ever with over 12,000 participants in the world’s largest meeting ever devoted to physics. UConn showed strong as graduate students, postdoctoral fellows, research scientists, and faculty researchers attended the meeting […]

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The passing of Dr. Garry Bent

March 17, 2023

Gary Dean Bent, 82, a former assistant head of the Physics Department at the University of Connecticut for 23 years, passed away on Friday, March 3, 2023. He was born on October 9, 1940, in Battle Creek, Michigan. Growing up in Florida, he studied at the Georgia Institute of Technology where he earned Bachelor’s and […]

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The Milky Way Laboratory Contributes to Art Exhibit at the University of Hartford

March 2, 2023

Prof. Cara Battersby’s research group, the Milky Way Laboratory, was invited to collaborate with Genevieve de Leon, the 2022-23 Koopman Distinguished Chair in the Painting Department at the University of Hartford, for an exhibition focused on the intersection between the Maya calendrical cycles and scientific studies of the cosmos. From the Milky Way Laboratory, H […]

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Prof. Jonathan Trump interviewed by The Conversation about JWST Discoveries

February 8, 2023

The Conversation interviewed Prof. Jonathan Trump about his recent work with the James Webb Space Telescope (JWST), with an article and podcast interview available at this link. The interview includes discussion of Prof. Trump’s recent journal paper that used spectroscopic observations from JWST to understand the chemical enrichment of galaxies in the early Universe.

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2023 HEAD Early-Career Prize is awarded to Prof. Mingarelli

January 24, 2023

The 2023 High Energy Astrophysics Division’s Early-Career Prize is awarded to Dr. Chiara Mingarelli for her leadership in the analysis of pulsar timing array data and her contributions to our understanding of the stochastic gravitational wave background.

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Apr 5 Condensed Matter Physics Seminar2:00pm

Condensed Matter Physics Seminar

Wednesday, April 5th, 2023

02:00 PM - 03:00 PM

Storrs Campus
GS-117

Prof. Pouyan Ghaemi, City College of New York

Quantum algorithm to realize and study fractional Hall states and their dynamics on near term quantum computers: A tabletop experiment on quantum gravity

Intermediate-scale quantum technologies provide unprecedented opportunities for scientific discoveries while posing the challenge of identifying important problems that can take advantage of them through algorithmic innovations. Fractional Hall systems which are one class of correlated electron systems with many interesting and puzzling properties. In this talk, I present an efficient quantum algorithm to generate an equivalent many-body state to Laughlin's ν=1/3 fractional quantum Hall state on a digitized quantum computer. Our algorithm only uses quantum gates acting on neighboring qubits in a quasi-one-dimensional setting, and its circuit depth is linear in the number of qubits. I then present another quantum algorithm to generate and study out-of-equilibrium properties of the fractional Hall state. Such features reveal novel geometric aspects of fractional Hall states which mimics gravitons.

References

PRX Quantum 1, 020309 (2020)

Phys. Rev. Lett. 129, 056801 (2022)

Contact Information: Prof. I. Sochnikov
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Apr 7 Agostino Marinelli, Stanford (UConn Physics Colloquium)3:30pm

Agostino Marinelli, Stanford (UConn Physics Colloquium)

Friday, April 7th, 2023

03:30 PM - 04:30 PM

Storrs Campus
GW-002

Prof. Agostino Marinelli
Stanford University

UConn Physics Dept. Colloquium

Title and abstract: TBD

Contact Information: Prof. Nora Berrah
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Apr 12 Condensed Matter Physics Seminar2:00pm

Condensed Matter Physics Seminar

Wednesday, April 12th, 2023

02:00 PM - 03:00 PM

Storrs Campus
GS-117

Dr. Johnny Pelliciari, Brookhaven National Laboratory

Title and abstract: TBA

Contact Information: Prof. J. Hancock
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Apr 17 PhD Dissertation Defense1:30pm

PhD Dissertation Defense

Monday, April 17th, 2023

01:30 PM - 03:30 PM

Storrs Campus
GS-117

Graduate student Brandin Davis, Department of Physics, University of Connecticut

Title and Abstract TBA

Contact Information: Brandin Davis
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Apr 17 Particle, Astrophysics and Nuclear Physics Seminar2:00pm

Particle, Astrophysics and Nuclear Physics Seminar

Monday, April 17th, 2023

02:00 PM - 03:00 PM

Storrs Campus
GS-119

Dr. En-Hung Chao, Columbia University

The anomalous magnetic moment of the muon from Lattice QCD with coordinate-space formalisms

The discrepancy between the experimentally measured value for the anomalous magnetic moment of the muon (\(a_\mu\)) and the Standard Model prediction is a long-standing puzzle in modern particle physics. As of the theory consensus reached in 2020, the tension lies at the 4.2-\(\sigma\) level. Currently, the theory uncertainty is dominated by hadronic contributions. The two most relevant categories of such contributions are the Hadronic Vacuum Polarization (HVP) and the Hadronic Light-by-Light (HLbL), starting at the second and third order in the fine structure constant respectively. Over the past years, Lattice Quantum Chromodynamics (LQCD) has been successfully applied to determine the HVP and the HLbL contributions and the estimates are being continuously improved. With these updates, tensions emerge between LQCD and the data-driven methods, based on which the leading-order HVP contribution of the 2020 theory consensus is given.

In this talk, I will present two \(a_\mu\)-related LQCD activities of the Mainz group. Firstly, I will discuss a recent publication on the calculation of the intermediate window quantity of the HVP [arXiv:2211.15581], where precise comparisons between LQCD and the data-driven methods can be made. Our calculation is done in a covariant coordinate-space framework and performed at an unphysical reference pion mass with a careful treatment for the finite-volume effects. Our result is consistent with the Mainz 2022 result based on another more conventional formalism, the time-momentum representation, interpolated to the same reference pion mass. Secondly, I will review the Mainz endeavor on the direct calculation of the HLbL contribution to \(a_\mu\) [arXiv: 2006.16224, 2104.02632, 2204.08844], where the QED effects are treated in the continuum and infinite volume. This effort includes many different lattice spacings and heavier-than-physical pion masses, allowing for a robust extrapolation to the physical point for the up-, down- and strange-quark contributions. An estimate for the charm quark contribution is also given based on a partially-quenched calculation at the SU(3)-flavor symmetric limit.

Contact Information: Prof. L. Jin
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Prof. Eleanor Close Texas State University, Prof. Eleanor Close, Texas State (Physics Colloquium)3:30pm 3/31

Prof. Eleanor Close Texas State University, Prof. Eleanor Close, Texas State (Physics Colloquium)

Friday, March 31st, 2023

03:30 PM - 04:30 PM

Storrs Campus
GW-002

Prof. Eleanor Close
Texas State University

Title and abstract: TBD

Contact Information: Prof. Erin Scanlon
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Prof. Alan Wuosmaa, Department of Physics, University of Connecticut, " "Exotic Nuclei" - What are they, how do we study them and why we should care?", Graduate Student Seminar12:15pm 3/31

Prof. Alan Wuosmaa, Department of Physics, University of Connecticut, " "Exotic Nuclei" - What are they, how do we study them and why we should care?", Graduate Student Seminar

Friday, March 31st, 2023

12:15 PM - 01:15 PM

Storrs Campus
GS-119

Prof. Alan Wuosmaa, Department of Physics, University of Connecticut

"Exotic Nuclei" - What are they, how do we study them and why we should care?

Just over one hundred years after their discovery by Rutherford, the nuclei of atoms are the focus of considerable renewed interest. Only about 300 nuclear isotopes are stable and can be found in nature, but nearly 3000 nuclei that are stable with respect to proton or neutron emission have been artificially produced in the laboratory. Our understanding of the behavior of the nucleus has largely been guided by ideas developed by studying the nuclei that are stable, however for unstable nuclei with a very large imbalance between protons and neutrons (so-called "exotic nuclei"), these ideas are proving insufficient. The experimental data needed to refine our understanding of the nucleus can only be obtained by performing reactions with short-lived radioactive nuclei. Experiments with such beams are difficult, and introduce many technical challenges. The data they can provide, however, are important not only to understanding nuclear structure, but many other situations such as the violent environments found in exploding stars in the cosmos. I will discuss some of the background behind studies of the structure of exotic nuclei, some modern experimental methods, and prospects for the future.

Contact Information: Prof. V. Kharchenko
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Connor Occhialini, Massachusetts Institute of Technology, "Non-collinear magnetism and multiferroic order in atomically-thin van der Waals materials", Condensed Matter Physics Seminar2:00pm 3/29

Connor Occhialini, Massachusetts Institute of Technology, "Non-collinear magnetism and multiferroic order in atomically-thin van der Waals materials", Condensed Matter Physics Seminar

Wednesday, March 29th, 2023

02:00 PM - 03:00 PM

Storrs Campus
GS-117

Connor Occhialini, Massachusetts Institute of Technology

Non-collinear magnetism and multiferroic order in atomically-thin van der Waals materials

The recent discovery of magnetic order down to the single-layer limit of van der Waals (vdW) materials has launched substantial interest in realizing functional properties associated to magnetoelectric or topological magnetic phases in two-dimensions (2D). One approach to realize such properties is through non-collinear magnetism, including spiral (e.g. helical/cycloidal) or skyrmionic spin textures. Here, I will discuss our recent work on the nickel dihalides (NiX₂, X = Cl, Br, I) which are semiconducting triangular-lattice vdW magnets with frustrated exchange interactions from which non-collinear magnetic phases are stabilized in the bulk. In particular, NiI₂ hosts an incommensurate helimagnetic ground state (Q = 0.138a* + 1.457c*) alongside a spin-induced ferroelectric order and is therefore a type-II multiferroic with TN ~ 60 K. We identified multiple optical signatures, including optical linear dichroism, second harmonic generation and Raman spectroscopy, which reflect the characteristic symmetry-breaking attributed to polar magnetism and allow us to track the multiferroic phase transition in atomically-thin samples. Our results provide evidence for the persistence of type-II multiferroic order down to the single-layer limit of NiI₂ with a transition temperature of T_N ~ 21 K. We conclude a helimagnetic order in the single-layer that is stabilized by anisotropic symmetric exchange and enhanced by a dimensionality-tuned interlayer interaction in multilayers. I will also discuss complementary optical and X-ray diffraction measurements at high-pressures which reveal a significant pressure enhancement of the multiferroic transition temperature in the bulk at a rate of 14.4 K/GPa. This observation is in quantitative agreement with first-principles calculations of the exchange interactions which reveal a stabilized helimagnetic order from pressure-enhanced interlayer and third-nearest neighbor intralayer exchange. These results provide a generalized route to realize intrinsic multiferroic order in 2D materials with high transition temperature.

References:

- Qian Song, Connor A. Occhialini, Emre Ergeçen, and Batyr Ilyas et al, "Evidence for a single-layer van der Waals multiferroic", Nature 602, 601-605 (2022).

- Connor A. Occhialini, Luiz G. P. Martins et al, "Pressure-stabilized magnetic phase transitions in van der Waals multiferroic NiI₂" (In preparation, 2023).

Contact Information: Prof. J. Hancock
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Zachary Harris, Department of Physics, University of Connecticut, "Resurgence in QED: Probing the Schwinger effect in inhomogeneous fields", Particle, Astrophysics and Nuclear Physics Seminar2:00pm 3/27

Zachary Harris, Department of Physics, University of Connecticut, "Resurgence in QED: Probing the Schwinger effect in inhomogeneous fields", Particle, Astrophysics and Nuclear Physics Seminar

Monday, March 27th, 2023

02:00 PM - 03:00 PM

Storrs Campus
GS-119

Zachary Harris, Department of Physics, University of Connecticut

Resurgence in QED: Probing the Schwinger effect in inhomogeneous fields

The structure of the QED vacuum is a subject of great interest, especially as experiments begin to more directly probe the non-linear regime of the theory. One of the most striking features of the vacuum is its polarization in the presence of an electric field -- a non-perturbative phenomenon that leads to pair production. Detailed information about this non-perturbative structure is contained in the divergence of perturbation theory, which is more generally described by the theory of resurgence. We study the one-loop QED effective action for an exactly solvable, inhomogeneous background field configuration and use Borel summation to illustrate the connection between perturbative and non-perturbative regimes. Using only 15 terms in the weak magnetic field perturbative expansion, we extrapolate to both strong magnetic field and electric field configurations and obtain a pair-production rate that agrees with the exact effective action to remarkable precision.

Contact Information: Prof. L. Jin
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Prof. Barrett Wells, Department of Physics, University of Connecticut, " Extreme Tuning of Quantum Materials", Graduate Student Seminar12:15pm 3/24

Prof. Barrett Wells, Department of Physics, University of Connecticut, " Extreme Tuning of Quantum Materials", Graduate Student Seminar

Friday, March 24th, 2023

12:15 PM - 01:15 PM

Storrs Campus
GS-119

Prof. Barrett Wells, Department of Physics, University of Connecticut

Extreme Tuning of Quantum Materials

I will describe recent research directions in my lab studying quantum materials with important properties. One set of work studies unusual and strange phase transitions, particularly a case where the change in symmetry with temperature is opposite of that expected. Another involves developing methods to study the atomic structure and electromagnetic properties of materials in the form of nanopillars, where they can be subjected to strain fields orders of magnitude higher than possible in normal sized materials. The discovery of superelasticity in nanopillars came from a UConn colleague studying the strength of materials. The technique appears to open a path towards extreme tuning of quantum properties if proper measurement techniques can be developed. Our group is working to enable nanodiffraction of the atomic structure under extreme strain.

In addition, I will make some general remarks about the department in my role as Department Head.

Contact Information: Prof. V. Kharchenko
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Zachary Harris, Department of Physics, University of Connecticut, "Resurgence in QED: Probing the Schwinger effect in inhomogeneous fields", CANCELLED: Particle, Astrophysics and Nuclear Physics Seminar2:00pm 3/20

Zachary Harris, Department of Physics, University of Connecticut, "Resurgence in QED: Probing the Schwinger effect in inhomogeneous fields", CANCELLED: Particle, Astrophysics and Nuclear Physics Seminar

Monday, March 20th, 2023

02:00 PM - 03:00 PM

Storrs Campus
GS-119

Zachary Harris, Department of Physics, University of Connecticut

Resurgence in QED: Probing the Schwinger effect in inhomogeneous fields

The structure of the QED vacuum is a subject of great interest, especially as experiments begin to more directly probe the non-linear regime of the theory. One of the most striking features of the vacuum is its polarization in the presence of an electric field -- a non-perturbative phenomenon that leads to pair production. Detailed information about this non-perturbative structure is contained in the divergence of perturbation theory, which is more generally described by the theory of resurgence. We study the one-loop QED effective action for an exactly solvable, inhomogeneous background field configuration and use Borel summation to illustrate the connection between perturbative and non-perturbative regimes. Using only 15 terms in the weak magnetic field perturbative expansion, we extrapolate to both strong magnetic field and electric field configurations and obtain a pair-production rate that agrees with the exact effective action to remarkable precision.

Contact Information: Prof. L. Jin
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Dr. Norah Hoffmann, Columbia University, "Light-Matter Interactions: From Classical to Quantum ", Atomic, Molecular, and Optical Physics Seminar2:00pm 3/9

Dr. Norah Hoffmann, Columbia University, "Light-Matter Interactions: From Classical to Quantum ", Atomic, Molecular, and Optical Physics Seminar

Thursday, March 9th, 2023

02:00 PM - 03:00 PM

Storrs Campus
GS-117

Dr. Norah Hoffmann, Columbia University

Light-Matter Interactions: From Classical to Quantum

The influence of light plays a paramount role in our everyday life, from fundamental biological mechanisms to sustainable energy applications. Therefore, controlling and optimizing the underlying processes is of great interest.

The use of (oriented) classical electric fields to modify chemical reactions is a promising, emerging technique. In this talk, I will discuss a non-empirical linear free energy relationship that microscopically relates field-induced changes in the activation energy to those in the reaction energy, providing a powerful new framework for the design and characterization of electrostatic catalysis. On the other hand, experimental developments in the emerging field of polaritonic chemistry opened up new possibilities for modifying and controlling chemical processes that depend on the interaction of quantized light fields with matter. I will give an overview of the strong light-matter interaction that arises when the matter is confined in optical cavities, its computational challenges, and potential solutions focusing on mixed quantum-classical methods for photons.

Contact Information: Prof. D. McCarron
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Dr. Han Fu, University of Chicago, "Nonequilibrium dynamics in ultracold atomic systems ", Atomic, Molecular, and Optical Physics Seminar2:00pm 3/6

Dr. Han Fu, University of Chicago, "Nonequilibrium dynamics in ultracold atomic systems ", Atomic, Molecular, and Optical Physics Seminar

Monday, March 6th, 2023

02:00 PM - 03:00 PM

Storrs Campus
GS-117

Dr. Han Fu, University of Chicago

Nonequilibrium dynamics in ultracold atomic systems

The experimental advances in preparing, controlling, and probing ultra-cold atomic systems provide powerful platforms for the study of non-equilibrium dynamics of quantum systems. When trapped particles are subjected to external driving or undergo quantum quenches, they display a rich variety of emergent phenomena not accessible in an equilibrium state.

In this talk, I will discuss my recent works on driven ultracold Bose atoms based on Gross-Pitaevskii numerical simulations. When applying an oscillating magnetic field to the system, interactions between Bose atoms will change periodically in time. We find that this leads to the formation of 'Bose fireworks', a fascinating physical phenomenon demonstrating driven-induced amplification of quantum fluctuations. When we modulate our trapping potentials, the energy spectrum of Bose atoms forms an effective band structure. In this case, we discover that Bose atoms can condense via a highly nontrivial process. These findings not only lead to our proposal of a new imaging method to probe ultracold Bose systems, but also reveal key aspects of thermalization in quantum many-body systems.

Contact Information: Prof. D. McCarron
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