STM Study of 2D Metal Chalcogenides and Heterostructures

Zhang, Fan

31 January 2022

In recent years, two-dimensional (2D) van der Waals (vdW) materials have aroused much interest for their unique structural, thermal, optical, and electronic properties and have become a hot topic in condensed matter physics and material science. Many research methods, including scanning tunneling microscopy (STM), transmission electron microscopy (TEM), optical and transport measurements, have been used to investigate these unique properties. Among them, STM stands out as a powerful characterization tool with atomic resolution and is capable of simultaneously revealing both atomic structures and local electronic properties. This dissertation focuses on scanning tunneling microscopy and spectroscopy (STM/S) investigation of 2D metal chalcogenides and heterostructures. The first part of the dissertation focuses on the continuous interface in WS2/MoS2 heterostructures grown by the chemical vapor deposition (CVD) method. We observed a closed interface between the MoS2 monolayer and the heterobilayer with atomic resolution. Furthermore, our scanning tunneling spectroscopy (STS) results and density functional theory (DFT) calculations revealed band gaps of the heterobilayer and the MoS2 monolayer agree with previously reported values for MoS2 monolayer and MoS2/WS2 heterobilayer on SiO2 fabricated through the mechanical exfoliation method. The results could deepen our understanding of the growth mechanism, interlayer interactions and electronic structures of 2D transition metal dichalcogenides (TMD) heterostructures synthesized via CVD. The second part of the dissertation focuses on phase transformation in 2D In2Se3. We observed that 2D In2Se3 layers with thickness ranging from single to ~20 layers stabilized at the beta phase with a superstructure at room temperature. After cooling down to around 180 K, the beta phase converted to a more stable beta' phase that was distinct from previously reported phases in 2D In2Se3. The kinetics of the reversible thermally driven beta-to-beta' phase transformation was investigated by temperature dependent transmission electron microscopy and Raman spectroscopy, combined with the expected minimum-energy pathways obtained from our first-principles calculations. Furthermore, DFT calculations reveal in-plane ferroelectricity in the beta' phase. STS measurements show that the indirect bandgap of monolayer beta' In2Se3 is 2.50 eV, which is larger than that of the multilayer form with a measured value of 2.05 eV. Our results on the reversible thermally driven phase transformation in 2D In2Se3 will provide insights to tune the functionalities of 2D In2Se3 and other emerging 2D ferroelectric materials and shed light on their numerous potential applications like non-volatile memory devices. The third part of the dissertation focuses on domain boundaries in 2D ferroelectric In2Se3. The atomic structure of domain boundaries in two-dimensional (2D) ferroelectric beta' In2Se3 is visualized with scanning tunneling microscopy and spectroscopy (STM/S) combined with DFT calculations. A double-barrier energy potential across the 60° tail to tail domain boundaries in monolayer beta' In2Se3 is also revealed. The results will deepen our understanding of domain boundaries in 2D ferroelectric materials and stimulate innovative applications of these materials. / Doctor of Philosophy / Two-dimensional (2D) materials are materials consisting of a single layer or a few layers of atoms. They exhibit unique and interesting properties distinct from their bulk counterparts. Over the past decade, much effort has been devoted to a large family of 2D materials — 2D metal chalcogenides that exhibit fascinating structural and electronic properties. These 2D metal chalcogenides can also be stacked together to form various heterostructures. The scanning tunneling microscope (STM) is a powerful tool to study these materials with atomic resolution and is capable of simultaneously revealing both atomic structures and local electronic properties. It can also be used to manipulate nanometer-scale structures on the material surface. In this dissertation, we use scanning tunneling microscopy and spectroscopy (STM/S) to investigate 2D metal chalcogenides and heterostructures. The first part of the dissertation focuses on WS2/MoS2 heterostructures grown by the chemical vapor deposition (CVD) method. We observed a closed interface between the MoS2 monolayer and the heterobilayer with atomic resolution. Furthermore, our scanning tunneling spectroscopy (STS) results and density functional theory (DFT) calculations revealed band gaps of the heterobilayer and the MoS2 monolayer. The results could deepen our understanding of the growth mechanism, interlayer interactions and electronic structures of 2D transition metal dichalcogenides (TMD) heterostructures synthesized via CVD. The second part of the dissertation focuses on phase transformation in 2D In2Se3. We observed that 2D In2Se3 layers transform from beta phase to a more stable beta' phase when the sample is cooled down from room temperature to 77 K. This thermally driven beta-to-beta' phase transformation was found to be reversible by temperature dependent transmission electron microscopy and Raman spectroscopy, corroborated with the expected minimum-energy pathways obtained from our first-principles calculations. Furthermore, DFT calculations reveal in-plane ferroelectricity in the beta' phase. Our results on the reversible thermally driven phase transformation in 2D In2Se3 will provide insights to tune the functionalities of 2D In2Se3 and other emerging 2D ferroelectric materials. The third part of the dissertation focuses on domain boundaries in 2D ferroelectric In2Se3. The atomic structure of domain boundaries in 2D ferroelectric beta' In2Se3 is visualized by using STM/S combined with DFT calculations. A double-barrier energy potential across the 60° tail to tail domain boundaries in monolayer beta' In2Se3 is also revealed. The results will deepen our understanding of domain boundaries in 2D ferroelectric materials and stimulate innovative applications of these materials.

2D materials

Scanning Tunneling Microscopy (STM)

Transition Metal Dichalcogenides (TMD)

Ferroelectricity

Electroluminescence from Nanoscale Gaps and Single-Molecule Junctions

Paoletta, Angela Lyn

January 2024

The term “electroluminescence” refers to light emission resulting from the application of an electrical bias. Electron tunneling across a biased, nanoscale junction can serve as the excitation source for photon emission. This effect is also mediated by the plasmonic environment of the junction, where a strong local field can enhance light emission by orders of magnitude. This dissertation presents measurements of electroluminescence from nanoscale gaps and single-molecule junctions. These measurements are made possible by a custom light emission detection system coupled to a scanning tunneling microscope break junction (STM-BJ) instrument. Conductance and light emission data are obtained simultaneously for thousands of junctions. Chapter 1 discusses molecular optoelectronics, a field at the intersection of plasmonic phenomena and molecular electronics, and introduces the STM-BJ technique for measuring molecular junctions. Chapter 2 describes the light emission detection setup that is operated in tandem with the STM-BJ instrument. Chapter 3 presents a study of Au tunnel junctions. This lays the groundwork for the plasmonics at play in these electroluminescent systems, detangling how gap size, electrical bias, and emission wavelength affect plasmonic enhancement. In Chapters 4 and 5, Au-molecule-Au junctions are investigated in some of the first experimental studies of single-molecule electroluminescence at ambient conditions. Chapter 4 uses light emission data from molecular junctions to estimate finite-frequency shot noise and uncover critical information about transmission characteristics. Chapter 5 presents one of the first examples of single-molecule strong light-matter coupling in an electroluminescent system, substantiated by spectroscopy data. This dissertation greatly expands on existing knowledge of plasmonic phenomena, particularly in relation to electroluminescent devices. Furthermore, it lays a strong foundation for single-molecule spectroscopy studies using the STM-BJ technique.

Chemistry

Electroluminescence

Nanochemistry

Tunneling (Physics)

Scanning tunneling microscopy

Photon emission

Plasmons (Physics)

Optoelectronics

Applications of Charged Aromatic Species in Electronics

Prindle, Claudia

January 2024

Charged organic species are ubiquitous throughout organic chemistry. They are ideal ascomponents in organic electronics, and are common as transition states or intermediates in many organic transformations. This dissertation details the investigation of the effect of external electric fields on reactions with charged transition states, as well as the incorporation of triarylmethylium and triangulenium cations as components in single-molecule and organic electronics. Chapter 1 provides an introduction to the scanning tunneling microscope break junction (STM-BJ) technique, which is used as a tool to assess the effect of external electric fields on reaction rate and the performance of single-molecule devices. In this chapter, the different design criteria for molecules used in both single-molecule and optoelectronic devices are discussed. Chapter 2 evaluates the effect of electric fields on two classes of reactions with charged transition states – the Menshutkin reaction and the Chapman rearrangement. Chapter 3 describes triarylmethylium and triangulenium dyes as single-molecule devices, and how their conductance can be tuned through different pendant substituents via Fano resonances. Chapter 4 details an ongoing project that incorporates triangulenium cores to yield a modular donor-acceptor system that shows tunable quenching of emission. Finally, Chapter 5 chronicles the progress of our TikTok account called @IvyLeagueScience and outlines the success criteria for using short-form videos as a way of conducting scientific outreach.

Chemistry

Chemistry, Organic

Organic electronics

Cations

Scanning tunneling microscopy

Internet videos

Aromatic compounds

Electric Field and Neural Network in Catalysis: Amine Acylation in the Scanning Tunneling Microscope-Break Junction and Oxadiazoliums in Stetter Catalysis

Wang, Xiye

January 2024

Electric fields influence reactions by stabilization of charge-separated transition states. While this has been a longstanding hypothesis supported computationally, recent experimental confirmations highlight the potential for leveraging electric field effects to drive small molecule reactions far from equilibrium. Herein we report electric-field catalysis of an alkane solvent-derived acylation reaction in the scanning tunneling microscope-break junction (STM-BJ), providing additional support for this hypothesis. Additionally, the design and reactivity of an internally charged zwitterionic ligand are disclosed. Synthetic access of metal ligands bearing opposing charged functional groups permitted the examination of stochiometric metalation and catalytic behavior of electric field-bearing ligands.While traditionally computation has been used to rationalize why a particular catalyst is successful descriptively, it has been rarely used to screen candidates and prescriptively provide optimal catalyst structure. We report a neural network-enabled catalyst screening platform that dramatically reduce the resource intensity for examining a large chemical space. We leverage this platform to examine azolium N-heterocyclic carbene (NHC) precursors to address the lack of compatibility for electron-rich aryl aldehydes in the NHC-catalyzed Stetter reaction. This led to the discovery of a new class of azolium NHC precursor: oxadiazoliums that proved competent in achieving the target reaction addressing current limitations in Stetter catalysis.

Chemistry

Electric fields

Amines

Acylation

Polyzwitterions

Catalysis

Scanning tunneling microscopy

Carbenes (Methylene compounds)

Scanning Tunneling Microscopy Studies of Fe Dopants on GaAs (110)

Smith, Rebekah

January 2022

No description available.

Physics

Condensed Matter Physics

Scanning tunneling microscopy

STM

Fe dopants on GaAs (110) surface

scanning tunneling spectroscopy

SP-STM

GaAs

Fe

iron

dopant

GaAs (110)

dilute magnetic semiconductor

Microscopic tunneling experiments on atomic impurities in graphene and on magnetic thin films

Scheffler, Martha

24 August 2015

This thesis presents investigations on hydrogenated graphene by scanning tunneling microscopy and spectroscopy (STM/STS) as well as the implementation of spin-polarized STM. Preparation processes for a magnetic standard sample and spin-sensitive chromium tips are developed. The measurements on graphene reveal specific hydrogen adsorption sites in low coverage and the formation of a pattern at higher coverage. Both is found to be in agreement with previous predictions and calculations. Upon hydrogenation, an impurity midgap state emerges in the density of states which is measured directly for the first time. Complementing angle resolved photoemission experiments confirm that this state is dispersionless over the whole Brillouin zone. A routine is developed to prepare the standard sample system of ultra-thin iron films on tungsten (Fe/W(110)). Investigations on this system confirm the magnetic properties known from literature, including the presence of a spin spiral, and prove that it is well suited for the characterization of spin-polarized tips. Different approaches for the preparation of tips from the antiferromagnetic material chromium are tested. Among these, a promising new method is presented: The coating of crystalline chromium tips with fresh chromium material suggests reproducibility of the tip characteristics. The performance of the produced tips in STM measurements is excellent in regard to a fixed spin-polarization, high resolution and stability. Especially, a recovery of the tip magnetization direction proposed in this thesis makes this new preparation method superior to all processes yielding antiferromagnetic tips reported so far. / Inhalt der vorliegenden Arbeit sind Untersuchungen von hydogeniertem Graphen mittels Rastertunnelmikroskopie und -spektroskopie (RTM/RTS) sowie die Einführung spin-polarisierter RTM. Im Rahmen dessen wurden Präparationsprozesse für magnetische Standardproben und spin-sensitive Chrom-Spitzen entwickelt. Die Messungen an Graphen zeigen spezifische Wasserstoff-Adsorptionsstellen bei geringer Bedeckung und die Ausbildung eines Musters bei höherer Bedeckung, jeweils in Übereinstimmung mit Vorhersagen und Berechnungen. Der durch Hydrogenierung entstehende Störstellenzustand in der Bandlücke der Zustandsdichte wurde zum ersten Mal direkt gemessen. Ergänzende winkelaufgelöste Photoelektronenspektroskopieexperimente bestätigen, dass dieser Zustand in der gesamten Brillouinzone dispersionsfrei ist. Ein Verfahren zur Herstellung magnetischer Standardproben aus ultradünnen Eisenfilmen auf Wolfram (Fe/W(110)) wurde entwickelt. RTM-Untersuchungen an diesem System bestätigen die bereits aus der Literatur bekannten magnetischen Eigenschaften, insbesondere das Vorhandensein einer Spinspirale. Damit ist Fe/W(110) hervorragend geeignet für die Charakterisierung spin-polarisierter Spitzen. Verschiedene Ansätze, die zur Herstellung von Spitzen aus dem antiferromagnetischen Material Chrom verfolgt wurden, werden präsentiert, darunter auch eine vielversprechende neue Methode: Das Aufwachsen eines frischen Chromfilms auf kristalline Spitzen desselben Materials verspricht eine Reproduzierbarkeit von Spitzeneigenschaften. Der Einsatz von so hergestellten Spitzen in RTMMessungen ist geprägt von einer festgelegten Spin-Polarisation, hohem Auflösungsvermögen und Stabilität. Insbesondere die mögliche Reproduzierbarkeit der Magnetisierungsrichtung, die in dieser Arbeit diskutiert wird, macht diese Methode allen bisher berichteten Herstellungprozessen antiferromagnetischer Spitzen überlegen.

STM

Rastertunnelmikroskopie

spinpolarisiert

Graphen

Magnetismus

STM

scanning tunneling microscopy

spin polarized

graphene

magnetism

ddc:530

rvk:UH 6320

The electronic structure of the nematic materials Sr₃Ru₂O₇ and Ca(Co[subscript(x)]Fe[subscript(1-x)])₂As₂

Allan, Milan P.

January 2010

We investigated the electronic structure of the two nematic materials Sr₃Ru₂O₇ and Ca(Fe₀.₉₇Co₀.₀₃As)₂ using spectroscopic – imaging scanning tunneling microscopy (SI-STM) and angle resolved photoemission spectroscopy (ARPES). – – – Sr₃Ru₂O₇ is an itinerant metamagnet that shows a putative quantum critical endpoint at 8 Tesla, submersed by the formation of a nematic electronic phase. Using ARPES, we identified at least 5 Fermi pockets in agreement with quantum oscillation measurements. Surprisingly, we found Fermi velocities up to an order of magnitude lower than in single layer Sr₂RuO₄ and up to 35 times lower than predicted by ab initio calculations. Many bands are confined in an energy range of only ∼10 meV below the Fermi level. This, as well as distinct peak-dip-hump shapes of the spectra with a characteristic energy of around ∼5 meV indicate strong correlations and a possible nontrivial mechanism that is absent in single layer Sr₂RuO₄ and connected to the nematicity. The quasiparticle interference of one of the bands was detected by SI-STM, which was also used to measure subatomic features with the symmetries of the relevant Ru d orbitals. – – – In the second mate- rial, the iron-based high-temperature superconductor Ca(Fe[subscript(1-x)]Co[subscript(x)]As)₂, we discovered electronic nematic nano-pattern in its under-doped ‘parent’ state. We spectroscopically imaged this state in real space over large areas and across domain boundaries that change the directionality of the nano-pattern by 90°. We propose that oriented, dimer-shaped electronic nematogens are responsible for this pattern, in striking contrast to what has been expected and observed in electronic nematic materials. The dimers consist of two Gaussian conductance peaks separated by about 8 a[subscript(FeFe)]. Unidirectionality also shows in the quasiparticle interference pattern of the delocalized electrons. The dispersion is in agreement with scattering from the α₂ band discovered by ARPES but has distinct C₂ symmetry, not inconsistent with a C₄-symmetric band scattered by the proposed dimers.

Alkali metal and simple gas atom adsorption and coadsorption on transition metal surfaces

Norris, Andrew George

January 2000

No description available.

530.41

Fullerene nanostructures, monolayers and thin films

Cotier, Bradley Neville

January 2000

No description available.

530.41

STM studies of semiconducting metal oxides

Dixon, Richard

January 1999

No description available.

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