Mr. Jonathan Dietz Profile

Jonathan Dietz

at Harvard Univ

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Publications (3)

Proceedings Article | 11 June 2024 Presentation

Electrical manipulation of telecom color centers in silicon

Madison Sutula, Aaron Day, Jonathan Dietz, Alex Ruan, Denis Sukachev, Mihir Bhaskar, Evelyn Hu

Proceedings Volume PC12993, PC1299303 (2024) https://doi.org/10.1117/12.3015087

KEYWORDS: Silicon, Color centers, Quantum emitters, Quantum devices, Electric fields, Solids, Silicon carbide, Semiconductors, Semiconducting wafers, Quantum technologies

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Proceedings Article | 4 March 2019 Paper

Studies on a time-energy entangled photon pair source and superconducting nanowire single-photon detectors for increased quantum system efficiency

Evan Katz, Benjamin Child, Ian Nemitz, Brian Vyhnalek, Tony Roberts, Andrew Hohne, Bertram Floyd, Jonathan Dietz, John Lekki

Proceedings Volume 10910, 1091015 (2019) https://doi.org/10.1117/12.2508736

KEYWORDS: Sensors, Nanowires, Silicon, Avalanche photodetectors, Photodetectors, Quantum efficiency, Single photon detectors, Superconductors, Time correlated photon counting, Signal to noise ratio

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Time-energy entangled photon pairs are created by a system consisting of a 1064 nm pump diode laser that is fiber coupled to a high generation rate photon pair source. The source is a dual element periodically poled Magnesium Oxide doped Lithium Niobate (MgO:LN) waveguide that upconverts 1064 nm photons to single 532 nm photons in the first stage. In the second stage, the green photons are down converted to time-energy entangled photon pairs at 794 nm and 1614 nm. The output photon pairs are guided by fiber to sorting optics where they are separated and sent into high-efficiency photon detectors. In particular, the 1614 nm photons are detected by a superconducting nanowire with efficiency near 85% and dead time less than 30 ns. Detector output electrical signals are sent to a time tagger with bin resolution as narrow as 25 ps for coincidence counting. The ultimate goal of this setup is to demonstrate a single-source, high efficiency, high data rate, low noise, quantum communication system to enable Earth-space quantum networks. Test results that characterize the time-energy entangled photon pair creation rates of our source will be presented, via measures of accidental and true coincidence rates versus pump current. To reduce noise (accidentals) as much as possible, and for better understanding of our overall quantum system path-efficiency, studies of fluorescence caused by our pump’s 1064 nm and 532 nm photons will be investigated and discussed. Finally, characteristic measurements of our superconducting nanowire detector, such as dead time and detection efficiency versus electrical bias, will be offered. Please verify that (1) all pages are present, (2) all figures are correct, (3) all fonts and special characters are correct, and (4) all text and figures fit within the red margin lines shown on this review document. Complete formatting information is available at http://SPIE.org/manuscripts Return to the Manage Active Submissions page at http://spie.org/submissions/tasks.aspx and approve or disapprove this submission. Your manuscript will not be published without this approval. Please contact author_help@spie.org with any questions or concerns.

Proceedings Article | 4 March 2019 Paper

Bell inequality experiment for a high brightness time-energy entangled source

Ian Nemitz, Jonathan Dietz, Evan Katz, Brian Vynhalek, Benjamin Child, Bertram Floyd, John Lekki

Proceedings Volume 10902, 109021U (2019) https://doi.org/10.1117/12.2509849

KEYWORDS: Interferometers, Visibility, Single photon, Fiber optics, Mach-Zehnder interferometers, Photodetectors, Quantum communications, Particles, Single mode fibers, Waveguides

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