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1. Coupling Spin Defects in a Layered Material to Nanoscale Plasmonic Cavities

Author

Mendelson, N, Ritika, R, Kianinia, M, Scott, J, Kim, S, Froch, JE, Gazzana, C, Westerhausen, M, Xiao, L, Mohajerani, SS, Strauf, S, Toth, M, Aharonovich, I, Xu, Z-Q, Mendelson, N, Ritika, R, Kianinia, M, Scott, J, Kim, S, Froch, JE, Gazzana, C, Westerhausen, M, Xiao, L, Mohajerani, SS, Strauf, S, Toth, M, Aharonovich, I, and Xu, Z-Q

Abstract

Spin defects in hexagonal boron nitride, and specifically the negatively charged boron vacancy (VB - ) centers, are emerging candidates for quantum sensing. However, the VB - defects suffer from low quantum efficiency and, as a result, exhibit weak photoluminescence. In this work, a scalable approach is demonstrated to dramatically enhance the VB - emission by coupling to a plasmonic gap cavity. The plasmonic cavity is composed of a flat gold surface and a silver cube, with few-layer hBN flakes positioned in between. Employing these plasmonic cavities, two orders of magnitude are extracted in photoluminescence enhancement associated with a corresponding twofold enhancement in optically detected magnetic resonance contrast. The work will be pivotal to progress in quantum sensing employing 2D materials, and in realization of nanophotonic devices with spin defects in hexagonal boron nitride.

Published
2022

2. Room-temperature optically detected magnetic resonance of single defects in hexagonal boron nitride.

Author

Stern, HL, Gu, Q, Jarman, J, Eizagirre Barker, S, Mendelson, N, Chugh, D, Schott, S, Tan, HH, Sirringhaus, H, Aharonovich, I, Atatüre, M, Stern, HL, Gu, Q, Jarman, J, Eizagirre Barker, S, Mendelson, N, Chugh, D, Schott, S, Tan, HH, Sirringhaus, H, Aharonovich, I, and Atatüre, M

Abstract

Optically addressable solid-state spins are important platforms for quantum technologies, such as repeaters and sensors. Spins in two-dimensional materials offer an advantage, as the reduced dimensionality enables feasible on-chip integration into devices. Here, we report room-temperature optically detected magnetic resonance (ODMR) from single carbon-related defects in hexagonal boron nitride with up to 100 times stronger contrast than the ensemble average. We identify two distinct bunching timescales in the second-order intensity-correlation measurements for ODMR-active defects, but only one for those without an ODMR response. We also observe either positive or negative ODMR signal for each defect. Based on kinematic models, we relate this bipolarity to highly tuneable internal optical rates. Finally, we resolve an ODMR fine structure in the form of an angle-dependent doublet resonance, indicative of weak but finite zero-field splitting. Our results offer a promising route towards realising a room-temperature spin-photon quantum interface in hexagonal boron nitride.

Published
2022

3. Spin defects in hexagonal boron nitride for strain sensing on nanopillar arrays.

Author

Yang, T, Mendelson, N, Li, C, Gottscholl, A, Scott, J, Kianinia, M, Dyakonov, V, Toth, M, Aharonovich, I, Yang, T, Mendelson, N, Li, C, Gottscholl, A, Scott, J, Kianinia, M, Dyakonov, V, Toth, M, and Aharonovich, I

Abstract

Two-dimensional hexagonal boron nitride (hBN) has attracted much attention as a platform for studies of light-matter interactions at the nanoscale, especially in quantum nanophotonics. Recent efforts have focused on spin defects, specifically negatively charged boron vacancy (VB-) centers. Here, we demonstrate a scalable method to enhance the VB- emission using an array of SiO2 nanopillars. We achieve a 4-fold increase in photoluminescence (PL) intensity, and a corresponding 4-fold enhancement in optically detected magnetic resonance (ODMR) contrast. Furthermore, the VB- ensembles provide useful information about the strain fields associated with the strained hBN at the nanopillar sites. Our results provide an accessible way to increase the emission intensity as well as the ODMR contrast of the VB- defects, while simultaneously form a basis for miniaturized quantum sensors in layered heterostructures.

Published
2022

4. Tunable Fiber-Cavity Enhanced Photon Emission from Defect Centers in hBN

Author

Häußler, S, Bayer, G, Waltrich, R, Mendelson, N, Li, C, Hunger, D, Aharonovich, I, and Kubanek, A

Subjects
0205 Optical Physics, 0906 Electrical and Electronic Engineering, 0912 Materials Engineering, Physics::Accelerator Physics, Physics::Optics
Abstract

Realization of quantum photonic devices requires coupling single quantum emitters to the mode of optical resonators. In this work, a hybrid system consisting of defect centers in few-layer hexagonal boron nitride (hBN) grown by chemical vapor deposition and a fiber-based Fabry–Pérot cavity is presented. The sub 10-nm thickness of hBN and its smooth surface enable efficient integration into the cavity mode. This hybrid platform is operated over a broad spectral range larger than 30 nm and its tuneability is used to explore different coupling regimes. Consequently, very large cavity-assisted signal enhancement up to 50-fold and strongly narrowed linewidths are achieved, which is owing to cavity funneling, a record for hBN-cavity systems. Additionally, an excitation and readout scheme is implemented for resonant excitation that allows to establish cavity-assisted photoluminescence excitation (PLE) spectroscopy. This work marks an important milestone for the deployment of 2D materials coupled to fiber-based cavities in practical quantum technologies.

Published
2021

5. Identifying carbon as the source of visible single-photon emission from hexagonal boron nitride

Author

Mendelson, N, Chugh, D, Reimers, JR, Cheng, TS, Gottscholl, A, Long, H, Mellor, CJ, Zettl, A, Dyakonov, V, Beton, PH, Novikov, SV, Jagadish, C, Tan, HH, Ford, MJ, Toth, M, Bradac, C, and Aharonovich, I

Subjects
Mechanics of Materials, Mechanical Engineering, General Materials Science, General Chemistry, Nanoscience & Nanotechnology, Condensed Matter Physics
Abstract

Single-photon emitters (SPEs) in hexagonal boron nitride (hBN) have garnered increasing attention over the last few years due to their superior optical properties. However, despite the vast range of experimental results and theoretical calculations, the defect structure responsible for the observed emission has remained elusive. Here, by controlling the incorporation of impurities into hBN via various bottom-up synthesis methods and directly through ion implantation, we provide direct evidence that the visible SPEs are carbon related. Room-temperature optically detected magnetic resonance is demonstrated on ensembles of these defects. We perform ion-implantation experiments and confirm that only carbon implantation creates SPEs in the visible spectral range. Computational analysis of the simplest 12 carbon-containing defect species suggest the negatively charged [Formula: see text] defect as a viable candidate and predict that out-of-plane deformations make the defect environmentally sensitive. Our results resolve a long-standing debate about the origin of single emitters at the visible range in hBN and will be key to the deterministic engineering of these defects for quantum photonic devices.

Published
2021

6. Grain Dependent Growth of Bright Quantum Emitters in Hexagonal Boron Nitride

Author

Mendelson, N, Morales-Inostroza, L, Li, C, Ritika, R, Nguyen, MAP, Loyola-Echeverria, J, Kim, S, Goetzinger, S, Toth, M, Aharonovich, I, Mendelson, N, Morales-Inostroza, L, Li, C, Ritika, R, Nguyen, MAP, Loyola-Echeverria, J, Kim, S, Goetzinger, S, Toth, M, and Aharonovich, I

Abstract

Point defects in hexagonal boron nitride have emerged as a promising quantum light source due to their bright and photostable room temperature emission. In this work, the incorporation of quantum emitters during chemical vapor deposition growth on a nickel substrate is studied. Combining a range of characterization techniques, it is demonstrated that the incorporation of quantum emitters is limited to (001) oriented nickel grains. Such emitters display improved emission properties in terms of brightness and stability. These emitters are further utilized and integrated with a compact optical antenna enhancing light collection from the sources. The hybrid device yields average saturation count rates of ≈2.9 × 106 cps and an average photon purity of g(2)(0) ≈ 0.1. The results advance the understanding of single photon emitter incorporation during chemical vapor deposition growth and demonstrate a key step towards compact devices for achieving maximum collection efficiency.

Published
2021

7. Direct Growth of Hexagonal Boron Nitride on Photonic Chips for High-Throughput Characterization

Author

Glushkov, E, Mendelson, N, Chernev, A, Ritika, R, Lihter, M, Zamani, RR, Comtet, J, Navikas, V, Aharonovich, I, Radenovic, A, Glushkov, E, Mendelson, N, Chernev, A, Ritika, R, Lihter, M, Zamani, RR, Comtet, J, Navikas, V, Aharonovich, I, and Radenovic, A

Abstract

Adapting optical microscopy methods for nanoscale characterization of defects in two-dimensional (2D) materials is a vital step for photonic on-chip devices. To increase the analysis throughput, waveguide-based on-chip imaging platforms have been recently developed. Their inherent disadvantage, however, is the necessity to transfer the 2D material from the growth substrate to the imaging chip, which introduces nonuniform material coverage and contamination, potentially altering the characterization results. Here we present a unique approach to circumvent these shortfalls by directly growing a widely used 2D material (hexagonal boron nitride, hBN) on silicon nitride chips and optically characterizing the defects in the intact as-grown material. We compare the direct growth approach to the standard PMMA-assisted wet transfer method and confirm the clear advantages of the direct growth. While demonstrated with hBN in the current work, the method can be extended to other 2D materials.

Published
2021

8. Scalable and Deterministic Fabrication of Quantum Emitter Arrays from Hexagonal Boron Nitride.

Author

Li, C, Mendelson, N, Ritika, R, Chen, Y, Xu, Z-Q, Toth, M, Aharonovich, I, Li, C, Mendelson, N, Ritika, R, Chen, Y, Xu, Z-Q, Toth, M, and Aharonovich, I

Abstract

We demonstrate the fabrication of large-scale arrays of single-photon emitters (SPEs) in hexagonal boron nitride (hBN). Bottom-up growth of hBN onto nanoscale arrays of dielectric pillars yields corresponding arrays of hBN emitters at the pillar sites. Statistical analysis shows that the pillar diameter is critical for isolating single defects, and diameters of ∼250 nm produce a near-unity yield of a single emitter at each pillar site. Our results constitute a promising route toward spatially controlled generation of hBN SPEs and provide an effective and efficient method to create large-scale SPE arrays. The results pave the way to scalability and high throughput fabrication of SPEs for advanced quantum photonic applications.

Published
2021

9. Resonant energy transfer between hexagonal boron nitride quantum emitters and atomically layered transition metal dichalcogenides

Author

Li C, Xu ZQ, Mendelson N, Kianinia M, Wan Y, Toth M, Aharonovich I, and Bradac C

Subjects
Condensed Matter::Materials Science, 0303 Macromolecular and Materials Chemistry, 0912 Materials Engineering, 1007 Nanotechnology
Abstract

© 2020 IOP Publishing Ltd. Van der Waals heterostructures offer a unique platform to investigate light matter interaction at the nanoscale. In this work, we explore resonant energy transfer processes between van der Waals materials from two fundamentally different systems: single-photon emitters in two-dimensional hexagonal boron nitride and excitons in transition metal dichalcogenide monolayers. We study the photodynamics between these two systems by performing time-resolved fluorescence spectroscopy. Our results show that colour centres in hexagonal boron nitride do interact with transition metal dichalcogenide excitons and provide important insights into harnessing these interactions in van der Waals heterostructures for advanced nanophotonic devices.

Published
2020

10. Charge and energy transfer of quantum emitters in 2D heterostructures

Author

Xu ZQ, Mendelson N, Scott JA, Li C, Abidi IH, Liu H, Luo Z, Aharonovich I, and Toth M

Subjects
Condensed Matter::Materials Science, Physics::Optics, 0303 Macromolecular and Materials Chemistry, 0912 Materials Engineering, 1007 Nanotechnology, Physics::Chemical Physics
Abstract

© 2020 IOP Publishing Ltd. Graphene is often used as an acceptor in highly efficient energy transfer processes between its electrons and neighbouring optical emitters such as quantum dots, fluorescent molecules and color centres in crystals. Here we demonstrate that graphene can act not only as an acceptor in energy transfer processes, but also an acceptor of charge donated by photoexcited quantum emitters. Specifically, we use heterostructures comprised of graphene and hexagonal boron nitride (hBN) to demonstrate a reversible charge transfer process from quantum emitters in hBN to graphene. The process acts as a controllable, energy-resolved filter that quenches quantum emitters with ground states located above the Fermi level of graphene. Our findings shed light on the positions of hBN defect states within the bandgap of hBN, and are important for the design of devices based on 2D heterostructures, opening new avenues to technologies based on electrical excitation, manipulation, and readout of the quantum states of optical emitters.

Published
2020

11. Coupling Hexagonal Boron Nitride Quantum Emitters to Photonic Crystal Cavities

Author

Fröch JE, Kim S, Mendelson N, Kianinia M, Toth M, and Aharonovich I

Subjects
Physics::Optics, Nanoscience & Nanotechnology
Abstract

Quantum photonics technologies require a scalable approach for the integration of nonclassical light sources with photonic resonators to achieve strong light confinement and enhancement of quantum light emission. Point defects from hexagonal boron nitride (hBN) are among the front runners for single photon sources due to their ultra-bright emission; however, the coupling of hBN defects to photonic crystal cavities has so far remained elusive. Here we demonstrate on-chip integration of hBN quantum emitters with photonic crystal cavities from silicon nitride (Si3N4) and achieve an experimentally measured quality factor (Q-factor) of 3300 for hBN/Si3N4 hybrid cavities. We observed 6-fold photoluminescence enhancement of an hBN single photon emission at room temperature. Our work will be useful for further development of cavity quantum electrodynamic experiments and on-chip integration of two-dimensional (2D) materials.

Published
2020

12. Low-Temperature Electron–Phonon Interaction of Quantum Emitters in Hexagonal Boron Nitride

Author

Grosso G, Moon H, Ciccarino CJ, Flick J, Mendelson N, Mennel L, Toth M, Aharonovich I, Narang P, and Englund DR

Subjects
Condensed Matter::Materials Science, 0205 Optical Physics, 0206 Quantum Physics, 0906 Electrical and Electronic Engineering
Abstract

© 2020 American Chemical Society. Single photon sources based on atomic defects in layered hexagonal boron nitride (hBN) have emerged as promising solid state quantum emitters with atom-like photophysical and quantum optoelectronic properties. Similar to other atom-like emitters, defect-phonon coupling in hBN governs the characteristic single-photon emission and provides an opportunity to investigate the atomic and electronic structure of emitters as well as the coupling of their spin- and charge-dependent electronic states to phonons. Here, we investigate these questions using photoluminescence excitation (PLE) experiments at T = 4 K on single-photon emitters in multilayer hBN grown by chemical vapor deposition. By scanning up to 250 meV from the zero phonon line (ZPL), we can precisely measure the emitter's coupling efficiency to different phonon modes. Our results show that excitation mediated by the absorption of one in-plane optical phonon increases the emitter absorption probability 10-fold compared to that mediated by acoustic or out-of-plane optical phonons. We perform complementary theoretical predictions by first-principles density-functional theory of four defect candidates for which we calculate prevalent charge states and their spin-dependent coupling to bulk and local phonon modes. We discuss possible hypotheses to overcome the disparity between experimental results and theoretical predictions. Our work illuminates the phonon-coupled dynamics in hBN quantum emitters at cryogenic temperature, with implications more generally for mesoscopic quantum emitter systems in 2D materials, and represents possible applications in solid-state quantum technologies.

Published
2020

13. Grain Dependent Growth of Bright Quantum Emitters in Hexagonal Boron Nitride

Author

Mendelson N, Morales-Inostroza L, Li C, Ritika R, Nguyen MAP, Loyola-Echeverria J, Kim S, Götzinger S, Toth M, and Aharonovich I

Subjects
0205 Optical Physics, 0906 Electrical and Electronic Engineering, 0912 Materials Engineering
Abstract

© 2020 Wiley-VCH GmbH Point defects in hexagonal boron nitride have emerged as a promising quantum light source due to their bright and photostable room temperature emission. In this work, the incorporation of quantum emitters during chemical vapor deposition growth on a nickel substrate is studied. Combining a range of characterization techniques, it is demonstrated that the incorporation of quantum emitters is limited to (001) oriented nickel grains. Such emitters display improved emission properties in terms of brightness and stability. These emitters are further utilized and integrated with a compact optical antenna enhancing light collection from the sources. The hybrid device yields average saturation count rates of ≈2.9 × 106 cps and an average photon purity of g(2)(0) ≈ 0.1. The results advance the understanding of single photon emitter incorporation during chemical vapor deposition growth and demonstrate a key step towards compact devices for achieving maximum collection efficiency.

Published
2020

14. Quantum emitters in two-dimensional hexagonal boron nitride

Author

Xu, ZQ, Li, C, Mendelson, N, Aharonovich, I, Toth, M, Xu, ZQ, Li, C, Mendelson, N, Aharonovich, I, and Toth, M

Abstract

Quantum emitters (QEs) in hexagonal boron nitride (hBN) are critical components with potential applications in quantum technologies. This talk will review our recent study on fabrication, modulation of QEs in 2D hBN and integration to photonics resonators.

Published
2020

15. Identifying Carbon as the Source of Visible Single Photon Emission from Hexagonal Boron Nitride

Author

Mendelson, N, Chugh, D, Reimers, JR, Cheng, TS, Gottscholl, A, Long, H, Mellor, CJ, Zettl, A, Dyakonov, V, Beton, PH, Novikov, SV, Jagadish, C, Tan, HH, Ford, MJ, Toth, M, Bradac, C, Aharonovich, I, Mendelson, N, Chugh, D, Reimers, JR, Cheng, TS, Gottscholl, A, Long, H, Mellor, CJ, Zettl, A, Dyakonov, V, Beton, PH, Novikov, SV, Jagadish, C, Tan, HH, Ford, MJ, Toth, M, Bradac, C, and Aharonovich, I

Published
2020

16. Strain-Induced Modification of the Optical Characteristics of Quantum Emitters in Hexagonal Boron Nitride.

Author

Mendelson, N, Doherty, M, Toth, M, Aharonovich, I, Tran, TT, Mendelson, N, Doherty, M, Toth, M, Aharonovich, I, and Tran, TT

Abstract

Quantum emitters in hexagonal boron nitride (hBN) are promising building blocks for the realization of integrated quantum photonic systems. However, their spectral inhomogeneity currently limits their potential applications. Here, tensile strain is applied to quantum emitters embedded in few-layer hBN films and both red and blue spectral shifts are realized with tuning magnitudes up to 65 meV, a record for any 2D quantum source. Reversible tuning of the emission and related photophysical properties is demonstrated. Rotation of the optical dipole in response to strain is also observed, suggesting the presence of a second excited state. A theoretical model is derived to describe strain-based tuning in hBN, and the rotation of the optical dipole. The study demonstrates the immense potential for strain tuning of quantum emitters in layered materials to enable their employment in scalable quantum photonic networks.

Published
2020

17. Photodynamics and quantum efficiency of germanium vacancy color centers in diamond

Author

Nguyen, M, Nikolay, N, Bradac, C, Kianinia, M, Ekimov, EA, Mendelson, N, Benson, O, Aharonovich, I, Nguyen, M, Nikolay, N, Bradac, C, Kianinia, M, Ekimov, EA, Mendelson, N, Benson, O, and Aharonovich, I

Abstract

Color centers in diamond-especially group IV defects-have been advanced as a viable solid-state platform for quantum photonics and information technologies. We investigate the photodynamics and characteristics of germanium-vacancy (GeV) centers hosted in high-pressure high-temperature diamond nanocrystals. Through back-focal plane imaging, we analyze the far-field radiation pattern of the investigated emitters and derive a crossed-dipole emission, which is strongly aligned along one axis. We use this information in combination with lifetime measurements to extract the decay rate statistics of the GeV emitters and determine their quantum efficiency, which we estimated to be ∼ (22 ± 2) %. Our results offer further insight into the photodynamic properties of the GeV center in nanodiamonds and confirm its suitability as a desirable system for quantum technologies.

Published
2019

18. Direct measurement of quantum efficiency of single-photon emitters in hexagonal boron nitride

Author

Nikolay, N, Mendelson, N, Özelci, E, Sontheimer, B, Böhm, F, Kewes, G, Toth, M, Aharonovich, I, Benson, O, Nikolay, N, Mendelson, N, Özelci, E, Sontheimer, B, Böhm, F, Kewes, G, Toth, M, Aharonovich, I, and Benson, O

Abstract

© 2019 Optical Society of America. Single-photon emitters (SPEs) in two-dimensional materials are promising candidates for the future generation of quantum photonic technologies. In this work, we experimentally determine the quantum efficiency (QE) of SPEs in few-layer hexagonal boron nitride (h-BN). We employ a metal hemisphere that is attached to the tip of an atomic force microscope to directly measure the lifetime variation of the SPEs as the tip approaches the h-BN. This technique enables nondestructive, yet direct and absolute measurement of the QE of SPEs. We find that the emitters exhibit very high QEs approaching (87 ± 7)% at wavelengths of ≈580 nm, which is among the highest QEs recorded for a solid-state SPE.

Published
2019

19. Purification of single-photon emission from hBN using post-processing treatments

Author

Li, C, Xu, ZQ, Mendelson, N, Kianinia, M, Toth, M, Aharonovich, I, Li, C, Xu, ZQ, Mendelson, N, Kianinia, M, Toth, M, and Aharonovich, I

Abstract

© 2019 Zai-Quan Xu, Igor Aharonovich et al., published by De Gruyter 2019. Single-photon emitters (SPEs) in hexagonal boron nitride (hBN) are promising components for on-chip quantum information processing. Recently, large-area hBN films prepared by chemical vapor deposition (CVD) were found to host uniform, high densities of SPEs. However, the purity of these emitters has, to date, been low, hindering their applications in practical devices. In this work, we present two methods for post-growth processing of hBN, which significantly improve SPEs in hBN films that had been transferred from substrates used for CVD. The emitters exhibit high photon purities in excess of 90% and narrow linewidths of ~3 nm at room temperature. Our work lays a foundation for producing high-quality emitters in an ultra-compact two-dimensional material system and paves the way for deployment of hBN SPEs in scalable on-chip photonic and quantum devices.

Published
2019

20. Integrated on Chip Platform with Quantum Emitters in Layered Materials

Author

Kim, S, Duong, NMH, Nguyen, M, Lu, TJ, Kianinia, M, Mendelson, N, Solntsev, A, Bradac, C, Englund, DR, Aharonovich, I, Kim, S, Duong, NMH, Nguyen, M, Lu, TJ, Kianinia, M, Mendelson, N, Solntsev, A, Bradac, C, Englund, DR, and Aharonovich, I

Abstract

© 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim Integrated quantum photonic circuitry is an emerging topic that requires efficient coupling of quantum light sources to waveguides and optical resonators. So far, great effort is devoted to engineering on-chip systems from 3D crystals such as diamond or gallium arsenide. In this study, room-temperature coupling is demonstrated of quantum emitters embedded in layered hexagonal boron nitride to an on-chip aluminum nitride waveguide. 1.35% light coupling efficiency is achieved in the device and transmission of single photons through the waveguide is demonstrated. The results serve as foundation for integrating layered materials to on-chip components and realizing integrated quantum photonic circuitry.

Published
2019

21. Selective Defect Formation in Hexagonal Boron Nitride

Author

Abidi, IH, Mendelson, N, Tran, TT, Tyagi, A, Zhuang, M, Weng, LT, Özyilmaz, B, Aharonovich, I, Toth, M, Luo, Z, Abidi, IH, Mendelson, N, Tran, TT, Tyagi, A, Zhuang, M, Weng, LT, Özyilmaz, B, Aharonovich, I, Toth, M, and Luo, Z

Abstract

© 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim Luminescent defects in hexagonal boron nitride (hBN) have emerged as promising single photon emitters (SPEs) due to their high brightness and robust operation at room temperature. The ability to create such emitters with well-defined optical properties is a cornerstone toward their integration into on-chip photonic architectures. Here, an effective approach is reported to fabricate hBN SPEs with desired emission properties in distinct spectral regions via the manipulation of boron diffusion through copper during atmospheric pressure chemical vapor deposition (CVD)—a process termed gettering. Using the gettering technique the resulting zero-phonon line is deterministically placed between the regions 550 and 600 nm or from 600 to 650 nm, paving the way for hBN SPEs with tailored emission properties. Additionally, rational control over the observed SPE density in the resulting films is demonstrated. The ability to control defect formation during hBN growth provides a cost effective means to improve the crystallinity of CVD hBN films, and lower defect density making it applicable to hBN growth for a wide-range of applications. The results are important to understand defect formation of quantum emitters in hBN and deploy them for scalable photonic technologies.

Published
2019

22. Very Large and Reversible Stark-Shift Tuning of Single Emitters in Layered Hexagonal Boron Nitride

Author

Nikolay, N, Mendelson, N, Sadzak, N, Böhm, F, Tran, TT, Sontheimer, B, Aharonovich, I, Benson, O, Nikolay, N, Mendelson, N, Sadzak, N, Böhm, F, Tran, TT, Sontheimer, B, Aharonovich, I, and Benson, O

Abstract

© 2019 American Physical Society. Combining solid-state single-photon emitters (SPEs) with nanophotonic platforms is a key goal in integrated quantum photonics. In order to realize functionality in potentially scalable elements, suitable SPEs have to be bright, stable, and widely tunable at room temperature. In this work, we show that selected SPEs embedded in a few-layer hexagonal boron nitride (h-BN) meet these demands. In order to show the wide tunability of these SPEs we employ an atomic force microscope (AFM) with a conductive tip to apply an electrostatic field to individual h-BN emitters sandwiched between the tip and an indium-tin-oxide-coated glass slide. A very large and reversible Stark shift of (5.5±0.3)nm at a zero-field wavelength of 670 nm is induced by applying just 20 V, which exceeds the typical resonance linewidths of nanodielectric and even nanoplasmonic resonators. Our results help to further understand the physical origin of SPEs in h-BN as well as for practical quantum photonic applications where wide spectral tuning and on/off resonance switching are required.

Published
2019

34. Regulation of Bacillus subtilis macrofiber twist development by D-alanine

Author

Surana, U, Wolfe, A J, and Mendelson, N H

Subjects
Alanine, Chloramphenicol, Ammonium Sulfate, Cell Wall, Temperature, Molecular Biology, Microbiology, Research Article, Bacillus subtilis, Culture Media
Abstract

Twist states of Bacillus subtilis macrofibers were found to vary as a function of the concentration of D-alanine in the medium during growth. L-Alanine in the same concentration range had no effect. Increasing concentrations of D-alanine resulted in structures progressively more right-handed (or less left-handed). All strains examined in this study, including mutants fixed in the left-hand domain as a function of temperature, responded to D-alanine in the same way. All twist states from tight left- to tight right-handedness could be achieved solely by varying the D-alanine concentration. The D-alanine-requiring macrofiber strain 2C8, which carries a genetic defect (dal-1) in the alanine racemase, behaved in a similar fashion. The combined effects of D-alanine and ammonium sulfate (a factor known to influence macrofiber twist development in the leftward direction) were examined by using both strains able to undergo temperature-induced helix hand inversion and others incapable of doing so. In all cases, the effects of D-alanine predominated. A synergism was found in which increasing the concentration of ammonium sulfate in the presence of D-alanine enhanced the right-factor activity of the latter. A D-alanine pulse protocol provided evidence that structures undergo a transient inversion indicative of "memory." Chloramphenicol treatment inhibited the establishment of memory in the D-alanine-induced right to left inversion, supporting the existence of a "left twist protein(s)" that is required for the attainment of left-handed twist states. Chemical analysis of cell walls obtained from right- and left-handed macrofibers produced in the presence and absence of D-alanine, respectively, failed to reveal twist state-specific differences in the overall composition of either peptidoglycan or wall teichoic acids.

Published
1988

36. Helical growth of Bacillus subtilis: a new model of cell growth.

Author

Mendelson, N H

Abstract

A multiple mutant of Bacillus subtilis that grows in an unusual double-helix morphology was studied. Construction of models led to the assumption that cell surface elongation must proceed in a helical path in this mutant. The observation that all newly formed double-helix clones propagated, after spore outgrowth in fluid culture, consisted of closed-circular structures suggested that double-helix structures are tension-registered forms.

Published
1976
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37. Use of Bacillus subtilis minicells to demonstrate an antigenic relationship between the poles and lateral cylindrical regions of rod-shaped cells

Author

Coyne, S I and Mendelson, N H

Abstract

Purified minicells produced by Bacillus subtilis div IV-B1 mutants were used to immunize rabbits. Immune serum was obtained that agglutinated minicells and was able to form precipitin lines when reacted with minicell antigens in double-diffusion or immunoelectrophoretic procedures. Antiminicell serum agglutinated rod-shaped B. subtilis cells to long filaments produced by growth of a cell division-defective mutant at restrictive temperature. These findings indicate that minicells are immunogens capable of eliciting the production of antibodies that cross-react with the lateral, cylindrical regions of B. subtilis rods. It appears, therefore, that poles share a common antigen(s) with cylindrical regions of the cell.

Published
1975
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38. Cellular organization of Bacillus subtilis: sodium dodecyl sulfate-induced cell partitioning into zebra structures

Author

Mendelson, N H, Haag, S M, and Cole, R M

Abstract

Cells of Bacillus subtilis heated in high concentrations of sodium dodecyl sulfate (5%) and then washed free of detergent with a hot salt solution (80 C) become structurally reorganized into regions of densely compacted cytoplasm (termed zebras) and regions of sparsely filled material (termed spaces). Size distribution studies of zebras indicate that division-suppressed mutants and wild-type cells both yield zebras of comparable length. Similarly the lengths of zebras found in populations emerging from spores are uniform in one-, two-, three-, and four-zebra-containing cells. In contrast, the length of spaces is slightly larger than that of zebras and is unusually large in two-zebra-containing cells. The locations of zebras and spaces along cell length have been studied in spore out-growth populations. A statistical procedure developed previously in genome location investigations was used to analyze the location of zebras along cell length. The data indicate that as cells elongate, new sites arise where the cell contents are strongly bound to the cell surface. Within filament populations produced by division-suppressed mutants there is a linear relationship of mean filament length and zebra number per filament. These data indicate that cytoplasm in filaments with no obvious structural compartmentalizations may be organized into units associated with particular regions of cell surface. The attachment of cell contents to the cell surface may involve deoxyribonucleic acid. Zebra-containing cells digested with proteolytic enzyme and ribonuclease are converted to cells that contain a crystalline-like granule fixed at the location of each zebra. Exposure to deoxyribonuclease mobilizes these granules within the cell wall.

Published
1976
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39. Brittle Bacteria:  A Biomimetic Approach to the Formation of Fibrous Composite Materials

Author

Davis, S. A., Mayes, E. L., Patel, H. M., Mendelson, N. H., Franco, G., and Mann, S.

Abstract

Organized bacterial superstructures have been used as 3-D templates for the fabrication of ordered inorganic−organic fibrous composites. Preformed magnetic (Fe3O4) and semiconducting (CdS) inorganic nanoparticles were incorporated into macroscopic threads of Bacillus subtilis by reversible swelling of the superstructure in colloidal sols. The air-dried mineralized fibers consisted of a closely packed array of 0.5 μm diameter multicellular bacterial filaments, each of which was coated with a 30−70 nm thick layer of aggregated colloidal particles. Inorganic patterning of the interfilament spaces was influenced by the surface charge of the nanoparticles used. Whereas negatively charged magnetite colloids gave good infiltration and replication of the bacterial superstructure, the neutral-ligand-capped CdS colloid, although internalized to some extent, was preferentially localized at the surface of the thread. Positively charged sols of TiO2, in contrast, did not penetrate the swollen fiber but produced coherent surface coatings of uniform thickness. Attempts to pattern the deposition of CdS using molecular precursors by exposing a Cd(II)-containing bacterial fiber to H2S gas produced an uneven surface coat of CdS particles. Removal of the bacterial component from the magnetic composite by heating at elevated temperatures resulted in structural collapse.

Published
1998

41. Biomechanics of bacterial walls: studies of bacterial thread made from Bacillus subtilis.

Author

Thwaites, J J and Mendelson, N H

Abstract

Bacterial threads of up to 1 m in length have been produced from filaments of separation-suppressed mutants of Bacillus subtilis. Individual threads may contain 20,000 cellular filaments in parallel alignment. The tensile properties of bacterial threads have been examined by using conventional textile engineering techniques. The kinetics of elongation at constant load are indicative of a viscoelastic material. Both Young's modulus and breaking stress are highly dependent upon relative humidity. By extrapolation to 100% relative humidity, it appears that cell walls may be able to bear only internal osmotic pressures of about 2 atmospheres (2.03 X 105(5) Pa) in living cells. Similarly, the strength of wall material limits the amount of cell-surface charge permissible to only a small fraction of that known to be carried by the negatively charged wall polymers.

Published
1985
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42. Cell wall mechanical properties as measured with bacterial thread made from Bacillus subtilis

Author

Mendelson, N H and Thwaites, J J

Abstract

Engineering approaches used in the study of textile fibers have been applied to the measurement of mechanical properties of bacterial cell walls by using the Bacillus subtilis bacterial thread system. Improved methods have been developed for the production of thread and for measuring its mechanical properties. The best specimens of thread produced from cultures of strain FJ7 grown in TB medium at 20 degrees C varied in diameter by a factor of 1.09 over a 30-mm thread length. The stress-strain behavior of cell walls was determined over the range of relative humidities between 11 and 98%. Measurements of over 125 specimens indicated that cell wall behaved like other viscoelastic polymers, both natural and man-made, exhibiting relaxation under constant elongation and recovery upon load removal. This kinetic behavior and also the cell wall strength depended greatly on humidity. The recovery from extension observed after loading even up to a substantial fraction of the breaking load indicated that the properties measured were those of cell wall material rather than of behavior of the thread assemblage. Control experiments showed that neither drying of thread nor the length of time it remained dry before testing influenced the mechanical properties of the cell walls. Specimens drawn from TB medium and then washed in water and redrawn were found to be stiffer and stronger than controls not washed. However, tensile properties were not changed by exposure of cells to lysozyme before thread production. This suggests that glycan backbones are not arranged along the length of the cell cylinder. The strength of the cell wall in vivo was estimated by extrapolation to 100% relative humidity to be about 3 N/mm2. Walls of this strength would be able to bear a turgor pressure of 6 atm (ca. 607.8 kPa), but if the increase in strength of water-washed threads was appropriate, the figure could be 24 atm (ca. 2,431.2 kPa).

Published
1989
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43. Regulation of Bacillus subtilis macrofiber twist development by D-cycloserine

Author

Mendelson, N H

Abstract

The effect of D-cycloserine on the establishment of twist states in Bacillus subtilis macrofibers was examined. Macrofibers produced in the presence of the drug differed in twist compared with those produced in its absence. The degree of twist alteration was dependent on the concentration of D-cycloserine in the growth medium. Macrofibers of different twist states representative of the entire twist spectrum from tight left-handedness to tight right-handedness were produced in strains FJ7 and C6D in four different ways: by control of the concentration of D-alanine, magnesium sulfate, or ammonium sulfate in the growth medium or by control of the growth temperature. The structures so produced were used to determine the effect of D-cycloserine on twist establishment starting from different twist states throughout the twist spectrum. In all but one case, twist resulting from growth in the presence of D-cycloserine was further towards the left-hand end of the twist spectrum than that produced in its absence, the exception being the unusual left-handed twist states produced in strains C6D and the closely related RHX 11S at high D-alanine concentrations described here. Studies of the interaction between D-cycloserine and D-alanine both used alone and used independently with the other twist-modifying systems (temperature, magnesium sulfate, and ammonium sulfate) revealed that changes in twist resulting from D-cycloserine were always in the opposite direction from those resulting from D-alanine. This antagonism suggests that the biochemical mechanism of twist regulation involves the metabolism of peptidoglycan, particularly reactions involving D-alanine or the dipeptide D-alanyl-D-alanine. This antagonism suggests that the biochemical mechanism of twist regulation involves the metabolism of peptidoglycan, particularly reactions involving D-alanine or the dipeptide D-alanyl-D-alanine. The possibility that peptidoglycan cross-linking is involved is discussed.

Published
1988
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44. Regulation of Bacillus subtilis macrofiber twist development by ions: effects of magnesium and ammonium

Author

Mendelson, N H and Favre, D

Abstract

The steady-state twist of Bacillus subtilis macrofibers produced by growth in complex medium was found to vary as a function of the magnesium and ammonium concentrations. Four categories of macrofiber-producing strains that differed in their response to temperature regulation of twist were studied. Macrofibers were cultured in the complex medium TB used in previous experiments and in two derivative media, T (consisting of Bacto Tryptose), in which most strains produced left-handed structures, and Be (consisting of Bacto Beef Extract), in which right-handed macrofibers arose. In nearly all cases, increasing concentrations of magnesium led to the production of macrofibers with greater right-handed twist. Some strains unable to form right-handed structures as a function of temperature could be made to do so by the addition of magnesium. Inversion from right- to left-handedness in strain FJ7 induced by temperature shift-up was blocked by the addition of magnesium. The presence of magnesium during a high-temperature pulse did not block the establishment of "memory," although it delayed the initiation of the transient inversion following return to low temperature. The twist state of macrofibers grown without a magnesium supplement was not instantaneously affected by the addition of magnesium. Such fibers were, however, protected from lysozyme attack and associated relaxation motions. Lysozyme degradation of purified cell walls (both intact and lacking teichoic acid) was also blocked by the addition of magnesium. Ammonium ions influenced macrofiber twist development towards the left-hand end of the twist spectrum. Macrofiber twist produced in mixtures of magnesium and ammonium was strain and medium dependent.(ABSTRACT TRUNCATED AT 250 WORDS)

Published
1987
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45. Helical macrofiber formation in Bacillus subtilis: inhibition by penicillin G

Author

Zaritsky, A and Mendelson, N H

Abstract

The folding process required for helical macrofiber formation after the outgrowth of Bacillus subtilis spores was found to be blocked by very low concentrations of penicillin G (1 to 3 ng/ml). Under such conditions, growth and septation without cell separation resulted in characteristic disorganized multicellular structures. Higher concentrations (4 and 10 ng/ml) were needed to inhibit spore outgrowth and vegetative growth, respectively.

Published
1984
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46. Characterization of nutrition-induced helix hand inversion of Bacillus subtilis macrofibers

Author

Wolfe, A J and Mendelson, N H

Abstract

The kinetics of Bacillus subtilis macrofiber helix hand inversion was examined. Inversion was induced by transfer of structures produced in one medium to another medium. When cultured at 20 degrees C in either medium, the doubling time was approximately 100 min. To establish a baseline, the macrofiber twist state produced in one medium was measured over the same time course during which other macrofibers underwent inversion after transfer to a second medium. The baseline was used to identify the time of inversion initiation: the point at which curves representing changes of twist as a function of time after transfer to the new medium intersected the baseline. Right- and left-handed macrofibers of different twists were produced by growth in mixtures of TB and S1 media. These were used to determine the influence of initial twist on the time course of inversion initiation. In the right to left inversion, a positive correlation was found between initial twist and the time of inversion initiation. The left to right inversion differed, however, in that a constant time was required for inversion initiation regardless of the starting left-handed twist. When a nutritional pulse was administered by transferring fibers from TB to S1 to TB medium, the time to initiation of inversion was found to decrease with incubation of increasing duration in S1 medium. A similar pulse protocol was used in conjunction with inhibitors to examine the protein and peptidoglycan synthesis requirements for the establishment of nutrition-induced memory that leads to initiation of inversion. Nutritionally induced right to left inversion but not left to right inversion required protein synthesis. The addition of trypsin to left-handed macrofibers apparently required, as described previously for the temperature-regulated twist system (D. Favre, D. Karamata, and N. H. Mendelson, J. Bacteriol. 164:1141-1145, 1985), for the production of left-handed twist states in the nutrition system.

Published
1987
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47. Morphological and genetic characterization of a bacteriophage-resistant Bacillus subtilis macrofiber-producing strain

Author

Saxe, C L and Mendelson, N H

Abstract

Bacillus subtilis C6 phi R4 is an SPO1-resistant derivative of strain C6D, a left-hand macrofiber-producing strain described previously (N. H. Mendelson, Proc. Natl. Acad. Sci. U.S.A. 75:2478-2482, 1978). In addition to the phage resistance property, strain C6 phi R4 differs from its parent in macrofiber organization and formation of aggregates in liquid shake cultures. The phage resistance mutation was located in the gtaC gene. The macrofiber organization and aggregation phenotypes also appear to be controlled by the gtaC locus. Strains constructed by introduction of the gtaC mutation into C6D appear to be identical to the original C6 phi R4 strain in all phenotypic properties. In contrast, other constructs carrying either gtaA or gtaB that are resistant to SPO1 do not display the characteristic C6 phi R4 morphological phenotypes.

Published
1984
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48. Cell division suppression in the Bacillus subtilis div IC-A1 minicell-producing mutant

Author

Mendelson, N H

Abstract

Growth and division patterns of Bacillus subtilis wild-type (div IV-A1+) and minicell-producing mutant (div IV-A1) clones were studied after spore germination during microcolony development in chambers that facilitate continuous observation with a phase contrast microscope. Data obtained from 13 div IV-A1+ clones were used to derive the equation DE equals [(mum minus 17.6)/8.8], which expresses the relationship of cell divisions present in clones of various lengths. This equation was used to determine the number of divisions expected in div IV-A1 clones if the mutant clones were able to divide as often as wild-type clones. The observed number of divisions present in mutant clones was found to be only 25.27% of the number expected on the basis of this equation. Although individual div IV-A1 clones varied in the percentage of division equivalents expressed, there appeared to be no correlation between the overall clone growth rate and the number of divisions expressed. Culturing div IV-A1+ and div IV-A1 clones together in the same growth chamber revealed that there were no diffusible interactions influencing the division phenotypes of either mutant or wild-type cells. At later stages of growth, mixed microcolonies containing cells of both genotypes were formed. A length analysis of individual cells in these populations indicated that the relative division suppression of mutant compared with wild-type cells characteristic of the initial stages of clone development was maintained. It is likely, therefore, that the excessive length of minicell-producing cells (div IV-A1) is a reflection primarily of division suppression in the mutant and not simply of mislocation of division along cell length.

Published
1975
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49. Sol−Gel Synthesis of Organized Matter

Author

Mann, S., Burkett, S. L., Davis, S. A., Fowler, C. E., Mendelson, N. H., Sims, S. D., Walsh, D., and Whilton, N. T.

Abstract

In this review, we describe four approaches to the materials synthesis of organized inorganic matter. These include the use of self-assembled organic templates (transcriptive synthesis), cooperative assemblies of templates and building blocks (synergistic synthesis), spatially restricted reaction fields (morphosynthesis), and combinations of these approaches (integrative synthesis) in the area of sol−gel chemistry. We illustrate these strategies, respectively, by describing recent work on the formation of silica-based organized materials, viz. the preparation of ordered silica macrostructures using bacterial templates, template-directed synthesis of ordered hybrid mesophases and organoclays, synthesis of microskeletal frameworks of silica and other metal oxides in compartmentalized liquids, and use of bacterial superstructures in the fabrication of hierarchical macrostructures of mesoscopically ordered silica.

Published
1997

50. Twisted states of Bacillus subtilis macrofibers reflect structural states of the cell wall.

Author

Mendelson, N H, Favre, D, and Thwaites, J J

Abstract

Static and dynamic studies of helical Bacillus subtilis macrofibers reveal that a spectrum of twisted states exists ranging from tight left-handed structures with twist equal to approximately equal to 40 left turns per mm to tight right-handed structures with twist equal to 57 right turns per mm. In the lytic-deficient strain FJ7 , twist varies as a function of growth temperature above or below 39 degrees C, where there is zero twist. The relationship between the temperature (below 39 degrees C) at which right-hand structures are produced to the time it takes for them to begin the inversion process in which they become left-handed following transfer to 48 degrees C reveals that structures with less twist are more rapidly converted to left-handedness than are those with higher values of twist. The initial response of live macrofibers to digestion by lysozyme consists of "relaxation" motions in which the twist of both left- and right-handed structures changes towards the right-hand end of the spectrum. The rate of relaxation is approximately equal to 5-fold higher at the left-hand end than at the right-hand end. These findings suggest that cell wall polymers can assume a range of structural states during helical growth and that these determine the quantitative aspects of macrofiber shape as well as the sensitivity of walls to attack by lysozyme.

Published
1984
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