Andrew J. Mannix
Assistant Professor of Materials Science and Engineering
Web page: https://www.2d-matsci.com/
Bio
Andrew J. Mannix is an assistant professor of Materials Science and Engineering at Stanford University. He completed his B.S. in Materials Science and Engineering at the University of Illinois at Urbana-Champaign, and his Ph.D. in Materials Science and Engineering at Northwestern University as an NSF GRFP Fellow, where he worked on the growth and atomic-scale characterization of new 2D materials. Before moving to Stanford, Andy was a Kadanoff-Rice Postdoctoral Fellow in the James Franck Institute at the University of Chicago, where he developed new methods of atomically-thin nanomaterials growth, processing, and automated heterostructure assembly. His lab at Stanford focuses on the growth, assembly and atomic-scale characterization of 2D materials for new electronic and quantum information science applications.
Professional Education
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Ph.D., Northwestern University, Materials Science and Engineering (2017)
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B.S., University of Illinois at Urbana-Champaign, Materials Science and Engineering (2012)
Current Research and Scholarly Interests
Atomically thin 2D materials incorporated into van der Waals heterostructures are a promising platform to deterministically engineer quantum materials with atomically resolved thickness and abrupt interfaces across macroscopic length scales while retaining excellent material properties. Because 2D materials exhibit a wide range of electronic characteristics with properties that often rival conventional electronic materials — e.g., metals, semiconductors, insulators, and superconductors — it is possible to combine them in virtually infinite variety to achieve diverse heterostructures. Furthermore, the van der Waals interface enables interlayer twist engineering to modify the interlayer symmetry, periodic potential (moiré superlattice), and hybridization, which has resulted in novel quantum states of matter. Many of these heterostructures, especially those involving specific interlayer twist angles, would be otherwise infeasible through direct growth.
The Mannix Group is developing a unique set of in-house capabilities to systematically elucidate the fundamental structure-property relationships underpinning the growth of 2D materials and their inclusion into van der Waals heterostructures. Greater understanding will allow us to provide a platform for engineering the properties of matter at the atomic scale and offer guidance for emerging applications in novel electronics and in quantum information science.
To accomplish this, we employ: precise growth techniques such as chemical vapor deposition and molecular beam epitaxy; automated van der Waals assembly; and atomically-resolved microscopy including cryo-STM/AFM.
2024-25 Courses
- Ethics and Broader Impacts in Materials Science
MATSCI 232 (Spr) - Introduction to Materials Science, Energy Emphasis
ENGR 50E (Win) - Materials Science Colloquium
MATSCI 230 (Aut, Win, Spr) - Structure and Symmetry
MATSCI 184 (Aut) - Structure and Symmetry
MATSCI 214 (Aut) -
Independent Studies (5)
- Master's Research
MATSCI 200 (Aut, Win, Spr) - Ph.D. Research
MATSCI 300 (Aut, Win, Spr) - Practical Training
MATSCI 299 (Aut, Win, Spr) - Undergraduate Independent Study
MATSCI 100 (Aut, Win, Spr) - Undergraduate Research
MATSCI 150 (Aut, Win, Spr)
- Master's Research
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Prior Year Courses
2023-24 Courses
- Ethics and Broader Impacts in Materials Science
MATSCI 232 (Spr) - Introduction to Materials Science, Energy Emphasis
ENGR 50E (Win) - Materials Science Colloquium
MATSCI 230 (Aut, Win, Spr) - Structure and Symmetry
MATSCI 184 (Aut) - Structure and Symmetry
MATSCI 214 (Aut)
2022-23 Courses
- Ethics and Broader Impacts in Materials Science
MATSCI 232 (Spr) - Introduction to Materials Science, Energy Emphasis
ENGR 50E (Win) - Structure and Symmetry
MATSCI 184 (Aut) - Structure and Symmetry
MATSCI 214 (Aut)
2021-22 Courses
- Ethics and Broader Impacts in Materials Science
MATSCI 232 (Spr) - Structure and Symmetry
MATSCI 184 (Aut) - Structure and Symmetry
MATSCI 214 (Aut)
- Ethics and Broader Impacts in Materials Science
Stanford Advisees
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Doctoral Dissertation Reader (AC)
Lauren Hoang, Jackson Meng, Crystal Nattoo, Katie Neilson, Chenyi Xia -
Postdoctoral Faculty Sponsor
Qingrui Cao, Anh Tuan Hoang, Zhepeng Zhang, Xiang Zhu -
Doctoral Dissertation Advisor (AC)
Aldo Chavez, Risa Hocking -
Master's Program Advisor
Emily Kuo, Ting-Yu Kuo, Tommy Lin -
Doctoral Dissertation Co-Advisor (AC)
Yuan-Mau Lee
All Publications
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Understanding the Impact of Contact-Induced Strain on the Electrical Performance of Monolayer WS2 Transistors.
Nano letters
2024
Abstract
Two-dimensional (2D) electronics require low contact resistance (RC) to approach their fundamental limits. WS2 is a promising 2D semiconductor that is often paired with Ni contacts, but their operation is not well understood considering the nonideal alignment between the Ni work function and the WS2 conduction band. Here, we investigate the effects of contact size on nanoscale monolayer WS2 transistors and uncover that Ni contacts impart stress, which affects the WS2 device performance. The strain applied to the WS2 depends on contact size, where long (1 μm) contacts (RC ≈ 1.7 kΩ·μm) show a 78% reduction in RC compared to shorter (0.1 μm) contacts (RC ≈ 7.8 kΩ·μm). We also find that thermal annealing can relax the WS2 strain in long-contact devices, increasing RC to 8.5 kΩ·μm. These results reveal that thermo-mechanical phenomena can significantly influence 2D semiconductor-metal contacts, presenting opportunities to optimize device performance through nanofabrication and thermal budget.
View details for DOI 10.1021/acs.nanolett.4c02616
View details for PubMedID 39365938
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Chemically Tailored Growth of 2D Semiconductors via Hybrid Metal-Organic Chemical Vapor Deposition.
ACS nano
2024
Abstract
Two-dimensional (2D) semiconducting transition-metal dichalcogenides (TMDCs) are an exciting platform for excitonic physics and next-generation electronics, creating a strong demand to understand their growth, doping, and heterostructures. Despite significant progress in solid-source (SS-) and metal-organic chemical vapor deposition (MOCVD), further optimization is necessary to grow highly crystalline 2D TMDCs with controlled doping. Here, we report a hybrid MOCVD growth method that combines liquid-phase metal precursor deposition and vapor-phase organo-chalcogen delivery to leverage the advantages of both MOCVD and SS-CVD. Using our hybrid approach, we demonstrate WS2 growth with tunable morphologies─from separated single-crystal domains to continuous monolayer films─on a variety of substrates, including sapphire, SiO2, and Au. These WS2 films exhibit narrow neutral exciton photoluminescence line widths down to 27-28 meV and room-temperature mobility up to 34-36 cm2 V-1 s-1. Through simple modifications to the liquid precursor composition, we demonstrate the growth of V-doped WS2, MoxW1-xS2 alloys, and in-plane WS2-MoS2 heterostructures. This work presents an efficient approach for addressing a variety of TMDC synthesis needs on a laboratory scale.
View details for DOI 10.1021/acsnano.4c02164
View details for PubMedID 39230253
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Torsional force microscopy of van der Waals moirés and atomic lattices.
Proceedings of the National Academy of Sciences of the United States of America
2024; 121 (10): e2314083121
Abstract
In a stack of atomically thin van der Waals layers, introducing interlayer twist creates a moiré superlattice whose period is a function of twist angle. Changes in that twist angle of even hundredths of a degree can dramatically transform the system's electronic properties. Setting a precise and uniform twist angle for a stack remains difficult; hence, determining that twist angle and mapping its spatial variation is very important. Techniques have emerged to do this by imaging the moiré, but most of these require sophisticated infrastructure, time-consuming sample preparation beyond stack synthesis, or both. In this work, we show that torsional force microscopy (TFM), a scanning probe technique sensitive to dynamic friction, can reveal surface and shallow subsurface structure of van der Waals stacks on multiple length scales: the moirés formed between bi-layers of graphene and between graphene and hexagonal boron nitride (hBN) and also the atomic crystal lattices of graphene and hBN. In TFM, torsional motion of an Atomic Force Microscope (AFM) cantilever is monitored as it is actively driven at a torsional resonance while a feedback loop maintains contact at a set force with the sample surface. TFM works at room temperature in air, with no need for an electrical bias between the tip and the sample, making it applicable to a wide array of samples. It should enable determination of precise structural information including twist angles and strain in moiré superlattices and crystallographic orientation of van der Waals flakes to support predictable moiré heterostructure fabrication.
View details for DOI 10.1073/pnas.2314083121
View details for PubMedID 38427599
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Torsional periodic lattice distortions and diffraction of twisted 2D materials.
Nature communications
2022; 13 (1): 7826
Abstract
Twisted 2D materials form complex moire structures that spontaneously reduce symmetry through picoscale deformation within a mesoscale lattice. We show twisted 2D materials contain a torsional displacement field comprised of three transverse periodic lattice distortions (PLD). The torsional PLD amplitude provides a single order parameter that concisely describes the structural complexity of twisted bilayer moires. Moreover, the structure and amplitude of a torsional periodic lattice distortion is quantifiable using rudimentary electron diffraction methods sensitive to reciprocal space. In twisted bilayer graphene, the torsional PLD begins to form at angles below 3.89° and the amplitude reaches 8 pm around the magic angle of 1.1°. At extremely low twist angles (e.g. below 0.25°) the amplitude increases and additional PLD harmonics arise to expand Bernal stacked domains separated by well defined solitonic boundaries. The torsional distortion field in twisted bilayer graphene is analytically described and has an upper bound of 22.6 pm. Similar torsional distortions are observed in twisted WS2, CrI3, and WSe2/MoSe2.
View details for DOI 10.1038/s41467-022-35477-x
View details for PubMedID 36535920
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Robotic four-dimensional pixel assembly of van der Waals solids.
Nature nanotechnology
1800
Abstract
Van der Waals (vdW) solids can be engineered with atomically precise vertical composition through the assembly of layered two-dimensional materials1,2. However, the artisanal assembly of structures from micromechanically exfoliated flakes3,4 is not compatible with scalable and rapid manufacturing. Further engineering of vdW solids requires precisely designed and controlled composition over all three spatial dimensions and interlayer rotation. Here, we report a robotic four-dimensional pixel assembly method for manufacturing vdW solids with unprecedented speed, deliberate design, large area and angle control. We used the robotic assembly of prepatterned 'pixels' made from atomically thin two-dimensional components. Wafer-scale two-dimensional material films were grown, patterned through a clean, contact-free process and assembled using engineered adhesive stamps actuated by a high-vacuum robot. We fabricated vdW solids with up to 80 individual layers, consisting of 100*100mum2 areas with predesigned patterned shapes, laterally/vertically programmed composition and controlled interlayer angle. This enabled efficient optical spectroscopic assays of the vdW solids, revealing new excitonic and absorbance layer dependencies in MoS2. Furthermore, we fabricated twisted N-layer assemblies, where we observed atomic reconstruction of twisted four-layer WS2 at high interlayer twist angles of ≥4°. Our method enables the rapid manufacturing of atomically resolved quantum materials, which could help realize the full potential of vdW heterostructures as a platform for novel physics2,5,6 and advanced electronic technologies7,8.
View details for DOI 10.1038/s41565-021-01061-5
View details for PubMedID 35075299
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Resist-Free Lithography for Monolayer Transition Metal Dichalcogenides.
Nano letters
1800
Abstract
Photolithography and electron-beam lithography are the most common methods for making nanoscale devices from semiconductors. While these methods are robust for bulk materials, they disturb the electrical properties of two-dimensional (2D) materials, which are highly sensitive to chemicals used during lithography processes. Here, we report a resist-free lithography method, based on direct laser patterning and resist-free electrode transfer, which avoids unintentional modification to the 2D materials throughout the process. We successfully fabricate large arrays of field-effect transistors using MoS2 and WSe2 monolayers, the performance of which reflects the properties of the pristine materials. Furthermore, using these pristine devices as a reference, we reveal that among the various stages of a conventional lithography process, exposure to a solvent like acetone changes the electrical conductivity of MoS2 the most. This new approach will enable a rational design of reproducible processes for making large-scale integrated circuits based on 2D materials and other surface-sensitive materials.
View details for DOI 10.1021/acs.nanolett.1c04081
View details for PubMedID 35005964
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Near-equilibrium growth from borophene edges on silver
SCIENCE ADVANCES
2019; 5 (9): eaax0246
Abstract
Two-dimensional boron, borophene, was realized in recent experiments but still lacks an adequate growth theory for guiding its controlled synthesis. Combining ab initio calculations and experimental characterization, we study edges and growth kinetics of borophene on Ag(111). In equilibrium, the borophene edges are distinctly reconstructed with exceptionally low energies, in contrast to those of other two-dimensional materials. Away from equilibrium, sequential docking of boron feeding species to the reconstructed edges tends to extend the given lattice out of numerous polymorphic structures. Furthermore, each edge can grow via multiple energy pathways of atomic row assembly due to variable boron-boron coordination. These pathways reveal different degrees of anisotropic growth kinetics, shaping borophene into diverse elongated hexagonal islands in agreement with experimental observations in terms of morphology as well as edge orientation and periodicity. These results further suggest that ultrathin borophene ribbons can be grown at low temperature and low boron chemical potential.
View details for DOI 10.1126/sciadv.aax0246
View details for Web of Science ID 000491128800091
View details for PubMedID 31598552
View details for PubMedCentralID PMC6764835
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Borophene as a prototype for synthetic 2D materials development
NATURE NANOTECHNOLOGY
2018; 13 (6): 444-450
Abstract
The synthesis of 2D materials with no analogous bulk layered allotropes promises a substantial breadth of physical and chemical properties through the diverse structural options afforded by substrate-dependent epitaxy. However, despite the joint theoretical and experimental efforts to guide materials discovery, successful demonstrations of synthetic 2D materials have been rare. The recent synthesis of 2D boron polymorphs (that is, borophene) provides a notable example of such success. In this Perspective, we discuss recent progress and future opportunities for borophene research. Borophene combines unique mechanical properties with anisotropic metallicity, which complements the canon of conventional 2D materials. The multi-centre characteristics of boron-boron bonding lead to the formation of configurationally varied, vacancy-mediated structural motifs, providing unprecedented diversity in a mono-elemental 2D system with potential for electronic applications, chemical functionalization, materials synthesis and complex heterostructures. With its foundations in computationally guided synthesis, borophene can serve as a prototype for ongoing efforts to discover and exploit synthetic 2D materials.
View details for DOI 10.1038/s41565-018-0157-4
View details for Web of Science ID 000434715700011
View details for PubMedID 29875501
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Synthesis and chemistry of elemental 2D materials
NATURE REVIEWS CHEMISTRY
2017; 1 (2)
View details for DOI 10.1038/s41570-016-0014
View details for Web of Science ID 000401919800003
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Synthesis of borophenes: Anisotropic, two-dimensional boron polymorphs
SCIENCE
2015; 350 (6267): 1513-1516
Abstract
At the atomic-cluster scale, pure boron is markedly similar to carbon, forming simple planar molecules and cage-like fullerenes. Theoretical studies predict that two-dimensional (2D) boron sheets will adopt an atomic configuration similar to that of boron atomic clusters. We synthesized atomically thin, crystalline 2D boron sheets (i.e., borophene) on silver surfaces under ultrahigh-vacuum conditions. Atomic-scale characterization, supported by theoretical calculations, revealed structures reminiscent of fused boron clusters with multiple scales of anisotropic, out-of-plane buckling. Unlike bulk boron allotropes, borophene shows metallic characteristics that are consistent with predictions of a highly anisotropic, 2D metal.
View details for DOI 10.1126/science.aad1080
View details for Web of Science ID 000366591100055
View details for PubMedID 26680195
View details for PubMedCentralID PMC4922135
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Deterministic fabrication of graphene hexagonal boron nitride moire superlattices.
Proceedings of the National Academy of Sciences of the United States of America
2024; 121 (40): e2410993121
Abstract
The electronic properties of moire heterostructures depend sensitively on the relative orientation between layers of the stack. For example, near-magic-angle twisted bilayer graphene (TBG) commonly shows superconductivity, yet a TBG sample with one of the graphene layers rotationally aligned to a hexagonal Boron Nitride (hBN) cladding layer provided experimental observation of orbital ferromagnetism. To create samples with aligned graphene/hBN, researchers often align edges of exfoliated flakes that appear straight in optical micrographs. However, graphene or hBN can cleave along either zig-zag or armchair lattice directions, introducing a [Formula: see text] ambiguity in the relative orientation of two flakes. By characterizing the crystal lattice orientation of exfoliated flakes prior to stacking using Raman and second-harmonic generation for graphene and hBN, respectively, we unambiguously align monolayer graphene to hBN at a near-[Formula: see text], not [Formula: see text], relative twist angle. We confirm this alignment by torsional force microscopy of the graphene/hBN moire on an open-face stack, and then by cryogenic transport measurements, after full encapsulation with a second, nonaligned hBN layer. This work demonstrates a key step toward systematically exploring the effects of the relative twist angle between dissimilar materials within moire heterostructures.
View details for DOI 10.1073/pnas.2410993121
View details for PubMedID 39331413
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Quantitative determination of twist angle and strain in Van der Waals moiré superlattices
APPLIED PHYSICS LETTERS
2024; 125 (11)
View details for DOI 10.1063/5.0223777
View details for Web of Science ID 001313187100002
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Thermal relaxation of strain and twist in ferroelectric hexagonal boron nitride moiré interfaces
JOURNAL OF APPLIED PHYSICS
2024; 136 (2)
View details for DOI 10.1063/5.0210112
View details for Web of Science ID 001272420800003
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Biaxial Tensile Strain Enhances Electron Mobility of Monolayer Transition Metal Dichalcogenides.
ACS nano
2024
Abstract
Strain engineering can modulate the properties of two-dimensional (2D) semiconductors for electronic and optoelectronic applications. Recent theory and experiments have found that uniaxial tensile strain can improve the electron mobility of monolayer MoS2, a 2D semiconductor, but the effects of biaxial strain on charge transport are not well characterized in 2D semiconductors. Here, we use biaxial tensile strain on flexible substrates to probe electron transport in monolayer WS2 and MoS2 transistors. This approach experimentally achieves 2* higher on-state current and mobility with 0.3% applied biaxial strain in WS2, the highest mobility improvement at the lowest strain reported to date. We also examine the mechanisms behind this improvement through density functional theory simulations, concluding that the enhancement is primarily due to reduced intervalley electron-phonon scattering. These results underscore the role of strain engineering in 2D semiconductors for flexible electronics, sensors, integrated circuits, and other optoelectronic applications.
View details for DOI 10.1021/acsnano.3c08996
View details for PubMedID 38921699
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Thiol-based defect healing of WSe2 and WS2
NPJ 2D MATERIALS AND APPLICATIONS
2023; 7 (1)
View details for DOI 10.1038/s41699-023-00421-0
View details for Web of Science ID 001053706300001
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Wafer-scale synthesis of monolayer two-dimensional porphyrin polymers for hybrid superlattices
SCIENCE
2019; 366 (6471): 1379-+
Abstract
The large-scale synthesis of high-quality thin films with extensive tunability derived from molecular building blocks will advance the development of artificial solids with designed functionalities. We report the synthesis of two-dimensional (2D) porphyrin polymer films with wafer-scale homogeneity in the ultimate limit of monolayer thickness by growing films at a sharp pentane/water interface, which allows the fabrication of their hybrid superlattices. Laminar assembly polymerization of porphyrin monomers could form monolayers of metal-organic frameworks with Cu2+ linkers or covalent organic frameworks with terephthalaldehyde linkers. Both the lattice structures and optical properties of these 2D films were directly controlled by the molecular monomers and polymerization chemistries. The 2D polymers were used to fabricate arrays of hybrid superlattices with molybdenum disulfide that could be used in electrical capacitors.
View details for DOI 10.1126/science.aax9385
View details for Web of Science ID 000502802300060
View details for PubMedID 31699884
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Edge states in the honeycomb reconstruction of two-dimensional silicon nanosheets
APPLIED PHYSICS LETTERS
2019; 115 (2)
View details for DOI 10.1063/1.5095414
View details for Web of Science ID 000486786000023
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Amino Acid Immobilization of Copper Surface Diffusion on Cu(111)
ADVANCED MATERIALS INTERFACES
2019; 6 (7)
View details for DOI 10.1002/admi.201900021
View details for Web of Science ID 000468010200016
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Borophene Synthesis on Au(111)
ACS NANO
2019; 13 (4): 3816-3822
Abstract
Borophene (the first two-dimensional (2D) allotrope of boron) is emerging as a groundbreaking system for boron-based chemistry and, more broadly, the field of low-dimensional materials. Exploration of the phase space for growth is critical because borophene is a synthetic 2D material that does not have a bulk layered counterpart and thus cannot be isolated via exfoliation methods. Herein, we report synthesis of borophene on Au(111) substrates. Unlike previously studied growth on Ag substrates, boron diffuses into Au at elevated temperatures and segregates to the surface to form borophene islands as the substrate cools. These observations are supported by ab initio modeling of interstitial boron diffusion into the Au lattice. Borophene synthesis also modifies the surface reconstruction of the Au(111) substrate, resulting in a trigonal network that templates growth at low coverage. This initial growth is composed of discrete borophene nanoclusters, whose shape and size are consistent with theoretical predictions. As the concentration of boron increases, nanotemplating breaks down and larger borophene islands are observed. Spectroscopic measurements reveal that borophene grown on Au(111) possesses a metallic electronic structure, suggesting potential applications in 2D plasmonics, superconductivity, interconnects, electrodes, and transparent conductors.
View details for DOI 10.1021/acsnano.8b09339
View details for Web of Science ID 000466052900007
View details for PubMedID 30844248
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Driving chemical interactions at graphene-germanium van der Waals interfaces via thermal annealing
APPLIED PHYSICS LETTERS
2018; 113 (21)
View details for DOI 10.1063/1.5053083
View details for Web of Science ID 000450896600024
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Resolving the Chemically Discrete Structure of Synthetic Borophene Polymorphs
NANO LETTERS
2018; 18 (5): 2816-2821
Abstract
Atomically thin two-dimensional (2D) materials exhibit superlative properties dictated by their intralayer atomic structure, which is typically derived from a limited number of thermodynamically stable bulk layered crystals (e.g., graphene from graphite). The growth of entirely synthetic 2D crystals, those with no corresponding bulk allotrope, would circumvent this dependence upon bulk thermodynamics and substantially expand the phase space available for structure-property engineering of 2D materials. However, it remains unclear if synthetic 2D materials can exist as structurally and chemically distinct layers anchored by van der Waals (vdW) forces, as opposed to strongly bound adlayers. Here, we show that atomically thin sheets of boron (i.e., borophene) grown on the Ag(111) surface exhibit a vdW-like structure without a corresponding bulk allotrope. Using X-ray standing wave-excited X-ray photoelectron spectroscopy, the positions of boron in multiple chemical states are resolved with sub-angström spatial resolution, revealing that the borophene forms a single planar layer that is 2.4 Å above the unreconstructed Ag surface. Moreover, our results reveal that multiple borophene phases exhibit these characteristics, denoting a unique form of polymorphism consistent with recent predictions. This observation of synthetic borophene as chemically discrete from the growth substrate suggests that it is possible to engineer a much wider variety of 2D materials than those accessible through bulk layered crystal structures.
View details for DOI 10.1021/acs.nanolett.7b05178
View details for Web of Science ID 000432093200011
View details for PubMedID 29653052
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Epitaxial graphene-encapsulated surface reconstruction of Ge(110)
PHYSICAL REVIEW MATERIALS
2018; 2 (4)
View details for DOI 10.1103/PhysRevMaterials.2.044004
View details for Web of Science ID 000429945400002
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Self-assembly of electronically abrupt borophene/organic lateral heterostructures
SCIENCE ADVANCES
2017; 3 (2): e1602356
Abstract
Two-dimensional boron sheets (that is, borophene) have recently been realized experimentally and found to have promising electronic properties. Because electronic devices and systems require the integration of multiple materials with well-defined interfaces, it is of high interest to identify chemical methods for forming atomically abrupt heterostructures between borophene and electronically distinct materials. Toward this end, we demonstrate the self-assembly of lateral heterostructures between borophene and perylene-3,4,9,10-tetracarboxylic dianhydride (PTCDA). These lateral heterostructures spontaneously form upon deposition of PTCDA onto submonolayer borophene on Ag(111) substrates as a result of the higher adsorption enthalpy of PTCDA on Ag(111) and lateral hydrogen bonding among PTCDA molecules, as demonstrated by molecular dynamics simulations. In situ x-ray photoelectron spectroscopy confirms the weak chemical interaction between borophene and PTCDA, while molecular-resolution ultrahigh-vacuum scanning tunneling microscopy and spectroscopy reveal an electronically abrupt interface at the borophene/PTCDA lateral heterostructure interface. As the first demonstration of a borophene-based heterostructure, this work will inform emerging efforts to integrate borophene into nanoelectronic applications.
View details for DOI 10.1126/sciadv.1602356
View details for Web of Science ID 000397039500039
View details for PubMedID 28261662
View details for PubMedCentralID PMC5321450
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Substrate-Induced Nanoscale Undulations of Borophene on Silver
NANO LETTERS
2016; 16 (10): 6622-6627
Abstract
Two-dimensional (2D) materials tend to be mechanically flexible yet planar, especially when adhered on metal substrates. Here, we show by first-principles calculations that periodic nanoscale one-dimensional undulations can be preferred in borophenes on concertedly reconstructed Ag(111). This "wavy" configuration is more stable than its planar form on flat Ag(111) due to anisotropic high bending flexibility of borophene that is also well described by a continuum model. Atomic-scale ultrahigh vacuum scanning tunneling microscopy characterization of borophene grown on Ag(111) reveals such undulations, which agree with theory in terms of topography, wavelength, Moiré pattern, and prevalence of vacancy defects. Although the lattice is coherent within a borophene island, the undulations nucleated from different sides of the island form a distinctive domain boundary when they are laterally misaligned. This structural model suggests that the transfer of undulated borophene onto an elastomeric substrate would allow for high levels of stretchability and compressibility with potential applications to emerging stretchable and foldable devices.
View details for DOI 10.1021/acs.nanolett.6b03349
View details for Web of Science ID 000385469800093
View details for PubMedID 27657852
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Sub-5 nm, globally aligned graphene nanoribbons on Ge(001)
APPLIED PHYSICS LETTERS
2016; 108 (21)
View details for DOI 10.1063/1.4950959
View details for Web of Science ID 000377024400037
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Electronic and Mechanical Properties of Graphene-Germanium Interfaces Grown by Chemical Vapor Deposition
NANO LETTERS
2015; 15 (11): 7414-7420
Abstract
Epitaxially oriented wafer-scale graphene grown directly on semiconducting Ge substrates is of high interest for both fundamental science and electronic device applications. To date, however, this material system remains relatively unexplored structurally and electronically, particularly at the atomic scale. To further understand the nature of the interface between graphene and Ge, we utilize ultrahigh vacuum scanning tunneling microscopy (STM) and scanning tunneling spectroscopy (STS) along with Raman and X-ray photoelectron spectroscopy to probe interfacial atomic structure and chemistry. STS reveals significant differences in electronic interactions between graphene and Ge(110)/Ge(111), which is consistent with a model of stronger interaction on Ge(110) leading to epitaxial growth. Raman spectra indicate that the graphene is considerably strained after growth, with more point-to-point variation on Ge(111). Furthermore, this native strain influences the atomic structure of the interface by inducing metastable and previously unobserved Ge surface reconstructions following annealing. These nonequilibrium reconstructions cover >90% of the surface and, in turn, modify both the electronic and mechanical properties of the graphene overlayer. Finally, graphene on Ge(001) represents the extreme strain case, where graphene drives the reorganization of the Ge surface into [107] facets. From this work, it is clear that the interaction between graphene and the underlying Ge is not only dependent on the substrate crystallographic orientation, but is also tunable and strongly related to the atomic reconfiguration of the graphene-Ge interface.
View details for DOI 10.1021/acs.nanolett.5b02833
View details for Web of Science ID 000364725400037
View details for PubMedID 26506006
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Graphene-Silicon Heterostructures at the Two-Dimensional Limit
CHEMISTRY OF MATERIALS
2015; 27 (17): 6085-6090
View details for DOI 10.1021/acs.chemmater.5b02602
View details for Web of Science ID 000361086100033
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Direct oriented growth of armchair graphene nanoribbons on germanium
NATURE COMMUNICATIONS
2015; 6: 8006
Abstract
Graphene can be transformed from a semimetal into a semiconductor if it is confined into nanoribbons narrower than 10 nm with controlled crystallographic orientation and well-defined armchair edges. However, the scalable synthesis of nanoribbons with this precision directly on insulating or semiconducting substrates has not been possible. Here we demonstrate the synthesis of graphene nanoribbons on Ge(001) via chemical vapour deposition. The nanoribbons are self-aligning 3° from the Ge〈110〉 directions, are self-defining with predominantly smooth armchair edges, and have tunable width to <10 nm and aspect ratio to >70. In order to realize highly anisotropic ribbons, it is critical to operate in a regime in which the growth rate in the width direction is especially slow, <5 nm h(-1). This directional and anisotropic growth enables nanoribbon fabrication directly on conventional semiconductor wafer platforms and, therefore, promises to allow the integration of nanoribbons into future hybrid integrated circuits.
View details for DOI 10.1038/ncomms9006
View details for Web of Science ID 000360351200004
View details for PubMedID 26258594
View details for PubMedCentralID PMC4918381
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Silicon Growth at the Two-Dimensional Limit on Ag(111)
ACS NANO
2014; 8 (7): 7538-7547
Abstract
Having fueled the microelectronics industry for over 50 years, silicon is arguably the most studied and influential semiconductor. With the recent emergence of two-dimensional (2D) materials (e.g., graphene, MoS2, phosphorene, etc.), it is natural to contemplate the behavior of Si in the 2D limit. Guided by atomic-scale studies utilizing ultrahigh vacuum (UHV), scanning tunneling microscopy (STM), and spectroscopy (STS), we have investigated the 2D limits of Si growth on Ag(111). In contrast to previous reports of a distinct sp(2)-bonded silicene allotrope, we observe the evolution of apparent surface alloys (ordered 2D silicon-Ag surface phases), which culminate in the precipitation of crystalline, sp(3)-bonded Si(111) nanosheets. These nanosheets are capped with a √3 honeycomb phase that is isostructural to a √3 honeycomb-chained-trimer (HCT) reconstruction of Ag on Si(111). Further investigations reveal evidence for silicon intermixing with the Ag(111) substrate followed by surface precipitation of crystalline, sp(3)-bonded silicon nanosheets. These conclusions are corroborated by ex situ atomic force microscopy (AFM), transmission electron microscopy (TEM), Raman spectroscopy, and X-ray photoelectron spectroscopy (XPS). Even at the 2D limit, scanning tunneling spectroscopy shows that the sp(3)-bonded silicon nanosheets exhibit semiconducting electronic properties.
View details for DOI 10.1021/nn503000w
View details for Web of Science ID 000339463100114
View details for PubMedID 25000460
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Solid-source growth and atomic-scale characterization of graphene on Ag(111)
NATURE COMMUNICATIONS
2013; 4
View details for DOI 10.1038/ncomms3804
View details for Web of Science ID 000328025800001