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Author: Luke Shaw Publisher: ISBN: Category : Languages : en Pages : 0
Book Description
Recent research has revealed an exciting discovery - two sheets of graphene, layers of one-atom thick carbon, stacked at specific relative twist angles ('magic angles') exhibit a diverse range of behaviour. Monolayer graphene, although an excellent conductor, does not display superconductivity on its own; twisted bilayer graphene (TwBLG) system does near 0K. Moreover, while the system is an insulator at charge neutrality when the bands are filled it also exhibits insluating phases at half-filling, with superconducting phases at fillings lower or higher than half-filling. Since, at half-filling, the Fermi level of the electrons should lie in the middle of the bands, one possible explanation for such insulating phases could be the creation of a Mott insulator at half-filling, or at least other strongly-correlated behaviour. In order to better understand this behaviour, Scanning Tunneling Microscopy (STM) is required to probe local electronic properties. This thesis introduces the basic tools of Solid State Physics and applies them to exact derivations of the band structures of monolayer graphene and rotated bilayer graphene in two limits (AA- and AB-stacking), before discussing the geometry and the first model of TwBLG, the continuum model. An approximate result is derived that qualitatively captures the flat band behaviour. A second, more recent model, the so-called 'ten-band' model, is introduced, and a development of it, using Mean-Field theory, treated in detail. Results of simulations indicate that this mean-field treatment exhibits contrasting behaviour depending on the convergence threshold used for the iterative solving step characteristic of Hartree-Fock methods ('Modelling'). Furthermore, the stops involved in the fabrication of TwBLG devices for STM are reviewed, including some optimisations of an established routine which were carried out by the author ('Fabrication'). Finally, in order to carry observe the interesting correlated behaviour, the devices must exhibit 'magic angle' stacking regions. Since STM is a time-consuming technique, a quick, easy characterisation method using Conductive Atomic Force Microscopy (C-AFM) is described and developed. Some preliminary STM measurements and basic theory are also summarised ('Characterisation').
Author: Luke Shaw Publisher: ISBN: Category : Languages : en Pages : 0
Book Description
Recent research has revealed an exciting discovery - two sheets of graphene, layers of one-atom thick carbon, stacked at specific relative twist angles ('magic angles') exhibit a diverse range of behaviour. Monolayer graphene, although an excellent conductor, does not display superconductivity on its own; twisted bilayer graphene (TwBLG) system does near 0K. Moreover, while the system is an insulator at charge neutrality when the bands are filled it also exhibits insluating phases at half-filling, with superconducting phases at fillings lower or higher than half-filling. Since, at half-filling, the Fermi level of the electrons should lie in the middle of the bands, one possible explanation for such insulating phases could be the creation of a Mott insulator at half-filling, or at least other strongly-correlated behaviour. In order to better understand this behaviour, Scanning Tunneling Microscopy (STM) is required to probe local electronic properties. This thesis introduces the basic tools of Solid State Physics and applies them to exact derivations of the band structures of monolayer graphene and rotated bilayer graphene in two limits (AA- and AB-stacking), before discussing the geometry and the first model of TwBLG, the continuum model. An approximate result is derived that qualitatively captures the flat band behaviour. A second, more recent model, the so-called 'ten-band' model, is introduced, and a development of it, using Mean-Field theory, treated in detail. Results of simulations indicate that this mean-field treatment exhibits contrasting behaviour depending on the convergence threshold used for the iterative solving step characteristic of Hartree-Fock methods ('Modelling'). Furthermore, the stops involved in the fabrication of TwBLG devices for STM are reviewed, including some optimisations of an established routine which were carried out by the author ('Fabrication'). Finally, in order to carry observe the interesting correlated behaviour, the devices must exhibit 'magic angle' stacking regions. Since STM is a time-consuming technique, a quick, easy characterisation method using Conductive Atomic Force Microscopy (C-AFM) is described and developed. Some preliminary STM measurements and basic theory are also summarised ('Characterisation').
Author: Rui Lv Publisher: ISBN: 9781085776806 Category : Graphene Languages : en Pages : 98
Book Description
In this dissertation, I report my work on making two-dimensional van der Waals heterostructure devices. Chapter one introduces the main concepts of the band structure of graphene and the quantum Hall effect. These are the necessary theoretical foundation to understand transport experiment results in the following chapters. Chapter two includes the device fabrication techniques and recipes for fabrication. In Chapter three, I illustrate different characterization methods to study the properties of van der Waals heterostructure devices. Chapter four presents more detailed work on transport measurements of twisted bilayer graphene devices.
Author: Vinod Tewary Publisher: Woodhead Publishing ISBN: 0128199199 Category : Technology & Engineering Languages : en Pages : 628
Book Description
Nano-scale materials have unique electronic, optical, and chemical properties that make them attractive for a new generation of devices. In the second edition of Modeling, Characterization, and Production of Nanomaterials: Electronics, Photonics, and Energy Applications, leading experts review the latest advances in research in the understanding, prediction, and methods of production of current and emerging nanomaterials for key applications. The chapters in the first half of the book cover applications of different modeling techniques, such as Green's function-based multiscale modeling and density functional theory, to simulate nanomaterials and their structures, properties, and devices. The chapters in the second half describe the characterization of nanomaterials using advanced material characterization techniques, such as high-resolution electron microscopy, near-field scanning microwave microscopy, confocal micro-Raman spectroscopy, thermal analysis of nanoparticles, and applications of nanomaterials in areas such as electronics, solar energy, catalysis, and sensing. The second edition includes emerging relevant nanomaterials, applications, and updated modeling and characterization techniques and new understanding of nanomaterials. - Covers the close connection between modeling and experimental methods for studying a wide range of nanomaterials and nanostructures - Focuses on practical applications and industry needs through a solid outlining of the theoretical background - Includes emerging nanomaterials and their applications in spintronics and sensing
Author: Emilio A. Codecido Publisher: ISBN: Category : Graphene Languages : en Pages : 0
Book Description
Since the discovery of graphene in 2004, 2D materials have been a rapidly growing and exciting field in condensed matter physics. More recently, twisted bilayer graphene twisted at the so-called magic angle of 1.1° has sparked tremendous interest due to the observation of correlated insulating and superconducting states. Here I will discuss a brief history of 2D materials and twisted graphene, the fabrication of twisted bilayer graphene devices, measurement techniques and equipment for cryogenic experiments, and our results in twisted bilayer graphene devices near the magic angle. I will also present a novel technique for suspending twisted bilayer graphene and fabricating a suspended top gate. Lastly, I will describe our results on a novel Nernst thermoelectric generator.
Author: Ankur Baburao Nipane Publisher: ISBN: Category : Languages : en Pages :
Book Description
Further, using graphene as a testbed, we demonstrate the use of a sacrificial monolayer WSe2 layer to protect the channel, which is etched in the final process step in a technique we call Sacrificial WSe2 with ALE Processing (SWAP). Furthermore, the top oxidized layer acts like an atomically thin degenerate p-type dopant for a large variety of semiconductors such as graphene, carbon nanotubes, and WSe2. We show that the TOS-doped graphene yields a low sheet resistance due to high mobility at a very high hole density that remains active even at 1.5 K. We apply this principle to improve the transmittance of graphene (>99%) at telecommunication bandwidth (1.5 to 1.6 ?m), that makes it a suitable replacement for Indium tin oxide (ITO) as a transparent electrode.
Author: Thao H. Dinh Publisher: ISBN: Category : Languages : en Pages : 79
Book Description
Magic-angle twisted bilayer graphene (MATBG) is a highly tunable material platform that exhibits a wide range of novel phases, including correlated insulating states and unconventional superconductivity. Its tunability and potentially high kinetic inductance in the superconducting state are desirable properties for high-coherence, small-form-factor superconducting qubits. This thesis presents a promising experimental method to characterize MATBG in the gigahertz-frequency regime, the operating regime of superconducting qubits. A hybrid on-chip DC-microwave circuit, which integrates a DC four-probe measurement and microwave resonator readout functionalities, enables the investigation of DC transport response and microwave response in the same twisted bilayer graphene device. By measuring the frequency shift of a standard Aluminum coplanar waveguide resonator terminated by a twisted bilayer graphene device, we can extract the contribution of the twisted bilayer graphene inductance. We expect that the experimental method can be utilized to measure MATBG kinetic inductance and superfluid density in a non-invasive manner. This experiment will also be a crucial step towards realizing MATBG-based superconducting qubit circuits.
Author: Ado Jorio Publisher: John Wiley & Sons ISBN: 3527643907 Category : Science Languages : en Pages : 319
Book Description
Raman spectroscopy is the inelastic scattering of light by matter. Being highly sensitive to the physical and chemical properties of materials, as well as to environmental effects that change these properties, Raman spectroscopy is now evolving into one of the most important tools for nanoscience and nanotechnology. In contrast to usual microscopyrelated techniques, the advantages of using light for nanoscience relate to both experimental and fundamental aspects.
Author: Luke Shaw
Author: Luke Shaw
Author: Rui Lv
Author: Vinod Tewary
Author: Muhammad Hassan Kiani
Author: Emilio A. Codecido
Author: Ankur Baburao Nipane
Author: Thao H. Dinh
Author: Venkata Karthik Nagareddy
Author: Venkata Karthik Nagareddy
Author: Ado Jorio