Andrew J. R. Puckett, Associate Professor, Department of Physics
Professor Puckett is an experimental nuclear/particle physicist studying the internal structure of strongly interacting matter in high-energy fixed-target electron-nucleon and electron-nucleus scattering experiments at Jefferson Lab (JLab). The recently completed 12 GeV upgrade of JLab's Continuous Electron Beam Accelerator Facility to a maximum beam energy of 11 GeV (12 GeV) for electron-beam (photon-beam) experiments, augmented by state-of-the-art target and detector systems, will enable a world-leading physics program leading to three-dimensional imaging of the internal quark structure of protons, neutrons and nuclei with unprecedented precision in both coordinate and momentum space. The ultimate goal of the experiments is to understand how strongly interacting matter is built from its elementary quark and gluon constituents in terms of Quantum Chromodynamics, the theory of the strong interaction. Click the image to see the list of publications and citations (according to Google Scholar)
Recent news/events
Proton radius puzzle apparently resolved…
The PRAD collaboration recently published their results on very low Q2 electron-proton scattering in Hall B at Jefferson Lab, extracting a proton charge radius of rp = 0.831 ± 0.007 (stat) ± 0.012 (syst) fm, consistent with the precise extraction of this quantity from measurements of the Lamb shift in muonic hydrogen, first published in […]
[Read More]Professor Puckett gives invited talk at ECT* “Diquark” Workshop
Professor Puckett is attending and presenting an invited talk at the workshop “Diquark Correlations in Hadron Physics” at the European Center for Theoretical Studies in Nuclear Physics and Related Areas (ECT*) in Trento, Italy, during the week of Sept. 23-27. The webpage and program of the workshop can be found at the following link.
[Read More]First paper from Tritium family of experiments in Hall A published
The first paper from the recently completed family of tritium target experiments in JLab’s Hall A is now published in Physics Letters B. The final published version of the paper can be found online at https://doi.org/10.1016/j.physletb.2019.134890 The INSPIRE-HEP database entry for the paper can be found at http://inspirehep.net/record/1720567 The paper reports the first measurement of […]
[Read More]Physics Department Upcoming Events
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Jul
14
Condensed Matter Physics Seminar10:00am
Condensed Matter Physics Seminar
Tuesday, July 14th, 2020
10:00 AM - 11:00 AM
Storrs Campus online
Dr. D. Farfurnik, University of Maryland
Enhancing the coherence properties of quantum dots toward quantum photonic applications
Self-assembled Quantum Dots (QD) exhibit some of the best single photon emission properties, including nearly ideal efficiency and indistinguishability. As such, and considering their compatibility with nanofabrication techniques, on-chip integration of QDs as single photon emitters and non-linear components plays a key role in integrated photonic-based information processing and may pave the way toward the creation of quantum networks. Manipulating and storing quantum information utilizing QD spins, however, is limited by their short coherence times originating from interactions with a nuclear bath. In this talk, I will describe our approaches for addressing this challenge: First, the application of dynamical decoupling (DD) pulse sequences prolongs the coherence times by decoupling the QD spins from the environment. While the performance of such protocols is often limited by the accumulation of pulse imperfections, arbitrary spin control enabling composite and concatenated sequencing could further enhance the achievable spin control fidelities [1]. Such a sequencing is implementable by driving a Lambda system of the QD utilizing an optical signal arbitrarily modulated by a temperature-stabilized electro optical modulator (EOM). I will present a recent experimental demonstration of such a control [2], our analysis for optimizing the EOM working point for enhancing the achievable optical rotation Rabi frequencies, as well as the efficiency of the protocol for QDs strongly coupled to L3 photonic crystal cavities. Second, the resulting coherence properties may be further enhanced by utilizing molecules of coupled QDs (QDM), which offer a singlet-triplet ground state decoherence-free subspace [3]. Beyond the promising combination of such a subspace with the application of DD sequences, leveraging the isolated optical transitions of the QDM may offer single-shot spin readout capabilities. I will present our approach for implementing such a spin readout incorporating microwave pi-pulses, its experimental feasibility utilizing optimally designed transmission lines, and the expected readout fidelities based on the achievable microwave Rabi frequencies [4].
[1] D. Farfurnik et al., ``Optimizing a dynamical decoupling protocol for solid-state electronic spin ensembles in diamond’’, Phys. Rev. B 92, 060301(R) (2015)
[2] J.H. Bodey et al., ``Optical spin locking of a solid-state qubit’’, npj Quantum Information 5, 95 (2019)
[3] D. Kim et al., ``Ultrafast optical control of entanglement between two quantum-dot spins’’, Nat. Phys. 7, 223–229 (2011)
[4] D. Farfurnik et al., ``Experimental realization of time-dependent phase-modulated continuous dynamical decoupling’’, Phys. Rev. A 96, 013850 (2017)
Zoom Meeting: https://kth-se.zoom.us/j/61809414846Contact Information: Prof. A. Balatsky.
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Sep
18
Dr. James Guillochon3:30pm
Dr. James Guillochon
Friday, September 18th, 2020
03:30 PM - 04:30 PM
Storrs Campus BPB-131
Physics colloquium
Dr. James GuillochonContact Information: Prof. Cara Battersby
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Contact Information
| Phone: | (860) 486-7137 (Office) |
|---|---|
| E-mail: | andrew.puckett@uconn.edu |
| Address: | 196 Auditorium Road, Unit 3046 Storrs, CT 06269-3046 |
| More: | https://physics.uconn.edu/person/andrew-puckett/ |