Atomic-Scale Mapping of Thermoelectric Power on Graphene: Role of Defects and Boundaries CNMS Staff Science Highlight Scientific Achievement Significance.

Slides:

Advertisements

Similar presentations

Scanning tunnelling spectroscopy

Advertisements

Room Temperature Tunneling Behaviors of Boron Nitride Nanotubes Functionalized with Gold Quantum Dots CNMS User Project Highlight Scientific Achievement.

Polaronic transport and current blockades in epitaxial silicide nanowires and nanowire arrays CNMS Staff Science Highlight Scientific Achievement Significance.

Morphological Evolution during Graphene Formation on SiC(0001) Randall Feenstra, Carnegie Mellon University, DMR Graphene, consisting of monolayer.

What do you think is Liang doing?. Nano-Energy Laboratory  Principal Investigator: Dr. Choongho Yu  Graduate Assistants: Liang Yin, Yeontack Ryu,

Thermal Radiation Scanning Tunneling Microscopy Yannick De Wilde, Florian Formanek, Remi Carminati, Boris Gralak, Paul-Arthur Lemoine, Karl Joulain, Jean-Philippe.

VTSLM images taken again at (a) 4.5  (T=84.7K), (b) 3.85  (T=85.3K), (c) 22.3  (T=85.9K), and (d) 31.6  (T=86.5K) using F-H for current and A-C for.

Surface Characterization by Spectroscopy and Microscopy

Basic Imaging Modes Contact mode AFM Lateral Force Microscopy ( LFM)

Molecular Magnet: an Example of STM Application J. Wu Phys. Dept. C203 course.

Do it with electrons !. Microscopy Structure determines properties We have discussed crystal structure (x-ray diffraction) But consider now different.

Scanning Probe Microscopy (SPM) Real-Space Surface Microscopic Methods.

Tools of the Nanosciences There’s plenty of room at the bottom It is my intention to offer a prize of $1,000 to the first guy who can take the information.

Thermoelectricity of Semiconductors

BMFB 3263 Materials Characterization Scanning Probe Microscopy & Relates Techniques Lecture 5 1.

Demolding ENGR Pre Lab.

Methods and Tehniques in Surface Science Prof. Dumitru LUCA “Alexandru Ion Cuza” University, Iasi, Romania.

TAPPINGMODE™ IMAGING APPLICATIONS AND TECHNOLOGY

Chapters Thermodynamics Introduction 1. Equilibrium of mechanical systems: the concept of temperature Three parameters were needed to describe the.

Diamonds and Dust Some History Discovery of Carbon NT’s Electronics on Really Short Length Scales New Tubes Applications There’s Plenty of Tubes at the.

Self-Organized and Cu-Coordinated Surface Linear Polymerization CNMS Staff Science Highlight write Q. Li, J. Owens, C. Han, B. G. Sumpter, W. Lu, J. Bernholc,

What has enabled Nanoscience? Advances in Computing Power New Generation of Scientific Instruments Scanning Probe Microscopes An incomplete list.... Very.

1 ME 381R Fall 2003 Micro-Nano Scale Thermal-Fluid Science and Technology Lecture 15: Introduction to Thermoelectric Energy Conversion (Reading: Handout)

Creative Research Initiatives Seoul National University Center for Near-field Atom-Photon Technology - Near Field Scanning Optical Microscopy - Electrostatic.

Nano-electronics Vision: Instrumentation and methods for analysis of atomic scale physical properties, and methods to correlate these properties with nano-electronic.

Tutorial 4 Derek Wright Wednesday, February 9 th, 2005.

Energy transfer insulation Energy can be transferred from one location to another, as in the sun's energy travels through space to Earth. The two ways.

NAME DATE The Unit Organizer BIGGER PICTURE LAST UNIT/Experience CURRENT UNIT NEXT UNIT/Experience UNIT FOCUS QUESTIONS is about... Student Activities.

 Explain how the main features of a Scanning Tunnelling Microscope allow an image to be formed  Explain how the main features of a Transmission.

Chapter 4-15 Grain boundaries: are boundaries between crystals. are produced by the solidification process, for example. have a change in crystal orientation.

(b) Constant height mode Measure the tunneling current while scanning on a given, smooth x-y-z contour. The z-position (output of feedback loop) is measured.

Scanning Probe Microscopy Colin Folta Matt Hense ME381R 11/30/04.

5 kV  = 0.5 nm Atomic resolution TEM image EBPG (Electron beam pattern generator) 100 kV  = 0.12 nm.

Nitrogen-Doped Carbon

Spatially Resolved Mapping of Electrical Conductivity Across Domain and Grain Boundaries in Graphene CNMS Staff Science Highlight Scientific Achievement.

Engr College of Engineering Engineering Education Innovation Center Engr 1182 Nano Pre-Lab Demolding Rev: 20XXMMDD, InitialsPresentation Short.

Energy Transformations Or: How do we change one type of energy to another type?

Real-Time Optical Diagnostics of Rapid Graphene Growth CNMS Staff Science Highlight Real-time Raman spectroscopy, optical reflectivity, and microscope.

Local Density of States in Mesoscopic Samples from Scanning Gate Microscopy Julian Threatt EE235.

NAME DATE The Unit Organizer BIGGER PICTURE LAST UNIT/Experience CURRENT UNIT NEXT UNIT/Experience UNIT FOCUS QUESTIONS is about... Student Activities.

University of Arkansas, Fayetteville Above right is a schematic diagram showing a top view of the UHV chamber for the two-tip low- temperature STM system.

Scattering and Interference in Epitaxial Graphene by G. M. Rutter, J. N. Crain, N. P. Guisinger, T. Li, P. N. First, and J. A. Stroscio Science Volume.

Two-dimensional (2D) materials have attracted the attention of many researchers. The first created 2D material was graphene, it was discovered in the early.

Date of download: 6/29/2016 Copyright © ASME. All rights reserved. From: Hot Spot Cooling and Harvesting Central Processing Unit Waste Heat Using Thermoelectric.

Date of download: 7/6/2016 Copyright © ASME. All rights reserved. From: Performance Analysis of a Combination System of Concentrating Photovoltaic/Thermal.

Date of download: 9/16/2016 Copyright © ASME. All rights reserved. From: Thermoelectric Performance of Novel Composite and Integrated Devices Applied to.

Thermoelectric Modules (TEM)

Date of download: 10/9/2017 Copyright © ASME. All rights reserved.

Atomic Resolution Imaging

Molecular spectroscopy and reaction dynamics Group III

Translating Spin Seebeck Effect Physics into Practice

Who am I? Jerzy Leszczynski Professor of Chemistry and

Scanning Probe Microscopy

Characterization of CNT using Electrostatic Force Microscopy

J. Appl. Phys. 112, (2012); Scanning Tunneling Microscopy/Spectroscopy Studies of Resistive Switching in Nb-doped.

Date of download: 12/19/2017 Copyright © ASME. All rights reserved.

Scientific Achievement

Prepared by Dr Diane Aston, IOM3

Volume 3, Issue 2, Pages (August 2017)

Imaging exciton polariton transport in MoSe2

Probing Membrane Order and Topography in Supported Lipid Bilayers by Combined Polarized Total Internal Reflection Fluorescence-Atomic Force Microscopy

Wei Wang,1 Dong Xiao Niu,2 Xinju Yang1

Electro-Magnetic Induction

Quantitative Membrane Electrostatics with the Atomic Force Microscope

The defect is the device: (A) An atomic-resolution scanning transmission electron microscopy (STEM) image of a 109° domain wall in the multiferroic BiFeO3.

3 A Figure 1. Schematic of a conventional scanning tunneling microscope (STM).

“Small and Fast: femtosecond light-matter interactions at 0

Composition distribution and electrical properties of

Fig. 2 Electrical and scanning probe characterization.

Fig. 2 Temperature-sensing properties of the flexible rGO/PVDF nanocomposite film. Temperature-sensing properties of the flexible rGO/PVDF nanocomposite.

Presentation transcript:

Atomic-Scale Mapping of Thermoelectric Power on Graphene: Role of Defects and Boundaries CNMS Staff Science Highlight Scientific Achievement Significance and Impact Research Details J. Park, G. He, R. M. Feenstra, and A.-P. Li, Nano Lett. DOI: /nl401473j Highlighted in Nature Nanotech. DOI: /nnano Thermoelectric power was spatially resolved on graphene with a scanning tunneling microscopy (STM) method. Periodic oscillations and microscopic domains are revealed, showing the interplays of thermoelectric power and local variation of the electronic structures due to defects, local strains, and structural boundaries. The thermal generation of a voltage also occurs in a scanning tunneling microscope when the tip and the sample are at different temperatures. This study reveals the roles of individual defects and boundaries, providing information on the thermal to electrical energy conversion process at an unprecedented atomic level. Thermoelectric properties are studied by measuring the thermovoltage between a tip and a sample caused by a temperature gradient across the tunneling barrier in a STM. Structures and thermopower are measured simultaneously across particular defects and boundaries. (b) (a) Schematic diagram of simultaneous structure and thermovoltage measurement with an STM. Atomic resolution images of (b) topography and (c) thermovoltage. 3D contours of topography and thermovoltage showing domains induced by step boundaries and structural wrinkles. Work was performed at CNMS-ORNL and at the Carnegie Mellon University

Atomic-Scale Mapping of Thermoelectric Power Reveals Hot Spots on Graphene CNMS Staff Science Highlight Scientific Achievement Significance and Impact Research Details J. Park, G. He, R. M. Feenstra, and A.-P. Li, Nano Lett. DOI: /nl401473j Highlighted in Nature Nanotech. DOI: /nnano Scanning tunneling microscopy has been used to map the spatial distribution of thermoelectric power on graphene. Atomic scale changes in thermoelectric response has been revealed in areas containing defects and structural boundaries. The thermal generation of a voltage is the basis of thermoelectric devices, which can transform wasted heat into electricity, or through the opposite principle, can act as solid- state refrigerators. A better understanding of thermoelectric response near defects is important for designing more efficient thermoelectric devices. Thermoelectric properties are studied by measuring the thermovoltage between a tip and a sample caused by a temperature gradient across the tunneling barrier in a STM. Structures and thermopower are measured simultaneously across particular defects and boundaries. (b) (a) Schematic diagram of simultaneous structure and thermovoltage measurement with an STM. Atomic resolution images of (b) topography and (c) thermovoltage. 3D contours of topography and thermovoltage showing domains induced by step boundaries and structural wrinkles. Work was performed at CNMS-ORNL and at the Carnegie Mellon University