Your search keyword '"Susi, T"' showing total 96 results

1. Manipulating low-dimensional materials down to the level of single atoms with electron irradiation

Author

Susi, T., Meyer, J. C., and Kotakoski, J.

Subjects

Condensed Matter - Materials Science

Abstract

Recent advances in scanning transmission electron microscopy (STEM) instrumentation have made it possible to focus electron beams with sub-atomic precision and to identify the chemical structure of materials at the level of individual atoms. Here we discuss the dynamics that are observed in the structure of low-dimensional materials under electron irradiation, and the potential use of electron beams for single-atom manipulation. As a demonstration of the latter capability, we show how momentum transfer from the electrons of a 60-keV {\AA}ngstr\"om-sized STEM probe can be used to move silicon atoms embedded in the graphene lattice with atomic precision., Comment: partly review (Fig. 1-3) and partly new results (Fig. 4-5)

Published

2017

2. STEM Developments: A Versatile Light Injector/Collector, Fast 4D-STEM, and High Energy Resolution EELS without Compromising Beam Current.

Author

Martis, J, Plotkin-Swing, B, Haas, B, Susi, T, Hotz, M T, Krivanek, O L, Dellby, N, Mittelberger, A, Quillin, S C, and Lovejoy, T C

Published

2024

3. A platinum nanowire electrocatalyst on single-walled carbon nanotubes to drive hydrogen evolution

Author

Rajala, T., Kronberg, R., Backhouse, R., Buan, M.E.M., Tripathi, M., Zitolo, A., Jiang, H., Laasonen, K., Susi, T., Jaouen, F., and Kallio, T.

Published

2020

4. Understanding the effect of imperfections on 3D electron diffraction intensities using multislice simulations

Author

Cabaj, M. K., primary, Klar, P. B., additional, Madsen, J., additional, Kaur, M., additional, Susi, T., additional, and Palatinus, L., additional

Published

2023

5. Single Heteroatom Configurations in Graphene and Diamond

Author

Trentino, A, primary, Zagler, G, additional, Längle, M, additional, Propst, D, additional, Ahlgren, E H, additional, Mangler, C, additional, Mustonen, K, additional, Susi, T, additional, and Kotakoski, J, additional

Published

2023

6. Ion-Induced Surface Charge Dynamics in Freestanding Monolayers of Graphene and MoS2 Probed by the Emission of Electrons

Author

Niggas, A., Schwestka, J., Balzer, K., Weichselbaum, D., Schlünzen, N., Heller, R., Sascha, C., Inani, H., Tripathi, M., Speckmann, C., McEvoy, N., Susi, T., Kotakoski, J., Gan, Z., George, A., Turchanin, A., Bonitz, M., Aumayr, F., Wilhelm, R. A., Niggas, A., Schwestka, J., Balzer, K., Weichselbaum, D., Schlünzen, N., Heller, R., Sascha, C., Inani, H., Tripathi, M., Speckmann, C., McEvoy, N., Susi, T., Kotakoski, J., Gan, Z., George, A., Turchanin, A., Bonitz, M., Aumayr, F., and Wilhelm, R. A.

Abstract

We compare the ion-induced electron emission from freestanding monolayers of graphene and MoS2 to find a sixfold higher number of emitted electrons for graphene even though both materials have similar work functions. An effective single-band Hubbard model explains this finding by a charge-up in MoS2 that prevents low energy electrons from escaping the surface within a period of a few femtoseconds after ion impact. We support these results by measuring the electron energy distribution for correlated pairs of electrons and transmitted ions. The majority of emitted primary electrons have an energy below 10 eVand are therefore subject to the dynamic charge-up effects at surfaces.

Published

2022

7. Diffraction of 80 eV hydrogen through suspended graphene

Author

Brand, C, primary, Susi, T, additional, Kotakoski, J, additional, Arndt, M, additional, Debiossac, M, additional, Aguillon, F, additional, and Roncin, P, additional

Published

2020

8. Perforating Freestanding Molybdenum Disulfide Monolayers with Highly Charged Ions

Author

Kozubek, R., Tripathi, M., (0000-0003-3060-4369) Ghorbani-Asl, M., Kretschmer, S., Madauß, L., Pollmann, E., O'Brien, M., Mcevoy, N., Ludacka, U., Susi, T., Duesberg, G. S., Wilhelm, R. A., (0000-0003-0074-7588) Krasheninnikov, A. V., Kotakoski, J., Schleberger, M. Y., Kozubek, R., Tripathi, M., (0000-0003-3060-4369) Ghorbani-Asl, M., Kretschmer, S., Madauß, L., Pollmann, E., O'Brien, M., Mcevoy, N., Ludacka, U., Susi, T., Duesberg, G. S., Wilhelm, R. A., (0000-0003-0074-7588) Krasheninnikov, A. V., Kotakoski, J., and Schleberger, M. Y.

Abstract

Porous single-layer molybdenum disulfide (MoS2) is a promising material for applications such as DNA sequencing and water desalination. In this work, we introduce irradiation with highly charged ions (HCIs) as a new technique to fabricate well-defined pores in MoS2. Surprisingly, we find a linear increase of the pore creation efficiency over a broad range of potential energies. Comparison to atomistic simulations reveals the critical role of energy deposition from the ion to the material through electronic excitation in the defect creation process, and suggests an enrichment in molybdenum in the vicinity of the pore edges at least for ions with low potential energies. Analysis of the irradiated samples with atomic resolution scanning transmission electron microscopy reveals a clear dependence of the pore size on the potential energy of the projectiles, establishing irradiation with highly charged ions as an effective method to create pores with narrow size distributions and radii between ca. 0.3 and 3 nm.

Published

2019

9. Implanting Germanium into Graphene

Author

Tripathi, M., Markevich, A., Böttger, R., Facsko, S., Besley, E., Kotakoski, J., Susi, T., Tripathi, M., Markevich, A., Böttger, R., Facsko, S., Besley, E., Kotakoski, J., and Susi, T.

Abstract

Incorporating heteroatoms into the graphene lattice may be used to tailor its electronic, mechanical and chemical properties, although directly observed substitutions have thus far been limited to incidental Si impurities and P, N and B dopants introduced using low-energy ion implantation. We present here the heaviest impurity to date, namely 74Ge+ ions implanted into monolayer graphene. Although sample contamination remains an issue, atomic resolution scanning transmission electron microscopy imaging and quantitative image simulations show that Ge can either directly substitute single atoms, bonding to three carbon neighbors in a buckled out-of-plane configuration, or occupy an in-plane position in a divacancy. First-principles molecular dynamics provides further atomistic insight into the implantation process, revealing a strong chemical effect that enables implantation below the graphene displacement threshold energy. Our results demonstrate that heavy atoms can be implanted into the graphene lattice, pointing a way toward advanced applications such as single-atom catalysis with graphene as the template.

Published

2018

10. Towards atomically precise manipulation of 2D nanostructures in the electron microscope

Author

Susi, T, Kepaptsoglou, D, Lin, Y-C, Ramasse, QM, Meyer, JC, Suenaga, K, and Kotakoski, J

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences

Abstract

Despite decades of research, the ultimate goal of nanotechnology--top-down manipulation of individual atoms--has been directly achieved with only one technique: scanning probe microscopy. In this Review, we demonstrate that scanning transmission electron microscopy (STEM) is emerging as an alternative method for the direct assembly of nanostructures, with possible applications in plasmonics, quantum technologies, and materials science. Atomically precise manipulation with STEM relies on recent advances in instrumentation that have enabled non-destructive atomic-resolution imaging at lower electron energies. While momentum transfer from highly energetic electrons often leads to atom ejection, interesting dynamics can be induced when the transferable kinetic energies are comparable to bond strengths in the material. Operating in this regime, very recent experiments have revealed the potential for single-atom manipulation using the Angstrom-sized electron beam. To truly enable control, however, it is vital to understand the relevant atomic-scale phenomena through accurate dynamical simulations. Although excellent agreement between experiment and theory for the specific case of atomic displacements from graphene has been recently achieved using density functional theory molecular dynamics, in many other cases quantitative accuracy remains a challenge. We provide a comprehensive reanalysis of available experimental data on beam-driven dynamics in light of the state-of-the-art in simulations, and identify important targets for improvement. Overall, the modern electron microscope has great potential to become an atom-scale fabrication platform, especially for covalently bonded 2D nanostructures. We review the developments that have made this possible, argue that graphene is an ideal starting material, and assess the main challenges moving forward., Perspective article, 12 pages with 4 figures and 1 table

Published

2017

11. Single-atom spectroscopy of phosphorus dopants implanted into graphene

Author

Susi, T, Hardcastle, TP, Hofsäss, H, Mittelberger, A, Pennycook, TJ, Mangler, C, Drummond-Brydson, R, Scott, AJ, Meyer, JC, and Kotakoski, J

Subjects

Condensed Matter::Materials Science, Condensed Matter - Materials Science, Physics, Physics::Atomic and Molecular Clusters, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, electron energy loss spectroscopy, heteroatom doping, ion implantation, scanning transmission electron microscopy, density functional theory

Abstract

One of the keys behind the success of the modern semiconductor technology has been the ion implantation of silicon, which allows its electronic properties to be tailored. For similar purposes, heteroatoms have been introduced into carbon nanomaterials both during growth and using post-growth methods. However, due to the nature of the samples, it has been challenging to determine whether the heteroatoms have been incorporated into the lattice as intended, with direct observations so far being limited to N and B dopants, and incidental Si impurities. Furthermore, ion implantation of these materials is more challenging due to the requirement of very low ion energies and atomically clean surfaces. Here, we provide the first atomic-resolution imaging and electron energy loss spectroscopy (EELS) evidence of phosphorus atoms incorporated into the graphene lattice by low-energy ion irradiation. The measured P L-edge response of an single-atom EELS spectrum map shows excellent agreement with an ab initio spectrum simulation, conclusively identifying the P in a buckled substitutional configuration. Our results demonstrate the viability of phosphorus as a lattice dopant in $sp^2$-bonded carbon structures and provide its unmistakeable fingerprint for further studies., 15 pages, 5 figures

Published

2017

12. Graphene hybrids and extended defects: Revealing 3D structures and new insights to radiation damage

Author

Hofer, C., primary, Mustonen, K., additional, Mittelberger, A., additional, Monazam, M.R.A., additional, Hussain, A., additional, Mangier, C., additional, Kramberger, C., additional, Kauppinen, E. I., additional, Susi, T., additional, Kotakoski, J., additional, and Meyer, J. C., additional

Published

2018

13. $\textit{Ab initio}$ density functional theory study on the atomic and electronic structure of GaP/Si(001) heterointerfaces

Author

Romanyuk, O, Supplie, O, Susi, T, May, MM, Hannappel, T, May, Matthias [0000-0002-1252-806X], and Apollo - University of Cambridge Repository

Subjects

Condensed Matter::Materials Science, 34 Chemical Sciences, 3406 Physical Chemistry, 5104 Condensed Matter Physics, 51 Physical Sciences

Abstract

The atomic and electronic band structures of GaP/Si(001) heterointerfaces were investigated by $\textit{ab initio}$ density functional theory calculations. Relative total energies of abrupt interfaces and mixed interfaces with Si substitutional sites within a few GaP layers were derived. It was found that Si diffusion into GaP layers above the first interface layer is energetically unfavorable. An interface with Si/Ga substitution sites in the first layer above the Si substrate is energetically the most stable one in thermodynamic equilibrium. The electronic band structure of the epitaxial GaP/Si(001) heterostructure terminated by the (2×2) surface reconstruction consists of surface and interface electronic states in the common band gap of two semiconductors. The dispersion of the states is anisotropic and differs for the abrupt Si-Ga, Si-P, and mixed interfaces. Ga 2$\textit{p}$, P 2$\textit{p}$, and Si 2$\textit{p}$ core-level binding-energy shifts were computed for the abrupt and the lowest-energy heterointerface structures. Negative and positive core-level shifts due to heterovalent bonds at the interface are predicted for the abrupt Si-Ga and Si-P interfaces, respectively. The distinct features in the heterointerface electronic structure and in the core-level shifts open new perspectives in the experimental characterization of buried polar-on-nonpolar semiconductor heterointerfaces.

Published

2016

14. A new detection scheme for van der Waals heterostructures, imaging individual fullerenes between graphene sheets, and controlling the vacuum in scanning transmission electron microscopy

Author

Argentero, G., primary, Mustonen, K., additional, Mirzayev, R., additional, Mittelberger, A., additional, Susi, T., additional, Leuthner, G.T., additional, Cao, Y., additional, Monazam, M.R.A., additional, Pennycook, T.J., additional, Mangler, C., additional, Kramberger, C., additional, Geim, A.K., additional, Kotakoski, J., additional, and Meyer, J. C., additional

Published

2017

15. Understanding and Exploiting the Interaction of Electron Beams With Low-dimensional Materials - From Controlled Atomic-level Manipulation to Circumventing Radiation Damage

Author

Susi, T., primary, Mittelberger, A., additional, Kramberger, C., additional, Mangier, C., additional, Hofer, C., additional, Pennycook, T.J., additional, Kotakoski, J., additional, and Meyer, J. C., additional

Published

2017

16. Robust theoretical modelling of core ionisation edges for quantitative electron energy loss spectroscopy of B- and N-doped graphene

Author

Hardcastle, T P, primary, Seabourne, C R, additional, Kepaptsoglou, D M, additional, Susi, T, additional, Nicholls, R J, additional, Brydson, R M D, additional, Scott, A J, additional, and Ramasse, Q M, additional

Published

2017

17. Ab initiodensity functional theory study on the atomic and electronic structure of GaP/Si(001) heterointerfaces

Author

Romanyuk, O., primary, Supplie, O., additional, Susi, T., additional, May, M. M., additional, and Hannappel, T., additional

Published

2016

18. Comment on “Temperature dependence of atomic vibrations in mono-layer graphene” [J. Appl. Phys. 118, 074302 (2015)]

Author

Susi, T., primary and Kotakoski, J., additional

Published

2016

19. Uncovering the ultimate performance of single-walled carbon nanotube films as transparent conductors

Author

Mustonen, K., primary, Laiho, P., additional, Kaskela, A., additional, Susi, T., additional, Nasibulin, A. G., additional, and Kauppinen, E. I., additional

Published

2015

20. Gas phase synthesis of non-bundled, small diameter single-walled carbon nanotubes with near-armchair chiralities

Author

Mustonen, K., primary, Laiho, P., additional, Kaskela, A., additional, Zhu, Z., additional, Reynaud, O., additional, Houbenov, N., additional, Tian, Y., additional, Susi, T., additional, Jiang, H., additional, Nasibulin, A. G., additional, and Kauppinen, E. I., additional

Published

2015

21. Atom-by-Atom STEM Investigation of Defect Engineering in Graphene

Author

Ramasse, Q.M., primary, Kepapstoglou, D.M., additional, Hage, F.S., additional, Susi, T., additional, Kotakoski, J., additional, Mangler, C., additional, Ayala, P., additional, Meyer, J., additional, Hinks, J.A., additional, Donnelly, S., additional, Zan, R., additional, Pan, C.T., additional, Haigh, S.J., additional, and Bangert, U., additional

Published

2014

22. Situated play

Author

Rambusch, J., Susi, T., Rambusch, J., and Susi, T.

Abstract

Cognitive science faces a major methodological and conceptual change since the 90's. Whereas the brain was traditionally conceived as being the only seat of intelligence, many researches emphasize the entrenchment of the brain in body, context and culture. In 2006, a conference was held at the Universite du Quebec a Montreal (UQAM) and allowed researchers from various fields to interact and discuss such issues. Cognitio 2006 was an occasion for philosophers, cognitive scientists and biologists to present the latest developments in their discipline, and this book aims at providing a general overview of current research on embodied, situated and distributed cognition.

Published

2008

23. A comparative study of field emission from NanoBuds, nanographite and pure or N-doped single-wall carbon nanotubes

Author

Kleshch, V. I., primary, Susi, T., additional, Nasibulin, A. G., additional, Obraztsova, E. D., additional, Obraztsov, A. N., additional, and Kauppinen, E. I., additional

Published

2010

24. Viewing portraits by Rembrandt: fMRI reveals cerebellar and prefrontal cortical involvement.

Author

Schirillo, J., primary, Susi, T., additional, Burdette, J., additional, and Laurienti, P., additional

Published

2010

25. Graphene hybrids and extended defects: Revealing 3D structures and new insights to radiation damage.

Author

Hofer, C., Mustonen, K., Mittelberger, A., Monazam, M.R.A., Hussain, A., Mangier, C., Kramberger, C., Kauppinen, E. I., Susi, T., Kotakoski, J., and Meyer, J. C.

Published

2019

26. A platinum nanowire electrocatalyst on single-walled carbon nanotubes to drive hydrogen evolution

Author

Rajala, T., Kronberg, R., Backhouse, R., Buan, M.E.M., Tripathi, M., Zitolo, A., Jiang, H., Laasonen, K., Susi, T., Jaouen, F., Kallio, T., Synchrotron SOLEIL (SSOLEIL), Centre National de la Recherche Scientifique (CNRS), Institut Charles Gerhardt Montpellier - Institut de Chimie Moléculaire et des Matériaux de Montpellier (ICGM ICMMM), Université Montpellier 1 (UM1)-Université Montpellier 2 - Sciences et Techniques (UM2)-Ecole Nationale Supérieure de Chimie de Montpellier (ENSCM)-Institut de Chimie du CNRS (INC)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS), SOLEIL Synchrotron, L'Orme des Merisiers, 91198 Gif-sur-Yvette, France, Ecole Nationale Supérieure de Chimie de Montpellier (ENSCM)-Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM)-Université Montpellier 1 (UM1)-Université Montpellier 2 - Sciences et Techniques (UM2)-Institut de Chimie du CNRS (INC), Computational Chemistry, ITM Power, Department of Chemistry and Materials Science, University of Vienna, Synchrotron Soleil, NanoMaterials, Université de Montpellier, Electrochemical Energy Conversion, Department of Applied Physics, Aalto-yliopisto, and Aalto University

Subjects

[CHIM]Chemical Sciences

Abstract

openaire: EC/H2020/721065/EU//CREATE Pertinent existing hydrogen technologies for energy storage require unsustainable amounts of scarce platinum group metals. Here, an electrocatalyst comprising high-aspect-ratio platinum nanowires (PtNWs) on single-walled carbon nanotubes (SWNTs) with ultralow Pt content (340 ngPt cm−2) is employed for hydrogen evolution reaction (HER). A comparable activity (10 mA cm−2 at −18 mV vs. RHE) to that of state-of-the-art Pt/C (38,000 ngPt cm−2) is reached in acidic aqueous electrolyte. This is attributed to favorable PtNW interaction with SWNTs and PtNW edge-sites which adsorb hydrogen optimally and aid at alleviating repulsive interactions. Moreover, the metallic nature of Pt, morphological effects and enhanced wetting contribute positively. The PtNW/SWNT relevance is emphasized at a proton-exchange-membrane electrolyzer generating stable voltage for more than 2000 h, successfully competing with the state-of-the-art reference but with one tenth of Pt mass loading. Overall, this work presents an unprecedently efficient HER catalyst and opens up avenues for PtNW/SWNT catalyzing other high-impact reactions.

27. Ab initio density functional theory study on the atomic and electronic structure of GaP/Si(001) heterointerfaces.

Author

Romanyuk, O., Supplie, O., Susi, T., May, M. M., and Hannappel, T.

Subjects

*DENSITY functional theory, *ELECTRONIC structure, *BAND gaps, *DIFFUSION, *SEMICONDUCTORS

Abstract

The atomic and electronic band structures of GaP/Si(001) heterointerfaces were investigated by ab initio density functional theory calculations. Relative total energies of abrupt interfaces and mixed interfaces with Si substitutional sites within a few GaP layers were derived. It was found that Si diffusion into GaP layers above the first interface layer is energetically unfavorable. An interface with Si/Ga substitution sites in the first layer above the Si substrate is energetically the most stable one in thermodynamic equilibrium. The electronic band structure of the epitaxial GaP/Si(001) heterostructure terminated by the (2?2) surface reconstruction consists of surface and interface electronic states in the common band gap of two semiconductors. The dispersion of the states is anisotropic and differs for the abrupt Si-Ga, Si-P, and mixed interfaces. Ga 2p, P 2p, and Si 2p core-level binding-energy shifts were computed for the abrupt and the lowest-energy heterointerface structures. Negative and positive core-level shifts due to heterovalent bonds at the interface are predicted for the abrupt Si-Ga and Si-P interfaces, respectively. The distinct features in the heterointerface electronic structure and in the core-level shifts open new perspectives in the experimental characterization of buried polar-on-nonpolar semiconductor heterointerfaces. [ABSTRACT FROM AUTHOR]

Published

2016

28. Automated image acquisition and analysis of graphene and hexagonal boron nitride from pristine to highly defective and amorphous structures.

Author

Propst D, Joudi W, Längle M, Madsen J, Kofler C, Mayer BM, Lamprecht D, Mangler C, Filipovic L, Susi T, and Kotakoski J

Abstract

Defect-engineered and even amorphous two-dimensional (2D) materials have recently gained interest due to properties that differ from their pristine counterparts. Since these properties are highly sensitive to the exact atomic structure, it is crucial to be able to characterize them at atomic resolution over large areas. This is only possible when the imaging process is automated to reduce the time spent on manual imaging, which at the same time reduces the observer bias in selecting the imaged areas. Since the necessary datasets include at least hundreds if not thousands of images, the analysis process similarly needs to be automated. Here, we introduce disorder into graphene and monolayer hexagonal boron nitride (hBN) using low-energy argon ion irradiation, and characterize the resulting disordered structures using automated scanning transmission electron microscopy annular dark field imaging combined with convolutional neural network-based analysis techniques. We show that disorder manifests in these materials in a markedly different way, where graphene accommodates vacancy-type defects by transforming hexagonal carbon rings into other polygonal shapes, whereas in hBN the disorder is observed simply as vacant lattice sites with very little rearrangement of the remaining atoms. Correspondingly, in the case of graphene, the highest introduced disorder leads to an amorphous membrane, whereas in hBN, the highly defective lattice contains a large number of vacancies and small pores with no indication of amorphisation. Overall, our study demonstrates that combining automated imaging and image analysis is a powerful way to characterize the structure of disordered and amorphous 2D materials, while also illustrating some of the remaining shortcomings with this methodology., (© 2024. The Author(s).)

Published

2024

29. Single atoms and metal nanoclusters anchored to graphene vacancies.

Author

Trentino A, Zagler G, Längle M, Madsen J, Susi T, Mangler C, Åhlgren EH, Mustonen K, and Kotakoski J

Abstract

Fabricating dispersed single atoms and size-controlled metal nanoclusters remains a difficult challenge due to sintering. Here, we demonstrate that atoms and clusters can be immobilized using atomically clean defect-engineered graphene as the matrix. The graphene is first cleaned of surface contamination with laser heating, after which low-energy Ar irradiation is used to create spatially well-separated vacancies into it. Metal atoms are then evaporated either via thermal or ebeam evaporation onto graphene, where they diffuse until being trapped into a vacancy. The density of embedded structures can be controlled through irradiation dose, and the size of the structures through evaporation time. The resulting structures are confirmed through atomic-resolution scanning transmission electron microscopy and electron energy loss spectroscopy. We demonstrate here incorporation of Al, Ti, Fe, Ag and Au single atoms or nanoclusters, but the method should work equally well for other elements., Competing Interests: Declaration of Competing Interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Jani Kotakoski reports financial support was provided by Austrian Science Fund. Harriet Ahlgren reports financial support was provided by Austrian Science Fund. Kimmo Mustonen reports financial support was provided by Austrian Science Fund. Toma Susi reports financial support was provided by European Research Council. If there are other authors, they declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2024

30. GPAW: An open Python package for electronic structure calculations.

Author

Mortensen JJ, Larsen AH, Kuisma M, Ivanov AV, Taghizadeh A, Peterson A, Haldar A, Dohn AO, Schäfer C, Jónsson EÖ, Hermes ED, Nilsson FA, Kastlunger G, Levi G, Jónsson H, Häkkinen H, Fojt J, Kangsabanik J, Sødequist J, Lehtomäki J, Heske J, Enkovaara J, Winther KT, Dulak M, Melander MM, Ovesen M, Louhivuori M, Walter M, Gjerding M, Lopez-Acevedo O, Erhart P, Warmbier R, Würdemann R, Kaappa S, Latini S, Boland TM, Bligaard T, Skovhus T, Susi T, Maxson T, Rossi T, Chen X, Schmerwitz YLA, Schiøtz J, Olsen T, Jacobsen KW, and Thygesen KS

Abstract

We review the GPAW open-source Python package for electronic structure calculations. GPAW is based on the projector-augmented wave method and can solve the self-consistent density functional theory (DFT) equations using three different wave-function representations, namely real-space grids, plane waves, and numerical atomic orbitals. The three representations are complementary and mutually independent and can be connected by transformations via the real-space grid. This multi-basis feature renders GPAW highly versatile and unique among similar codes. By virtue of its modular structure, the GPAW code constitutes an ideal platform for the implementation of new features and methodologies. Moreover, it is well integrated with the Atomic Simulation Environment (ASE), providing a flexible and dynamic user interface. In addition to ground-state DFT calculations, GPAW supports many-body GW band structures, optical excitations from the Bethe-Salpeter Equation, variational calculations of excited states in molecules and solids via direct optimization, and real-time propagation of the Kohn-Sham equations within time-dependent DFT. A range of more advanced methods to describe magnetic excitations and non-collinear magnetism in solids are also now available. In addition, GPAW can calculate non-linear optical tensors of solids, charged crystal point defects, and much more. Recently, support for graphics processing unit (GPU) acceleration has been achieved with minor modifications to the GPAW code thanks to the CuPy library. We end the review with an outlook, describing some future plans for GPAW., (© 2024 Author(s). All article content, except where otherwise noted, is licensed under a Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).)

Published

2024

31. Creation of Single Vacancies in hBN with Electron Irradiation.

Author

Bui TA, Leuthner GT, Madsen J, Monazam MRA, Chirita AI, Postl A, Mangler C, Kotakoski J, and Susi T

Abstract

Understanding electron irradiation effects is vital not only for reliable transmission electron microscopy characterization, but increasingly also for the controlled manipulation of 2D materials. The displacement cross sections of monolayer hexagonal boron nitride (hBN) are measured using aberration-corrected scanning transmission electron microscopy in near ultra-high vacuum at primary beam energies between 50 and 90 keV. Damage rates below 80 keV are up to three orders of magnitude lower than previously measured at edges under poorer residual vacuum conditions, where chemical etching appears to dominate. Notably, it is possible to create single vacancies in hBN using electron irradiation, with boron almost twice as likely as nitrogen to be ejected below 80 keV. Moreover, any damage at such low energies cannot be explained by elastic knock-on, even when accounting for the vibrations of the atoms. A theoretical description is developed to account for the lowering of the displacement threshold due to valence ionization resulting from inelastic scattering of probe electrons, modeled using charge-constrained density functional theory molecular dynamics. Although significant reductions are found depending on the constrained charge, quantitative predictions for realistic ionization states are currently not possible. Nonetheless, there is potential for defect-engineering of hBN at the level of single vacancies using electron irradiation., (© 2023 The Authors. Small published by Wiley-VCH GmbH.)

Published

2023

32. Replacing academic journals.

Author

Brembs B, Huneman P, Schönbrodt F, Nilsonne G, Susi T, Siems R, Perakakis P, Trachana V, Ma L, and Rodriguez-Cuadrado S

Abstract

Replacing traditional journals with a more modern solution is not a new idea. Here, we propose ways to overcome the social dilemma underlying the decades of inaction. Any solution needs to not only resolve the current problems but also be capable of preventing takeover by corporations: it needs to replace traditional journals with a decentralized, resilient, evolvable network that is interconnected by open standards and open-source norms under the governance of the scholarly community. It needs to replace the monopolies connected to journals with a genuine, functioning and well-regulated market. In this new market, substitutable service providers compete and innovate according to the conditions of the scholarly community, avoiding sustained vendor lock-in. Therefore, a standards body needs to form under the governance of the scholarly community to allow the development of open scholarly infrastructures servicing the entire research workflow. We propose a redirection of money from legacy publishers to the new network by funding bodies broadening their minimal infrastructure requirements at recipient institutions to include modern infrastructure components replacing and complementing journal functionalities. Such updated eligibility criteria by funding agencies would help realign the financial incentives for recipient institutions with public and scholarly interest., Competing Interests: We declare we have no competing interests., (© 2023 The Authors.)

Published

2023

33. Deep reinforcement learning for data-driven adaptive scanning in ptychography.

Author

Schloz M, Müller J, Pekin TC, Van den Broek W, Madsen J, Susi T, and Koch CT

Abstract

We present a method that lowers the dose required for an electron ptychographic reconstruction by adaptively scanning the specimen, thereby providing the required spatial information redundancy in the regions of highest importance. The proposed method is built upon a deep learning model that is trained by reinforcement learning, using prior knowledge of the specimen structure from training data sets. We show that using adaptive scanning for electron ptychography outperforms alternative low-dose ptychography experiments in terms of reconstruction resolution and quality., (© 2023. The Author(s).)

Published

2023

34. Linear indium atom chains at graphene edges.

Author

Elibol K, Susi T, Mangler C, Eder D, Meyer JC, Kotakoski J, Hobbs RG, van Aken PA, and Bayer BC

Abstract

The presence of metal atoms at the edges of graphene nanoribbons (GNRs) opens new possibilities toward tailoring their physical properties. We present here formation and high-resolution characterization of indium (In) chains on the edges of graphene-supported GNRs. The GNRs are formed when adsorbed hydrocarbon contamination crystallizes via laser heating into small ribbon-like patches of a second graphitic layer on a continuous graphene monolayer and onto which In is subsequently physical vapor deposited. Using aberration-corrected scanning transmission electron microscopy (STEM), we find that this leads to the preferential decoration of the edges of the overlying GNRs with multiple In atoms along their graphitic edges. Electron-beam irradiation during STEM induces migration of In atoms along the edges of the GNRs and triggers the formation of longer In atom chains during imaging. Density functional theory (DFT) calculations of GNRs similar to our experimentally observed structures indicate that both bare zigzag (ZZ) GNRs as well as In-terminated ZZ-GNRs have metallic character, whereas in contrast, In termination induces metallicity for otherwise semiconducting armchair (AC) GNRs. Our findings provide insights into the creation and properties of long linear metal atom chains at graphitic edges., Competing Interests: Competing interestsThe authors declare no competing interests., (© The Author(s) 2023.)

Published

2023

35. Identifying and manipulating single atoms with scanning transmission electron microscopy.

Author

Susi T

Subjects

Microscopy, Electron, Scanning Transmission, Silicon chemistry, Nanotubes, Carbon chemistry, Graphite chemistry

Abstract

The manipulation of individual atoms has developed from visionary speculation into an established experimental science. Using focused electron irradiation in a scanning transmission electron microscope instead of a physical tip in a scanning probe microscope confers several benefits, including thermal stability of the manipulated structures, the ability to reach into bulk crystals, and the chemical identification of single atoms. However, energetic electron irradiation also presents unique challenges, with an inevitable possibility of irradiation damage. Understanding the underlying mechanisms will undoubtedly continue to play an important role to guide experiments. Great progress has been made in several materials including graphene, carbon nanotubes, and crystalline silicon in the eight years since the discovery of electron-beam manipulation, but the important challenges that remain will determine how far we can expect to progress in the near future.

Published

2022

36. Computationally Efficient Handling of Partially Coherent Electron Sources in (S)TEM Image Simulations via Matrix Diagonalization.

Author

Li Z, Rose H, Madsen J, Biskupek J, Susi T, and Kaiser U

Abstract

We introduce a novel method to improve the computational efficiency for (S)TEM image simulation by employing matrix diagonalization of the mixed envelope function (MEF). The MEF is derived by taking the finite size and the energy spread of the effective electron source into account, and is a component of the transmission cross-coefficient that accounts for the correlation between partially coherent waves. Since the MEF is a four-dimensional array and its application in image calculations is time-consuming, we reduce the computation time by using its eigenvectors. By incorporating the aperture function into the matrix diagonalization, only a small number of eigenvectors are required to approximate the original matrix with high accuracy. The diagonalization enables for each eigenvector the calculation of the corresponding image by employing the coherent model. The individual images are weighted by the corresponding eigenvalues and then summed up, resulting in the total partially coherent image.

Published

2022

37. Ion-Induced Surface Charge Dynamics in Freestanding Monolayers of Graphene and MoS_{2} Probed by the Emission of Electrons.

Author

Niggas A, Schwestka J, Balzer K, Weichselbaum D, Schlünzen N, Heller R, Creutzburg S, Inani H, Tripathi M, Speckmann C, McEvoy N, Susi T, Kotakoski J, Gan Z, George A, Turchanin A, Bonitz M, Aumayr F, and Wilhelm RA

Abstract

We compare the ion-induced electron emission from freestanding monolayers of graphene and MoS_{2} to find a sixfold higher number of emitted electrons for graphene even though both materials have similar work functions. An effective single-band Hubbard model explains this finding by a charge-up in MoS_{2} that prevents low energy electrons from escaping the surface within a period of a few femtoseconds after ion impact. We support these results by measuring the electron energy distribution for correlated pairs of electrons and transmitted ions. The majority of emitted primary electrons have an energy below 10 eV and are therefore subject to the dynamic charge-up effects at surfaces.

Published

2022

38. Accurate Computational Prediction of Core-Electron Binding Energies in Carbon-Based Materials: A Machine-Learning Model Combining Density-Functional Theory and GW .

Author

Golze D, Hirvensalo M, Hernández-León P, Aarva A, Etula J, Susi T, Rinke P, Laurila T, and Caro MA

Abstract

We present a quantitatively accurate machine-learning (ML) model for the computational prediction of core-electron binding energies, from which X-ray photoelectron spectroscopy (XPS) spectra can be readily obtained. Our model combines density functional theory (DFT) with GW and uses kernel ridge regression for the ML predictions. We apply the new approach to disordered materials and small molecules containing carbon, hydrogen, and oxygen and obtain qualitative and quantitative agreement with experiment, resolving spectral features within 0.1 eV of reference experimental spectra. The method only requires the user to provide a structural model for the material under study to obtain an XPS prediction within seconds. Our new tool is freely available online through the XPS Prediction Server., Competing Interests: The authors declare no competing financial interest., (© 2022 The Authors. Published by American Chemical Society.)

Published

2022

39. Beam-driven Dynamics of Aluminium Dopants in Graphene.

Author

Zagler G, Stecher M, Trentino A, Kraft F, Su C, Postl A, Längle M, Pesenhofer C, Mangler C, Åhlgren EH, Markevich A, Zettl A, Kotakoski J, Susi T, and Mustonen K

Abstract

Substituting heteroatoms into graphene can tune its properties for applications ranging from catalysis to spintronics. The further recent discovery that covalent impurities in graphene can be manipulated at atomic precision using a focused electron beam may open avenues towards sub-nanometer device architectures. However, the preparation of clean samples with a high density of dopants is still very challenging. Here, we report vacancy-mediated substitution of aluminium into laser-cleaned graphene, and without removal from our ultra-high vacuum apparatus, study their dynamics under 60 keV electron irradiation using aberration-corrected scanning transmission electron microscopy and spectroscopy. Three- and four-coordinated Al sites are identified, showing excellent agreement with ab initio predictions including binding energies and electron energy-loss spectrum simulations. We show that the direct exchange of carbon and aluminium atoms predicted earlier occurs under electron irradiation, although unexpectedly it is less probable than the same process for silicon. We also observe a previously unknown nitrogen-aluminium exchange that occurs at Al─N double-dopant sites at graphene divacancies created by our plasma treatment., Competing Interests: Conflict of interest The authors declare no conflicts of interest.

Published

2022

40. Toward Exotic Layered Materials: 2D Cuprous Iodide.

Author

Mustonen K, Hofer C, Kotrusz P, Markevich A, Hulman M, Mangler C, Susi T, Pennycook TJ, Hricovini K, Richter C, Meyer JC, Kotakoski J, and Skákalová V

Abstract

Heterostructures composed of 2D materials are already opening many new possibilities in such fields of technology as electronics and magnonics, but far more could be achieved if the number and diversity of 2D materials were increased. So far, only a few dozen 2D crystals have been extracted from materials that exhibit a layered phase in ambient conditions, omitting entirely the large number of layered materials that may exist at other temperatures and pressures. This work demonstrates how such structures can be stabilized in 2D van der Waals (vdw) stacks under room temperature via growing them directly in graphene encapsulation by using graphene oxide as the template material. Specifically, an ambient stable 2D structure of copper and iodine, a material that normally only occurs in layered form at elevated temperatures between 645 and 675 K, is produced. The results establish a simple route to the production of more exotic phases of materials that would otherwise be difficult or impossible to stabilize for experiments in ambient., (© 2022 The Authors. Advanced Materials published by Wiley-VCH GmbH.)

Published

2022

41. ab initio description of bonding for transmission electron microscopy.

Author

Madsen J, Pennycook TJ, and Susi T

Subjects

Electrons, Microscopy, Electron, Microscopy, Electron, Scanning Transmission methods, Holography

Abstract

The simulation of transmission electron microscopy (TEM) images or diffraction patterns is often required to interpret their contrast and extract specimen features. This is especially true for high-resolution phase-contrast imaging of materials, but electron scattering simulations based on atomistic models are widely used in materials science and structural biology. Since electron scattering is dominated by the nuclear cores, the scattering potential is typically described by the widely applied independent atom model. This approximation is fast and fairly accurate, especially for scanning TEM (STEM) annular dark-field contrast, but it completely neglects valence bonding and its effect on the transmitting electrons. However, an emerging trend in electron microscopy is to use new instrumentation and methods to extract the maximum amount of information from each electron. This is evident in the increasing popularity of techniques such as 4D-STEM combined with ptychography in materials science, and cryogenic microcrystal electron diffraction in structural biology, where subtle differences in the scattering potential may be both measurable and contain additional insights. Thus, there is increasing interest in electron scattering simulations based on electrostatic potentials obtained from first principles, mainly via density functional theory, which was previously mainly required for holography. In this Review, we discuss the motivation and basis for these developments, survey the pioneering work that has been published thus far, and give our outlook for the future. We argue that a physically better justified ab initio description of the scattering potential is both useful and viable for an increasing number of systems, and we expect such simulations to steadily gain in popularity and importance., (Copyright © 2021. Published by Elsevier B.V.)

Published

2021

42. Single Indium Atoms and Few-Atom Indium Clusters Anchored onto Graphene via Silicon Heteroatoms.

Author

Elibol K, Mangler C, O'Regan DD, Mustonen K, Eder D, Meyer JC, Kotakoski J, Hobbs RG, Susi T, and Bayer BC

Abstract

Single atoms and few-atom nanoclusters are of high interest in catalysis and plasmonics, but pathways for their fabrication and placement remain scarce. We report here the self-assembly of room-temperature-stable single indium (In) atoms and few-atom In clusters (2-6 atoms) that are anchored to substitutional silicon (Si) impurity atoms in suspended monolayer graphene membranes. Using atomically resolved scanning transmission electron microscopy (STEM), we find that the symmetry of the In structures is critically determined by the three- or fourfold coordination of the Si "anchors". All structures are produced without electron-beam induced materials modification. In turn, when activated by electron beam irradiation in the STEM, we observe in situ the formation, restructuring, and translation of the Si-anchored In structures. Our results on In-Si-graphene provide a materials system for controlled self-assembly and heteroatomic anchoring of single atoms and few-atom nanoclusters on graphene.

Published

2021

43. Mechanism of Electron-Beam Manipulation of Single-Dopant Atoms in Silicon.

Author

Markevich A, Hudak BM, Madsen J, Song J, Snijders PC, Lupini AR, and Susi T

Abstract

The precise positioning of dopant atoms within bulk crystal lattices could enable novel applications in areas including solid-state sensing and quantum computation. Established scanning probe techniques are capable tools for the manipulation of surface atoms, but at a disadvantage due to their need to bring a physical tip into contact with the sample. This has prompted interest in electron-beam techniques, followed by the first proof-of-principle experiment of bismuth dopant manipulation in crystalline silicon. Here, we use first-principles modeling to discover a novel indirect exchange mechanism that allows electron impacts to non-destructively move dopants with atomic precision within the silicon lattice. However, this mechanism only works for the two heaviest group V donors with split-vacancy configurations, Bi and Sb. We verify our model by directly imaging these configurations for Bi and by demonstrating that the promising nuclear spin qubit Sb can be manipulated using a focused electron beam., Competing Interests: The authors declare no competing financial interest., (© 2021 The Authors. Published by American Chemical Society.)

Published

2021

44. Interferometric 4D-STEM for Lattice Distortion and Interlayer Spacing Measurements of Bilayer and Trilayer 2D Materials.

Author

Zachman MJ, Madsen J, Zhang X, Ajayan PM, Susi T, and Chi M

Abstract

Van der Waals materials composed of stacks of individual atomic layers have attracted considerable attention due to their exotic electronic properties that can be altered by, e.g., manipulating the twist angle of bilayer materials or the stacking sequence of trilayer materials. To fully understand and control the unique properties of these few-layer materials, a technique that can provide information about their local in-plane structural deformations, twist direction, and out-of-plane structure is needed. In principle, interference in overlap regions of Bragg disks originating from separate layers of a material encodes 3D information about the relative positions of atoms in the corresponding layers. Here, an interferometric 4D scanning transmission electron microscopy technique is described that utilizes this phenomenon to extract precise structural information from few-layer materials with nm-scale resolution. It is demonstrated how this technique enables measurement of local pm-scale in-plane lattice distortions as well as twist direction and average interlayer spacings in bilayer and trilayer graphene, and therefore provides a means to better understand the interplay between electronic properties and precise structural arrangements of few-layer 2D materials., (© 2021 Wiley-VCH GmbH.)

Published

2021

45. Atomic-Level Structural Engineering of Graphene on a Mesoscopic Scale.

Author

Trentino A, Madsen J, Mittelberger A, Mangler C, Susi T, Mustonen K, and Kotakoski J

Subjects

Vacuum, Graphite

Abstract

Structural engineering is the first step toward changing properties of materials. While this can be at relative ease done for bulk materials, for example, using ion irradiation, similar engineering of 2D materials and other low-dimensional structures remains a challenge. The difficulties range from the preparation of clean and uniform samples to the sensitivity of these structures to the overwhelming task of sample-wide characterization of the subjected modifications at the atomic scale. Here, we overcome these issues using a near ultrahigh vacuum system comprised of an aberration-corrected scanning transmission electron microscope and setups for sample cleaning and manipulation, which are combined with automated atomic-resolution imaging of large sample areas and a convolutional neural network approach for image analysis. This allows us to create and fully characterize atomically clean free-standing graphene with a controlled defect distribution, thus providing the important first step toward atomically tailored two-dimensional materials.

Published

2021

46. The abTEM code: transmission electron microscopy from first principles.

Author

Madsen J and Susi T

Abstract

Simulation of transmission electron microscopy (TEM) images or diffraction patterns is often required to interpret experimental data. Since nuclear cores dominate electron scattering, the scattering potential is typically described using the independent atom model, which completely neglects valence bonding and its effect on the transmitting electrons. As instrumentation has advanced, new measurements have revealed subtle details of the scattering potential that were previously not accessible to experiment. We have created an open-source simulation code designed to meet these demands by integrating the ability to calculate the potential via density functional theory (DFT) with a flexible modular software design. abTEM can simulate most standard imaging modes and incorporates the latest algorithmic developments. The development of new techniques requires a program that is accessible to domain experts without extensive programming experience. abTEM is written purely in Python and designed for easy modification and extension. The effective use of modern open-source libraries makes the performance of abTEM highly competitive with existing optimized codes on both CPUs and GPUs and allows us to leverage an extensive ecosystem of libraries, such as the Atomic Simulation Environment and the DFT code GPAW. abTEM is designed to work in an interactive Python notebook, creating a seamless and reproducible workflow from defining an atomic structure, calculating molecular dynamics (MD) and electrostatic potentials, to the analysis of results, all in a single, easy-to-read document.  This article provides ongoing documentation of abTEM development. In this first version, we show use cases for hexagonal boron nitride, where valence bonding can be detected, a 4D-STEM simulation of molybdenum disulfide including ptychographic phase reconstruction, a comparison of MD and frozen phonon modeling for convergent-beam electron diffraction of a 2.6-million-atom silicon system, and a performance comparison of our fast implementation of the PRISM algorithm for a decahedral 20000-atom gold nanoparticle., Competing Interests: No competing interests were disclosed., (Copyright: © 2021 Madsen J and Susi T.)

Published

2021

47. Tailoring Electronic and Magnetic Properties of Graphene by Phosphorus Doping.

Author

Langer R, Błoński P, Hofer C, Lazar P, Mustonen K, Meyer JC, Susi T, and Otyepka M

Abstract

The electronic and magnetic properties of graphene can be modulated by doping it with other elements, especially those with a different number of valence electrons. In this article, we first provide a three-dimensional reconstruction of the atomic structure of a phosphorus substitution in graphene using aberration-corrected scanning transmission electron microscopy. Turning then to theoretical calculations based on the density functional theory (DFT), we show that doping phosphorus in various bonding configurations can induce magnetism in graphene. Our simulations reveal that the electronic and magnetic properties of P-doped (Gr-P) and/or phosphono-functionalized graphene (Gr-PO 3 H 2 ) can be controlled by both the phosphorus concentration and configurations, ultimately leading to ferromagnetic (FM) and/or antiferromagnetic (AFM) features with the transition temperature up to room temperature. We also calculate core-level binding energies of variously bonded P to facilitate X-ray photoelectron spectroscopy-based identification of its chemical form present in P-doped graphene-based structures. These results may enable the design of graphene-based organic magnets with tailored properties for future magnetic or spintronic applications.

Published

2020

48. Direct imaging of light-element impurities in graphene reveals triple-coordinated oxygen.

Author

Hofer C, Skákalová V, Görlich T, Tripathi M, Mittelberger A, Mangler C, Monazam MRA, Susi T, Kotakoski J, and Meyer JC

Abstract

Along with hydrogen, carbon, nitrogen and oxygen are the arguably most important elements for organic chemistry. Due to their rich variety of possible bonding configurations, they can form a staggering number of compounds. Here, we present a detailed analysis of nitrogen and oxygen bonding configurations in a defective carbon (graphene) lattice. Using aberration-corrected scanning transmission electron microscopy and single-atom electron energy loss spectroscopy, we directly imaged oxygen atoms in graphene oxide, as well as nitrogen atoms implanted into graphene. The collected data allows us to compare nitrogen and oxygen bonding configurations, showing clear differences between the two elements. As expected, nitrogen forms either two or three bonds with neighboring carbon atoms, with three bonds being the preferred configuration. Oxygen, by contrast, tends to bind with only two carbon atoms. Remarkably, however, triple-coordinated oxygen with three carbon neighbors is also observed, a configuration that is exceedingly rare in organic compounds.

Published

2019

49. Influence of temperature on the displacement threshold energy in graphene.

Author

Chirita Mihaila AI, Susi T, and Kotakoski J

Abstract

The atomic structure of nanomaterials is often studied using transmission electron microscopy. In addition to image formation, the energetic electrons impinging on the sample may also cause damage. In a good conductor such as graphene, the damage is limited to the knock-on process caused by elastic electron-nucleus scattering. This process is determined by the kinetic energy an atom needs to be sputtered, i.e. its displacement threshold energy E d . This is typically assumed to have a fixed value for all electron impacts on equivalent atoms within a crystal. Here we show using density functional tight-binding simulations that the displacement threshold energy is affected by thermal perturbations of atoms from their equilibrium positions. This effect can be accounted for in the estimation of the displacement cross section by replacing the constant threshold energy value with a distribution. Our refined model better describes previous precision measurements of graphene knock-on damage, and should be considered also for other low-dimensional materials.

Published

2019

50. Microwave Energy Drives "On-Off-On" Spin-Switch Behavior in Nitrogen-Doped Graphene.

Author

Zoppellaro G, Bakandritsos A, Tuček J, Błoński P, Susi T, Lazar P, Bad'ura Z, Steklý T, Opletalová A, Otyepka M, and Zbořil R

Abstract

The established application of graphene in organic/inorganic spin-valve spintronic assemblies is as a spin-transport channel for spin-polarized electrons injected from ferromagnetic substrates. To generate and control spin injection without such substrates, the graphene backbone must be imprinted with spin-polarized states and itinerant-like spins. Computations suggest that such states should emerge in graphene derivatives incorporating pyridinic nitrogen. The synthesis and electronic properties of nitrogen-doped graphene (N content: 9.8%), featuring both localized spin centers and spin-containing sites with itinerant electron properties, are reported. This material exhibits spin-switch behavior (on-off-on) controlled by microwave irradiation at X-band frequency. This phenomenon may enable the creation of novel types of switches, filters, and spintronic devices using sp 2 -only 2D systems., (© 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2019