Your search keyword '"Johnston-Halperin, Ezekiel"' showing total 4 results

1. Strong photon-magnon coupling using a lithographically defined organic ferrimagnet

Author

Xu, Qin, Cheung, Hil Fung Harry, Cormode, Donley S., Puel, Tharnier O., Yusuf, Huma, Chilcote, Michael, Flatté, Michael E., Johnston-Halperin, Ezekiel, and Fuchs, Gregory D.

Subjects

Quantum Physics, Condensed Matter - Materials Science

Abstract

We demonstrate a hybrid quantum system composed of superconducting resonator photons and magnons hosted by the organic-based ferrimagnet vanadium tetracyanoethylene (V[TCNE]$_x$). Our work is motivated by the challenge of scalably integrating an arbitrarily-shaped, low-damping magnetic system with planar superconducting circuits, thus enabling a host of quantum magnonic circuit designs that were previously inaccessible. For example, by leveraging the inherent properties of magnons, one can enable nonreciprocal magnon-mediated quantum devices that use magnon propagation rather than electrical current. We take advantage of the properties of V[TCNE]$_x$, which has ultra-low intrinsic damping, can be grown at low processing temperatures on arbitrary substrates, and can be patterned via electron beam lithography. We demonstrate the scalable, lithographically integrated fabrication of hybrid quantum magnonic devices consisting of a thin-film superconducting resonator coupled to a low-damping, thin-film V[TCNE]$_x$ microstructure. Our devices operate in the strong coupling regime, with a cooperativity as high as 1181(44) at T$\sim$0.4 K, suitable for scalable quantum circuit integration. This work paves the way for the exploration of high-cooperativity hybrid magnonic quantum devices in which magnonic circuits can be designed and fabricated as easily as electrical wires., Comment: 31 pages preprint format with supplementary materials

Published

2022

2. Accelerating Progress Towards Practical Quantum Advantage: The Quantum Technology Demonstration Project Roadmap

Author

Alsing, Paul, Battle, Phil, Bienfang, Joshua C., Borders, Tammie, Brower-Thomas, Tina, Carr, Lincoln D., Chong, Fred, Dadras, Siamak, DeMarco, Brian, Deutsch, Ivan, Figueroa, Eden, Freedman, Danna, Everitt, Henry, Gauthier, Daniel, Johnston-Halperin, Ezekiel, Kim, Jungsang, Kira, Mackillo, Kumar, Prem, Kwiat, Paul, Lekki, John, Loiacono, Anjul, Loncar, Marko, Lowell, John R., Lukin, Mikhail, Merzbacher, Celia, Miller, Aaron, Monroe, Christopher, Pollanen, Johannes, Pappas, David, Raymer, Michael, Reano, Ronald, Rodenburg, Brandon, Savage, Martin, Searles, Thomas, and Ye, Jun

Subjects

Quantum Physics

Abstract

Quantum information science and technology (QIST) is a critical and emerging technology with the potential for enormous world impact and is currently invested in by over 40 nations. To bring these large-scale investments to fruition and bridge the lower technology readiness levels (TRLs) of fundamental research at universities to the high TRLs necessary to realize the promise of practical quantum advantage accessible to industry and the public, we present a roadmap for Quantum Technology Demonstration Projects (QTDPs). Such QTDPs, focused on intermediate TRLs, are large-scale public-private partnerships with a high probability of translation from laboratory to practice. They create technology demonstrating a clear 'quantum advantage' for science breakthroughs that are user-motivated and will provide access to a broad and diverse community of scientific users. Successful implementation of a program of QTDPs will have large positive economic impacts., Comment: Updated title and abstract

Published

2022

3. Building a Quantum Engineering Undergraduate Program

Author

Asfaw, Abraham, Blais, Alexandre, Brown, Kenneth R., Candelaria, Jonathan, Cantwell, Christopher, Carr, Lincoln D., Combes, Joshua, Debroy, Dripto M., Donohue, John M., Economou, Sophia E., Edwards, Emily, Fox, Michael F. J., Girvin, Steven M., Ho, Alan, Hurst, Hilary M., Jacob, Zubin, Johnson, Blake R., Johnston-Halperin, Ezekiel, Joynt, Robert, Kapit, Eliot, Klein-Seetharaman, Judith, Laforest, Martin, Lewandowski, H. J., Lynn, Theresa W., McRae, Corey Rae H., Merzbacher, Celia, Michalakis, Spyridon, Narang, Prineha, Oliver, William D., Palsberg, Jens, Pappas, David P., Raymer, Michael G., Reilly, David J., Saffman, Mark, Searles, Thomas A., Shapiro, Jeffrey H., and Singh, Chandralekha

Subjects

Physics - Physics Education, Quantum Physics

Abstract

The rapidly growing quantum information science and engineering (QISE) industry will require both quantum-aware and quantum-proficient engineers at the bachelor's level. We provide a roadmap for building a quantum engineering education program to satisfy this need. For quantum-aware engineers, we describe how to design a first quantum engineering course accessible to all STEM students. For the education and training of quantum-proficient engineers, we detail both a quantum engineering minor accessible to all STEM majors, and a quantum track directly integrated into individual engineering majors. We propose that such programs typically require only three or four newly developed courses that complement existing engineering and science classes available on most larger campuses. We describe a conceptual quantum information science course for implementation at any post-secondary institution, including community colleges and military schools. QISE presents extraordinary opportunities to work towards rectifying issues of inclusivity and equity that continue to be pervasive within engineering. We present a plan to do so and describe how quantum engineering education presents an excellent set of education research opportunities. Finally, we outline a hands-on training plan on quantum hardware, a key component of any quantum engineering program, with a variety of technologies including optics, atoms and ions, cryogenic and solid-state technologies, nanofabrication, and control and readout electronics. Our recommendations provide a flexible framework that can be tailored for academic institutions ranging from teaching and undergraduate-focused two- and four-year colleges to research-intensive universities., Comment: 25 pages, 2 figures

Published

2021

4. Predicted strong coupling of solid-state spins via a single magnon mode

Author

Candido, Denis R., Fuchs, Gregory D., Johnston-Halperin, Ezekiel, and Flatté, Michael E.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We propose an approach to realize a hybrid quantum system composed of a diamond nitrogen-vacancy (NV) center spin coupled to a magnon mode of the low-damping, low-moment organic ferrimagnet vanadium tetracyanoethylene. We derive an analytical expression for the spin-magnon cooperativity as a function of NV position under a micron-scale perpendicularly magnetized disk, and show that, surprisingly, the cooperativity will be higher using this magnetic material than in more conventional materials with larger magnetic moments, due to in part to the reduced demagnetization field. For reasonable experimental parameters, we predict that the spin-magnon-mode coupling strength is $g\sim 10$ kHz. For isotopically pure $^{12}$C diamond we predict strong coupling of an NV spin to the unoccupied magnon mode, with cooperativity $\mathcal C=6$ for a wide range of NV spin locations within the diamond, well within the spatial precision of NV center implantation. Thus our proposal describes a practical pathway for single-spin-state-to-single-magnon-occupancy transduction and for entangling NV centers over micron length scales., Comment: Main text (15 pages + 4 figures) and Supplemental Material

Published

2020