Lanthanum hexaboride Field Effect Scanning Electron Microscope (FESEM) tip imaged with a FESEM using a tungsten hair-pin tip. Wave pattern found on the.

Slides:

Advertisements

Similar presentations

Modulation of conductive property in VO 2 nano-wires through an air gap-mediated electric field Tsubasa Sasaki (Tanaka-lab) 2013/10/30.

Advertisements

Nano Fabrication Nano Fabrication.

Euglena viridis - “green in the middle, and before and behind white” Antony van Leeuwenhoek

Nanowire Presentation Alexandra Ford 4/9/08 NSE 203/EE 235.

ENEE-698E 2 nd presentation by: Saeed Esmaili Sardari November 06, 2007.

Hall Effect. E and B  Charged particles can be subject to both electric and magnetic fields.

Properties of Suspended ZnO Nanowire Field-Effect Transistor

Selectively Grown Silicon Nano-Wires for Transistor Devices Abstract The goal of this project is to fabricate a transistor device using silicon nano-wires.

Department of Electrical & Electronics Engineering ELE 1001: Basic Electrical Technology Lecture 5 Inductor.

 By bending single nanowires voltages are induced.  The electrical energy can be harnessed by contacting both ends of the nanowires. Thai Tran, Applied.

Applications: CO Gas Sensor

Acknowledgements: Dr. Anthony Wagner and Dr. Jill Ferguson Synthesis and Characterization of Silicon-carbide Nanowires Jacob Pederson, Kelsey Steinke,

Tanaka Lab. Yasushi Fujiwara Three dimensional patterned MgO substrates ~ fabrication of FZO nanowire structure~

A basic property of the tiny particles that make up matter; it can be positive or negative: Some particles of matter have an electric charge. Electric.

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.

Magnetorheological Fluids Paul Longwell Hollidaysburg Area High School 2007

Nanomaterial for Sensors Science & Technology Objective(s): To use the aligned nanotube array as sensor for monitoring gas flow rate To fabricate.

NANOFABRICATION -3 NOVEL PROCESSES EEE5425 Introduction to Nanotechnology1.

Nanostructure Formation: 1-D

Static electricity  The buildup of electric charges in one place.

Vapor-Liquid-Solid Growth of ZnSiN2

Wide Bandgap Semiconductor Nanowires for Sensing S.J. Pearton 1, B.S. Kang 1, B.P.Gila 1, D.P. Norton 1, L.C.Tien 1, H.T.Wang 2, F. Ren 2, Chih- Yang Chang.

Mark E. Reeves Department of Physics Ph:(202)

Jeopardy ELECTRICITY MATTER AND CHEMICAL CHANGE BIODIVERSITY ENVIRONMENTAL CHEMISTRY Q $100 Q $200 Q $300 Q $400 Q $500 Q $100 Q $200 Q $300 Q $400 Q.

Principles of Physics Meters and Motors. A wire loop placed in a uniform magnetic field experiences a turning force The loop only rotates 90˚, then stops.

MARL Field-Emission Scanning Electron Microscope (FE-SEM) Current JEOL SEM is over 20 years old and has a rated resolution of 4.0 nm New FEI SEM uses a.

Nanowires and Nanorings at the Atomic Level Midori Kawamura, Neelima Paul, Vasily Cherepanov, and Bert Voigtländer Institut für Schichten und Grenzflächen.

Techniques for Synthesis of Nano-materials

Fabrication of (Fe,Zn) 3 O 4 -BiFeO 3 nano-pillar structure by self- assembled growth Tanaka Laboratory Takuya Sakamoto.

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

Measurement of nano-scale physical characteristics in VO 2 nano-wires by using Scanning Probe Microscope (SPM) Tanaka lab. Kotaro Sakai a VO 2 nano-wire.

Piezoelectric Nanogenerators Based on Zinc Oxide Nanowire Arrays Zhong Lin Wang1,2,3* and Jinhui Song1 14 APRIL 2006 VOL 312 SCIENCE Presented by Yiin-Kuen(Michael)

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

Lithography. MAIN TYPES OF LITHOGRAPHY: * Photolithography * Electron beam lithography –X-ray lithography –Focused ion beam lithography –Neutral atomic.

This photograph of the tungsten filament from a light bulb was taken with a scanning electron microscope. The filament is magnified more than 100 times.

Electric Current Chapter 7 section 2.

Electricity Quiz Board Vocab

Ch Electricity II. Electric Current  Cell and Battery  Potential Difference  Current  Resistance  Ohm’s Law.

Lecture Nine Physics 100 Fall 2012  Review of Labs on Series and Parallel Circuits.

Direct-Current Nanogenerator Driven by Ultrasonic Waves

Two-Dimensional Patterning of Nanoparticle Thin Films from in situ Microreactors Jonathan Dwyer Arizona Space Grant Symposium April 18,

Ch Electricity II. Electric Current  Cell and Battery  Potential Difference  Current  Resistance  Ohm’s Law.

Form Quantum Wires and Quantum Dots on Surfaces

Manufacture of High Aspect Ratio Carbon Nanotube Atomic Force Microscopy Probes Y.N. Emirov 1, J.D. Schumacher 1, M. M. Beerbom 1, B. Lagel 1 B.B. Rossie.

Acknowledgements: UWEC Materials Science Center Dr. Anthony Wagner, MSC Analytical Scientist and Jake Pederson, UWEC Alum 4-Point Resistivity Measurements.

Hans W.P. Koops HaWilKo GmbH Ober-Ramstadt, Germany Focused Electron beam induced processing, a technology to develop and produce miniaturized Electron-,

 Transfer of energy by electromagnetic waves  Heat moving in the form of waves  Example: Sun heating Earth’s surface.

ZnO Nanostructures Grown by Pulsed Laser Deposition

Electric Fields and Potential. Electric Fields Every electric charge is surrounded by an electric field – the area around an electric charge where electric.

This photograph of the tungsten filament from a light bulb was taken with a scanning electron microscope. The filament is magnified more than 100 times.

E1 – Electrical Fundamentals

Electric Current.

Cells & Batteries.

E1 – Electrical Fundamentals

Warm Up #18 How do direct and alternating current differ?

in zinc oxide (ZnO) nanowires

Timed photon counter 5 ΔV 4 ΔV 3 ΔV 30 μm 2 ΔV ΔV Diameter 30 μm Pitch

Electron Optics and the Lau Interferometer

Tip-based functionalization of Group IV graphenes

Electric Current.

Nanocharacterization (III)

500 nm WRITE VOLTAGE 0 V.

Diffraction and Resolution

Ohm’s Law & Circuits Chapter 7.2 & 7.3.

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

SPATIAL & TEMPORAL EVOLUTION OF

PLTW Terms PLTW Vocabulary Set #8.

Presentation transcript:

Lanthanum hexaboride Field Effect Scanning Electron Microscope (FESEM) tip imaged with a FESEM using a tungsten hair-pin tip. Wave pattern found on the high voltage supply shaft. Taken at 10 kX. Image taken by Dan Cavanaugh at the Penn State NACK center. Electric Cold Flow

Field Effect Scanning Electron Microscope (FESEM) image of zinc oxide nano-shell. ZnO 2 nano-shells grown by pyrolysis in an Low Pressure Chemical Deposition (LPCVD). Center particle is 10 µm dia. Image taken by Dan Cavanaugh at the Penn State NACK center. My Pet “Spike”

Field Effect Scanning Electron Microscope (FESEM) image of resist patterned by nano-imprinting. Base widths are approximately 200 nm. False-color added with ImageJ freeware. Image taken by Suxing Pan at the Penn State NACK center. Infinite Isosceles Integration

Field Effect Scanning Electron Microscope (FESEM) image of carbon nano-wires (magenta-navy blue) with iron cap (orange). The nano-wires were formed by vapor-liquid-solid (VLS) growth in an Low Pressure Chemical Deposition (LPCVD). Wires are approximately 100 nm dia. by several microns long. Image taken by Dan Cavanaugh at the Penn State NACK center. Sprouts of the Future

Field Effect Scanning Electron Microscope (FESEM) image of zinc oxide nano-wires. ZnO 2 nano-wires grown by pyrolysis in an Low Pressure Chemical Deposition (LPCVD). Hundred’s of nano-wires (approximately 50 nm dia.) splitting from precursor nodes (approximately 10 µm wide). Image taken by Dan Cavanaugh at the Penn State NACK center. Nano-Thistle

Field Effect Scanning Electron Microscope (FESEM) image of zinc oxide nodes (precursors for nano-wire). ZnO 2 nodes grown by pyrolysis in an Low Pressure Chemical Deposition (LPCVD). Image taken by Dan Cavanaugh at the Penn State NACK center. Nano-Broccoli