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

Prof. Chiara Mingarelli awarded NSF grant

October 18, 2021

Chiara Mingarelli, Assistant Professor of Physics at UConn, is the lead researcher on a $650,000 Collaborative Research Grant from the National Science Foundation, half of which is earmarked for UConn, to conduct an experiment to prove the existence of supermassive black hole binaries. This grant will combine, for the first time, traditional astronomy with gravitational […]

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A Physics Ph.D. Student’s Step-By-Step Journey to Storrs and Distant Galaxies

October 7, 2021

UConn Physics graduate student Mohammed (Mo) Akhshik works on data gathered using the Hubble Space Telescope (HST) and has led to exciting discoveries, some while he served as the science Principle Investigator of the REQUIEM HST program from which he is co-author on two publications, one in Nature and one in Nature Astronomy. Akhshik is also […]

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Professor Daniel Anglés-Alcázar research featured in ‘UConn Today’ and CBC radio interview

October 4, 2021

At the center of galaxies, like our own Milky Way, lie massive black holes surrounded by spinning gas. Some shine brightly, with a continuous supply of fuel, while others go dormant for millions of years, only to reawaken with a serendipitous influx of gas. It remains largely a mystery how gas flows across the universe […]

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Dear Friends of UConn Physics

August 30, 2021

As we approach the beginning of the 2021-22 school year, UConn is set for having classes in person again, students on campus, and our first taste of somewhat normal university life in a year and a half. Students, faculty, and staff are all required to be vaccinated, masks are required indoors, classrooms will be fully […]

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Physics alumnus Prof. Douglas Goodman and Professor Emeritus Winthrop Smith Featured in Online Peer Review Journal

August 30, 2021

Prof. Emeritus Winthrop Smith and former student Prof. Douglas Goodman (Quinnipiac University) Edit Special Issue of Open Access Journal Atoms, on Low Energy Interactions between Ions and Ultracold Atoms The Special Issue of the online journal Atoms is a collection of current peer-reviewed articles by experts in the field of ultracold collisions and reactions involving […]

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Nov 5 Charles Reynolds Distinguished Lecture3:30pm

Charles Reynolds Distinguished Lecture

Friday, November 5th, 2021

03:30 PM - 04:30 PM

Storrs Campus
Gant North 20 (formerly IMS 20)

Prof. Chandra Varma, *University of California, Berkeley

From Quantum Fluctuations to Spin-Liquids

Is it possible that the possible states of matter in the limit of zero temperature for fermions and bosons are not just superfluids or crystals of some or the other variety? Can quantum fluctuations lead to states with a mass gap in their excitations or infinite range correlations, but no order? These questions appear to have been in the minds of several physicists for a long time but have been very actively discussed and their examples sought in experiments in only about the last thirty years. Recent experiments on very pure spin-1/2 based compounds suggest not only that the answer is yes, but allow the characterization of their excitations. There appear to be a scale-invariant magnetic fluctuations in them, but also gigantic density of ultra-low energy singlet excitations which may not be amenable to any direct experimental probe- a form of dark matter.

*Recalled Professor

Contact Information: Prof. Alexander Balatsky
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Nov 12 UConn Physics Colloquium3:30pm

UConn Physics Colloquium

Friday, November 12th, 2021

03:30 PM - 04:30 PM

Storrs Campus
Gant North 20 (formerly IMS-20)

Dr. Francisco Villaescusa-Navarro, Department of Astrophysical Sciences, Princeton University

The CAMELS Project: Cosmology and Astrophysics with MachinE Learning Simulations

In this talk, I will present the Cosmology and Astrophysics with MachinE Learning Simulations --CAMELS-- project, whose main goal is to provide theoretical predictions for cosmological observables as a function of cosmology and astrophysics. CAMELS contains a collection of 4,233 cosmological simulations, 2,049 N-body simulations and 2,184 state-of-the-art (magneto-)hydrodynamic simulations employing three different codes: Gadget-III, AREPO, and GIZMO. The simulations, designed to train machine learning models, span a very wide range in the value of the cosmological and astrophysical parameters. I will illustrate the potential of CAMELS by showing a few examples of tasks that we have carried out, such as teaching neural networks to extract cosmological information and marginalize over baryonic effects at the field level, finding a new universal relation between subhalo/galaxy properties, inferring the mass of a dark matter halo from the positions and properties of its galaxies, using neural networks to reconstruct masked data, doing cosmology with one single galaxy, and teaching neural networks to learn about cosmology and astrophysics with fast radio bursts. I will conclude by discussing how CAMELS will escalate in the coming years to generate millions of hydrodynamic simulations covering gigaparsec volumes for thousands of different cosmological and astrophysical models that will be used to extract the maximum cosmological information from upcoming cosmic surveys across the entire wavelength spectrum.

Contact Information: Prof. Daniel Angles-Alcazar
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Nov 15 Particle, Astrophysics, And Nuclear Physics Seminar2:00pm

Particle, Astrophysics, And Nuclear Physics Seminar

Monday, November 15th, 2021

02:00 PM - 03:00 PM

Storrs Campus
GS-119

Dr. Chien Yeah Seng, the University of Bonn

Radiative corrections in Kaon semileptonic decays and the Cabibbo angle anomaly

In recent years we observe a series of mutually inconsistent determinations of the Cabibbo angle which is responsible for the mixing between the up and down quark. These anomalies, that occur in various beta decay experiments, are at the level of 3 sigma and provide strong evidence of the deviation from precise Standard Model (SM) predictions. To sharpen them to a level sufficient to declare a discovery, we must improve the theory precision of all the precise SM inputs to these decay processes. In this talk I describe recent progress along this direction: A new high-precision calculation of the electroweak radiative corrections in Kaon semileptonic decays is
performed. It features a chiral resummation of the large
infrared-singular terms in the radiative corrections and a
well-under-control strong interaction uncertainty based on the most recent lattice QCD inputs (by UConn physicists and collaborators). While being consistent with the previous state-of-the-art results obtained from chiral perturbation theory, we reduce the existing theory uncertainty from $10^{-3}$ to $10^{-4}$. Our result suggests that the SM electroweak effects cannot account for the anomaly in the Vus sector.

Contact Information: Prof. Luchang Jin
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Nov 19 UConn Physics Colloquium3:30pm

UConn Physics Colloquium

Friday, November 19th, 2021

03:30 PM - 04:30 PM

Other
Online

Dr. Gökçe Basar, University of North Carolina

TBA

Contact Information: Prof. Gerald Dunne
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Dec 1 Condensed Matter Physics Seminar1:00pm

Condensed Matter Physics Seminar

Wednesday, December 1st, 2021

01:00 PM - 02:00 PM

Storrs Campus
GW-119

Prof. Hugh Churchill, University of Arkansas

Quantum Devices with 2D Insulators and Semiconductors

I will describe two applications of 2D layered materials for quantum devices. First, I will discuss gate-tunable Josephson junction field-effect transistors (JJ-FETs) based on Al/InAs in which the gate dielectric is thin hBN. Comparing devices with hBN and AlOx dielectrics, we observe that the product of normal resistance and critical current, IcRn, is comparable for both types of devices. However, Rn is strikingly higher for the hBN-based devices indicating that the surface is doped less compared to AlOx gate dielectric. These results demonstrate that hBN provides a superior gate dielectric compared to AlOx for JJ-FET devices with applications in superconducting logic and quantum information technologies such as gatemon qubits and topological superconductivity. Second, I will discuss our work to fabricate and characterize gate-defined, accumulation mode quantum dots using monolayer and bilayer WSe2. Temperature dependence of conductance in the Coulomb-blockade regime is consistent with transport through a single level, and excited-state transport through the dots is observed at temperatures up to 10 K. These devices provide a platform to evaluate valley-spin states in monolayer and bilayer WSe2 for application as qubits. I will also briefly advertise the recently established MonArk NSF Quantum Foundry which seeks to accelerate the fabrication and characterization of 2D quantum materials to serve a broad community of users.

Contact Information: Prof. I. Sochnikov
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Prof. Vernon Cormier, Department of Physics, University of Connecticut, "The 2021 Nobel Prize in Physics", UConn Physics Colloquium3:30pm 10/22

Prof. Vernon Cormier, Department of Physics, University of Connecticut, "The 2021 Nobel Prize in Physics", UConn Physics Colloquium

Friday, October 22nd, 2021

03:30 PM - 04:30 PM

Storrs Campus
Gant North 20 (formerly IMS-20)

Prof. Vernon Cormier, Department of Physics, University of Connecticut

The 2021 Nobel Prize in Physics

The 2021 Nobel Prize in Physics, awarded to Syukoro Manabe, Klaus Hasselmann, and Giorgio Parisi, recognizes contributions key to understanding complex systems and strategies to predict their evolution with time. The forecasting of climate change, although rooted in simple laws of conservation of mass, momentum, and energy is an example of one such complex system in which longer time trends must be extracted from a background of short-term cycles and a near white noise behavior of small spatial and temporal variations in data. This Nobel Prize recognizes the seminal work of Manabe, in advancing the sophistication of computational climate modeling, and the work of Hasselmann, in the statistical treatment of small-scale spatial and temporal variations in climate models and data. Their combined work has enabled a confident extraction of an anthropomorphic fingerprint of greenhouse gas additions to our climate. The work of Giorgio Parisi centers on the statistical treatment of complex systems existing in competing and evolving states. It originated in predicting the behavior of spin glasses in which the spin state of neighboring electrons of iron form an amorphous glass-like structure. Parisi's work has found applications in a broad range of sciences in which the evolution of competing states cannot accurately be predicted by a search for a stable equilibrium configuration.

Meeting URL: https://www.kaltura.com/index.php/extwidget/preview/partner_id/2090521/uiconf_id/37067881/entry_id/1_6kfe72n4/embed/iframe

Contact Information: Prof. P. Mannheim
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Prof. A. Balatsky, Department of Physics, University of Connecticut, "Dynamics and Entangled Orders", Graduate Student Seminar12:15pm 10/22

Prof. A. Balatsky, Department of Physics, University of Connecticut, "Dynamics and Entangled Orders", Graduate Student Seminar

Friday, October 22nd, 2021

12:15 PM - 01:15 PM

Other
Online

Prof. A. Balatsky, Department of Physics, University of Connecticut

Dynamics and Entangled Orders

Quantum matter out of equilibrium emerges as an important platform to induce correlations and transient orders. Broad basic questions about orders that are inherently dynamic have been addressed in the context of driven cold atoms, spins, magnetic states, and superconductors. In this lecture, I will discuss new orders that emerge in quantum matter as a result of dynamic drive, coherence, and entanglement[1].

I will introduce the concept of dynamic multiferroicity and illustrate it in ferroelectrics where driven electric fluctuations induce magnetization [2].

[1] Hidden, entangled, and resonating order, G Aeppli, AV Balatsky, HM Rønnow, NA Spaldin, Nature Reviews Materials 5 (7), 477-479 (2020)

[2] Dynamic multiferroicity of a ferroelectric quantum critical point, K Dunnett, JX Zhu, NA Spaldin, V Juričić, AV Balatsky, Physical review letters 122 (5), 057208 (2020); Dynamical multiferroicity, DM Juraschek, M Fechner, AV Balatsky, NA Spaldin, Physical Review Materials 1 (1), 014401(2017); Thermal magnetic fluctuations of a ferroelectric quantum critical point, A Khaetskii, V Juričič, AV Balatsky, Journal of Physics: Condensed Matter 33 (4), 04LT01 (2020). Dynamically induced magnetism in, RM Geilhufe, V Juričić, S Bonetti, JX Zhu, AV Balatsky, Physical Review Research 3 (2), L022011 (2021)

Contact Information: Prof. V. Kharchenko
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Dr. Yong Zhao, Argonne National Laboratory , "Precision calculation of the x-dependence of PDFs from lattice QCD", Particle, Astrophysics, And Nuclear Physics Seminar2:00pm 10/18

Dr. Yong Zhao, Argonne National Laboratory , "Precision calculation of the x-dependence of PDFs from lattice QCD", Particle, Astrophysics, And Nuclear Physics Seminar

Monday, October 18th, 2021

02:00 PM - 03:00 PM

Other
online

Dr. Yong Zhao, Argonne National Laboratory

Precision calculation of the x-dependence of PDFs from lattice QCD

The large-momentum effective theory (LaMET) is a general approach to calculate parton physics in high-energy scatterig from lattice gauge theory. In this approach, one approximates light-cone parton observables by time-independent Euclidean matrix elements in a boosted hadron state, and then extracts the former by performing a power expansion at large hadron momentum. With the subleading power corrections suppressed by the hadron momentum, the parton observable is obtained from the leading-power contribution through perturbative QCD running and matching, which therefore can be systematically improved. In this talk, we present a model-independent calculation of the x-dependence of pion valence PDF with LaMET, where we adopt the most up-to-date developments on the systematic corrections, including the hybrid renormalization scheme that rigorously renormalizes the lattice matrix elements at both short and long distances, as well as the next-to-next-to-leading matching kernel for extracting the PDF. As a result, we are able to make predictions for the PDF within a range of $x$ where the systematic uncertainties are under control, which is a firm step towards high-precision calculation.

Contact Information: Prof. Luchang Jin
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CANCELLED, Dr. Steve Mirmina, NASA (UConn Physics Colloquium), CANCELLED Dr. Steve Mirmina, NASA (UConn Physics Colloquium)3:30pm 10/15

CANCELLED, Dr. Steve Mirmina, NASA (UConn Physics Colloquium), CANCELLED Dr. Steve Mirmina, NASA (UConn Physics Colloquium)

Friday, October 15th, 2021

03:30 PM - 04:30 PM

Other
CANCELLED

CANCELLED

Dr. Steve Mirmina, NASA (UConn Physics Colloquium)

Title and abstract: TBD

Contact Information: Prof. Cara Battersby
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Prof. Cara Battersby, Department of Physics, University of Connecticut, "Our Galaxy's Center: a Window into the High-Redshift Universe", Graduate Student Seminar12:15pm 10/15

Prof. Cara Battersby, Department of Physics, University of Connecticut, "Our Galaxy's Center: a Window into the High-Redshift Universe", Graduate Student Seminar

Friday, October 15th, 2021

12:15 PM - 01:15 PM

Storrs Campus
GS-119

Prof. Cara Battersby, Department of Physics, University of Connecticut

Our Galaxy's Center: a Window into the High-Redshift Universe

Galaxy centers are the hubs of activity that drive galaxy evolution, from supermassive black holes to dense stellar clusters and feedback from newly-formed stars. Our own galaxy's center has properties (densities, temperatures, and turbulent line widths) that are reminiscent of galaxies at the peak of cosmic star formation, but in our own cosmic backyard, where the interplay of these physical processes can be resolved in detail. In this talk, I will discuss gas inflow into our Galaxy's Center, properties of the gas, and incipient star formation. I will discuss simulations of gas flows into the Galactic Center, which are thought to contribute to the unusual properties of star formation in this region, namely that it is producing 10x fewer stars than predicted by standard scaling relations. I will describe observations of the gas and incipient star formation in this region, as well as discuss efforts to measure whether or not this unusual environment results in a change to the Initial Mass Function.

Contact Information: Prof. V. Kharchenko
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Dr. Erez Michaely, UCLA, "Collisional Dynamics in the Field: Ultra-Wide BH Systems as Sources of GW Signals ", Astronomy Seminar2:00pm 10/13

Dr. Erez Michaely, UCLA, "Collisional Dynamics in the Field: Ultra-Wide BH Systems as Sources of GW Signals ", Astronomy Seminar

Wednesday, October 13th, 2021

02:00 PM - 03:00 PM

Other
Online

Dr. Erez Michaely, UCLA

Collisional Dynamics in the Field: Ultra-Wide BH Systems as Sources of GW Signals

Dynamical interactions are known to play an important role in the evolution of dense stellar systems such as globular clusters and galactic nuclei. In contrast, the galactic field (where most of the stellar systems are) is a low-density environment, where strong stellar encounters were thought to be too rare to play any role in collisional dynamics. However, the low density in the field also allows for the existence of long-lived ultra-wide systems which would have been quickly destroyed in a dense environment. The large separation of such binaries can therefore compensate for the low densities and still allow for relatively high rates of interactions with field stars. Such interactions change the orbital properties of the binaries or outer binaries in the case of triples. Therefore, when considering the evolution of ultra-wide systems one needs to account for random gravitational interaction with passing stars, flybys, even in low-density environments like the field of the host galaxy. The outcome of the interactions between ultra-wide black-holes (BH) systems with random field stars may excite the eccentricity of the system sufficiently to radiate gravitational waves (GW) and drive the system to a merger within Hubble time. This channel may explain a fraction of the current observed binary BH merger rate and provides predictions for future observational runs, e.g. eccentric mergers. The underlying dynamics of this channel is not unique to BH or GW sources, and have implications to other stellar exotica such: low-mass X-ray binaries, Type Ia SNe, main sequence - white dwarf collisions, and more.

Meeting URL: https://uconn-cmr.webex.com/meet/drl20003

Contact Information: Grad Student D. Lipman
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Prof. Dan Milisavljevic, Purdue University, "Multi-messenger Autopsies of Stellar Death", UConn Physics Colloquium3:30pm 10/8

Prof. Dan Milisavljevic, Purdue University, "Multi-messenger Autopsies of Stellar Death", UConn Physics Colloquium

Friday, October 8th, 2021

03:30 PM - 04:30 PM

Other
online

Prof. Dan Milisavljevic, Purdue University

Multi-messenger Autopsies of Stellar Death

The expanding zoo of astronomical transients has become one of the most important driving forces of scientific discovery in extreme astrophysics. Increasingly sophisticated all-sky surveys are uncovering unexpected phenomena that are forcing radical revisions to long-accepted models of massive star evolution and their compact remnant objects. These discoveries, which will increase by orders of magnitude in the upcoming decade, are shaping the priorities of the next generation of science facilities such as the Rubin Observatory, the James Webb Space Telescope, and Extremely Large Telescopes.

I will review how radio-through-X-ray investigations of transients are revolutionizing our understanding of stellar death and its myriad impacts. This includes the terminal and often dramatic evolutionary phases massive stars pass though when approaching core collapse; the physical mechanisms behind the subsequent supernova explosion; and the formation of powerful compact objects that can participate in the explosion dynamics. I will also discuss how the new synergy between electromagnetic, neutrino, and gravitational wave facilities can enable transformative progress towards finally solving the enigma of core collapse by accurately interpreting the multi-messenger signals from the next Galactic supernova, which will first be detected by the global network of neutrino facilities known as the Supernova Early Warning System.

Meeting URL: https://uconn-cmr.webex.com/meet/cab16109

Contact Information: Prof. Cara Battersby
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Prof. Menka Jain, Department of Physics, University of Connecticut, "Functional and Multiferroic Materials", Graduate Student Seminar12:15pm 10/8

Prof. Menka Jain, Department of Physics, University of Connecticut, "Functional and Multiferroic Materials", Graduate Student Seminar

Friday, October 8th, 2021

12:15 PM - 01:15 PM

Storrs Campus
GS-119

Prof. Menka Jain, Department of Physics, University of Connecticut

Functional and Multiferroic Materials

In this talk, some of the basic properties of ferroics and multiferroics, and their applications in many devices will be discussed. Functional materials, such as ferroic materials have been grouped by the driving field that aligns their ordering parameters. Four primary ferroic materials: ferroelectric, ferromagnetic, ferroelastic, and ferrotoroidic, are characterized by a wealth of intriguing physical properties. The entire class of ferroic materials has found extensive applications in consumer electronics, a variety of sensors, memory devices, health care, and military applications. Current trends toward device miniaturization have led to an increased interest in multifunctionality, multifunctional devices, and thin-film microelectronics where a single device component can do multiple tasks simultaneously. Multiferroic materials with the coexistence of at least two ferroic order parameters have the potential for such multifunctional devices. One interesting class of multiferroics is magnetoelectric materials, which concurrently have some form of magnetic and ferroelectric order parameters. The synthesis techniques, properties, and process optimization will be discussed that can impact the direct applications of these aforementioned materials.

Contact Information: Prof. V. Kharchenko
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