Your search keyword '"Sánchez, Ana M."' showing total 19 results

1. Flux-periodic supercurrent oscillations in an Aharonov-Bohm-type nanowire Josephson junction

Author

Zellekens, Patrick, Deacon, Russell S., Basaric, Farah, Juluri, Raghavendra, Randle, Michael D., Bennemann, Benjamin, Krause, Christoph, Zimmermann, Erik, Sanchez, Ana M., Grützmacher, Detlev, Pawlis, Alexander, Ishibashi, Koji, and Schäpers, Thomas

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity

Abstract

Phase winding effects in hollow semiconductor nanowires with superconducting shells have been proposed as a route to engineer topological superconducting states. We investigate GaAs/InAs core/shell nanowires with half-shells of epitaxial aluminium as a potential platform for such devices, where the thin InAs shell confines the electron wave function around the GaAs core. With normal contacts we observed pronounced $h/e$ flux periodic oscillations in the magnetoconductance, indicating the presence of a tubular conductive channel in the InAs shell. Conversely, the switching current in Josephson junctions oscillates with approximately half that period, i.e. $h/2e$, indicating transport via Andreev transport processes in the junction enclosing threading magnetic flux. On these structures, we systematically studied the gate-, field-, and temperature-dependent evolution of the supercurrent. Results indicate that Andreev transport processes can occur about the wire circumference indicating full proximitization of the InAs shell from the half-shell superconducting contacts., Comment: 13 pages, 6 figures

Published

2024

2. Teranga Go!: Carpooling Collaborative Consumption Community with multi-criteria hesitant fuzzy linguistic term set opinions to build confidence and trust

Author

Montes, Rosana, Sanchez, Ana M., Villar, Pedro, and Herrera, Francisco

Subjects

Computer Science - Computers and Society, Computer Science - Artificial Intelligence

Abstract

Classic Delphi and Fuzzy Delphi methods are used to test content validity of a data collection tools such as questionnaires. Fuzzy Delphi takes the opinion issued by judges from a linguistic perspective reducing ambiguity in opinions by using fuzzy numbers. We propose an extension named 2-Tuple Fuzzy Linguistic Delphi method to deal with scenarios in which judges show different expertise degrees by using fuzzy multigranular semantics of the linguistic terms and to obtain intermediate and final results expressed by 2-tuple linguistic values. The key idea of our proposal is to validate the full questionnaire by means of the evaluation of its parts, defining the validity of each item as a Decision Making problem. Taking the opinion of experts, we measure the degree of consensus, the degree of consistency, and the linguistic score of each item, in order to detect those items that affect, positively or negatively, the quality of the instrument. Considering the real need to evaluate a b-learning educational experience with a consensual questionnaire, we present a Decision Making model for questionnaire validation that solve it. Additionally, we contribute to this consensus reaching problem by developing an online tool under GPL v3 license. The software visualizes the collective valuations for each iteration and assists to determine which parts of the questionnaire should be modified to reach a consensual solution., Comment: project at https://github.com/rosanamontes/teranga.go. arXiv admin note: substantial text overlap with arXiv:2402.01775

Published

2024

3. Bi Incorporation and segregation in the MBE-grown GaAs-(Ga,Al)As-Ga(As,Bi) core-shell nanowires

Author

Sadowski, Janusz, Kaleta, Anna, Kryvyi, Serhii, Janaszko, Dorota, Kurowska, Bogusława, Bilska, Marta, Wojciechowski, Tomasz, Domagala, Jarosław Z., Sanchez, Ana M., and Kret, Sławomir

Subjects

Condensed Matter - Materials Science

Abstract

Incorporation of Bi into GaAs-(Ga,Al)As-Ga(As,Bi) core-shell nanowires grown by molecular beam epitaxy is studied with transmission electron microscopy. Nanowires are grown on GaAs(111)B substrates with Au-droplet assisted mode. Bi-doped shells are grown at low temperature (300 {\deg}C) with a close to stoichiometric Ga/As flux ratio. At low Bi fluxes, the Ga(As,Bi) shells are smooth, with Bi completely incorporated into the shells. Higher Bi fluxes (Bi/As flux ratio ~ 4%) led to partial segregation of Bi as droplets on the nanowires sidewalls, preferentially located at the nanowire segments with wurtzite structure. We demonstrate that such Bi droplets on the sidewalls act as catalysts for the growth of branches perpendicular to the GaAs trunks. Due to the tunability between zinc-blende and wurtzite polytypes by changing the nanowire growth conditions, this effect enables fabrication of branched nanowire architectures with branches generated from selected (wurtzite) nanowire segments., Comment: 41 pages, 14 figures

Published

2022

4. Te-doped selective-area grown InAs nanowires for superconducting hybrid devices

Author

Perla, Pujitha, Faustmann, Anton, Koelling, Sebastian, Zellekens, Patrick, Deacon, Russell, Fonseka, H. Aruni, Kölzer, Jonas, Sato, Yuki, Sanchez, Ana M., Moutanabbir, Oussama, Ishibashi, Koji, Grützmacher, Detlev, Lepsa, Mihail Ion, and Schäpers, Thomas

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Semiconductor nanowires have emerged as versatile components in superconducting hybrid devices for Majorana physics and quantum computing. The transport properties of nanowires can be tuned either by field-effect or doping. We investigated a series of InAs nanowires which conductivity has been modified by n-type doping using tellurium. In addition to electron microscopy studies, the wires were also examined with atomic probe tomography to obtain information about the local incorporation of Te atoms. It was found that the Te atoms mainly accumulate in the core of the nanowire and at the corners of the {110} side facets. The efficiency of n-type doping was also confirmed by transport measurements. As a demonstrator hybrid device, a Josephson junction was fabricated using a nanowire as a weak link. The corresponding measurements showed a clear increase of the critical current with increase of the dopant concentration., Comment: 9 pages, 9 figures

Published

2021

5. Thermally-driven formation of Ge quantum dots on self-catalysed thin GaAs nanowires

Author

Zhang, Yunyan, Fonseka, H. Aruni, Yang, Hui, Yu, Xuezhe, Jurczak, Pamela, Huo, Suguo, Sanchez, Ana M., and Liu, Huiyun

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Embedding quantum dots (QDs) on nanowire (NW) sidewalls allows the integration of multi-layers of QDs into the active region of radial p-i-n junctions to greatly enhance light emission/absorption. However, the surface curvature makes the growth much more challenging compared with growths on thin-films, particularly on NWs with small diameters ({\O} <100 nm). Moreover, the {110} sidewall facets of self-catalyzed NWs favor two-dimensional growth (2D), with the realization of three-dimensional (3D) Stranski-Krastanow growth becoming extremely challenging. Here, we demonstrate thermally-driven formation of Ge dots on the {110} sidewalls facets of thin self-catalyzed NWs without using any surfactant or surface treatment. The 2D-3D transition of the pseudomorphic Ge layer grown on GaAs NWs is driven by energy minimization under high-temperature annealing. This method opens a new avenue to integrate QDs on NWs without any restriction on NW diameter or elastic strain, which can allow the formation of QDs in a wider range of materials systems where the growth of islands by traditional mechanisms is not possible, with benefits for novel NWQD-based optoelectronic devices., Comment: 4

Published

2021

6. Robust Protection of III-V Nanowires in Water Splitting by a Thin Compact TiO$_2$ Layer

Author

Cui, Fan, Zhang, Yunyan, Fonseka, H. Aruni, Promdet, Premrudee, Channa, Ali Imran, Wang, Mingqing, Xia, Xueming, Sathasivam, Sanjayan, Liu, Hezhuang, Parkin, Ivan P., Yang, Hui, Li, Ting, Choy, Kwang-Leong, Wu, Jiang, Blackman, Chris, Sanchez, Ana M., and Liu, Huiyun

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Chemical Physics

Abstract

Narrow-bandgap III-V semiconductor nanowires (NWs) with a suitable band structure and strong light-trapping ability are ideal for high-efficiency low-cost solar water-splitting systems. However, due to their nanoscale dimension, they suffer more severe corrosion by the electrolyte solution than the thin-film counterparts. Thus, short-term durability is the major obstacle for using these NWs for practical water splitting applications. Here, we demonstrated for the first time that a thin layer (~7 nm thick) of compact TiO$_2$ deposited by atomic layer deposition can provide robust protection to III-V NWs. The protected GaAs NWs maintain 91.4% of its photoluminescence intensity after 14 months of storage in ambient atmosphere, which suggests the TiO$_2$ layer is pinhole-free. Working as a photocathode for water splitting, they exhibited a 45% larger photocurrent density compared with un-protected counterparts and a high Faraday efficiency of 91%, and can also maintain a record-long highly-stable performance among narrow-bandgap III-V NW photoelectrodes; after 67 hours photoelectrochemical stability test reaction in strong acid electrolyte solution (pH = 1), they show no apparent indication of corrosion, which is in stark contrast to the un-protected NWs that are fully failed after 35-hours. These findings provide an effective way to enhance both stability and performance of III-V NW based photoelectrodes, which are highly important for practical applications in solar-energy-based water splitting systems., Comment: 27 pages, 5 figures

Published

2020

7. Fully in-situ InAs nanowire Josephson junctions by selective-area growth and shadow evaporation

Author

Perla, Pujitha, Fonseka, H. Aruni, Zellekens, Patrick, Deacon, Russell, Han, Yisong, Kölzer, Jonas, Mörstedt, Timm, Bennemann, Benjamin, Ishibashi, Koji, Grützmacher, Detlev, Sanchez, Ana M., Lepsa, Mihail Ion, and Schäpers, Thomas

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Josephson junctions based on InAs semiconducting nanowires and Nb superconducting electrodes are fabricated in-situ by a special shadow evaporation scheme for the superconductor electrode. Compared to other metallic superconductors such as Al, Nb has the advantage of a larger superconducting gap which allows operation at higher temperatures and magnetic fields. Our junctions are fabricated by shadow evaporation of Nb on pairs of InAs nanowires grown selectively on two adjacent tilted Si (111) facets and crossing each other at a small distance. The upper wire relative to the deposition source acts as a shadow mask determining the gap of the superconducting electrodes on the lower nanowire. Electron microscopy measurements show that the fully in-situ fabrication method gives a clean InAs/Nb interface. A clear Josephson supercurrent is observed in the current-voltage characteristics, which can be controlled by a bottom gate. The excess current of 0.68 indicates a high junction transparency. Under microwave radiation, pronounced integer Shapiro steps are observed suggesting a sinusoidal current-phase relation. Owing to the large critical field of Nb, the Josephson supercurrent can be maintained to magnetic fields exceeding 1 T. Our results show that in-situ prepared Nb/InAs nanowire contacts are very interesting candidates for superconducting quantum circuits requiring large magnetic fields., Comment: 9 pages, 6 figures, supplementary information

Published

2020

8. Atomic and electronic structure of two-dimensional Mo(1-x)WxS2 alloys

Author

Xia, Xue, Loh, Siow Mean, Viner, Jacob, Teutsch, Natalie C., Graham, Abigail J., Kandyba, Viktor, Barinov, Alexei, Sanchez, Ana M., Smith, David C., Hine, Nicholas D. M., and Wilson, Neil R.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

Alloying enables engineering of the electronic structure of semiconductors for optoelectronic applications. Due to their similar lattice parameters, the two-dimensional semiconducting transition metal dichalcogenides of the MoWSeS group (MX2 where M= Mo or W and X=S or Se) can be grown as high-quality materials with low defect concentrations. Here we investigate the atomic and electronic structure of Mo(1-x)WxS2 alloys using a combination of high-resolution experimental techniques and simulations. Analysis of the Mo and W atomic positions in these alloys, grown by chemical vapour transport, shows that they are randomly distributed, consistent with Monte Carlo simulations that use interaction energies determined from first-principles calculations. Electronic structure parameters are directly determined from angle resolved photoemission spectroscopy measurements. These show that the spin-orbit splitting at the valence band edge increases linearly with W content from MoS2 to WS2, in agreement with linear-scaling density functional theory (LS-DFT) predictions. The spin-orbit splitting at the conduction band edge is predicted to reduce to zero at intermediate compositions. Despite this, polarisation-resolved photoluminescence spectra on monolayer Mo0.5W0.5S2 show significant circular dichroism, indicating that spin-valley locking is retained. These results demonstrate that alloying is an important tool for controlling the electronic structure of MX2 for spintronic and valleytronic applications., Comment: 16 + 11 pages, 6 + 8 figures

Published

2020

9. Hard-gap spectroscopy in a self-defined mesoscopic InAs/Al nanowire Josephson junction

Author

Zellekens, Patrick, Deacon, Russell, Perla, Pujitha, Fonseka, H. Aruni, Moerstedt, Timm, Hindmarsh, Steven A., Bennemann, Benjamin, Lentz, Florian, Lepsa, Mihail Ion, Sanchez, Ana M., Grützmacher, Detlev, Ishibashi, Koji, and Schäpers, Thomas

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Superconductor/semiconductor-nanowire hybrid structures can serve as versatile building blocks to realize Majorana circuits or superconducting qubits based on quantized levels such as Andreev qubits. For all these applications it is essential that the superconductor-semiconductor interface is as clean as possible. Furthermore, the shape and dimensions of the superconducting electrodes needs to be precisely controlled. We fabricated self-defined InAs/Al core/shell nanowire junctions by a fully in-situ approach, which meet all these criteria. Transmission electron microscopy measurements confirm the sharp and clean interface between the nanowire and the in-situ deposited Al electrodes which were formed by means of shadow evaporation. Furthermore, we report on tunnel spectroscopy, gate and magnetic field-dependent transport measurements. The achievable short junction lengths,the observed hard-gap and the magnetic field robustness make this new hybrid structure very attractive for applications which rely on a precise control of the number of sub-gap states, like Andreev qubits or topological systems., Comment: 9 pages, 6 figures. Inclusion of additional TEM and EDX data

Published

2020

10. Defect-Free Axially-Stacked GaAs/GaAsP Nanowire Quantum Dots with Strong Carrier Confinement

Author

Zhang, Yunyan, Velichko, Anton V., Fonseka, H. Aruni, Parkinson, Patrick, Davis, George, Gott, James A., Aagesen, Martin, Sanchez, Ana M., Mowbray, David, and Liu, Huiyun

Subjects

Physics - Applied Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

Axially-stacked quantum dots (QDs) in nanowires (NWs) have important applications in fabricating nanoscale quantum devices and lasers. Although their performances are very sensitive to crystal quality and structures, there is relatively little study on defect-free growth with Au-free mode and structure optimisation for achiving high performances. Here, we report a detailed study of the first self-catalyzed defect-free axially-stacked deep NWQDs. High structural quality is maintained when 50 GaAs QDs are placed in a single GaAsP NW. The QDs have very sharp interfaces (1.8~3.6 nm) and can be closely stacked with very similar structural properties. They exhibit the deepest carrier confinement (~90 meV) and largest exciton-biexciton splitting (~11 meV) among non-nitride III-V NWQDs, and can maintain good optical properties after being stored in ambient atmosphere for over 6 months due to excellent stability. Our study sets a solid foundation to build high-performance axially-stacked NWQD devices that are compatible with CMOS technologies., Comment: 38 pages, 9 figures, 1 table

Published

2020

11. High yield production of ultrathin fibroid semiconducting nanowire of Ta$_2$Pd$_3$Se$_8$

Author

Liu, Xue, Liu, Sheng, Antipina, Liubov Yu., Zhu, Yibo, Ning, Jinliang, Liu, Jinyu, Yue, Chunlei, Joshy, Abin, Zhu, Yu, Sun, Jianwei, Sanchez, Ana M, Sorokin, Pavel B., Mao, Zhiqiang, Xiong, Qihua, and Wei, Jiang

Subjects

Physics - Applied Physics, Condensed Matter - Materials Science

Abstract

Immediately after the demonstration of the high-quality electronic properties in various two dimensional (2D) van der Waals (vdW) crystals fabricated with mechanical exfoliation, many methods have been reported to explore and control large scale fabrications. Comparing with recent advancements in fabricating 2D atomic layered crystals, large scale production of one dimensional (1D) nanowires with thickness approaching molecular or atomic level still remains stagnant. Here, we demonstrate the high yield production of a 1D vdW material, semiconducting Ta2Pd3Se8 nanowires, by means of liquid-phase exfoliation. The thinnest nanowire we have readily achieved is around 1 nm, corresponding to a bundle of one or two molecular ribbons. Transmission electron microscopy and transport measurements reveal the as-fabricated Ta2Pd3Se8 nanowires exhibit unexpected high crystallinity and chemical stability. Our low frequency Raman spectroscopy reveals clear evidence of the existing of weak inter-ribbon bindings. The fabricated nanowire transistors exhibit high switching performance and promising applications for photodetectors.

Published

2019

12. Quantum oscillation and unusual protection mechanism of the surface state in nonsymmorphic semimetals

Author

Liu, Xue, Yue, Chunlei, Erohin, Sergey V., Zhu, Yanglin, Joshy, Abin, Liu, Jinyu, Sanchez, Ana M, Graf, David, Sorokin, Pavel B., Mao, Zhiqiang, Hu, Jin, and Wei, Jiang

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

In a topological semimetal with Dirac or Weyl points, the bulk edge correspondence principle predicts a gapless edge mode if the essential symmetry is still preserved at the surface. The detection of such topological surface state has been considered as the fingerprint prove for crystals with nontrivial topological bulk band. On the contrary, it has been proposed that even with symmetry broken at the surface, a new surface band can emerge in nonsymmorphic topological semimetals. The symmetry reduction at the surface lifts the bulk band degeneracies, produces an unusual floating surface band with trivial topology. Here, we report quantum transport probing to ZrSiSe thin flakes and reveal transport signatures of this new surface state. Remarkably, though topologically trivial, such a surface band exhibit substantial two dimensional Shubnikov de Haas quantum oscillations with high mobility, which signifies a new protection mechanism and may open applications for surface-related devices.

Published

2019

13. High-Responsivity Photodetection by Self-Catalyzed Phase-Pure P-GaAs Nanowire

Author

Ali, Hassan, Zhang, Yunyan, Tang, Jing, Peng, Kai, Sun, Sibai, Sun, Yue, Song, Feilong, Falak, Attia, Wu, Shiyao, Qian, Chenjiang, Wang, Meng, Zuo, Zhanchun, Jin, Kui-Juan, Sanchez, Ana M., Liu, Huiyun, and Xu, Xiulai

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Applied Physics

Abstract

Defects are detrimental for optoelectronics devices, such as stacking faults can form carrier-transportation barriers, and foreign impurities (Au) with deep-energy levels can form carrier traps and non-radiative recombination centers. Here, we first developed self-catalyzed p-type GaAs nanowires (NWs) with pure zinc blende (ZB) structure, and then fabricated photodetector made by these NWs. Due to absence of stacking faults and suppression of large amount of defects with deep energy levels, the photodetector exhibits room-temperature high photo responsivity of 1.45 x 105 A W^-1 and excellent specific detectivity (D*) up to 1.48 x 10^14 Jones for low-intensity light signal of wavelength 632.8 nm, which outperforms previously reported NW-based photodetectors. These results demonstrate that these self-catalyzed pure-ZB GaAs NWs to be promising candidates for optoelectronics applications., Comment: 22 pages,6 figures

Published

2018

14. Thermal tuners on a Silicon Nitride platform

Author

Pérez, Daniel, Fernández, Juan, Baños, Rocío, Doménech, José David, Sánchez, Ana M., Cirera, Josep M., Mas, Roser, Sánchez, Javier, Durán, Sara, Pardo, Emilio, Domínguez, Carlos, Pastor, Daniel, Capmany, José, and Muñoz, Pascual

Subjects

Physics - Optics

Abstract

In this paper, the design trade-offs for the implementation of small footprint thermal tuners on silicon nitride are presented, and explored through measurements and supporting simulations of a photonic chip based on Mach-Zehnder Interferometers. Firstly, the electrical properties of the tuners are assessed, showing a compromise between compactness and deterioration. Secondly, the different variables involved in the thermal efficiency, switching power and heater dimensions, are analysed. Finally, with focus on exploring the limits of this compact tuners with regards to on chip component density, the thermal-cross talk is also investigated. Tuners with footprint of 270x5 {\mu}m 2 and switching power of 350 mW are reported, with thermal-cross talk, in terms of induced phase change in adjacent devices of less than one order of magnitude at distances over 20 {\mu}m. Paths for the improvement of thermal efficiency, power consumption and resilience of the devices are also outlined

Published

2016

15. Artefacts in geometric phase analysis of compound materials

Author

Petersa, Jonathan J. P., Beanland, Richard, Alexe, Marin, Cockburn, John W., Revin, Dmitry G., Zhang, Shiyong Y., and Sanchez, Ana M.

Subjects

Condensed Matter - Materials Science

Abstract

The geometric phase analysis (GPA) algorithm is known as a robust and straightforward technique that can be used to measure lattice strains in high resolution transmission electron microscope (TEM) images. It is also attractive for analysis of aberration-corrected scanning TEM (ac-STEM) images that resolve every atom column, since it uses Fourier transforms and does not require real-space peak detection and assignment to appropriate sublattices. Here it is demonstrated that in ac-STEM images of compound materials (i.e. with more than one atom per unit cell) an additional phase is present in the Fourier transform. If the structure changes from one area to another in the image (e.g. across an interface), the change in this additional phase will appear as a strain in conventional GPA, even if there is no lattice strain. Strategies to avoid this pitfall are outlined., Comment: 9 pages, 7 figures, Preprint before review, submitted to Ultramicroscopy 7 April 2015

Published

2015

16. Design rules for dislocation filters

Author

Ward, Tom, Sánchez, Ana M., Tang, Mingchu, Wu, Jiang, Liu, Huiyun, Dunstan, David J., and Beanland, Richard

Subjects

Condensed Matter - Materials Science

Abstract

The efficacy of strained layer threading dislocation filter structures in single crystal epitaxial layers is evaluated using numerical modeling for (001) face-centred cubic materials, such as GaAs or Si(1-x)Ge(x), and (0001) hexagonal materials such as GaN. We find that threading dislocation densities decay exponentially as a function of the strain relieved, irrespective of the fraction of threading dislocations that are mobile. Reactions between threading dislocations tend to produce a population that is a balanced mixture of mobile and sessile in (001) cubic materials. In contrast, mobile threading dislocations tend to be lost very rapidly in (0001) GaN, often with little or no reduction in the immobile dislocation density. The capture radius for threading dislocation interactions is estimated to be approx. 40nm using cross section transmission electron microscopy of dislocation filtering structures in GaAs monolithically grown on Si. We find that the minimum threading dislocation density that can be obtained in any given structure is likely to be limited by kinetic effects to approx. 1.0e+04 to 1.0e+05 per square cm., Comment: 18 pages, 9 figures

Published

2014

17. Lateral heterojunctions within monolayer semiconductors

Author

Huang, Chunming, Wu, Sanfeng, Sanchez, Ana M., Peters, Jonathan J. P., Beanland, Richard, Ross, Jason S., Rivera, Pasqual, Yao, Wang, Cobden, David H., and Xu, Xiaodong

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

Heterojunctions between three-dimensional (3D) semiconductors with different bandgaps are the basis of modern light-emitting diodes, diode lasers, and high-speed transistors. Creating analogous heterojunctions between different two-dimensional (2D) semiconductors would enable band engineering within the 2D plane and open up new realms in materials science, device physics and engineering. Here we demonstrate that seamless high-quality in-plane heterojunctions can be grown between the 2D monolayer semiconductors MoSe2 and WSe2. The junctions, grown by lateral hetero-epitaxy using physical vapor transport, are visible in an optical microscope and show enhanced photoluminescence. Atomically resolved transmission electron microscopy reveals that their structure is an undistorted honeycomb lattice in which substitution of one transition metal by another occurs across the interface. The growth of such lateral junctions will allow new device functionalities, such as in-plane transistors and diodes, to be integrated within a single atomically thin layer., Comment: 14 pages manuscript + 12 pages supplementary information

Published

2014

18. III-V quantum light source and cavity-QED on Silicon

Author

Luxmoore, Isaac J., Toro, Romain, Del Pozo-Zamudio, Osvaldo, Wasley, Nicholas A., Chekhovich, Evgeny A., Sanchez, Ana M., Beanland, Richard, Fox, A. Mark, Skolnick, Maurice S., Liu, Huiyun Y., and Tartakovskii, Alexander I.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

Non-classical light sources offer a myriad of possibilities in fundamental science and applications including quantum cryptography and quantum lithography. Single photons can encode quantum information and multi-qubit gates in silica waveguide circuits have been used to demonstrate linear optical quantum computing. Scale-up requires miniaturisation of the waveguide circuit and multiple photon sources. Silicon photonics, driven by the incentive of optical interconnects, is a highly promising platform for the passive components, but integrated light sources are limited by silicon's indirect band-gap. III-V semiconductor quantum-dots, on the other hand, are proven quantum emitters. Here we demonstrate single-photon emission from quantum-dots coupled to photonic crystal nanocavities fabricated from III-V material grown directly on silicon substrates. The high quality of the III-V material and photonic structures is emphasized by observation of the strong-coupling regime. This work opens-up the advantages of silicon photonics to the integration and scale-up of solid-state quantum optical systems.

Published

2012

19. Cubic MnSb: epitaxial growth of a predicted room temperature half-metal

Author

Aldous, James D., Burrows, Christopher W., Sánchez, Ana M., Beanland, Richard, Maskery, Ian, Bradley, Matthew K., Dias, Manuel dos Santos, Staunton, Julie B., and Bell, Gavin R.

Subjects

Condensed Matter - Materials Science

Abstract

Epitaxial films including bulk-like cubic and wurtzite polymorphs of MnSb have been grown by molecular beam epitaxy on GaAs via careful control of the Sb4/Mn flux ratio. Nonzero-temperature density functional theory was used to predict ab initio the spin polarization as a function of reduced magnetization for the half-metals NiMnSb and cubic MnSb. In both cases, half-metallicity is lost at a threshold magnetization reduction, corresponding to a temperature T*< Tc. This threshold is far higher for cubic MnSb compared to NiMnSb and corresponds to T* > 350K, making epitaxial cubic MnSb a promising candidate for room temperature spin injection into semiconductors., Comment: 3 figures

Published

2011