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Electronic Properties of Heterostructures of 2D Materials: An Ab-Initio StudyHadadi, Wafa 31 January 2020 (has links)
Researchers have recently become interested in two-dimensional materials such as graphene,
hexagonal boron nitride (h-BN), Transition Metal Dichalcogenides (TMDs), etc. Their 2D
hexagonal structures result in unique properties, which make these materials attractive for
scientists and engineers. In this work, we investigated the electronic properties of graphene,
h-BN, and MoS2 based on density functional theory (DFT). We first studied the electronic
properties of monolayers of different materials. We found a zero bandgap and observed
massless Dirac Hamiltonian in graphene. For h-BN, a large bandgap at K-point was observed.
Also, we observed the bandgap opening in MoS2 and a strong splitting of its bands. Then,
we extended these studies to graphene and h-BN bilayers. For graphene bilayer, we observed
a gapless material and massive Dirac fermions. For h-BN bilayer, an indirect bandgap was
observed, smaller in comparison with its monolayer. The main focus of this study was the
investigation of graphene/h-BN heterostructures for different stacking configurations. The
suitability of h-BN as a substrate for graphene is due to its small lattice constant mismatch
with graphene and its high insulating gap (~ 5 eV). Another important aspect to be observed
in graphene/h-BN heterostructures is the gap opening brought by the h-BN layer proximity
to the initially gapless graphene layer. We found the effect of bandgap opening in graphene/h-
BN and determined the most stable configuration which is the AB[CB]. This work supports
the findings of many researchers who demonstrate that graphene/h-BN heterostructures are
very useful as building blocks for nanodevices with desirable electronic properties.
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Aerosol Jet Printing of Selective Molecular Inks for Patterning of 2D MoS<sub>2</sub>Lai, Diane Wenbi January 2017 (has links)
No description available.
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Multimodal Quantum Sensing with Solid-State Spins in Diamond:Zhang, Xin-Yue January 2024 (has links)
Thesis advisor: Brian B. Zhou / This thesis presents work in the context of multimodal magnetometry for two-dimensional (2d) materials. Research on van der Waals materials has been rapidly emerging and several imaging techniques have been developed in the past decades. Among the modern techniques, solid-state spins feature outstanding sensitivity and nano-scale spatial resolution. Yet their full capacity in sensing still has room for improvement, as the quantum nature of their properties haven't been fully utilized. My research involves developing state-of-the-art sensing techniques to add new `function modules' to the nitrogen-vacancy (NV) centers, with the goal of uncovering dynamical magnetic and electrical phenomena of 2d materials. In the first chapter I will briefly discuss the basic opto-spin properties of the NV center. One shall see why NV is preferred as a quantum sensing probe: the opto-spin property comes handy as one simply counts photons to manipulate and read out quantum states, and the stability and long quantum coherence time makes NV adaptive with various environments and engineering. In the second chapter I will discuss the experimental setup with the focus on the home-built confocal microscope, which equips our sensing technique with the pump-probe scanning ability of sub-um 2d resolution. In the third chapter I will discuss the developments of the sensing protocols, including the ac susceptometry and the opto-magnetization mapping, based on the lock-in method using the quantum dynamical decoupling sequences. In the fourth chapter I will describe the ac susceptibility measurements on thin CrBr3 flakes. The magnetization behaviors under kHz to MHz excitations reveal the domain morphology and domain wall mobility, providing insights to the exchange interaction of the chromium trihalides in the 2d limit. In the fifth chapter I will describe the pump-probe measurements on few-layer CrCl3 flakes. The mapping result demonstrates a photo-generated enhancement of the in-plane magnetization. Along with the time-resolved photoluminescence measurement, the results are indicative of a defect-assisted Auger recombination process of excitons. To conclude, the multimodal sensing techniques with NV developed in this thesis allow for more versatile experiments with sensitivity for low-dimensional systems. The developments bring up new perspectives on fundamental physics in atomically thin materials, providing new ideas for future technological applications such as spintronics and quantum memory. / Thesis (PhD) — Boston College, 2024. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Physics.
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Modification of graphene for applications in optoelectronic devicesJones, Gareth Francis January 2017 (has links)
In this thesis, we investigate how the optical and electronic properties of graphene may be modified in proximity to various other materials. We present several examples of how modification in this way can help make graphene better suited for specific device applications. We develop a method of up-scaling the fabrication of FeCl3-intercalated few-layer graphene from micron-sized flakes to macroscopic films so that it may be used as a transparent electrode in flexible light-emitting devices. We also find that photo-responsive junctions can be arbitrarily written into FeCl3-intercalated few-layer graphene by means of optical lithography. These junctions produce photocurrent signals that are directly proportional to incident optical power over an extended range compared to other graphene photodetectors. Through theoretical analysis of these junctions, we conclude that the enhanced cooling of hot carriers with lattice phonons is responsible for this behaviour. Finally, we trial rubrene single crystals as the light-absorbing layer in a graphene phototransistor. We find that rubrene single crystal-graphene interfaces exhibit enhanced charge transfer efficiencies under illumination with extremely weak light signals. Through a comparative study with similar devices, we conclude that the wide variation in sensitivity amongst graphene phototransistors is largely due to extraneous factors relating to device geometry and measurement conditions.
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Experimental and theoretical studies of electronic and mechanical properties of two-dimensional (2D) WSe₂Zhang, Rui January 2018 (has links)
Two-dimensional (2D) transition metal dichalcogenides (TMDs) with intrinsic band gaps are considered to be prospective alternatives for graphene in the applications of emerging nano-semiconductor devices. As a significant member of the TMDs family, WSe₂ with superior optical properties attracts increasing attention, especially in the optoelectronics. In this thesis, the electronic and mechanical properties of 2D WSe₂ have been studied experimentally and theoretically. Firstly, the fabrication of substrate-supported and suspended pre-patterned WSe₂ FETs with the low-cost optical lithography and vapour HF etching technology have been realised. The subsequent electrical measurement of the fabricated WSe₂ FETs indicates that the WSe₂/dielectric interface can affect the electrical performance of 2D WSe₂ negatively. To gain more insights on the impact of field-effect on 2D WSe₂, first-principle calculations have been conducted in this research to study the evolutions of the crystal structure, electronic band structure, conductive channel size, and electrical transport property of WSe2 under various levels of field-effect. Furthermore, a layer thinning and chemical doping method of 2D WSe₂ by vapour XeF₂ exposure featured with good air-stability, scalability, and controllability has been developed to enable the layer engineering of 2D WSe₂ and integration of 2D WSe₂ to logic circuits, solar cells, and light-emitting diodes (LED). The thinning and doping mechanism has been investigated with a combination of Raman spectroscopy, photoluminescence (PL) spectroscopy, and Xray photoelectron spectroscopy (XPS) characterization techniques. Afterwards, the inplane elastic properties (including the Young's modulus, breaking strain, and etc.) of 2D WSe₂ have been measured with nanoindentation experiments implemented by atomic force microscopy (AFM). The results prove the suitability of 2D WSe₂ in the applications of flexible devices and nanoelectromechanical systems (NEMS) operating in the audio resonance frequency, such as acoustic sensors and loudspeakers. To provide a comprehensive understanding of the strain engineering of 2D WSe₂, the strain induced variations of the crystal structure, electronic band structure, and electrical transport property of 2D WSe₂ have been further studied with first-principle calculations, which paves the way for the performance tuning of 2D WSe₂ devices via strain and applications of 2D WSe₂ in strain sensors.
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Quantum electrodynamics of semiconducting nanomaterials in optical microcavitiesFlatten, Lucas Christoph January 2017 (has links)
Semiconducting nanocrystals in open-access microcavities are promising systems in which enhanced light-matter interactions lead to quantum effects such as the modulation of the spontaneous emission process and exciton-polariton formation. In this thesis I present improvements of the open cavity platform which serves to confine the electromagnetic field with mode volumes down to the λ<sup>3</sup> regime and demonstrate results in both the weak and strong coupling regimes of cavity quantum electrodynamics with a range of different low-dimensional materials. I report cavity fabrication details allowing a peak finesse of 5 × 10<sup>4</sup> and advanced photonic structures such as coupled cavities in the open cavity geometry. By incorporating two-dimensional materials and nanoplatelets in the cavity I demonstrate the strong coupling regime of light-matter interaction with the formation of exciton-polaritons, quasi-particles composed of both photon and exciton, at room temperature. In the perturbative weak coupling regime I show pronounced modulation of the single-photon emission from CdSe/ZnS quantum dots and the two-dimensional material WSe<sub>2</sub> and demonstrate Purcell enhancement of the spontaneous emission rate by factors of 2 at room temperature and 8 at low temperature. The findings presented in this thesis pave the way to establish open microcavities as a platform for a wide range of applications in nanophotonics and quantum information technologies.
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Synthesis of 2D materials and their applications in advanced sodium ion batteriesZhang, Fan 22 March 2022 (has links)
Sodium-ion batteries (SIBs) are rechargeable batteries analogous to lithium-ion batteries but use sodium ions (Na+) as the charge carriers. They are considered a promising alternative for lithium-ion batteries (LIBs) in renewable large-scale energy storage applications due to their similar electrochemical mechanisms and abundant sodium resources. Two-dimensional (2D) materials, with atomic or molecular thickness and large lateral lengths, have emerged as important functional materials due to their unique structures and excellent properties. These 2D nanosheets have been highly studied as sodium-ion battery anodes. They have large interlayer spacing, which can effectively buffer the big volume expansion and prevent electrode collapse during the charge-discharge process. Different strategies such as preparing composites, heterostructures, expanded structures, and chemical functionalization can greatly improve cycling stability and lead to high reversible capacity. In this dissertation, state-of-the-art SIB based on 2D material electrodes will be presented. In particular, Tin-based 2D materials and laser-scribed graphene anodes are discussed. Different strategies involving engineering both synthesis methods, intrinsic properties of materials, and device architecture are used to optimize the battery performance.
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Functional Two-Dimensional Superatomic MaterialsHe, Shoushou January 2024 (has links)
This dissertation describes the synthesis of superatomic materials as well as their chemical modifications to tune properties and impart functions.
Chapter 1 gives a general introduction to the topics discussed in the later chapters. The discussion includes superatoms (molecular clusters) and superatomic materials. Chapter 2 discusses the site-selective surface modification of a two-dimensional (2D) superatomic semiconductor Re⁶Se⁸Cl² and its influence on the solution processibility of nanosheets. 2D superatomic Re⁶Se⁸Cl² will continue to be the focus of Chapters 3 and 4.
Chapter 3 discusses my efforts in advancing the surface modification of Re⁶Se⁸Cl² to build catalytically active monolayers on the surface of the superatomic nanosheets. Chapter 4 details an electrochemical doping method to significantly enhance the electrical transport properties of Re⁶Se⁸Cl². In Chapter 5, I will move onto discussing a molecular [Co⁶Se⁸] cluster.
I will detail my efforts on modifying the ligand coordination sphere, as well as its influence on the reactivity and electronic properties.
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Hybrid van der Waals heterostructures of zero-dimensional and two-dimensional materialsZheng, Zhikun, Zhang, Xianghui, Neumann, Christof, Emmrich, Daniel, Winter, Andreas, Vieker, Henning, Liu, Wei, Lensen, Marga, Gölzhäuser, Armin, Turchanin, Andrey 11 December 2015 (has links) (PDF)
van der Waals heterostructures meet other low-dimensional materials. Stacking of about 1 nm thick nanosheets with out-of-plane anchor groups functionalized with fullerenes integrates this zero-dimensional material into layered heterostructures with a well-defined chemical composition and without degrading the mechanical properties. The developed modular and highly applicable approach enables the incorporation of other low-dimensional materials, e.g. nanoparticles or nanotubes, into heterostructures significantly extending the possible building blocks.
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Two-dimensional Tellurium: Material Characterizations, Electronic Applications and Quantum TransportGang Qiu (7584812) 31 October 2019 (has links)
<div>Since the debut of graphene, many 2D materials have emerged as promising candidates for silicon alternatives to extend Moore’s Law, such as MoS<sub>2</sub> and phosphorene. However, some common shortcomings such as low mobility, instability and lack of massive production methods limit the exploration and applications of these materials. Here, we introduce a novel member to the 2D category – high-mobility air-stable 2D tellurium film (tellurene).</div><div><br></div><div>Tellurium (Te) is a narrow bandgap semiconductor with unique one-dimensional chiral structure. Recently, a hydrothermal synthesizing method was developed to produce large-area tellurene nanofilms with thickness ranging from tens of nanometers down to few layers. In this thesis, a thorough investigation of Te properties in 2D quantum region was first carried out by various material characterization techniques including TEM and Raman spectroscopy. Potential applications of Te-based electronics, optoelectronic and thermoelectric devices were explored, and high-performance Te FETs were achieved with record-high drive current over 1 A/mm via device scaling and contact engineering. Magneto-transport, including weak anti-localization and Shubnikov-de-Haas oscillations was studied at cryogenic temperature. Quantum Hall effect was observed for the first time in both 2D electron and hole gases with mobility of 6,000 and 3,000 cm<sup>2</sup>/Vs, and non-trivial Berry phase in Te 2D electron system was detected as the first experimental evidence of massive Weyl fermions. This work not only demonstrates the great potential of tellurene films for electronics and quantum device applications, but also expands the spectrum of topological matters into a new material species - Weyl semiconductors.</div>
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