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Research Interests:

My research in experimental particle physics focuses on observations of neutrinos and making measurements of their basic properties.

Neutrinos are elusive subatomic particles that are produced in large numbers in places such as the cores of stars, core-collapse supernovae, and the Big Bang. My research has focused on making observations of neutrinos, and looking for evidence that neutrinos change from one flavor to another. Studies of neutrino flavor change can yield information about fundamental neutrino properties, such as their masses and mixing angles. While a lot has been learned about neutrinos from natural sources, my current research takes advantage of neutrino beams produced by accelerators. I am part of the global effort to design and build theÌý ,Ìýwhich will send a beam of neutrinos from Fermilab to a liquid argon detector located deep underground at in the former Homestake gold mine in South Dakota.Ìý DUNE will make precision measurements of the disappearance of muon neutrinos and the appearance of electron neutrinos, and the same processes with anti-neutrinos to probe differences between matter and anti-matter. ÌýOn DUNE my groups recent efforts have focused on the near detector.Ìý For many years I was also part of the , which is sending a beam of muon neutrinos across Japan to the Super-Kamiokande detector. ÌýTo help us better understand the neutrino fluxes that are produced in accelerator-generated neutrino beams like the ones to T2K and DUNE, I am making measurements of hadron production with the at .Ìý

Selected Publications:

1. A.Abed Abud et al. (DUNE Collaboration), "DUNE Phase II: Scientific opportunities, detector concepts, technological solutions,'" JINST 19, no.12, P12005 (2024).
2. A. Abed Abud et al. (DUNE Collaboration), "Performance of a Modular Ton-Scale Pixel-Readout Liquid Argon Time Projection Chamber,'" Instruments Vol. 8, no.3, 41 (2024)
3. K. Abe et al. (T2K Collaboration), "Constraint on the matter–antimatter symmetry-violating phase in neutrino oscillations", Nature 580, 7803, 339-344 (2020)
4. A. Aduszkiewicz et al. (NA61/SHINE Collaboration), "Measurements of hadron production in \pi^{+}+ C and \pi^{+}+Be interactions at 60 GeV/c", Phys.Rev.D 100, 11, 112004 (2019)
5. ÌýK. Abe at al.Ìý (T2K Collaboration) "First measurement of the muon neutrino charged current single pion production cross section on water with the T2K near detector," Phys.Rev.D 95,1, 012010 (2017)
6. K. Abe et al. (T2K Collaboration), "Observation of Electron Neutrino Appearance in a Muon Neutrino Beam", Phys.Rev. Lett. 112, 061802 (2014)
7. S. Bhadra et al., "Optical Transition Radiation Monitor for the T2K Experiment", Nucl. Instrum. Meth. A 703, 45 (2013)
8. K. Abe et al. (T2K Collaboration), "Indication of Electron Neutrino Appearance from an Accelerator-produced Off-axis Muon Neutrino Beam", Phys. Rev. Lett. 107, 041801 (2011)
9. D.G. Michael et al. (The MINOS Collaboration), `"Observation of Muon Neutrino Disappearance with the MINOS Detectors in the NuMI neutrino Beam", Phys. Rev. Lett. 97, 191801 (2006).
10. S. N. Ahmed et al. (The SNO Collaboration), "Measurement of the total active B-8 solar neutrino flux at the Sudbury Neutrino Observatory with enhanced neutral current sensitivity",' Phys. Rev. Lett. 92, 181301 (2004).
11. Q. R. Ahmad et al. (The SNO Collaboration), "Direct Evidence for Neutrino Flavor Transformation from Neutral-Current Interactions in the Sudbury Neutrino Observatory", Phys. Rev. Lett. 89, 011301 (2002).