Donovan Sung EE235 Student Presentation 4/16/08 Chemical identification of individual surface atoms by atomic force microscopy.

Slides:

Advertisements

Similar presentations

AFM Basics Xinyong Chen.

Advertisements

Scanning Probe Microscopy

Scanning Probe Microscopy ( STM / AFM )

Detection of Percolating Paths in PMMA/CB Segregated Network Composites Using EFM and C-AFM Jacob Waddell, Runqing Ou, Sidhartha Gupta, Charles A. Parker,

The Principle of Microscopy : SEM, TEM, AFM

SCANNING PROBE MICROSCOPY By AJHARANI HANSDAH SR NO

Lecture 10. AFM.

AFM-Raman and Tip Enhanced Raman studies of modern nanostructures Pavel Dorozhkin, Alexey Shchekin, Victor Bykov NT-MDT Co., Build. 167, Zelenograd Moscow,

Development of Scanning Probe Lithography (SPL)

Force Microscopy Principle of Operation. Force Microscopy Basic Principle of Operation: detecting forces between a mass attached to a spring (cantilever),

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

Atomic Force Microscopy: characterization of surface topography Andrius Martinavičius.

Atomic force microscopy Jiří Boldyš. Outline Motivation Minisurvey of scanning probe microscopies Imaging principles Ideas about application of moment.

Atomic Force Microscopy

Atomic Force Microscop (AFM) 3 History and Definitions in Scanning Probe Microscopy (SPM) History Scanning Tunneling Microscope (STM) Developed.

Atomic Force Microscopy

Design of a compact AFM scanner

Atomic Force Microscopy

Copyright © 2005 SRI International Scanning Probe Microscopy “Seeing” at the nanoscale.

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.

Slide # 1 SPM Probe tips CNT attached to a Si probe tip.

Using Contact Probes For Nanomechanical Measurements Mark R. VanLandingham U. S. Army Research Laboratory Instrumentation and Metrology for Nanotechnology.

‘Wet’ Chemical Techniques One technique to analyze the chemistry of a mineral is to dissolve it –Water, Strong acids/bases, hydrofluoric acid, oxidants,

Scanning Tunneling Microscopy and Atomic Force Microscopy

Methods and Tehniques in Surface Science

Three-dimensional Silicon composite nanostructures, taken with a scanning electron microscope.

Demolding ENGR Pre Lab.

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

Tuning Fork Scanning Probe Microscopy Mesoscopic Group Meeting November 29, 2007.

2.002 Tutorial Presentation Problem 1-Atomic Force Microscopy Justin Lai.

Cover of Scientific American, October Source: Actuator driven by thermal expansion of water and air.

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

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

TRIBOELECTRIC PHENOMENA IN PARTICULATE MATERIALS - Role of Particle Size, Surface Properties, and Vapor - Scott C. Brown 1 Team: Yakov Rabinovich 1, Jennifer.

Scanning Probe Microscopy – the Nanoscience Tool NanoScience & NanoTechnology Tools that operate in real space with Ångstrom to nanometer spatial resolution,

Common scanning probe modes

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.

1 Manipulation and Imaging of Aromatic Organic Molecules with Atomically Sharp Tips: The Last Atom Matters Nicolae Atodiresei 1, Vasile Caciuc 2, Hendrik.

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

Atomic Force Microscopy (AFM)

Cover of Scientific American, October Source: Actuator driven by thermal expansion of water and air.

3.052 Nanomechanics of Materials and Biomaterials Prof. Christine Ortiz DMSE, RM Phone : (617) WWW :

Atomic Force Microscopy (AFM)

Scanning Probe Microscopy

Metallurgha.ir1. Lecture 5 Advanced Topics II Signal, Noise and Bandwidth. Fundamental Limitations of force measurement metallurgha.ir2.

Scanning Tunneling Microscopy

Characterization of CNT using Electrostatic Force Microscopy

Scanning Probe Microscopy History

7x7 surface have been removed and deposited.

Scanning Probe Microscopy History

Tapping mode AFM: simulation and experiment

Mapping vibrational modes of Si3N4 membrane - Ultrasonic Force Microscopies vs Laser Doppler Vibrometry The development of new micro and nano-electromechanical.

NANO 230 Micro/Nano characterization

Scanning Probe Microscope

Presentation to: NIST Metrology Workshop Metrology for Atomic Precision Fabrication John Randall Chief Technical Officer Zyvex Corp.

Wei Wang,1 Dong Xiao Niu,2 Xinju Yang1

Nanocharacterization (III)

The learning goal of this course is the basic operation of atomic force microscope, and operation principle of several basic imaging modes in the family.

Types of Microscopy Type Probe Technique Best Resolution Penetration

Scanning Probe Microscopy

Advances in Scanning Probe Microscopy

Atomic Force Microscope

Planck’s law: E=hn =hc/l

Atomic Force Microscopy

AFM modes 1- Contact Mode

Magnetic force resonance microscopy

Alan Van Orden, Department of Chemistry, Colorado State University

Presentation transcript:

Donovan Sung EE235 Student Presentation 4/16/08 Chemical identification of individual surface atoms by atomic force microscopy

Atomic Fingerprinting Goal: Identify different elements on a surface quickly and reproducibly using only a mechanical probe Challenges: 1. The AFM tip tends to change shape over time 2. Difficult to precisely position the AFM tip Sn on Si(111) Pb on Si(111) Silicon Lead Tin

Atomic Force Microscopy Principle: An AFM operated in ultrahigh vacuum (UHV) in noncontact mode can be used to detect the chemical forces between the outermost atom of the AFM tip and the atoms on the surface.

Dynamic Force Microscopy As the tip approaches the surface, different forces come into play depending on the distance between tip and surface.

Atom Tracking Atom tracking allows for a precise positioning of the tip on different locations over a single molecule, using a feedback system The radius δ R must be smaller than the dimensions of the surface atom

Compensation of Lateral Thermal Drift The precision of the positioning control is better than 0.2 Å peak to peak The interaction force can be obtained from the detuning of the resonance frequency of the cantilever with the tip-sample vertical distance

Probing short-range interaction forces Lead, tin, and silicon have similar electronic structures and tend to sit in similar positions on the surface Regardless of the structure and chemistry of the tip, the ratio of the force for lead and tin relative to silicon remains the same (Structure) (Chemistry)

Single-atom chemical identification Lead and tin atoms are nearly indistinguishable in topography in (a), while silicon and lead are indistinguishable in (b). However, the ratio of forces remains the same, allowing easy identification of the atoms in each case. (a) Si, Sn, Pb mixed equally(b) Pb surrounded by Si

Conclusion This work helps to establish the AFM as a metrology tool on the atomic scale Quick and reproducible way to identify atoms quickly, which should be widely applicable Developed a “standard” for identifying atoms, similar to element-specific forms of spectroscopy

References Abe, M. et al. “Room-temperature reproducible spatial force spectroscopy using atom-tracking technique.” Applied Physics Letters 87, (2005). Sugimoto, Y. et al. “Chemical identification of individual surface atoms by atomic force microscopy.” Nature 446, (2007).