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27 results on '"Regan, Blake"'

1. Nanofabrication of high Q, transferable, diamond resonators

Author

Regan, Blake, Trycz, Aleksandra, Fröch, Johannes E., Schaeper, Otto Cranwell, Kim, Sejeong, and Aharonovich, Igor

Subjects
Physics - Optics, Condensed Matter - Materials Science, Physics - Applied Physics
Abstract

Advancement of diamond based photonic circuitry requires robust fabrication protocols of key components, including diamond resonators and cavities. Here, we present 1D (nanobeam) photonic crystal cavities generated from single crystal diamond membranes utilising a metallic tungsten layer as a restraining, conductive and removable hard mask. The use of tungsten instead of a more conventional silicon oxide layer enables good repeatability and reliability of the fabrication procedures. The process yields high quality diamond cavities with quality factors (Q factors) approaching 10$^$4. Finally, we show that the cavities can be picked up and transferred onto a trenched substrate to realise fully suspended diamond cavities. Our fabrication process demonstrates the capability of diamond membranes as modular components for broader diamond based quantum photonic circuitry.

Published
2021

2. Photonic devices fabricated from (111) oriented single crystal diamond

Author

Regan, Blake, Kim, Sejeong, Ly, Anh Tu Huy, Trycz, Aleksandra, Bray, Kerem, Ganesan, Kumaravelu, Toth, Milos, and Aharonovich, Igor

Subjects
Physics - Optics, Condensed Matter - Materials Science, Quantum Physics
Abstract

Diamond is a material of choice in the pursuit of integrated quantum photonic technologies. So far, the majority of photonic devices fabricated from diamond, are made from (100)-oriented crystals. In this work, we demonstrate a methodology for the fabrication of optically-active membranes from (111)-oriented diamond. We use a liftoff technique to generate membranes, followed by chemical vapour deposition of diamond in the presence of silicon to generate homogenous silicon vacancy colour centers with emission properties that are superior to those in (100)-oriented diamond. We further use the diamond membranes to fabricate high quality microring resonators with quality factors exceeding ~ 3000. Supported by finite difference time domain calculations, we discuss the advantages of (111) oriented structures as building blocks for quantum nanophotonic devices.

Published
2019

3. A Diamond-Photonics Platform Based on Silicon-Vacancy Centers in a Single Crystal Diamond Membrane and a Fiber-Cavity

Author

Häußler, Stefan, Benedikter, Julia, Bray, Kerem, Regan, Blake, Dietrich, Andreas, Twamley, Jason, Aharonovich, Igor, Hunger, David, and Kubanek, Alexander

Subjects
Physics - Applied Physics, Physics - Optics, Quantum Physics
Abstract

We realize a potential platform for an efficient spin-photon interface, namely negatively-charged silicon-vacancy centers in a diamond membrane coupled to the mode of a fully-tunable, fiber-based, optical resonator. We demonstrate that introducing the thin ($\sim 200 \, \text{nm}$), single crystal diamond membrane into the mode of the resonator does not change the cavity properties, which is one of the crucial points for an efficient spin-photon interface. In particular, we observe constantly high Finesse values of up to $3000$ and a linear dispersion in the presence of the membrane. We observe cavity-coupled fluorescence froman ensemble of SiV$^{-}$ centers with an enhancement factor of $\sim 1.9$. Furthermore from our investigations we extract the ensemble absorption and extrapolate an absorption cross section of $(2.9 \, \pm \, 2) \, \cdot \, 10^{-12} \, \text{cm}^{2}$ for a single SiV$^{-}$ center, much higher than previously reported., Comment: 8 pages, 4 figures

Published
2018
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4. Anti-Stokes excitation of solid-state quantum emitters for nanoscale thermometry

Author

Tran, Toan Trong, Regan, Blake, Ekimov, Evgeny A., Mu, Zhao, Yu, Zhou, Gao, Weibo, Narang, Prineha, Solntsev, Alexander S., Toth, Milos, Aharonovich, Igor, and Bradac, Carlo

Subjects
Physics - Applied Physics, Physics - Optics, Quantum Physics
Abstract

Color centers in solids are the fundamental constituents of a plethora of applications such as lasers, light emitting diodes and sensors, as well as the foundation of advanced quantum information and communication technologies. Their photoluminescence properties are usually studied under Stokes excitation, in which the emitted photons are at a lower energy than the excitation ones. In this work, we explore the opposite Anti-Stokes process, where excitation is performed with lower energy photons. We report that the process is sufficiently efficient to excite even a single quantum system, namely the germanium-vacancy center in diamond. Consequently, we leverage the temperature-dependent, phonon-assisted mechanism to realize an all-optical nanoscale thermometry scheme that outperforms any homologous optical method employed to date. Our results frame a promising approach for exploring fundamental light-matter interactions in isolated quantum systems, and harness it towards the realization of practical nanoscale thermometry and sensing.

Published
2018

5. A random laser based on diamond nanoneedles

Author

Duong, Ngoc My Hanh, Regan, Blake, Toth, Milos, Aharonovich, Igor, and Dawes, Judith M

Subjects
Physics - Optics, Condensed Matter - Materials Science, Physics - Applied Physics
Abstract

Random lasers use radiative gain and multiple scatterers in disordered media to generate light amplification. In this study, we demonstrate a random laser based on diamond nanoneedles that act as scatterers in combination with fluorescent dye molecules that serve as a gain medium. Random lasers realized using diamond possess high spectral radiance with angle-free emission and thresholds of 0.16 mJ. The emission dependence on the pillar diameter and density is investigated, and optimum lasing conditions are measured for pillars with spacing and density of 336 nm and ~ 2.9x10^10 cm-2. Our results expand the application space of diamond as a material platform for practical, compact photonic devices and sensing applications.

Published
2018

6. Bottom up engineering of near-identical quantum emitters in atomically thin materials

Author

Mendelson, Noah, Xu, Zai-Quan, Tran, Toan Trong, Kianinia, Mehran, Bradac, Carlo, Scott, John, Nguyen, Minh, Bishop, James, Froch, Johannes, Regan, Blake, Aharonovich, Igor, and Toth, Milos

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science, Physics - Optics
Abstract

Quantum technologies require robust and photostable single photon emitters (SPEs) that can be reliably engineered. Hexagonal boron nitride (hBN) has recently emerged as a promising candidate host to bright and optically stable SPEs operating at room temperature. However, the emission wavelength of the fluorescent defects in hBN has, to date, been shown to be uncontrolled. The emitters usually display a large spread of zero phonon line (ZPL) energies spanning over a broad spectral range (hundreds of nanometers), which hinders the potential development of hBN-based devices and applications. We demonstrate bottom-up, chemical vapor deposition growth of large-area, few layer hBN that hosts large quantities of SPEs: 100 per 10x10 {\mu}m2. Remarkably, more than 85 percent of the emitters have a ZPL at (580{\pm}10)nm, a distribution which is over an order of magnitude narrower than previously reported. Exploiting the high density and uniformity of the emitters, we demonstrate electrical modulation and tuning of the ZPL emission wavelength by up to 15 nm. Our results constitute a definite advancement towards the practical deployment of hBN single photon emitters in scalable quantum photonic and hybrid optoelectronic devices based on 2D materials.

Published
2018

7. Single crystal diamond membranes containing germanium vacancy color centers

Author

Bray, Kerem, Regan, Blake, Trycz, Aleksandra, Previdi, Rodolfo, Seniutinas, Gediminas, Ganesan, Kumaravelu, Kianinia, Mehran, Kim, Sejeong, and Aharonovich, Igor

Subjects
Physics - Optics, Condensed Matter - Materials Science, Quantum Physics
Abstract

Single crystal diamond membranes that host optically active emitters are highly attractive components for integrated quantum nanophotonics. In this work we demonstrate bottom-up synthesis of single crystal diamond membranes containing the germanium vacancy (GeV) color centers. We employ a lift-off technique to generate the membranes and perform chemical vapour deposition in a presence of germanium oxide to realize the insitu doping. Finally, we show that these membranes are suitable for engineering of photonic resonators such as microring cavities with quality factors of 1500. The robust and scalable approach to engineer single crystal diamond membranes containing emerging color centers is a promising pathway for realization of diamond integrated quantum nanophotonic circuits on a chip.

Published
2018

9. Robust Solid State Quantum System Operating at 800 K

Author

Kianinia, Mehran, Tawfik, Sherif Abdulkader, Regan, Blake, Tran, Toan Trong, Ford, Michael J., Aharonovich, Igor, and Toth, Milos

Subjects
Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics
Abstract

Realization of Quantum information and communications technologies requires robust, stable solid state single photon sources. However, most existing sources cease to function above cryogenic or room temperature due to thermal ionization or strong phonon coupling which impede their emissive and quantum properties. Here we present an efficient single photon source based on a defect in a van der Waals crystal that is optically stable and operates at elevated temperatures of up to 800 K. The quantum nature of the source and the photon purity are maintained upon heating to 800 K and cooling back to room temperature. Our report of a robust high temperature solid state single photon source constitutes a significant step to-wards practical, integrated quantum technologies for real-world environments., Comment: 9 pages

Published
2016

12. The Relationship between State High School Exit Exams and Mathematical Proficiency: Analyses of the Complexity, Content, and Format of Items and Assessment Protocols

Author

Regan, Blake B.

Abstract

This study examined the relationship between high school exit exams and mathematical proficiency. With the No Child Left Behind (NCLB) Act requiring all students to be proficient in mathematics by 2014, it is imperative that high-stakes assessments accurately evaluate all aspects of student achievement, appropriately set the yardstick by which students will be measured, and clearly communicate these expectations to teachers and administrators. As states across the country transition to the Common Core State Standards, a key goal of this research was to provide current mathematics assessment information for the two consortia charged with the responsibility of creating assessments aligned to these new standards for mathematics. With this goal in mind, the researcher collected assessment data from Massachusetts's, Minnesota's, and Ohio's high school exit exams. These states were selected based upon their use of a comprehensive exit exam to evaluate student readiness for graduation. For each exam, the researcher determined which complexity level, which content strand, and which item format best predicts student proficiency classification. He then critically evaluated each exam based upon its protocol and the National Research Council's definition of mathematical proficiency. Results indicated that no single complexity level, content strand, or item format had the best predictive power for all of the exams. The results indicated that the greatest amount of variation in items' predictive power occurred across complexity level and the least amount of variation occurred across content strand. In addition, the selected exams were found to appropriately assess mathematical proficiency with the following exceptions: (a) they did not meet Norman L. Webb's six-item criterion for categorical concurrence requirements for each complexity-by-content strand category, and (b) two of the four assessments were deemed to have misclassified some students as proficient because the cut score was set too low to require students to earn points from the full range of desirable mathematical behaviors. Results from this study reinforce the idea that exams that intend to assess mathematical proficiency should be designed appropriately and implemented with attention to detail in order to do so. In particular, categorical concurrence and cut score emerged as two critical factors in such assessments. [The dissertation citations contained here are published with the permission of ProQuest LLC. Further reproduction is prohibited without permission. Copies of dissertations may be obtained by Telephone (800) 1-800-521-0600. Web page: http://www.proquest.com/en-US/products/dissertations/individuals.shtml.]

Published
2012

18. Plastic Deformation of Single‐Crystal Diamond Nanopillars

Author

Regan, Blake, primary, Aghajamali, Alireza, additional, Froech, Johannes, additional, Tran, Toan Trong, additional, Scott, John, additional, Bishop, James, additional, Suarez‐Martinez, Irene, additional, Liu, Ying, additional, Cairney, Julie M., additional, Marks, Nigel A, additional, Toth, Milos, additional, and Aharonovich, Igor, additional

Published
2020
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25. Anti-Stokes excitation of solid-state quantum emitters for nanoscale thermometry.

Author

Toan Trong Tran, Regan, Blake, Solntsev, Alexander S., Toth, Milos, Aharonovich, Igor, Bradac, Carlo, Ekimov, Evgeny A., Zhao Mu, Yu Zhou, Wei-bo Gao, and Prineha Narang

Subjects
*LIGHT emitting diodes, *LASERS
Abstract

Color centers in solids are the fundamental constituents of a plethora of applications such as lasers, light-emitting diodes, and sensors, as well as the foundation of advanced quantum information and communication technologies.

Published
2019
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27. A Random Laser Based on Hybrid Fluorescent Dye and Diamond Nanoneedles.

Author

Duong, Ngoc My Hanh, Regan, Blake, Toth, Milos, Aharonovich, Igor, and Dawes, Judith

Subjects
*DYE lasers, *FLUORESCENT dyes, *DIAMONDS, *NANOSTRUCTURED materials, *RADIANCE, *LIGHT scattering
Abstract

Random lasers use radiative gain and multiple scatterers in disordered media to generate light amplification. In this study, a random laser based on diamond nanoneedles that act as scatterers in combination with fluorescent dye molecules that serve as a gain medium has been demonstrated. Random lasers realized using diamond possess high spectral radiance with angle‐free emission and thresholds of 0.16 mJ. The emission dependence on the pillar diameter and density is investigated, and optimum lasing conditions are measured for pillars with spacing and density of ≈336 ± 40 nm and ≈2.9 × 1010 cm−2. Our results expand the application space of diamond as a material platform for practical, compact photonic devices, and sensing applications. In this study, a random laser is realized for the first time by integrating Rhodamine 6G dye into a diamond nanoneedles matrix. This work paves the way to potential applications of diamond nanoneedles in imaging, sensing, and display technologies. [ABSTRACT FROM AUTHOR]

Published
2019
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