# Publications Sort & Filters close ## Filters Year of Publication expand\_more 2024 (1) 2023 (5) 2022 (1) 2021 (2) 2020 (6) 2019 (2) 2018 (4) 2017 (4) 2016 (8) 2015 (6) 2014 (8) 2013 (7) 2012 (8) 2011 (6) 2010 (6) 2009 (7) 2008 (5) 2007 (11) 2006 (9) 2005 (10) 2004 (12) 2003 (7) 2002 (3) 2001 (2) 2000 (2) 1999 (1) 1998 (1) 1996 (1) 1992 (1) 1990 (1) Search Within Results Search Within Results search ## 147 results Show filters filter\_alt Sort by Year of PublicationAlphabetical A-Z sort ## 147 results Download 147 citations download- [BibTeX](/node/805436/export?format=bibtex) - [EndNote X3 XML](/node/805436/export?format=endnote8) - [EndNote 7 XML](/node/805436/export?format=endnote7) - [Endnote tagged](/node/805436/export?format=tagged) - [Marc](/node/805436/export?format=marc) - [PubMedId](/node/805436/export?format=pubmed_id) - [RIS](/node/805436/export?format=ris) ### 2024 Day, Aaron M., Madison Sutula, Jonathan R. Dietz, Alexander Raun, Denis D. Sukachev, Mihir K. Bhaskar, and Evelyn L. Hu. 2024. “[Electrical Manipulation of Telecom Color Centers in Silicon](/publications/electrical-manipulation-telecom-color-centers-silicon)”. *Nature Communications* 15: 4722. Day, Aaron M., Madison Sutula, Jonathan R. Dietz, Alexander Raun, Denis D. Sukachev, Mihir K. Bhaskar, and Evelyn L. Hu. 2024. “[Electrical Manipulation of Telecom Color Centers in Silicon](/publications/electrical-manipulation-telecom-color-centers-silicon)”. *Nature Communications* 15: 4722. - [ descriptionPublisher's Version](https://www.nature.com/articles/s41467-024-48968-w) - [ descriptionPublisher's Version](https://www.nature.com/articles/s41467-024-48968-w) ### 2023 Dietz, Jonathan R., Boyang Jiang, Aaron M. Day, Sunil A. Bhave, and Evelyn L. Hu. 2023. “[Spin-Acoustic Control of Silicon Vacancies in 4H Silicon Carbide](https://www.nature.com/articles/s41928-023-01029-4)”. *Nature Electronics*, 1-7. Dietz, Jonathan R., Boyang Jiang, Aaron M. Day, Sunil A. Bhave, and Evelyn L. Hu. 2023. “[Spin-Acoustic Control of Silicon Vacancies in 4H Silicon Carbide](https://www.nature.com/articles/s41928-023-01029-4)”. *Nature Electronics*, 1-7. - add\_circle\_outline do\_not\_disturb\_on Abstract - [ descriptionPublisher's Version](https://www.nature.com/articles/s41928-023-01029-4) Bulk acoustic resonators can be fabricated on the same substrate as other components and can operate at various frequencies with high quality factors. Mechanical dynamic metrology of these devices is challenging as the surface information available... - [ descriptionPublisher's Version](https://www.nature.com/articles/s41928-023-01029-4) Day, Aaron M., Jonathan R. Dietz, Madison Sutula, Matthew Yeh, and Evelyn L. Hu. 2023. “[Laser Writing of Spin Defects in Nanophotonic Cavities](https://www.nature.com/articles/s41563-023-01544-x)”. *Nature Materials*, 1-7. Day, Aaron M., Jonathan R. Dietz, Madison Sutula, Matthew Yeh, and Evelyn L. Hu. 2023. “[Laser Writing of Spin Defects in Nanophotonic Cavities](https://www.nature.com/articles/s41563-023-01544-x)”. *Nature Materials*, 1-7. - add\_circle\_outline do\_not\_disturb\_on Abstract - [ descriptionPublisher's Version](https://www.nature.com/articles/s41563-023-01544-x) High-yield engineering and characterization of cavity–emitter coupling is an outstanding challenge in developing scalable quantum network nodes. Ex situ defect formation systems prevent real-time analysis, and previous in situ methods are limited to bulk... - [ descriptionPublisher's Version](https://www.nature.com/articles/s41563-023-01544-x) Raun, Alexander, Haoning Tang, Xueqi Ni, Eric Mazur, and Evelyn L. Hu. 2023. “[GaN Magic Angle Laser in a Merged Moire Photonic Crystal](/publications/gan-magic-angle-laser-merged-moire-photonic-crystal)”. *ACS Photonics* 10 (9): 3001-7. Raun, Alexander, Haoning Tang, Xueqi Ni, Eric Mazur, and Evelyn L. Hu. 2023. “[GaN Magic Angle Laser in a Merged Moire Photonic Crystal](/publications/gan-magic-angle-laser-merged-moire-photonic-crystal)”. *ACS Photonics* 10 (9): 3001-7. - [ descriptionPublisher's Version](https://pubs.acs.org/doi/abs/10.1021/acsphotonics.3c01064) - [ descriptionPublisher's Version](https://pubs.acs.org/doi/abs/10.1021/acsphotonics.3c01064) Ni, X. 2023. “[Three-Dimensional Reconfigurable Optical Singularities in Bilayer Photonic Crystals.](/publications/three-dimensional-reconfigurable-optical-singularities-bilayer-photonic)”. *Physical Review Letters* 132 (7): 073804. Ni, X. 2023. “[Three-Dimensional Reconfigurable Optical Singularities in Bilayer Photonic Crystals.](/publications/three-dimensional-reconfigurable-optical-singularities-bilayer-photonic)”. *Physical Review Letters* 132 (7): 073804. - [ descriptionPublisher's Version](https://doi.org/10.1103/PhysRevLett.132.073804) - [ picture\_as\_pdfphysrevlett.132.073804.pd...](/sites/g/files/omnuum6386/files/physrevlett.132.073804.pdf) - [ descriptionPublisher's Version](https://doi.org/10.1103/PhysRevLett.132.073804) - [ picture\_as\_pdfphysrevlett.132.073804.pd...](/sites/g/files/omnuum6386/files/physrevlett.132.073804.pdf) Panday, A. 2023. “[Deterministic Creation of Strained Color Centers in Nanostructures via High-Stress Thin Films.](/publications/deterministic-creation-strained-color-centers-nanostructures-high-stress-thin)”. *Applied Physics Letters* 123 (24): 244001. Panday, A. 2023. “[Deterministic Creation of Strained Color Centers in Nanostructures via High-Stress Thin Films.](/publications/deterministic-creation-strained-color-centers-nanostructures-high-stress-thin)”. *Applied Physics Letters* 123 (24): 244001. ### 2022 Dietz, Jonathan R., and Evelyn L. Hu. 2022. “[Optical and Strain Stabilization of Point Defects in Silicon Carbide](https://aip.scitation.org/doi/full/10.1063/5.0087805)”. *Applied Physics Letters* 120 (18): 184001. Dietz, Jonathan R., and Evelyn L. Hu. 2022. “[Optical and Strain Stabilization of Point Defects in Silicon Carbide](https://aip.scitation.org/doi/full/10.1063/5.0087805)”. *Applied Physics Letters* 120 (18): 184001. - add\_circle\_outline do\_not\_disturb\_on Abstract - [ descriptionPublisher's Version](https://aip.scitation.org/doi/full/10.1063/5.0087805) The photoluminescence and spin properties of ensembles of color centers in silicon carbide are enhanced by fabricating optically isolated slab waveguide structures and carefully controlling annealing and cooling conditions. We find that the... - [ descriptionPublisher's Version](https://aip.scitation.org/doi/full/10.1063/5.0087805) ### 2021 Hu, Awschalom, and al. 2021. “[Development of Quantum Interconnects (QuICs) for Next-Generation Information Technologies](/publications/development-quantum-interconnects-quics-next-generation-information)”. *PRX Quantum* 2 (1). Hu, Awschalom, and al. 2021. “[Development of Quantum Interconnects (QuICs) for Next-Generation Information Technologies](/publications/development-quantum-interconnects-quics-next-generation-information)”. *PRX Quantum* 2 (1). - add\_circle\_outline do\_not\_disturb\_on Abstract - [ descriptionPublisher's Version](https://doi.org/10.1103/PRXQuantum.2.017002) Just as “classical” information technology rests on a foundation built of interconnected information-processing systems, quantum information technology (QIT) must do the same. A critical component of such systems is the “interconnect,” a device or process... - [ descriptionPublisher's Version](https://doi.org/10.1103/PRXQuantum.2.017002) Gadalla, Mena N., Andrew S. Greenspon, Rodrick Kuate Defo, Xingyu Zhang, and Evelyn L. Hu. 2021. “[Enhanced Cavity Coupling to Silicon Vacancies in 4H Silicon Carbide Using Laser Irradiation and Thermal Annealing](/publications/enhanced-cavity-coupling-silicon-vacancies-4h-silicon-carbide-using-laser)”. *Proceedings of the National Academy of Sciences* 118 (12). Gadalla, Mena N., Andrew S. Greenspon, Rodrick Kuate Defo, Xingyu Zhang, and Evelyn L. Hu. 2021. “[Enhanced Cavity Coupling to Silicon Vacancies in 4H Silicon Carbide Using Laser Irradiation and Thermal Annealing](/publications/enhanced-cavity-coupling-silicon-vacancies-4h-silicon-carbide-using-laser)”. *Proceedings of the National Academy of Sciences* 118 (12). - add\_circle\_outline do\_not\_disturb\_on Abstract - [ descriptionPublisher's Version](https://www.pnas.org/content/118/12/e2021768118) The negatively charged silicon monovacancy VSi— in 4H silicon carbide (SiC) is a spin-active point defect that has the potential to act as a qubit in solid-state quantum information applications. Photonic crystal cavities (PCCs) can augment the optical... - [ descriptionPublisher's Version](https://www.pnas.org/content/118/12/e2021768118) ### 2020 Gadalla, Mena, Chaudhary Kundan, Federico Capasso, and Evelyn Hu. 2020. “[Imaging of Surface Plasmon Polaritons and Spoof Plasmons in Low-Loss Highly Metallic Titanium Nitride Thin Films in Visible and Infrared Regimes](https://www.osapublishing.org/oe/abstract.cfm?uri=oe-28-10-14536)”. *Optics Express* 28 (10): 14536-46. Gadalla, Mena, Chaudhary Kundan, Federico Capasso, and Evelyn Hu. 2020. “[Imaging of Surface Plasmon Polaritons and Spoof Plasmons in Low-Loss Highly Metallic Titanium Nitride Thin Films in Visible and Infrared Regimes](https://www.osapublishing.org/oe/abstract.cfm?uri=oe-28-10-14536)”. *Optics Express* 28 (10): 14536-46. - add\_circle\_outline do\_not\_disturb\_on Abstract - [ descriptionPublisher's Version](https://www.osapublishing.org/oe/abstract.cfm?uri=oe-28-10-14536) Titanium nitride (TiN) has been identified as a promising refractory material for high temperature plasmonic applications such as surface plasmon polaritons (SPPs) waveguides, lasers and light sources, and near field optics. Such SPPs are sensitive not... - [ descriptionPublisher's Version](https://www.osapublishing.org/oe/abstract.cfm?uri=oe-28-10-14536) Crook, Alexander L., Christopher P. Anderson, Kevin C. Miao, Alexandre Bourassa, Hope Lee, Sam L. Bayliss, David O. Bracher, et al. 2020. “[Purcell Enhancement of a Single Silicon Carbide Color Center With Coherent Spin Control](/publications/purcell-enhancement-single-silicon-carbide-color-center-coherent-spin-control)”. *NanoLetters* 20 (5): 3427-34. Crook, Alexander L., Christopher P. Anderson, Kevin C. Miao, Alexandre Bourassa, Hope Lee, Sam L. Bayliss, David O. Bracher, et al. 2020. “[Purcell Enhancement of a Single Silicon Carbide Color Center With Coherent Spin Control](/publications/purcell-enhancement-single-silicon-carbide-color-center-coherent-spin-control)”. *NanoLetters* 20 (5): 3427-34. - add\_circle\_outline do\_not\_disturb\_on Abstract - [ descriptionPublisher's Version](https://pubs.acs.org/doi/10.1021/acs.nanolett.0c00339) - [ picture\_as\_pdf2020\_433\_crook\_nanoletter...](/sites/g/files/omnuum6386/files/hugroup/files/2020_433_crook_nanoletters.pdf) - [ picture\_as\_pdf2020\_433\_crook\_supplement...](/sites/g/files/omnuum6386/files/hugroup/files/2020_433_crook_supplementary.pdf) Silicon carbide has recently been developed as a platform for optically addressable spin defects. In particular, the neutral divacancy in the 4H polytype displays an optically addressable spin-1 ground state and near-infrared optical emission. Here, we... - [ descriptionPublisher's Version](https://pubs.acs.org/doi/10.1021/acs.nanolett.0c00339) - [ picture\_as\_pdf2020\_433\_crook\_nanoletter...](/sites/g/files/omnuum6386/files/hugroup/files/2020_433_crook_nanoletters.pdf) - [ picture\_as\_pdf2020\_433\_crook\_supplement...](/sites/g/files/omnuum6386/files/hugroup/files/2020_433_crook_supplementary.pdf) Turner, M., N. Langelier, R. Bainbridge, D. Walters, S. Meesala, T. Babinec, P. Kehauas, et al. 2020. “[Magnetic Field Fingerprinting of Integrated-Circuit Activity With a Quantum Diamond Microscope](/publications/magnetic-field-fingerprinting-integrated-circuit-activity-quantum-diamond)”. *Physical Review Applied* 14 (014097). Turner, M., N. Langelier, R. Bainbridge, D. Walters, S. Meesala, T. Babinec, P. Kehauas, et al. 2020. “[Magnetic Field Fingerprinting of Integrated-Circuit Activity With a Quantum Diamond Microscope](/publications/magnetic-field-fingerprinting-integrated-circuit-activity-quantum-diamond)”. *Physical Review Applied* 14 (014097). - [ descriptionPublisher's Version](10.1103/PhysRevApplied.14.014097) - [ picture\_as\_pdf2020\_435\_turner\_supplemen...](/sites/g/files/omnuum6386/files/hugroup/files/2020_435_turner_supplementary.pdf) - [ descriptionPublisher's Version](10.1103/PhysRevApplied.14.014097) - [ picture\_as\_pdf2020\_435\_turner\_supplemen...](/sites/g/files/omnuum6386/files/hugroup/files/2020_435_turner_supplementary.pdf) - Previous page chevron\_left - [1](?page=0 "Current page") - [2](?page=1 "Go to page 2") - [3](?page=2 "Go to page 3") - [ Last page 13 ](?page=12 "Go to last page") - [ Next page chevron\_right ](?page=1 "Go to next page")