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21 results on '"Greenaway, Mark T."'

2. Universal mobility characteristics of graphene originating from electron/hole scattering by ionised impurities

Author

Gosling, Jonathan H., Makarovsky, Oleg, Wang, Feiran, Cottam, Nathan D, Greenaway, Mark T., Patanè, Amalia, Wildman, Ricky, Tuck, Christopher J., Turyanska, Lyudmila, and Fromhold, T. Mark

Subjects
Condensed Matter - Materials Science, 82
Abstract

Pristine graphene and graphene-based heterostructures exhibit exceptionally high electron mobility and conductance if their surface contains few electron-scattering impurities. Here, we reveal a universal connection between graphene's carrier mobility and the variation of its electrical conductance with carrier density. Our model of graphene conductivity is based on a convolution of carrier density and its uncertainty, which reproduces the observed universality. Taking a single conductance measurement as input, this model accurately predicts the full shape of the conductance versus carrier density curves for a wide range of reported graphene samples. We verify the convolution model by numerically solving the Boltzmann transport equation to analyse in detail the effects of charged impurity scattering on carrier mobility. In this model, we also include optical phonons, which relax high-energy charge carriers for small impurity densities. Our numerical and analytical results both capture the universality observed in experiment and provide a way to estimate all key transport parameters of graphene devices. Our results demonstrate how the carrier mobility can be predicted and controlled, thereby providing insights for engineering the properties of 2D materials and heterostructures., Comment: 20 pages, 4 figures

Published
2020

4. Magnon-assisted tunnelling in van der Waals heterostructures based on CrBr3

Author

Ghazaryan, Davit, Greenaway, Mark T., Wang, Zihao, Guarochico-Moreira, Victor H., Vera-Marun, Ivan J., Yin, Jun, Liao, Yuanxun, Morozov, Serge V., Kristanovski, Oleg, Lichtenstein, Alexander I., Katsnelson, Mikhail I., Withers, Fred, Mishchenko, Artem, Eaves, Laurence, Geim, Andre K., Novoselov, Kostya S., and Misra, Abhishek

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The growing family of two-dimensional (2D) materials that are now available can be used to assemble van der Waals heterostructures with a wide range of properties. Of particular interest are tunnelling heterostructures, which have been used to study the electronic states both in the tunnelling barrier and in the emitter and collector contacts. Recently, 2D ferromagnets have been studied theoretically and experimentally. Here we investigate electron tunnelling through a thin (2-6 layers) ferromagnetic CrBr3 barrier. For devices with non-magnetic barriers, conservation of momentum can be relaxed by phonon-assisted tunnelling or by tunnelling through localised states. In the case of our ferromagnetic barrier the dominant tunnelling mechanisms are the emission of magnons at low temperatures or scattering of electrons on localised magnetic excitations above the Curie temperature. Tunnelling with magnon emission offers the possibility of injecting spin into the collector electrode.

Published
2018
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9. Nondestructive Picosecond Ultrasonic Probing of Intralayer and van der Waals Interlayer Bonding in ?- and ?-In2Se3

Author

Yan, Wenjing, Akimov, Andrey V., Page, Joseph A., Greenaway, Mark T., Balanov, Alexander G., and Kent, Anthony J.

Subjects
Biomaterials, Electrochemistry, Condensed Matter Physics, Electronic, Optical and Magnetic Materials
Abstract

The interplay between the strong intralayer covalent-ionic bonds and the weak interlayer van der Waals (vdW) forces between the neighboring layers of vdW crystals gives rise to unique physical and chemical properties. Here, the intralayer and interlayer bondings in ? and ? polytypes of In2Se3 are studied, a vdW material with potential applications in advanced electronic and optical devices. Picosecond ultrasonic experiments are conducted to probe the sound velocity in the direction perpendicular to the vdW layers. The measured sound velocities are different in ?- and ?-In2Se3, suggesting a significant difference in their elastic properties. Density functional theory and an effective spring model are used to calculate the elastic stiffness of the layer and vdW gap in ?- and ?-In2Se3. The calculated elastic moduli show good agreement with experimental values and reveal the dominant contribution of interlayer atomic bonding to the different elastic properties of the two polytypes. The findings show the power of picosecond ultrasonics for probing the fundamental elastic properties of vdW materials. The data and analysis also provide a reliable description of the intra- and interlayer forces in complex crystal structures, such as the polytype phases of In2Se3.

Published
2021

13. Inter-Flake Quantum Transport of Electrons and Holes in Inkjet-Printed Graphene Devices

Author

Wang, Feiran, Gosling, Jonathan H, Trindade, Gustavo F, Rance, Graham A, Makarovsky, Oleg, Cottam, Nathan D, Kudrynskyi, Zakhar, Balanov, Alexander G, Greenaway, Mark T, Wildman, Ricky D., Hague, Richard, Tuck, Christopher, Fromhold, T. Mark, and Turyanska, Lyudmila

Subjects
percolation dynamics, inkjet printing, field effect transistor, graphene, Monte Carlo simulations
Abstract

© 2020 The Authors. Advanced Functional Materials published by Wiley-VCH GmbH 2D materials have unique structural and electronic properties with potential for transformative device applications. However, such devices are usually bespoke structures made by sequential deposition of exfoliated 2D layers. There is a need for scalable manufacturing techniques capable of producing high-quality large-area devices comprising multiple 2D materials. Additive manufacturing with inks containing 2D material flakes is a promising solution. Inkjet-printed devices incorporating 2D materials have been demonstrated, however there is a need for greater understanding of quantum transport phenomena as well as their structural properties. Experimental and theoretical studies of inkjet-printed graphene structures are presented. Detailed electrical and structural characterization is reported and explained by comparison with transport modeling that include inter-flake quantum tunneling transport and percolation dynamics. The results reveal that the electrical properties are strongly influenced by the flakes packing fraction and by complex meandering electron trajectories, which traverse several printed layers. Controlling these trajectories is essential for printing high-quality devices that exploit the properties of 2D materials. Inkjet-printed graphene is used to make a field effect transistor and Ohmic contacts on an InSe phototransistor. This is the first time that inkjet-printed graphene has successfully replaced single layer graphene as a contact material for 2D metal chalcogenides.

Published
2021

15. Inter‐Flake Quantum Transport of Electrons and Holes in Inkjet‐Printed Graphene Devices

Author

Wang, Feiran, primary, Gosling, Jonathan H., additional, Trindade, Gustavo F., additional, Rance, Graham A., additional, Makarovsky, Oleg, additional, Cottam, Nathan D., additional, Kudrynskyi, Zakhar, additional, Balanov, Alexander G., additional, Greenaway, Mark T., additional, Wildman, Ricky D., additional, Hague, Richard, additional, Tuck, Christopher, additional, Fromhold, T. Mark, additional, and Turyanska, Lyudmila, additional

Published
2020
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16. Nondestructive Picosecond Ultrasonic Probing of Intralayer and van der Waals Interlayer Bonding in α‐ and β‐In2Se3.

Author

Yan, Wenjing, Akimov, Andrey V., Page, Joseph A., Greenaway, Mark T., Balanov, Alexander G., Patanè, Amalia, and Kent, Anthony J.

Subjects
ELASTICITY, ULTRASONICS, DENSITY functional theory, ELASTIC modulus, OPTICAL devices, LAMINATED glass
Abstract

The interplay between the strong intralayer covalent‐ionic bonds and the weak interlayer van der Waals (vdW) forces between the neighboring layers of vdW crystals gives rise to unique physical and chemical properties. Here, the intralayer and interlayer bondings in α and β polytypes of In2Se3 are studied, a vdW material with potential applications in advanced electronic and optical devices. Picosecond ultrasonic experiments are conducted to probe the sound velocity in the direction perpendicular to the vdW layers. The measured sound velocities are different in α‐ and β‐In2Se3, suggesting a significant difference in their elastic properties. Density functional theory and an effective spring model are used to calculate the elastic stiffness of the layer and vdW gap in α‐ and β‐In2Se3. The calculated elastic moduli show good agreement with experimental values and reveal the dominant contribution of interlayer atomic bonding to the different elastic properties of the two polytypes. The findings show the power of picosecond ultrasonics for probing the fundamental elastic properties of vdW materials. The data and analysis also provide a reliable description of the intra‐ and interlayer forces in complex crystal structures, such as the polytype phases of In2Se3. [ABSTRACT FROM AUTHOR]

Published
2021
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17. Tunnel spectroscopy of localised electronic states in hexagonal boron nitride

Author

Greenaway, Mark T., Vdovin, E. E., Ghazaryan, Davit, Misra, Abhishek, Mishchenko, Artem, Cao, Yang, Wang, Zihao, Wallbank, John, Holwill, Matthew, Morozov, Sergey, Patane, Amalia, Geim, Andre, Fal'ko, Vladimir, Novoselov, Konstantin, and Eaves, Laurence

Subjects
National Graphene Institute, ResearchInstitutes_Networks_Beacons/national_graphene_institute, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect
Abstract

Hexagonal boron nitride is a large band gap layered crystal, frequently incorporated in van der Waals heterostructures as an insulating or tunnel barrier. Localised states with energies within its band gap can emit visible light, relevant to applications in nanophotonics and quantum information processing. However, they also give rise to conducting channels, which can induce electrical breakdown when a large voltage is applied. Here we use gated tunnel transistors to study resonant electron tunnelling through the localised states in few atomic-layer boron nitride barriers sandwiched between two monolayer graphene electrodes. The measurements are used to determine the energy, linewidth, tunnelling transmission probability, and depth within the barrier of more than 50 distinct localised states. A three-step process of electron percolation through two spatially separated localised states is also investigated.

Published
2018
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19. Magnetic-field-induced miniband conduction in semiconductor superlattices

Author

Fowler, Daivid, primary, Hardwick, David P. A., additional, Patanè, Amalia, additional, Greenaway, Mark T., additional, Balanov, Alexander G., additional, Fromhold, Timothy M., additional, Eaves, Laurence, additional, Henini, Mohamed, additional, Kozlova, Nadezda, additional, Freudenberger, Jens, additional, and Mori, Nobuya, additional

Published
2007
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21. Nondestructive Picosecond Ultrasonic Probing of Intralayer and van der Waals Interlayer Bonding in α‐ and β‐In2Se3.

Author

Yan, Wenjing, Akimov, Andrey V., Page, Joseph A., Greenaway, Mark T., Balanov, Alexander G., Patanè, Amalia, and Kent, Anthony J.

Subjects
*ELASTICITY, *ULTRASONICS, *DENSITY functional theory, *ELASTIC modulus, *OPTICAL devices, *LAMINATED glass
Abstract

The interplay between the strong intralayer covalent‐ionic bonds and the weak interlayer van der Waals (vdW) forces between the neighboring layers of vdW crystals gives rise to unique physical and chemical properties. Here, the intralayer and interlayer bondings in α and β polytypes of In2Se3 are studied, a vdW material with potential applications in advanced electronic and optical devices. Picosecond ultrasonic experiments are conducted to probe the sound velocity in the direction perpendicular to the vdW layers. The measured sound velocities are different in α‐ and β‐In2Se3, suggesting a significant difference in their elastic properties. Density functional theory and an effective spring model are used to calculate the elastic stiffness of the layer and vdW gap in α‐ and β‐In2Se3. The calculated elastic moduli show good agreement with experimental values and reveal the dominant contribution of interlayer atomic bonding to the different elastic properties of the two polytypes. The findings show the power of picosecond ultrasonics for probing the fundamental elastic properties of vdW materials. The data and analysis also provide a reliable description of the intra‐ and interlayer forces in complex crystal structures, such as the polytype phases of In2Se3. [ABSTRACT FROM AUTHOR]

Published
2021
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