Atomic Force Microscopy Studies of Gold Thin Films

Slides:

Advertisements

Similar presentations

Anodic Aluminum Oxide.

Advertisements

John A. Patten, Muralidhar Ghantasala, Amir R. Shayan, Huseyin Bogac Poyraz, Deepak Ravindra (WMU, Kalamazoo, MI ) 2009 NSF CMMI Engineering Research.

Lecture 11. Microscopy. Optical or light microscopy involves passing visible light transmitted through or reflected from the sample through a single or.

RADIATIVE PROPERTIES OF REAL MATERIALS Electromagnetic Theory: ▪ ideal, optically smooth surface ▪ valid for spectral range larger than visible Real Materials:

Dielectric Properties of Ceramic Thin Films Mara Howell Materials Science and Engineering Junior, Purdue University Professor Kvam, Research Advisor.

Huseyin Bogac Poyraz, Amir R. Shayan, Deepak Ravindra, Muralidhar Ghantasala and John A. Patten (WMU, Kalamazoo, MI ) 2009 NSF CMMI Engineering Research.

U N C L A S S I F I E D Experiments and Simulations of Ablatively Driven Shock Waves in Gadolinium Richard Kraus, Eric Loomis, Shengnian Luo, Dennis Paisley,

Part 4ii: Dip Pen Nanolithography (DPN) After completing PART 4i of this course you should have an understanding of, and be able to demonstrate, the.

Lecture 8: Measurement of Nanoscale forces II. What did we cover in the last lecture? The spring constant of an AFM cantilever is determined by its material.

Alloy Thin Films by Multi-Target Sputtering Karla L. Perez MSE/REU Final Presentation Adv. Prof. King and Prof. Dayananda August 5, 2004.

SYNTHESIS OF COPPER NANOWIRES WITH NANO- TWIN SUBSTRUCTURES 1 Joon-Bok Lee 2 Dr. Bongyoung I. Yoo 2 Dr. Nosang V. Myung 1 Department of Chemical Engineering,

Activities during UK-Japan Young Scientist Workshop Dr Riz Khan Room 31DJ02, x6062, Advanced Technology Institute University.

1 Oxidation Effects on the Optical Constants of Heavy Metals in the Extreme Ultraviolet Amy Grigg R. Steven Turley Brigham Young University.

In-Situ Observation of Crack Behavior in Plasma-Sprayed 7 wt% Yttria-Stabilized Zirconia Jonathan Levin Purdue University Advisor: Prof. Trice.

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

1 X-Ray Photoelectron Molecular By Amy Baker R. Steven Turley, David Allred, Matt Linford, Yi Lang, BYU Thin Special Thanks to R. Steven Turley, David.

STM / AFM Images Explanations from

Atomic Force Microscopy

NATSYCO. microscopy Optical microscopy Electron microscopy Scanning probe microscope.

We have discovered that exposing the surface of PMMA with halogenated solvents can change the adhesion of Au or Pt thin films from nearly 0% to over 90%.

Grazing Incidence X-ray Scattering from Patterned Nanoscale Dot Arrays D.S. Eastwood, D. Atkinson, B.K. Tanner and T.P.A. Hase Nanoscale Science and Technology.

Restructuring the Physics 234 Course to Include Nanoscale Investigations Stephanie Barker and Kurt Vandervoort Funding for this project was provided by.

Methods and Tehniques in Surface Science

Growth and Analysis of MOCVD Grown Crystalline GaAs Andrew Howard, Dr. S. Phillip Ahrenkiel SDSM&T Nanoscience Department NSF REU Grant # Objectives.

Demolding ENGR Pre Lab.

.Abstract Field effect gas sensors based on zinc oxide were fabricated. In order to increase gas sensor’s sensitivity to carbon monoxide, Au nanoparticles.

[1] The Chemical Society of Japan (Ed.): Ultrafine Particle Science and Application, JSSP, 28 (1985). [2] B. D. Plouffe et al. Journal of Magnetism and.

Scholar: Abdul Aziz Abdul Rehman Al-Muqhim Supervisor: Prof. Dr. Abdul Majid Department of Physics, College of Science Majmaah University (Zulfi Campus)

UIC Atomic Force Microscopy (AFM) Stephen Fahey Ph.D. Advisor: Professor Sivananthan October 16, 2009.

Atomic Scale Analysis of Nanostructures Gregory B. Thompson, University of Alabama, DMR Intellectual Merit Ta enrichment at a triple junction grain.

CCMR – RET 2008 Week 1 June 29 to July Day 1 Monday June 29, 2008 Kevin’s “Cornell is up on a hill so it is extremely steep between the.

Fluid Interface Atomic Force Microscopy (FI-AFM) D. Eric Aston Prof. John C. Berg, Advisor Department of Chemical Engineering University of Washington.

1 K. Overhage, Q. Tao, G. M. Jursich, C. G. Takoudis Advanced Materials Research Laboratory University of Illinois at Chicago.

1 X-Ray Photoelectron Spectroscopy to Examine Molecular Composition Amy Baker R. Steven Turley Brigham Young University.

NANO 225 Micro/Nanofabrication Characterization: Scanning Probe Microscopy 1.

Tao Yuan, Jingzhou Xu, and Xicheng Zhang Rensselaer Polytechnic Institute, Troy, New York Scanning THz Emission Microscope Abstract A THz image system.

Abstract poly(1,3,5-phenylene-4,4’-biphenylene-2,2’-disulfonic acid) (CPPSA) rings are promising, new polymers being produced by Dr. Litt’s research group.

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

Today –Homework #4 Due –Scanning Probe Microscopy, Optical Spectroscopy –11 am NanoLab Tour Tomorrow –Fill out project outline –Quiz #3 in regular classroom.

Senior Project - Electrical Engineering Coupling of Audio Signals into AFM Images Matthew Manning Advisor: Prof. Catravas Atomic force microscopy.

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

Introduction P. Chelvanathan 1, Y. Yusoff 2, M. I. Hossain 1, M. Akhtaruzzaman 1, M. M. Alam 3, Z. A. AlOthman 3, K. Sopian 1, N. Amin 1,2,3 1 Solar Energy.

UIC Physics Tessa Cooper Materials Science and Engineering Rutgers University Advisors: Dr. R. Klie and Q. Qiao Department of Physics, University of Illinois.

Ferroelectric Nanolithography Extended to Flexible Substrates Dawn A. Bonnell, University of Pennsylvania, DMR Recent advances in materials synthesis.

Center for Materials for Information Technology an NSF Materials Science and Engineering Center Substrate Preparation Techniques Lecture 7 G.J. Mankey.

The Role of Surface-Energy on Texture Development in Rare-Earth-Free Auxetic and Magnetostrictive Materials Alison B. Flatau, University of Maryland College.

National Science Foundation Outcome: Researchers at University of Maryland have created a 3D biological templated current collector with improved solar.

Applications   Semiconductors   Electric & Magnetic Devices   Carbon Nanotubes   Oxide materials   Nanoparticles and Nanocrystals   Dielectrics.

This is standard 4-point probe configuration. You can source current through the left probes and measure the voltage through the right probes. OPTICAL.

Electrical Characterization of GUMBOS Using Conductive-Probe Atomic Force Microscopy NAVEEN JAGADISH, SERGIO DE ROOY, ATIYA JORDAN, ASHLEIGH WRIGHT, SUSMITA.

Atomic Force Microscopy (AFM)

Roughness and Electrical Resistivity of Thin Films Spencer Twining, Marion Titze, Ozgur Yavuzcetin University of Wisconsin – Whitewater, Department of.

Determining Physical and Chemical Constants of Sputtered Uranium and Thorium as Thin Film Reflectors Within the Extreme Ultraviolet (EUV) Winston Larson.

Window Coating Absorbance Spectra

Magnetic Thin Films and Devices: NSF CAREER AWARD

Ching-Rong “Ada” Chung Mentor: Dr. Jing Zhou Department of Chemistry

THE EFFECT OF SPIN COATING RATE ON MICROSTRUCTURES OF CUPROUS OXIDE THIN FILM PREPARED BY SOL-GEL TECHNIQUE DEWI SURIYANI BT CHE HALIN School of Material.

Thermoplasmonic Decay of Metal-Polymer Nanocomposites

Scanning Probe Microscopy History

Scanning Probe Microscopy History

Prepared by Dr Diane Aston, IOM3

Niki Farnsworth R. Steven Turley

NANO 230 Micro/Nano characterization

Various Instruments for the Study of Microstructure

Determination of the Dielectric Function of Nickel Ferrite Thin Films

Nanocharacterization (III)

Types of Microscopy Type Probe Technique Best Resolution Penetration

Advances in Scanning Probe Microscopy

Nanometer-Scale Shearing and Curvature-Driven Grain Boundary Migration in Diblock Copolymer Thin Films Matthew L. Trawick, Physics Department, University.

Presentation transcript:

Atomic Force Microscopy Studies of Gold Thin Films Dara Gough Advisor: Prof. King

Overview Brief Background Purpose of the project Project objectives Why use gold films? Experimental approach Setbacks Results

Background The angle formed by the grain surfaces at the grain boundary is constant The triple junction was ignored in previous research It is now believed to have a line tension associated with it that affects the grains

Background Theory: Groove (grain boundary and triple junction) depths increase with decreasing grain size The effects may be significant in Nano-scale

Purpose Eventual Goal: Triple junctions may be “doped” to high levels (Via Diffusion Along the Triple Junction) to make them conductive in an insulating material, or magnetic, or otherwise active regions of near-atomic dimension. Courtesy of Prof. King

Purpose To study the development of grooves as a function of the film thickness The relative height (Hr) is approximately equivalent to 4/3 and is derived by the expression: zg zgb ztj

Objectives To create gold thin films of varying thicknesses To anneal the film samples To obtain surface profiles of the samples

Objectives To analyze the surface profiles and obtain data points The data points are the height differences between: The center of the grain and the middle of the grain boundary The center of the grain and the triple junction

Why Gold? Gold is the ideal metal for this experiment because: It is polycrystalline It does not oxidize in atmospheric conditions It evaporates easily in high temperature-low pressure environment

Experimental Approach Evaporation coat glass substrates with a gold thin film Thicknesses ranging from (150-450nm) Anneal the samples at 350°C for 72 hours To create dome-shaped grains that are approximately equal in size to the film thickness Image courtesy of Prof. King

Experimental Approach Obtain profiles of the gold film using the Atomic Force Microscope (AFM) Multiple images must be taken of each film in order to obtain hundreds of data points 12 x 12 microns Image courtesy of Raghavan Narayanan

Experimental Approach The next step in the project is to analyze the images This is done using Scanning Probe Microscopy Software The software analyzes changes in height along the surface and provides relative height differences

Setbacks Problems: Multiple scan errors with the AFM Vibration lines in images Improper engagement of the tip 1.0 x 1.0 micron

Image courtesy of Raghavan Narayanan Setbacks This is an ideal image obtained using the AFM 1.0 x 1.0 micron This is the type of image obtained from the AFM recently 6 x 6 microns Image courtesy of Raghavan Narayanan

Setbacks My initial set of gold films was over-annealed This resulted in the gold receding from the substrate

Setbacks This optical microscopy image was taken using reflected light This is the same image taken using transmitted light

Image courtesy of Raghavan Narayanan Results I was able to begin analyzing an image provided by Raghavan Narayanan Average grain size is 1270 nm2 (counted 252 grains) 1.0 x 1.0 micron Image courtesy of Raghavan Narayanan

Results 170 Data Points

Future Work Take more surface profiles using the AFM Over a wider variety of film thicknesses (grain sizes) Analyze the surface profiles using the Scanning Probe Microscopy Software

Acknowledgements I would like to thank the National Science Foundation (REU Grant DMR-0243830) for financing my research alongside the Department of Energy I would like to thank Prof. Alex King for his support and guidance I would also like to thank Raghavan Narayanan for his assistance throughout the course of the project

Questions? (Questions)