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1. Reactivity of ultra-thin Kagome Metal FeSn towards Oxygen and Water

Author

Blyth, James, Sridhar, Sadhana, Zhao, Mengting, Ali2, Sajid, Vu, Thi Hai Yen, Li, Qile, Maniatis, Johnathon, Causer, Grace, Fuhrer, Michael S., Medhekar, Nikhil V., Tadich, Anton, and Edmonds, Mark

Subjects
Condensed Matter - Materials Science
Abstract

The kagome metal FeSn, consists of alternating layers of kagome-lattice Fe3Sn and honeycomb Sn2, and exhibits great potential for applications in future low energy electronics and spintronics because of an ideal combination of novel topological phases and high-temperature magnetic ordering. Robust synthesis methods for ultra-thin FeSn films, as well as an understanding of their air stability is crucial for its development and long-term operation in future devices. In this work, we realize large area, sub-10 nm epitaxial FeSn thin films, and explore the oxidation process via synchrotron-based photoelectron spectroscopy using in-situ oxygen and water dosing, as well as ex-situ air exposure. Upon exposure to atmosphere the FeSn films are shown to be highly reactive, with a stable ~3 nm thick oxide layer forming at the surface within 10 minutes. Notably the surface Fe remains largely unoxidized when compared to Sn, which undergoes near-complete oxidation. This is further confirmed with controlled in-situ dosing of O2 and H2O where only the Sn2 (stanene) inter-layers within the FeSn lattice oxidize, suggesting the Fe3Sn kagome layers remain almost pristine. These results are in excellent agreement with first principles calculations, which show Fe-O bonds to the Fe3Sn layer are energetically unfavorable, and furthermore, a large formation energy preference of 1.37 eV for Sn-O bonds in the stanene Sn2 layer over Sn-O bonds in the kagome Fe3Sn layer. The demonstration that oxidation only occurs within the stanene layers may provide new avenues in how to engineer, handle and prepare future kagome metal devices., Comment: 21 pages, 5 figures, 4 SI figures

Published
2024

2. Design Principles of Diketopyrrolopyrrole‐Thienopyrrolodione Acceptor1–Acceptor2 Copolymers

Author

Erhardt, Andreas, Hungenberg, Julian, Chantler, Paul, Kuhn, Meike, Huynh, Thanh Tung, Hochgesang, Adrian, Goel, Mahima, Müller, Christian J, Roychoudhury, Subhayan, Thomsen, Lars, Medhekar, Nikhil V, Herzig, Eva M, Prendergast, David, Thelakkat, Mukundan, and McNeill, Christopher R

Subjects
Engineering, Macromolecular and Materials Chemistry, Materials Engineering, Chemical Sciences, acceptor(1)-acceptor(2) copolymers, all-polymer solar cells, microstructure, OFET, organic semiconductors, Physical Sciences, Materials, Chemical sciences, Physical sciences
Abstract

The design principles of acceptor1–acceptor2 copolymers featuring alternating diketopyrrolopyrrole (DPP) and thienopyrrolodione (TPD) moieties are investigated. The investigated series of polymers is obtained by varying the aromatic linker between the two acceptor motifs between thiophene, thiazole, pyridine, and benzene. High electron affinities between 3.96 and 4.42 eV, facilitated by the synergy of the acceptor motifs are determined with optical gaps between 1.37 and 2.02 eV. Grazing incidence wide-angle X-ray scattering studies reveal a range of film morphologies after thermal annealing, including face-on, end-on and superstructure edge-on-like crystallites. Conversely, all materials form thin edge-on layers on the polymer–air interface, as demonstrated by multi-elemental near-edge X-ray absorption fine-structure spectroscopy. The benefit of the electron-deficient linkers thiazole and pyridine is evident: In organic field effect transistors, electron mobilities of up to 4.6 × 10−2 cm2 V−1 s−1 are obtained with outstanding on/off current ratios of 5 × 105, facilitated by the absence of detectable hole transport in these materials. Viability for all-polymer solar cells is assessed in active layer blends with the donor polymer PM6, yielding a maximum average power conversion efficiency of 4.8% and an open circuit voltage above 1 V.

Published
2024

3. Electric Field Control of Molecular Charge State in a Single-Component 2D Organic Nanoarray

Author

Kumar, Dhaneesh, Krull, Cornelius, Yin, Yuefeng, Medhekar, Nikhil V., and Schiffrin, Agustin

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

Quantum dots (QD) with electric-field-controlled charge state are promising for electronics applications, e.g., digital information storage, single-electron transistors and quantum computing. Inorganic QDs consisting of semiconductor nanostructures or heterostructures often offer limited control on size and composition distribution, as well as low potential for scalability and/or nanoscale miniaturization. Owing to their tunability and self-assembly capability, using organic molecules as building nano-units can allow for bottom-up synthesis of two-dimensional (2D) nanoarrays of QDs. However, 2D molecular self-assembly protocols are often applicable on metals surfaces, where electronic hybridization and Fermi level pinning can hinder electric-field control of the QD charge state. Here, we demonstrate the synthesis of a single-component self-assembled 2D array of molecules [9, 10-dicyanoanthracene (DCA)] that exhibit electric-field-controlled spatially periodic charging on a noble metal surface, Ag(111). The charge state of DCA can be altered (between neutral and negative), depending on its adsorption site, by the local electric field induced by a scanning tunneling microscope tip. Limited metal-molecule interactions result in an effective tunneling barrier between DCA and Ag(111) that enables electric-field-induced electron population of the lowest unoccupied molecular orbital (LUMO) and hence charging of the molecule. Subtle site-dependent variation of the molecular adsorption height translates into a significant spatial modulation of the molecular polarizability, dielectric constant and LUMO energy level alignment, giving rise to a spatially dependent effective molecule-surface tunneling barrier and likelihood of charging. This work offers potential for high-density 2D self-assembled nanoarrays of identical QDs whose charge states can be addressed individually with an electric field.

Published
2024
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4. Generic Approach to Intrinsic Magnetic Second-order Topological Insulators via Inverted $p-d$ Orbitals

Author

Liu, Zhao, Liu, Bing, Yin, Yuefeng, and Medhekar, Nikhil V.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons
Abstract

The integration of intrinsically magnetic and topologically nontrivial two-dimensional materials holds tantalizing prospects for the exotic quantum anomalous Hall insulators and magnetic second-order topological insulators (SOTIs). Compared with the well-studied nonmagnetic counterparts, the pursuit of intrinsic magnetic SOTIs remains limited. In this work, we address this gap by focusing on $p-d$ orbitals inversion, a fundamental but often overlooked phenomena in the construction of topological materials. We begin by developing a theoretical framework to elucidate $p-d$ orbitals inversion through a combined density-functional theory calculation and Wannier downfolding. Subsequently we showcase the generality of this concept in realizing ferromagnetism SOTIs by identifying two real materials with distinct lattices: 1$T$-VS$_2$ in a hexagonal lattice, and CrAs monolayer in a square lattice. We further compare it with other mechanisms requiring spin-orbit coupling and explore the similarities to topological Kondo insulators. Our findings establish a generic pathway towards intrinsic magnetic SOTIs., Comment: 4 figures, all comments are welcomed !

Published
2024
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5. Quasi-free-standing AA-stacked bilayer graphene induced by calcium intercalation of the graphene-silicon carbide interface

Author

Grubišić-Čabo, Antonija, Kotsakidis, Jimmy C., Yin, Yuefeng, Tadich, Anton, Haldon, Matthew, Solari, Sean, Riley, John, Huwald, Eric, Daniels, Kevin M., Myers-Ward, Rachael L., Edmonds, Mark T., Medhekar, Nikhil, Gaskill, D. Kurt, and Fuhrer, Michael S.

Subjects
Condensed Matter - Materials Science
Abstract

We study quasi-freestanding bilayer graphene on silicon carbide intercalated by calcium. The intercalation, and subsequent changes to the system, were investigated by low-energy electron diffraction, angle-resolved photoemission spectroscopy (ARPES) and density-functional theory (DFT). Calcium is found to intercalate only at the graphene-SiC interface, completely displacing the hydrogen terminating SiC. As a consequence, the system becomes highly n-doped. Comparison to DFT calculations shows that the band dispersion, as determined by ARPES, deviates from the band structure expected for Bernal-stacked bilayer graphene. Instead, the electronic structure closely matches AA-stacked bilayer graphene on Ca-terminated SiC, indicating a spontaneous transition from AB- to AA-stacked bilayer graphene following calcium intercalation of the underlying graphene-SiC interface., Comment: 14 pages, 3 figures

Published
2023
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6. Designing optoelectronic properties by on-surface synthesis: formation and electronic structure of an iron-terpyridine macromolecular complex

Author

Schiffrin, Agustin, Capsoni, Martina, Farahi, Gelareh, Wang, Chen-Guang, Krull, Cornelius, Castelli, Marina, Roussy, Tanya S., Cochrane, Katherine A., Yin, Yuefeng, Medhekar, Nikhil, Shaw, Adam Q., Ji, Wei, and Burke, Sarah A.

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

Supramolecular chemistry protocols applied on surfaces offer compelling avenues for atomic scale control over organic-inorganic interface structures. In this approach, adsorbate-surface interactions and two-dimensional confinement can lead to morphologies and properties that differ dramatically from those achieved via conventional synthetic approaches. Here, we describe the bottom-up, on-surface synthesis of one-dimensional coordination nanostructures based on an iron (Fe)-terpyridine (tpy) interaction borrowed from functional metal-organic complexes used in photovoltaic and catalytic applications. Thermally activated diffusion of sequentially deposited ligands and metal atoms, and intra-ligand conformational changes, lead to Fe-tpy coordination and formation of these nanochains. Low-temperature Scanning Tunneling Microscopy and Density Functional Theory were used to elucidate the atomic-scale morphology of the system, providing evidence of a linear tri-Fe linkage between facing, coplanar tpy groups. Scanning Tunneling Spectroscopy reveals highest occupied orbitals with dominant contributions from states located at the Fe node, and ligand states that mostly contribute to the lowest unoccupied orbitals. This electronic structure yields potential for hosting photo-induced metal-to-ligand charge transfer in the visible/near-infrared. The formation of this unusual tpy/tri-Fe/tpy coordination motif has not been observed for wet chemistry synthesis methods, and is mediated by the bottom-up on-surface approach used here.

Published
2023
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7. Gigantic Anisotropy of Self-Induced Spin-Orbit Torque in Weyl Ferromagnet Co2MnGa

Author

Aoki, Motomi, Yin, Yuefeng, Granville, Simon, Zhang, Yao, Medhekar, Nikhil V., Leiva, Livio, Ohshima, Ryo, Ando, Yuichiro, and Shiraishi, Masashi

Subjects
Condensed Matter - Materials Science
Abstract

Spin-orbit torque (SOT) is receiving tremendous attention from both fundamental and application-oriented aspects. Co2MnGa, a Weyl ferromagnet that is in a class of topological quantum materials, possesses cubic-based high structural symmetry, the L21 crystal ordering, which should be incapable of hosting anisotropic SOT in conventional understanding. Here we show the discovery of a gigantic anisotropy of self-induced SOT in Co2MnGa. The magnitude of the SOT is comparable to that of heavy metal/ferromagnet bilayer systems despite the high inversion symmetry of the Co2MnGa structure. More surprisingly, a sign inversion of the self-induced SOT is observed for different crystal axes. This finding stems from the interplay of the topological nature of the electronic states and their strong modulation by external strain. Our research enriches the understanding of the physics of self-induced SOT and demonstrates a versatile method for tuning SOT efficiencies in a wide range of materials for topological and spintronic devices., Comment: 15pages, 4figures (To appear Nano Lett.)

Published
2023
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9. Local gate control of Mott metal-insulator transition in a 2D metal-organic framework

Author

Lowe, Benjamin, Field, Bernard, Hellerstedt, Jack, Ceddia, Julian, Nourse, Henry L., Powell, Ben J., Medhekar, Nikhil V., and Schiffrin, Agustin

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

Electron-electron interactions in materials lead to exotic many-body quantum phenomena including Mott metal-insulator transitions (MITs), magnetism, quantum spin liquids, and superconductivity. These phases depend on electronic band occupation and can be controlled via the chemical potential. Flat bands in two-dimensional (2D) and layered materials with a kagome lattice enhance electronic correlations. Although theoretically predicted, correlated-electron Mott insulating phases in monolayer 2D metal-organic frameworks (MOFs) with a kagome structure have not yet been realised experimentally. Here, we synthesise a 2D kagome MOF on a 2D insulator. Scanning tunnelling microscopy (STM) and spectroscopy reveal a MOF electronic energy gap of ~200 meV, consistent with dynamical mean field theory predictions of a Mott insulator. Combining template-induced (via work function variations of the substrate) and STM probe-induced gating, we locally tune the electron population of the MOF kagome bands and induce Mott MITs. These findings enable technologies based on electrostatic control of many-body quantum phases in 2D MOFs., Comment: 34 pages, 4 figures + SI 53 pages, 33 figures

Published
2023
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10. Enhanced Itinerant Ferromagnetism in Hole-doped Transition Metal Oxides: Beyond the Canonical Double Exchange Mechanism

Author

Liu, Zhao and Medhekar, Nikhil V.

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science
Abstract

Here we demonstrate the occurrence of robust itinerant ferromagnetism in Mott-Hubbard systems at both low and high doping concentrations. Specifically, we study the effect of hole doping on the experimentally synthesized LaCrAsO via first-principles calculations and observe that the parent G-type antiferromagnetism vanishes quickly at low doping concentration ($x$ $\sim$ 0.20) and the system becomes ferromagnetic metal due to the canonical double exchange (CDE) mechanism. As $x$ continues to increase, the onsite energy difference between Cr 3$d$ and As 4$p$ orbitals decreases and the system transitions to a ferromagnetic negative charge-transfer energy metal. Therefore, the itinerant ferromagnetism doesn't terminate at intermediate $x$ as CDE mechanism usually predicts. Furthermore, our calculations reveal that both nearest and next-nearest ferromagnetic exchange coupling strengths keep growing with $x$, showing that ferromagnetism caused by negative charge-transfer energy state is "stronger" than that of CDE picture. Our work not only unveils an alternative mechanism of itinerant ferromagnetism, but also has the potential to attract immediate interest among experimentalists., Comment: 6 pages, 3 figures, comments are welcomed

Published
2023
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11. Extracting unconventional spin texture in two dimensional topological crystalline insulator bismuthene via tuning bulk-edge interactions

Author

Yin, Yuefeng, Wang, Chutian, Fuhrer, Michael S., and Medhekar, Nikhil V.

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

Tuning the interaction between the bulk and edge states of topological materials is a powerful tool for manipulating edge transport behavior, opening up exciting opportunities for novel electronic and spintronic applications. This approach is particularly suited to topological crystalline insulators (TCI), a class of topologically nontrivial compounds that are endowed with multiple degrees of topological protection. In this study, we investigate how bulk-edge interactions can influence the edge transport in planar bismuthene, a TCI with metallic edge states protected by in-plane mirror symmetry, using first principles calculations and symmetrized Wannier tight-binding models. By exploring the impact of various perturbation effects, such as device size, substrate potentials, and applied transverse electric field, we examine the evolution of the electronic structure and edge transport in planar bismuthene. Our findings demonstrate that the TCI states of planar bismuthene can be engineered to exhibit either a gapped or conducting unconventional helical spin texture via a combination of substrate and electric field effects. Furthermore, under strong electric fields, the edge states can be stabilized through a delicate control of the bulk-edge interactions. These results open up new directions for discovering novel spin transport patterns in topological materials and provide critical insights for the fabrication of topological spintronic devices., Comment: 23 pages, 8 figures

Published
2023
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12. Electrically Controlled Reversible Strain Modulation in MoS$_2$ Field-effect Transistors via an Electro-mechanically Coupled Piezoelectric Thin Film

Author

Varghese, Abin, Pandey, Adityanarayan, Sharma, Pooja, Yin, Yuefeng, Medhekar, Nikhil, and Lodha, Saurabh

Subjects
Physics - Applied Physics
Abstract

Strain can efficiently modulate the bandgap and carrier mobilities in two-dimensional (2D) materials. Conventional mechanical strain-application methodologies that rely on flexible, patterned or nano-indented substrates are severely limited by low thermal tolerance, lack of tunability and/or poor scalability. Here, we leverage the converse piezoelectric effect to electrically generate and control strain transfer from a piezoelectric thin film to electro-mechanically coupled ultra-thin 2D MoS$_2$. Electrical bias polarity change across the piezoelectric film tunes the nature of strain transferred to MoS$_2$ from compressive $\sim$0.23% to tensile $\sim$0.14% as verified through peak shifts in Raman and photoluminescence spectroscopies and substantiated by density functional theory calculations. The device architecture, built on a silicon substrate, uniquely integrates an MoS$_2$ field-effect transistor on top of a metal-piezoelectric-metal stack enabling strain modulation of transistor drain current 130$\times$, on/off current ratio 150$\times$, and mobility 1.19$\times$ with high precision, reversibility and resolution. Large, tunable tensile (1056) and compressive (-1498) strain gauge factors, easy electrical strain modulation, high thermal tolerance and substrate compatibility make this technique promising for integration with silicon-based CMOS and micro-electro-mechanical systems., Comment: Manuscript and Supplementary Information

Published
2023

13. Predicting the Early Stages of Solid-State Precipitation in Al-rich Al-Pt Alloys

Author

Su, Shenghan, Bourgeois, Laure, and Medhekar, Nikhil V.

Subjects
Condensed Matter - Materials Science
Abstract

The high strength of structural aluminium alloys depends strongly on the controlled precipitation of specific intermetallic phases, whose identity and crystal structure can be difficult to predict. Here, we investigate the Al-Pt system, which shows some similarity to the Al-Cu system as one of their main intermetallic phases, $Al_2Pt$, is nearly isostructural with $\theta^{\prime} (Al_2Cu)$, the metastable phase responsible for the high-strength of Al-Cu alloys. However, phases in Al-Pt alloys are complex and have not been studied in detail. Using a combination of density-functional theory (DFT) calculations and classical nucleation theory (CNT) applied to the Al-Pt system, we design a workflow to predict the thermodynamics of solid solution, intermediate phases such as GP zones, stable and metastable precipitates, and their precipitation sequence. This workflow can be applied to an arbitrary binary alloying system. We confirm the known stable phases $Al_4Pt$, $Al_{21}Pt_8$, $Al_2Pt$, $Al_3Pt_2$, $AlPt (\alpha \& \beta)$, $Al_3Pt_5$, $AlPt_2 (\alpha \& \beta)$ and $AlPt_3 (\alpha \& \beta)$. We also reveal the possible existence of two phases of chemical formulae $Al_5Pt$ and $Al_3Pt$. This large number of intermetallic phases is due to the strong bonding between Al and Pt, which also leads to significant favourable Pt solute formation energy in the Al matrix. Our findings are compared with the known precipitation characteristics of the binary Al-Cu and Al-Au systems. We find that the $\theta^{\prime}$-like $Al_2Pt$ precipitate phase has a lower coherent interfacial energy than $\theta^{\prime}$. Our calculations strongly suggest that $Al_2Pt$ will precipitate first in Al-rich Al-Pt alloys and will form bulk-like interfaces similar to $\eta (Al_2Au)$ rather than like $\theta^{\prime}(Al_2Cu)$., Comment: 32 pages, 9 figures in the main text. 12 pages, 7 figures in the supplementary inforamtion

Published
2023
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14. Coherent backscattering in the topological Hall effect

Author

Liu, Hong, Atencia, Rhonald Burgos, Medhekar, Nikhil, and Culcer, Dimitrie

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The mutual interplay between electron transport and magnetism has attracted considerable attention in recent years, primarily motivated by strategies to manipulate magnetic degrees of freedom electrically, such as spin-orbit torques and domain wall motion. Within this field the topological Hall effect, which originates from scalar spin chirality, is an example of inter-band quantum coherence induced by real-space inhomogeneous magnetic textures, and its magnitude depends on the winding number and chiral spin features that establish the total topological charge of the system. Remarkably, in the two decades since its discovery, there has been no research on the quantum correction to the topological Hall effect. Here we will show that, unlike the ordinary Hall effect, the inhomogeneous magnetization arising from the spin texture will give additional scattering terms in the kinetic equation, which result in a quantum correction to the topological Hall resistivity. We focus on 2D systems, where weak localization is strongest, and determine the complicated gradient corrections to the Cooperon and kinetic equation. Whereas the weak localization correction to the topological Hall effect is not large in currently known materials, we show that it is experimentally observable in dilute magnetic semiconductors. Our theoretical results will stimulate experiments on the topological Hall effect and fill the theoretical knowledge gap on weak localization corrections to transverse transport., Comment: Under review

Published
2022
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15. Correlation-induced magnetism in substrate-supported 2D metal-organic frameworks

Author

Field, Bernard, Schiffrin, Agustin, and Medhekar, Nikhil V.

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

Two-dimensional (2D) metal-organic frameworks (MOFs) in a kagome lattice can exhibit strong electron-electron interactions, which can lead to tunable quantum phases including many exotic magnetic phases. While technological developments of 2D MOFs typically take advantage of substrates for growth, support, and electrical contacts, investigations often ignore substrates and their dramatic influence on electronic properties of MOFs. Here, we show how substrates alter the correlated magnetic phases in kagome MOFs using systematic density functional theory and mean-field Hubbard calculations. We demonstrate that MOF-substrate coupling, MOF-substrate charge transfer, strain, and external electric fields are key variables, activating and deactivating magnetic phases in these materials. While we consider the example of kagome-arranged 9,10-dicyanoanthracene molecules coordinated with copper atoms, our findings should generalise to any kagome lattice. This work offers useful predictions for tunable interaction-induced magnetism in surface-supported 2D organic materials, opening the door to solid-state electronic and spintronic technologies based on such systems., Comment: 29 pages, 16 figures (including supplementary information). Clarified several of our arguments, added extra panels to Supplementary Figure 10, clarified some figure legends (results unchanged)

Published
2022
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16. Proposal for a Negative Capacitance Topological Quantum Field-Effect Transistor

Author

Fuhrer, Michael S., Edmonds, Mark T., Culcer, Dimitrie, Nadeem, Muhammad, Wang, Xiaolin, Medhekar, Nikhil, Yin, Yuefeng, and Cole, Jared H

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

A topological quantum field effect transistor (TQFET) uses electric field to switch a material from topological insulator ("on", with conducting edge states) to a conventional insulator ("off"), and can have low subthreshold swing due to strong Rashba spin-orbit interaction. Numerous materials have been proposed, and electric field switching has been demonstrated in ultrathin Na${_3}$Bi. Here we propose a negative capacitance (NC) TQFET which uses a ferroelectric to amplify the electric field and potentially achieve very low switching voltages and energies. Materials challenges for realizing the NC-TQFET are discussed., Comment: Accepted version of paper number 38-2 presented at the 67th Annual IEEE International Electron Devices Meeting (IEDM) on 15 December 2021

Published
2022

18. Large Magnetic Gap in a Designer Ferromagnet–Topological Insulator–Ferromagnet Heterostructure

Author

Li, Qile, Trang, Chi Xuan, Wu, Weikang, Hwang, Jinwoong, Cortie, David, Medhekar, Nikhil, Mo, Sung‐Kwan, Yang, Shengyuan A, and Edmonds, Mark T

Subjects
Quantum Physics, Physical Sciences, Condensed Matter Physics, heterostructure thin films, lossless transport, magnetic proximity, magnetic topological insulators, quantum anomalous Hall insulators, Chemical Sciences, Engineering, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences
Abstract

Combining magnetism and nontrivial band topology gives rise to quantum anomalous Hall (QAH) insulators and exotic quantum phases such as the QAH effect where current flows without dissipation along quantized edge states. Inducing magnetic order in topological insulators via proximity to a magnetic material offers a promising pathway toward achieving the QAH effect at a high temperature for lossless transport applications. One promising architecture involves a sandwich structure comprising two single-septuple layers (1SL) of MnBi2 Te4 (a 2D ferromagnetic insulator) with ultrathin few quintuple layer (QL) Bi2 Te3 in the middle, and it is predicted to yield a robust QAH insulator phase with a large bandgap greater than 50 meV. Here, the growth of a 1SL MnBi2 Te4 /4QL Bi2 Te3 /1SL MnBi2 Te4 heterostructure via molecular beam epitaxy is demonstrated and the electronic structure probed using angle-resolved photoelectron spectroscopy. Strong hexagonally warped massive Dirac fermions and a bandgap of 75 ± 15 meV are observed. The magnetic origin of the gap is confirmed by the observation of the exchange-Rashba effect, as well as the vanishing bandgap above the Curie temperature, in agreement with density functional theory calculations. These findings provide insights into magnetic proximity effects in topological insulators and reveal a promising platform for realizing the QAH effect at elevated temperatures.

Published
2022

19. Near-Infrared and Visible-range Optoelectronics in 2D Hybrid Perovskite/Transition Metal Dichalcogenide Heterostructures

Author

Varghese, Abin, Yin, Yuefeng, Wang, Mingchao, Lodha, Saurabh, and Medhekar, Nikhil V.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The application of ultrathin two-dimensional (2D) perovskites in near-infrared and visible-range optoelectronics has been limited owing to their inherent wide bandgaps, large excitonic binding energies and low optical absorption at higher wavelengths. Here, we show that by tailoring interfacial band alignments via conjugation with low-dimensional materials like monolayer transition metal dichalcogenides (TMD), the functionalities of 2D perovskites can be extended to diverse, visible-range photophysical applications. Based on the choice of individual constituents in the 2D perovskite/TMD heterostructures, our first principles calculations demonstrate widely tunable type-II band gaps, carrier effective masses and band offsets to enable an effective separation of photogenerated excitons for enhanced photodetection and photovoltaic applications. In addition, we show the possibilities of achieving a type-I band alignment for recombination based light emitters as well as a type-III configuration for tunnelling devices. Further, we evaluate the effect of strain on the electronic properties of the heterostructures to show a significant strain tolerance, making them prospective candidates in flexible photosensors., Comment: 38 pages, main manuscript and supporting information

Published
2021
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20. Large bandgap quantum anomalous hall insulator in a designer ferromagnet-topological insulator-ferromagnet heterostructure

Author

Li, Qile, Trang, Chi Xuan, Wu, Weikang, Hwang, Jinwoong, Medhekar, Nikhil, Mo, Sung-Kwan, Yang, Shengyuan A., and Edmonds, Mark T

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

Combining magnetism and nontrivial band topology gives rise to quantum anomalous Hall (QAH) insulators and exotic quantum phases such as the QAH effect where current flows without dissipation along quantized edge states. Inducing magnetic order in topological insulators via proximity to a magnetic material offers a promising pathway towards achieving QAH effect at high temperature for lossless transport applications. One promising architecture involves a sandwich structure comprising two single layers of MnBi2Te4 (a 2D ferromagnetic insulator) with ultra-thin Bi2Te3 in the middle, and is predicted to yield a robust QAH insulator phase with a bandgap well above thermal energy at room temperature (25 meV). Here we demonstrate the growth of a 1SL MnBi2Te4 / 4QL Bi2Te3 /1SL MnBi2Te4 heterostructure via molecular beam epitaxy, and probe the electronic structure using angle resolved photoelectron spectroscopy. We observe strong hexagonally warped massive Dirac Fermions and a bandgap of 75 meV. The magnetic origin of the gap is confirmed by the observation of broken time reversal symmetry and the exchange-Rashba effect, in excellent agreement with density functional theory calculations. These findings provide insights into magnetic proximity effects in topological insulators, that will move lossless transport in topological insulators towards higher temperature., Comment: 24 pages

Published
2021

21. Manifestation of strongly correlated electrons in a 2D kagome metal-organic framework

Author

Kumar, Dhaneesh, Hellerstedt, Jack, Field, Bernard, Lowe, Benjamin, Yin, Yuefeng, Medhekar, Nikhil V., and Schiffrin, Agustin

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science
Abstract

The kagome lattice, whose electronic valence band (VB) structure includes two Dirac bands and one flat band, offers a rich space to realise tuneable topological and strongly correlated electronic phases in two-dimensional (2D) and layered materials. While strong electron correlations have been observed in inorganic kagome crystals, they remain elusive in organic systems. The latter offer versatile synthesis protocols via molecular self-assembly and metal-ligand coordination. Here, we report the synthesis of a 2D metal-organic framework (MOF) where di-cyano-anthracene (DCA) molecules form a kagome arrangement via coordination with copper (Cu) atoms on a silver surface [Ag(111)]. Low-temperature scanning tunnelling spectroscopy revealed Kondo screening--by the Ag(111) conduction electrons--of magnetic moments localised at Cu and DCA sites of the MOF. Density functional theory and mean-field Hubbard modelling show that these local moments emerge from strong interactions between kagome MOF electrons, enabling organic 2D materials as viable platforms for strongly correlated nanoelectronics and spintronics., Comment: Main text: 32 pages, 5 figures. Supplementary Information: 51 pages, 20 figures

Published
2021
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22. Localized Wannier function based tight-binding models for two-dimensional allotropes of bismuth

Author

Li, Qile, Smith, Jackson S., Yin, Yuefeng, Wang, Chutian, Klymenko, Mykhailo V., Cole, Jared H., and Medhekar, Nikhil V.

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

With its monoelemental composition, various crystalline forms and an inherently strong spin-orbit coupling, bismuth has been regarded as an ideal prototype material to expand our understanding of topological electronic structures. In particular, two-dimensional bismuth thin films have attracted a growing interest due to potential applications in topological transistors and spintronics. This calls for an effective physical model to give an accurate interpretation of the novel topological phenomena shown by two-dimensional bismuth. However, the conventional semi-empirical approach of adapting bulk bismuth hoppings fails to capture the topological features of two-dimensional bismuth allotropes because the electronic band topology is heavily influenced by crystalline symmetries as well as atom spacings. Here we provide a new parameterization using localized Wannier functions derived from the Bloch states in first-principles calculations. We construct new tight-binding models for three types of two-dimensional bismuth allotropes: a Bi (111) bilayer, bismuthene and a Bi(110) bilayer. We demonstrate that our tight-binding models can successfully reproduce the band structures, symmetries and topological features of these two-dimensional allotropes. We anticipate that these models can be extended to other similar two-dimensional topological structures such as antimonene and arsenene. Moreover, these models can serve as a starting point for investigating the electron/spin transport and electromagnetic response in low-dimensional topological devices., Comment: 20 pages, 6 figures

Published
2021
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23. Thickness dependent tuning of the Berry curvature in a ferromagnetic Weyl semimetal

Author

Zhang, Yao, Yin, Yuefeng, Dubuis, Guy, Butler, Tane, Medhekar, Nikhil V., and Granville, Simon

Subjects
Condensed Matter - Materials Science
Abstract

Magnetic Weyl semimetals with spontaneously broken time-reversal symmetry exhibit a large intrinsic anomalous Hall effect originating from the Berry curvature. To employ this large Hall current for room temperature topo-spintronics applications, it is necessary to fabricate these materials as thin or ultrathin films. Here, we experimentally demonstrate that Weyl semimetal Co2MnGa thin films (20-50 nm) show a very large anomalous Hall angle ~11.4% at low temperature and ~9.7% at room temperature, which can be ascribed to the nontrivial topology of the band structure with large intrinsic Berry curvature. However, the anomalous Hall angle decreases significantly with thicknesses below 20 nm, which band structure calculations confirm is due to the reduction of the majority spin contribution to the Berry curvature. Our results suggest that Co2MnGa is an excellent material to realize room temperature topo-spintronics applications, however the significant thickness dependence of the Berry curvature has important implications for thin film device design

Published
2021
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24. Crossover from 2D ferromagnetic insulator to wide bandgap quantum anomalous Hall insulator in ultra-thin MnBi2Te4

Author

Trang, Chi Xuan, Li, Qile, Yin, Yuefeng, Hwang, Jinwoong, Akhgar, Golrokh, Di Bernardo, Iolanda, Grubišić-Čabo, Antonija, Tadich, Anton, Fuhrer, Michael S., Mo, Sung- Kwan, Medhekar, Nikhil, and Edmonds, Mark T.

Subjects
Condensed Matter - Materials Science
Abstract

Intrinsic magnetic topological insulators offer low disorder and large magnetic bandgaps for robust magnetic topological phases operating at higher temperatures. By controlling the layer thickness, emergent phenomena such as the Quantum Anomalous Hall (QAH) effect and axion insulator phases have been realised. These observations occur at temperatures significantly lower than the Neel temperature of bulk MnBi2Te4, and measurement of the magnetic energy gap at the Dirac point in ultra-thin MnBi2Te4 has yet to be achieved. Critical to achieving the promise of this system is a direct measurement of the layer-dependent energy gap and verifying whether the gap is magnetic in the QAH phase. Here we utilise temperature dependent angle-resolved photoemission spectroscopy to study epitaxial ultra-thin MnBi2Te4. We directly observe a layer dependent crossover from a 2D ferromagnetic insulator with a bandgap greater than 780 meV in one septuple layer (1 SL) to a QAH insulator with a large energy gap (>100 meV) at 8 K in 3 and 5 SL MnBi2Te4. The QAH gap is confirmed to be magnetic in origin, as it abruptly diminishes with increasing temperature above 8 K. The direct observation of a large magnetic energy gap in the QAH phase of few-SL MnBi2Te4 is promising for further increasing the operating temperature of QAH materials.

Published
2020
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25. Magnesium-intercalated graphene on SiC: highly n-doped air-stable bilayer graphene at extreme displacement fields

Author

Grubišić-Čabo, Antonija, Kotsakidis, Jimmy C., Yin, Yuefeng, Tadich, Anton, Haldon, Matthew, Solari, Sean, di Bernardo, Iolanda, Daniels, Kevin M., Riley, John, Huwald, Eric, Edmonds, Mark T., Myers-Ward, Rachael, Medhekar, Nikhil V., Gaskill, D. Kurt, and Fuhrer, Michael S.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We use angle-resolved photoemission spectroscopy to investigate the electronic structure of bilayer graphene at high n-doping and extreme displacement fields, created by intercalating epitaxial monolayer graphene on silicon carbide with magnesium to form quasi-freestanding bilayer graphene on magnesium-terminated silicon carbide. Angle-resolved photoemission spectroscopy reveals that upon magnesium intercalation, the single massless Dirac band of epitaxial monolayer graphene is transformed into the characteristic massive double-band Dirac spectrum of quasi-freestanding bilayer graphene. Analysis of the spectrum using a simple tight binding model indicates that magnesium intercalation results in an n-type doping of 2.1 $\times$ 10$^{14}$ cm$^{-2}$, creates an extremely high displacement field of 2.6 V/nm, opening a considerable gap of 0.36 eV at the Dirac point. This is further confirmed by density-functional theory calculations for quasi-freestanding bilayer graphene on magnesium-terminated silicon carbide, which show a similar doping level, displacement field and bandgap. Finally, magnesium-intercalated samples are surprisingly robust to ambient conditions; no significant changes in the electronic structure are observed after 30 minutes exposure in air., Comment: 46 pages including supporting information, 4 figures in the main paper and 9 figures in the supporting information

Published
2020
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26. Freestanding n-Doped Graphene via Intercalation of Calcium and Magnesium into the Buffer Layer - SiC(0001) Interface

Author

Kotsakidis, Jimmy C., Grubišić-Čabo, Antonija, Yin, Yuefeng, Tadich, Anton, Myers-Ward, Rachael L., Dejarld, Matthew, Pavunny, Shojan P., Currie, Marc, Daniels, Kevin M., Liu, Chang, Edmonds, Mark T., Medhekar, Nikhil V., Gaskill, D. Kurt, de Parga, Amadeo L. Vazquez, and Fuhrer, Michael S.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Superconductivity
Abstract

The intercalation of epitaxial graphene on SiC(0001) with Ca has been studied extensively, yet precisely where the Ca resides remains elusive. Furthermore, the intercalation of Mg underneath epitaxial graphene on SiC(0001) has not been reported. Here, we use low energy electron diffraction, x-ray photoelectron spectroscopy, secondary electron cut-off photoemission and scanning tunneling microscopy to elucidate the physical and electronic structure of both Ca- and Mg-intercalated epitaxial graphene on 6H-SiC(0001). We find that Ca intercalates underneath the buffer layer and bonds to the Si-terminated SiC surface, breaking the C-Si bonds of the buffer layer i.e. 'freestanding' the buffer layer to form Ca-intercalated quasi-freestanding bilayer graphene (Ca-QFSBLG). The situation is similar for the Mg-intercalation of epitaxial graphene on SiC(0001), where an ordered Mg-terminated reconstruction at the SiC surface and Mg bonds to the Si-terminated SiC surface are formed, resulting in Mg-intercalated quasi-freestanding bilayer graphene (Mg-QFSBLG). Ca-intercalation underneath the buffer layer has not been considered in previous studies of Ca-intercalated epitaxial graphene. Furthermore, we find no evidence that either Ca or Mg intercalates between graphene layers. However, we do find that both Ca-QFSBLG and Mg-QFSBLG exhibit very low workfunctions of 3.68 and 3.78 eV, respectively, indicating high n-type doping. Upon exposure to ambient conditions, we find Ca-QFSBLG degrades rapidly, whereas Mg-QFSBLG remains remarkably stable., Comment: 58 pages, 10 figures, 4 tables. Revised text and figures

Published
2020
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27. Crossover from 2D Ferromagnetic Insulator to Wide Band Gap Quantum Anomalous Hall Insulator in Ultrathin MnBi2Te4

Author

Trang, Chi Xuan, Li, Qile, Yin, Yuefeng, Hwang, Jinwoong, Akhgar, Golrokh, Di Bernardo, Iolanda, Grubišić-Čabo, Antonija, Tadich, Anton, Fuhrer, Michael S, Mo, Sung-Kwan, Medhekar, Nikhil V, and Edmonds, Mark T

Subjects
Quantum Physics, Physical Sciences, Condensed Matter Physics, magnetic topological insulator, thin film, MnBi2Te4, quantum anomalous Hall insulator, ferromagnetic insulator, angle-resolved photoemission spectroscopy, Nanoscience & Nanotechnology
Abstract

Intrinsic magnetic topological insulators offer low disorder and large magnetic band gaps for robust magnetic topological phases operating at higher temperatures. By controlling the layer thickness, emergent phenomena such as the quantum anomalous Hall (QAH) effect and axion insulator phases have been realized. These observations occur at temperatures significantly lower than the Néel temperature of bulk MnBi2Te4, and measurement of the magnetic energy gap at the Dirac point in ultrathin MnBi2Te4 has yet to be achieved. Critical to achieving the promise of this system is a direct measurement of the layer-dependent energy gap and verification of a temperature-dependent topological phase transition from a large band gap QAH insulator to a gapless TI paramagnetic phase. Here we utilize temperature-dependent angle-resolved photoemission spectroscopy to study epitaxial ultrathin MnBi2Te4. We directly observe a layer-dependent crossover from a 2D ferromagnetic insulator with a band gap greater than 780 meV in one septuple layer (1 SL) to a QAH insulator with a large energy gap (>70 meV) at 8 K in 3 and 5 SL MnBi2Te4. The QAH gap is confirmed to be magnetic in origin, as it becomes gapless with increasing temperature above 8 K.

Published
2021

28. Near-direct bandgap $WSe_2$/$ReS_2$ type-II pn heterojunction for enhanced ultrafast photodetection and high-performance photovoltaics

Author

Varghese, Abin, Saha, Dipankar, Thakar, Kartikey, Jindal, Vishwas, Ghosh, Sayantan, Medhekar, Nikhil V, Ghosh, Sandip, and Lodha, Saurabh

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

PN heterojunctions comprising layered van der Waals (vdW) semiconductors have been used to demonstrate current rectifiers, photodetectors, and photovoltaic devices. However, a direct or near-direct bandgap at the heterointerface that can significantly enhance optical generation, for high light absorbing few/multi-layer vdW materials, has not yet been shown. In this work, for the first time, few-layer group-6 transition metal dichalcogenide (TMD) $WSe_2$ is shown to form a sizeable (0.7 eV) near-direct bandgap with type-II band alignment at its interface with the group-7 TMD $ReS_2$ through density functional theory calculations. Further, the type-II alignment and photogeneration across the interlayer bandgap have been experimentally confirmed through micro-photoluminescence and IR photodetection measurements, respectively. High optical absorption in few-layer flakes, large conduction and valence band offsets for efficient electron-hole separation and stacking of light facing, direct bandgap $ReS_2$ on top of gate tunable $WSe_2$ are shown to result in excellent and tunable photodetection as well as photovoltaic performance through flake thickness dependent optoelectronic measurements. Few-layer flakes demonstrate ultrafast response time (5 $\mu$s) at high responsivity (3 A/W) and large photocurrent generation and responsivity enhancement at the heterostructure overlap region (10-100X) for 532 nm laser illumination. Large open-circuit voltage of 0.64 V and short-circuit current of 2.6 $\mu$A enables high output electrical power. Finally, long term air-stability and a facile single contact metal fabrication process makes the multi-functional few-layer $WSe_2$/$ReS_2$ heterostructure diode technologically promising for next-generation optoelectronic applications., Comment: Manuscript- 27 pages, 8 figures. Supporting Information- 17 pages, 17 figures

Published
2019
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29. Electronic bandstructure of in-plane ferroelectric van der Waals $\beta '-In_{2}Se_{3}$

Author

Collins, James L., Wang, Chutian, Tadich, Anton, Yin, Yuefeng, Zheng, Changxi, Hellerstedt, Jack, Grubišić-Čabo, Antonija, Tang, Shujie, Mo, Sung-Kwan, Riley, John, Huwald, Eric, Medhekar, Nikhil V., Fuhrer, Michael S., and Edmonds, Mark T.

Subjects
Condensed Matter - Materials Science
Abstract

Layered indium selenides ($In_{2}Se_{3}$) have recently been discovered to host robust out-of-plane and in-plane ferroelectricity in the $\alpha$ and $\beta$' phases, respectively. In this work, we utilise angle-resolved photoelectron spectroscopy to directly measure the electronic bandstructure of $\beta '-In_{2}Se_{3}$, and compare to hybrid density functional theory (DFT) calculations. In agreement with DFT, we find the band structure is highly two-dimensional, with negligible dispersion along the c-axis. Due to n-type doping we are able to observe the conduction band minima, and directly measure the minimum indirect (0.97 eV) and direct (1.46 eV) bandgaps. We find the Fermi surface in the conduction band is characterized by anisotropic electron pockets with sharp in-plane dispersion about the $\overline{M}$ points, yielding effective masses of 0.21 $m_{0}$ along $\overline{KM}$ and 0.33 $m_{0}$ along $\overline{\Gamma M}$. The measured band structure is well supported by hybrid density functional theory calculations. The highly two-dimensional (2D) bandstructure with moderate bandgap and small effective mass suggest that $\beta'-In_{2}Se_{3}$ is a potentially useful new van der Waals semiconductor. This together with its ferroelectricity makes it a viable material for high-mobility ferroelectric-photovoltaic devices, with applications in non-volatile memory switching and renewable energy technologies., Comment: 19 pages, 4 + 1 figures; typos corrected;added references; updated figures & discussion to reflect changes in model

Published
2019
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30. Dirac-point photocurrents due to photothermoelectric effect in non-uniform graphene devices

Author

Fuhrer, Michael S. and Medhekar, Nikhil V.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Q. Ma et al.[1] recently reported a strong photocurrent associated with charge neutrality in graphene devices with non-uniform geometries, which they interpreted as an intrinsic photoresponse enhanced by the momentum non-relaxing nature of electron-electron collisions at charge neutrality. Here we argue that gradients in charge carrier density give rise to a photothermoelectric effect (PTE) which is strongly peaked around charge neutrality, i.e. at p-n junctions, and such p-n junctions naturally arise at the edges of graphene devices due to fringing capacitance. Using known parameters, the PTE effect in the presence of charge density gradients predicts the sign, spatial distribution, gate voltage dependence, and temperature dependence of the photoresponse in non-uniform graphene devices, including predicting the observed sign change of the signal away from charge neutrality, and the non-monotonic temperature dependence, neither of which is explained by the intrinsic photocurrents in graphene. We propose future experiments which may disentangle the contributions of PTE and intrinsic photocurrent in graphene devices., Comment: Nat. Nanotechnol. (2020). Submitted as Matters Arising to Nature Nanotechnology regarding [1] Ma, Q. et al., "Giant intrinsic photoresponse in pristine graphene", Nature Nanotechnology 14, 145 (2019)

Published
2019
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31. Electronic Band Structure of In-Plane Ferroelectric van der Waals β′-In2Se3

Author

Collins, James L, Wang, Chutian, Tadich, Anton, Yin, Yuefeng, Zheng, Changxi, Hellerstedt, Jack, Grubišić-Čabo, Antonija, Tang, Shujie, Mo, Sung-Kwan, Riley, John, Huwald, Eric, Medhekar, Nikhil V, Fuhrer, Michael S, and Edmonds, Mark T

Subjects
Affordable and Clean Energy, ferroelectric, electronic band structure, indium selenide, van der Waals, infrared bandgap, optoelectronics, ARPES
Abstract

Layered indium selenides (In2Se3) have recently been discovered to host robust out-of-plane and in-plane ferroelectricity in the α- and β′-phases, respectively. In this work, we utilize angle-resolved photoelectron spectroscopy to directly measure the electronic band structure of β′In2Se3 and compare to hybrid density functional theory (DFT) calculations. In agreement with DFT, we find the band structure is highly two-dimensional, with negligible dispersion along the c-axis. Because of n-type doping we can observe the conduction band minima and directly measure the minimum indirect (0.97 eV) and direct (1.46 eV) bandgaps. We find the Fermi surface in the conduction band is characterized by anisotropic electron pockets with sharp in-plane dispersion about the M points, yielding effective masses of 0.21m0 along KM and 0.33m0 along ΓM. The measured band structure is well supported by hybrid density functional theory calculations. The highly two-dimensional (2D) band structure with moderate bandgap and small effective mass suggests that β′-In2Se3 is a potentially useful van der Waals semiconductor. This, together with its ferroelectricity makes it a viable material for high-mobility ferroelectric−photovoltaic devices, with applications in nonvolatile memory switching and renewable energy technologies.

Published
2020

34. Selective Control of Surface Spin Current in Topological Materials based on Pyrite-type OsX2 (X = Se, Te) Crystals

Author

Yin, Yuefeng, Fuhrer, Michael S., and Medhekar, Nikhil V.

Subjects
Condensed Matter - Materials Science
Abstract

Topological materials host robust surface states, which could form the basis for future electronic devices. As such states have spins that are locked to the momentum, they are of particular interest for spintronic applications. Understanding spin textures of the surface states of topologically nontrivial materials, and being able to manipulate their polarization, is therefore essential if they are to be utilized in future technologies. Here we use first-principles calculations to show that pyrite-type crystals OsX2 (X= Se, Te) are a class of topological material that can host surface states with spin polarization that can be either in-plane or out-of-plane. We show that the formation of low-energy states with symmetry-protected energy- and direction-dependent spin textures on the (001) surface of these materials is a consequence of a transformation from a topologically trivial to nontrivial state, induced by spin orbit interactions. The unconventional spin textures of these surface states feature an in-plane to out-of-plane spin polarization transition in the momentum space protected by local symmetries. Moreover, the surface spin direction and magnitude can be selectively filtered in specific energy ranges. Our demonstration of a new class of topological material with controllable spin textures provide a platform for experimentalists to detect and exploit unconventional surface spin textures in future spin-based nanoelectronic devices.

Published
2018
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35. Atomistic Mechanisms of Mg Insertion Reactions in Group XIV Anodes for Mg-Ion Batteries

Author

Wang, Mingchao, Yuwono, Jodie A., Vasudevan, Vallabh, Birbilis, Nick, and Medhekar, Nikhil V.

Subjects
Condensed Matter - Materials Science
Abstract

Magnesium (Mg) metal has been widely explored as an anode material for Mg-ion batteries (MIBs) owing to its large specific capacity and dendrite-free operation. However critical challenges, such as the formation of passivation layers during battery operation and anode-electrolyte-cathode incompatibilities, limit the practical application of Mg-metal anodes for MIBs. Motivated by the promise of group XIV elements (namely Si, Ge and Sn) as anodes for lithium- and sodium-ion batteries, here we conduct systematic first principles calculations to explore the thermodynamics and kinetics of group XIV anodes for Mg-ion batteries, and to identify the atomistic mechanisms of the electrochemical insertion reactions of Mg ions. We confirm the formation of amorphous MgxX phases (where X = Si, Ge, Sn) in anodes via the breaking of the stronger X-X bonding network replaced by weaker Mg-X bonding. Mg ions have higher diffusivities in Ge and Sn anodes than in Si, resulting from weaker Ge-Ge and Sn-Sn bonding networks. In addition, we identify thermodynamic instabilities of MgxX that require a small overpotential to avoid aggregation (plating) of Mg at anode/electrolyte interfaces. Such comprehensive first principles calculations demonstrate that amorphous Ge and crystalline Sn can be potentially effective anodes for practical applications in Mg-ion batteries., Comment: 29 pages, 6 figures

Published
2018

36. Tunable electronic properties of partially edge-hydrogenated armchair boron-nitrogen-carbon nanoribbons

Author

Alaal, Naresh, Medhekar, Nikhil, and Shukla, Alok

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

We employ first-principles calculations based density-functional-theory (DFT) approach to study electronic properties of partially and fully edge-hydrogenated armchair boron-nitrogen-carbon (BNC) nanoribbons (ABNCNRs), with widths between 0.85 nm to 2.3 nm. Due to the partial passivation of edges, electrons which do not participate in the bonding, form new energy states located near the Fermi-level. Because of these additional bands, some ABNCNRs exhibit metallic behavior, which is quite uncommon in armchair nanoribbons. Our calculations reveal that the metallic behavior is observed for the following passivation patterns: (i) when B atom from one edge, and N atom from another edge, are unpassivated. (ii) when N atoms from both the edges are unpassivated. (iii) when C atom from one edge, and N atom from another edge, are unpassivated. Furthermore, spin-polarization is also observed for certain passivation schemes, which is also quite uncommon for armchair nanoribbons. Thus, our results suggest that ABNCNRs exhibit a wide range of electronic and {magnetic }properties in that the fully edge-hydrogenated ABNCNRs are direct band gap semiconductors, while partially edge-hydrogenated ones are either semiconducting, or metallic, while simultaneously exhibiting spin polarization, based on the nature of passivation. We also find that the ribbons with larger widths are more stable, as compared to the narrower ones., Comment: 23 pages, 18 figures (main paper); 4 pages, 5 figures (supporting information), accepted for publication in Physical Chemistry Chemical Physics

Published
2018
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39. The bi-layered precipitate phase zeta in the Al-Ag alloy system

Author

Zhang, Zezhong, Bourgeois, Laure, Rosalie, Julian M., and Medhekar, Nikhil V.

Subjects
Condensed Matter - Materials Science
Abstract

The Al-Ag system is thought to be a well-understood model system used to study diffusional phase transformations in alloys. Here we report the existence of a new precipitate phase, zeta, in this classical system using scanning transmission electron microscopy (STEM). The zeta phase has a modulated structure composed of alternating bilayers enriched in Al or Ag. Our in situ annealing experiments reveal that the zeta phase is an intermediate precipitate phase between GP zones epsilon and gamma prime. First-principles calculations show that z is a local energy minimum state formed during Ag clustering in Al. The layered structure of zeta is analogous to the well-known Ag segregation at the precipitate-matrix interfaces when Ag is micro- alloyed in various aluminium alloys., Comment: This is the preprint before paper submission. Please refer to Acta Materialia for the final version of the paper, supplementary materials and movies. Link: http://www.sciencedirect.com/science/article/pii/S1359645417303555

Published
2017
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40. From Half-metal to Semiconductor: Electron-correlation Effects in Zigzag SiC Nanoribbons From First Principles

Author

Alaal, Naresh, Loganathan, Vaideesh, Medhekar, Nikhil, and Shukla, Alok

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

We performed electronic structure calculations based on the first-principles many-body theory approach in order to study quasiparticle band gaps, and optical absorption spectra of hydrogen-passivated zigzag SiC nanoribbons. Self-energy corrections are included using the GW approximation, and excitonic effects are included using the Bethe-Salpeter equation. We have systematically studied nanoribbons that have widths between 0.6 $\text{nm}$ and 2.2 $\text{nm}$. Quasiparticle corrections widened the Kohn-Sham band gaps because of enhanced interaction effects, caused by reduced dimensionality. Zigzag SiC nanoribbons with widths larger than 1 nm, exhibit half-metallicity at the mean-field level. The self-energy corrections increased band gaps substantially, thereby transforming the half-metallic zigzag SiC nanoribbons, to narrow gap spin-polarized semiconductors. Optical absorption spectra of these nanoribbons get dramatically modified upon inclusion of electron-hole interactions, and the narrowest ribbon exhibits strongly bound excitons, with binding energy of 2.1 eV. Thus, the narrowest zigzag SiC nanoribbon has the potential to be used in optoelectronic devices operating in the IR region of the spectrum, while the broader ones, exhibiting spin polarization, can be utilized in spintronic applications., Comment: 22 pages, 6 figures (included)

Published
2017
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46. Tunable Hybridization Between Electronic States of Graphene and Physisorbed Hexacene

Author

Yin, Yuefeng, Cervenka, Jiri, and Medhekar, Nikhil V.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Non-covalent functionalization via physisorption of organic molecules provides a scalable approach for modifying the electronic structure of graphene while preserving its excellent carrier mobilities. Here we investigated the physisorption of long-chain acenes, namely, hexacene and its fluorinated derivative perfluorohexacene, on bilayer graphene for tunable graphene devices using first principles methods. We find that the adsorption of these molecules leads to the formation of localized states in the electronic structure of graphene close to its Fermi level, which could be readily tuned by an external electric field. The electric field not only creates a variable band gap as large as 250 meV in bilayer graphene, but also strongly influences the charge redistribution within the molecule-graphene system. This charge redistribution is found to be weak enough not to induce strong surface doping, but strong enough to help preserve the electronic states near the Dirac point of graphene., Comment: 17 pages, 7 figures, supporting information

Published
2015
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47. First principles many-body calculations of electronic structure and optical properties of SiC nanoribbons

Author

Alaal, Naresh, Loganathan, Vaideesh, Medhekar, Nikhil, and Shukla, Alok

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

A first principles many-body approach is employed to calculate the band structure and optical response of nanometer sized ribbons of SiC. Many-body effects are incorporated using the GW approximation, and excitonic effects are included using the Bethe-Salpeter equation. Both unpassivated and hydrogen passivated armchair SiC nanoribbons are studied. As a consequence of low dimensionality, large quasiparticle corrections are seen to the Kohn-Sham energy gaps. In both cases quasiparticle band gaps are increased by up to 2 eV, as compared to their Kohn-Sham energy values. Inclusion of electron-hole interactions modifies the absorption spectra significantly, giving rise to strongly bound excitonic peaks in these systems.The results suggest that hydrogen-passivated armchair SiC nanoribbons have the potential to be used in optoelectronic devices operating in the UV-Vis region of the spectrum. We also compute the formation energies of these nanoribbons as a function of their widths, and conclude that hydrogen-saturated ribbons will be much more stable as compared to the bare ones., Comment: 18 pages, 7 figures (included)

Published
2015
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48. Design Principles of Diketopyrrolopyrrole‐Thienopyrrolodione Acceptor1–Acceptor2 Copolymers.

Author

Erhardt, Andreas, Hungenberg, Julian, Chantler, Paul, Kuhn, Meike, Huynh, Thanh Tung, Hochgesang, Adrian, Goel, Mahima, Müller, Christian J., Roychoudhury, Subhayan, Thomsen, Lars, Medhekar, Nikhil V., Herzig, Eva M., Prendergast, David, Thelakkat, Mukundan, and McNeill, Christopher R.

Subjects
OPEN-circuit voltage, ORGANIC semiconductors, SOLAR cells, GRAZING incidence, ELECTRON mobility
Abstract

The design principles of acceptor1–acceptor2 copolymers featuring alternating diketopyrrolopyrrole (DPP) and thienopyrrolodione (TPD) moieties are investigated. The investigated series of polymers is obtained by varying the aromatic linker between the two acceptor motifs between thiophene, thiazole, pyridine, and benzene. High electron affinities between 3.96 and 4.42 eV, facilitated by the synergy of the acceptor motifs are determined with optical gaps between 1.37 and 2.02 eV. Grazing incidence wide‐angle X‐ray scattering studies reveal a range of film morphologies after thermal annealing, including face‐on, end‐on and superstructure edge‐on‐like crystallites. Conversely, all materials form thin edge‐on layers on the polymer–air interface, as demonstrated by multi‐elemental near‐edge X‐ray absorption fine‐structure spectroscopy. The benefit of the electron‐deficient linkers thiazole and pyridine is evident: In organic field effect transistors, electron mobilities of up to 4.6 × 10−2 cm2 V−1 s−1 are obtained with outstanding on/off current ratios of 5 × 105, facilitated by the absence of detectable hole transport in these materials. Viability for all‐polymer solar cells is assessed in active layer blends with the donor polymer PM6, yielding a maximum average power conversion efficiency of 4.8% and an open circuit voltage above 1 V. [ABSTRACT FROM AUTHOR]

Published
2024
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