OU NanoLab/NSF NUE/Bumm & Johnson Nano-Scale Structures Fabricated using Anodic Aluminum Oxide Templates Outline IIntroduction and Motivation IIPorous.

Slides:

Advertisements

Similar presentations

MICROELECTROMECHANICAL SYSTEMS ( MEMS )

Advertisements

(and briefly, Electrodeposition)

1 Solid oxide membranes for hydrogen separation and isolation Aurelija Martišiūtė.

Anodic Aluminum Oxide.

Carbon nanotube field effect transistors (CNT-FETs) have displayed exceptional electrical properties superior to the traditional MOSFET. Most of these.

Nanotechnology in Hydrogen Fuel Cells By Morten Bakker "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009.

Chemistry 1011 Slot 51 Chemistry 1011 TOPIC Electrochemistry TEXT REFERENCE Masterton and Hurley Chapter 18.

OXIDATION- Overview  Process Types  Details of Thermal Oxidation  Models  Relevant Issues.

Fabrication of large area sub-wavelength structures for anti-reflection optical film Reporter ﹕ Wen-Yu Lee Advisor ： Cheng-Hsin Chuang Department of Mechanical.

Metal-free-catalyst for the growth of Single Walled Carbon Nanotubes P. Ashburn, T. Uchino, C.H. de Groot School of Electronics and Computer Science D.C.

Enabling Next Generation MEMS with Integrated Porous Anodic Alumina Tyler Preston Advisors: Conrad R. Stoldt & Ken Gall Dept. of Mechanical Engineering.

Nanoscale structures in Integrated Circuits By Edward Mulimba.

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,

Interconnect Focus Center e¯e¯ e¯e¯ e¯e¯ e¯e¯ SEMICONDUCTOR SUPPLIERS Goal: Fabricate and perform electrical tests on various interconnected networks of.

Dr. Mansour Al Hoshan TiO 2 Nanotubes Arrays fabricated by anodizing process.

Nanotechnology is receiving a lot of attention of late across the globe. The term nano originates etymologically from the Greek, and it means.

Fabrication of Porous Anodic Alumina Templates with Sub-20nm Pores Shaud Tavakoli Sands Research Group Advisor: Manuel DaSilva.

INTEGRATED CIRCUITS Dr. Esam Yosry Lec. #5.

Thin Film Deposition Prof. Dr. Ir. Djoko Hartanto MSc

MEMs Fabrication Alek Mintz 22 April 2015 Abstract

Surface micromachining

Science and Technology of Nano Materials

Comparison of Field Emission Behaviors of Graphite, Vitreous Carbon and Diamond Powders S. H. Lee, K. R. Lee, K. Y. Eun Thin Film Technology Research Center,

The wondrous world of carbon nanotubes Final Presentation IFP 2 February 26, 2003.

Highly Ordered Nano-Structured Templates: Enabling New Devices, Sensors, and Transducers Student:Gilad A. Kusne (1st Year PhD) Professors:D. N. Lambeth.

PREPARATION OF ZnO NANOWIRES BY ELECTROCHEMICAL DEPOSITION

Overview of course Capabilities of photonic crystals Applications MW 3:10 - 4:25 PMFeatheringill 300 Professor Sharon Weiss.

INTEGRATED CIRCUITS Dr. Esam Yosry Lec. #2. Chip Fabrication  Silicon Ingots  Wafers  Chip Fabrication Steps (FEOL, BEOL)  Processing Categories 

STRUCTURE AND MAGNETIC PROPERTIES OF ULTRA-THIN MAGNETIC LAYERS

Spin Dependent Transport Properties of Magnetic Nanostructures Amédée d’Aboville, with Dr. J. Philip, Dr. S. Kang, with Dr. J. Philip, Dr. S. Kang, J.

M. CuffianiIPRD04, Siena, May A novel position detector based on nanotechnologies: the project M. Cuffiani M. C., G.P. Veronese (Dip. di Fisica,

Superhydrophilic Surface by Aluminum-Induced Crystallization of Amorphous Silicon Ken Kollias Pennsylvania State University Dr. Min Zou Mechanical Engineering.

Argonne National Laboratory is managed by The University of Chicago for the U.S. Department of Energy Nanofabrication H. Hau Wang Argonne National Laboratory.

IMPROVEMENT OF HEIGHT UNIFORMITY OF ZnO NANOWIRE ARRAYS BY USING ELECTROPOLISHING METHOD Nano-Scale Measurement & AnaLysis Lab.

Chemical and Materials Engineering Department, University of Cincinnati, Cincinnati, OH Nanoscale Ni/NiO films for electrode and electrochemical Devices.

NOVEL NANOARRAY STRUCTURES FORMED BY TEMPLATE BASED APPROACHES: TiO 2 NANOTUBES ARRAYS FABRICATED BY ANODIZING PROCESS COMPOSITE OF V 2 O 5 AEROGEL NANOWIRES.

Reminders Quiz#2 and meet Alissa and Mine on Wednesday –Quiz covers Bonding, 0-D, 1-D, 2-D, Lab #2 –Multiple choice, short answer, long answer (graphical.

Self-assembly Nanostructure and Lithography

Aluminum, its Corrosion Types, and Anodization Sun Mi Kim MSE 410 Project.

April 27, O’Dwyer, C. et al. Bottom-up growth of fully transparent contact layers of indium tin oxide nanowires for light emitting devices. Nature.

Motivation There has been increasing interest in the fabrication and characterization of 1D magnetic nanostructures because of their potential applications.

ADVANCED HIGH DENSITY INTERCONNECT MATERIALS AND TECHNIQUES DIVYA CHALLA.

Atomic Layer Deposition for Microchannel Plates Jeffrey Elam Argonne National Laboratory September 24, 2009.

1 1 nanometer (nm) = 10 hydrogen atoms side-by-side Meaning of “nano”: One billionth (10x-9) Nanometer (nm) = one billionth of a.

2. Design Determine grating coupler period from theory: Determine grating coupler period from theory: Determine photonic crystal lattice type and dimensions.

Updates of Iowa State University S. Dumpala, S. Broderick and K. Rajan Sep – 18, 2013.

1 ADC 2003 Nano Ni dot Effect on the structure of tetrahedral amorphous carbon films Churl Seung Lee, Tae Young Kim, Kwang-Ryeol Lee, Ki Hyun Yoon* Future.

Form Quantum Wires and Quantum Dots on Surfaces

2-D Nanostructure Synthesis (Making THIN FILMS!)

Molecular and Electronic Devices Based on Novel One-Dimensional Nanopore Arrays NSF NIRT Grant# PIs: Zhi Chen 1, Bruce J. Hinds 1, Vijay Singh.

Pinning Effect on Niobium Superconducting Thin Films with Artificial Pinning Centers. Lance Horng, J. C. Wu, B. H. Lin, P. C. Kang, J. C. Wang, and C.

Controlled fabrication and optical properties of one-dimensional SiGe nanostructures Zilong Wu, Hui Lei, Zhenyang Zhong Introduction Controlled Si and.

Shaping Carbon Nanotube Forests for Field Emission Ben Pound and T.-C. Shen Department of Physics Background Elastocapillary Self-Assembly Method to Make.

Prof. Jang-Ung Park (박장웅)

Nanowire Fabrication Based on Porous Alumina Template

Lecture 7 Fundamentals of Multiscale Fabrication

UV-Curved Nano Imprint Lithography

Fabrication of Nano-porous Templates Using Molecular Self-Assembly of Block Copolymers for the Synthesis of Nanostructures Luke Soule, Jason Tresback Center.

EXPERIMENTAL PROCEDURE EXPERIMENTAL PROCEDURE

Centro de Investigación y de Estudios Avanzados del Institúto Politécnico Nacional (Cinvestav IPN) Palladium Nanoparticles Formation in Si Substrates from.

Presented by Yiin-Kuen(Michael) Fuh 2007/3/19

Top-down and Bottom-up Processes

Layer Transfer Using Plasma Processing for SMART-Wafer

SILICON MICROMACHINING

Nanocharacterization (III)

IC AND NEMS/MEMS PROCESSES

KOLÁŘ Jakub, SVATOŠ Vojtěch, HUBÁLEK Jaromír, MOZALEV Alexander

Metal Assisted Chemical Etching (MacEtch)

Multiscale Modeling and Simulation of Nanoengineering:

Nano Technology Dr. Raouf Mahmood. Nano Technology Dr. Raouf Mahmood.

Presentation transcript:

OU NanoLab/NSF NUE/Bumm & Johnson Nano-Scale Structures Fabricated using Anodic Aluminum Oxide Templates Outline IIntroduction and Motivation IIPorous Alumina Masks IIIResults IVConclusions VNanoLab Experiments

OU NanoLab/NSF NUE/Bumm & Johnson Introduction Objective: Fabricate ordered arrays of structures on the nanometer scale using porous alumina templates.

OU NanoLab/NSF NUE/Bumm & Johnson Moores Law:  Dr. Gordon E. Moore, founder of Intel, predicted in 1965 that the number of transistors per IC doubles every 18 months. Integrated Circuits

OU NanoLab/NSF NUE/Bumm & Johnson  Current technology hits a roadblock in about 2012 in terms of fabrication and device operation.  Alternative patterning techniques and computing schemes are needed (e.g. Quantum, Molecular, Optical Computers, Carbon Nanotubes based devices, etc.). Important characteristics of “The 1999 National Technology Roadmap for Semiconductors” published by the SIA. Semiconductor Roadmap

OU NanoLab/NSF NUE/Bumm & Johnson Motivation: General What is Anodic Porous Alumina?  Aluminum oxide grown on an Al substrate in an electrolytic cell. The resulting structure consists of an array of tunable nanometer-sized pores surrounded by an alumina backbone. Purpose:  To understand the mechanisms involved in the growth and ordering of anodic porous alumina. Motivation: Why do we want to fabricate nanostructures?  Interest in using anodic porous alumina as a nano- template to fabricate nanometer-sized structures (e.g. nanofabrication of quantum dots). 1. Fundamental physical interest in the nanometer size regime. Properties of nano- sized structures are different from their bulk and molecular counterparts. 2. Technological applications as electronic and optical devices.

OU NanoLab/NSF NUE/Bumm & Johnson  Microfiltration.  Optical waveguides and photonic crystals for optical circuits.  Template for carbon nanotube growth for electronic, mechanical applications.  Ordered arrays of quantum dots for lasers, photodetectors.  ULSI memory devices and ICs. Porous Alumina used as optical waveguide. H. Masuda, et. al., Jpn. J. Appl. Phys. 38, L1403 (1999). Commercially available Anopore filter. pec_prep/filter2.html Ordered arrays of carbon nanotubes fabricated using a porous alumina template. J. Li, et al., Appl. Phys. Lett. 75(3), 367 (1999). 1. Physics:  Explore optical, electrical, and magnetic quantum confinement. 2. Engineering: Motivation: Applications

OU NanoLab/NSF NUE/Bumm & Johnson Overview of Anodic Oxide Films Two main types of anodic oxide films can be grown depending on the nature of the electrolyte: 1. Barrier-Type Films:  Grown Oxide Insoluble in Electrolyte  Nearly Neutral Electrolytes (pH 5-7) 2. Porous-Type Films:  Grown Oxide Slightly Soluble in Electrolyte  Aqueous Sulfuric, Oxalic, and Phosphoric Acid Electrolytes Fabrication  Anodize aluminum in electrolyte (e.g. Oxalic Acid)

OU NanoLab/NSF NUE/Bumm & Johnson Historical Timeline  1920’s Porous alumina starts to be used commercially to protect and finish bulk Al surfaces.  1940’s-1960’s With advent of electron microscopes, first characterization of structure of porous alumina, but growth theories are experimentally unsubstantiated.  1970 Manchester group does first real experimental work showing pore radius dependence on applied voltage,etc.  1992 First “quantitative” theoretical attempt to explain pore growth from first principles by Belorus group.  1995 Japanese group discovers pores will self-order into close packed array under the right anodization conditions.  1996-Present Use of porous alumina for nano-applications abound.  1998 Although mechanism for ordering still not clear, German group proposes one possible mechanism.

OU NanoLab/NSF NUE/Bumm & Johnson  Anodize aluminum in electrolyte (e.g. Oxalic Acid).  Oxide grows at the metal/oxide and oxide/electrolyte interfaces, pores initiate at random positions by field-assisted dissolution at the oxide/electrolyte interface.  Ordering requires appropriate potentials and long anodization times.  Ordering results from repulsion between neighboring pores due to mechanical stress at the metal/oxide interface. Apparatus H. Masuda and K. Fukuda, Science 268, 1466 (1995). Resulting Structure Porous Alumina

OU NanoLab/NSF NUE/Bumm & Johnson Barrier-Type Anodic Oxide Films  Oxide growth proceeds at the Aluminum anode (+).  Hydrogen gas is evolved at the Platinum cathode (-).  The current between the cathode and anode is carried by the electrolyte.  The overall electrochemical reaction occurring is: Growth Mechanism  Oxidation reactions at the Al anode  Reduction reaction at the cathode:  Electrolysis of water at aluminum oxide/ electrolyte interface

OU NanoLab/NSF NUE/Bumm & Johnson Barrier-Type Anodic Oxide Films  Oxide growth proceeds at the metal/oxide and the oxide/electrolyte interface.  Growth proceeds due to the motion of ions under the applied field. Growth Mechanism  Growth at the metal/oxide interface is due to oxygen containing anions (mainly OH - and O 2- ) moving through interstitial/vacancy sites.  Growth at the oxide/electrolyte interface is due to Al 3+ cations moving through interstitial/place exchange mechanisms.

OU NanoLab/NSF NUE/Bumm & Johnson V.P. Parkhutik, and V.I. Shershulsky, J. Phys. D:Appl. Phys. 25, 1258 (1992).  Oxide growth proceeds via ionic conduction and reaction of Al cations and oxygen containing anions under the influence of an applied field. (e.g. 2Al + + 3OH -  Al 2 O 3 +3H + +6e - )  Pores initiate at random positions through field-assisted dissolution of the oxide at the oxide/electrolyte interface.  Initially oxide growth dominates. (I)  Dissolution becomes competitive, barrier layer thins, and pores initiate. (II)  Approaches steady state where both mechanisms occur at roughly the same rate. (III and IV) Overview of Film Anodization

OU NanoLab/NSF NUE/Bumm & Johnson Field-Assisted Dissolution  This polarization effectively lowers the activation energy for dissolution of the oxide.  This promotes solvation of Al 3+ ions by water molecules and the removal of O 2- ions by H + ions.  This processes is strongly dependent on the E-field strength.  Application of a field across the oxide polarizes the oxide bonds. Porous-Type Anodic Oxide Films

OU NanoLab/NSF NUE/Bumm & Johnson Ordered Growth of Porous Alumina  In 1995, Japanese group found that pores will self-order under the right anodization conditions.  The two most important conditions are narrow voltage ranges and long anodization times.

OU NanoLab/NSF NUE/Bumm & Johnson Ordered Oxalic Ordered Nano-Templates Near-Ordered Sulfuric  Tunable diameters and spacings from 20 nm to 500 nm.  Polycrystalline structure: ordered micron-sized domains, defects at grain boundaries.  Low temperature growth produces unordered 4-10 nm arrays.

OU NanoLab/NSF NUE/Bumm & Johnson Ordered Growth of Porous Alumina  Ordered pore arrays obtained in three different electrolytes for long anodization times and appropriate voltages (specific for each electrolyte).  Polycrystalline structure with perfectly ordered domains a few microns in size. Defects occur at grain boundaries.

OU NanoLab/NSF NUE/Bumm & Johnson Mask Processing 7. Remove collodion and place alumina on desired substrate. H. Masuda et al., Jpn. J. Appl. Phys. 35, L126 (1996). AFM of Unopened Barrier Layer (1  m x 1  m) To create an ordered through-hole mask: 1. Anodize for a long time allowing pores to order. 2. Chemically remove the alumina in a mixture of phosphoric and chromic acid. 3. Anodize for a short time (now pores are ordered). 4. Coat top surface of alumina with a polymer (collodion) to protect it from further processing. 5. Remove Al Substrate in a saturated HgCl 2 solution. 6. Remove the barrier layer in 5 wt.% Phosphoric Acid.

OU NanoLab/NSF NUE/Bumm & Johnson Fluorine Beam Transfer mask pattern via etching into substrate for ordered arrays of trenches. Ion Beam Transfer mask pattern via ion etching into substrate for ordered arrays of trenches or pillars. Sputtering and Thermal Deposition Transfer mask pattern via deposition onto substrate for ordered arrays of dots. 1. Etching Processes 2. Growth Processes Pattern Transfer Techniques: Results

OU NanoLab/NSF NUE/Bumm & Johnson 50 nm X-SECT. VIEWTOP DOWN VIEW SAMPLE:~500nm thick Free-Standing AAO/Si(001) F-ETCH:1 min. 20 sec. T SUB = 250 o C PORES:Width 70 nm, Depth nm 200 nm  Walls are ~30 nm thick (near top). F-Etched Array of Si(001) Nano-Holes

OU NanoLab/NSF NUE/Bumm & Johnson SAMPLE:~500nm thick Free-Standing AAO/GaAs(100) ION BEAM:500 eV Ar +, 0.05 mA/cm 2 Time = 2hrs. 12min. PORES:Width 50 nm, Depth nm X-SECT. VIEW~TOP DOWN VIEWOBLIQUE VIEW Ion Etched Array of GaAs Nano-Holes

OU NanoLab/NSF NUE/Bumm & Johnson 3-D Rendered SEM Top Views Line Scan AFM Views Height: 12 nm  11% Diameter:60 nm  9% Spacing:110 nm  5% 200 nm MgF 2 dots/SiAu dots/SiO 2 Thermally Evaporated Nano-Dots: MgF 2

OU NanoLab/NSF NUE/Bumm & Johnson H. Masuda et al., Jpn. J. Appl. Phys. 35, L126 (1996).  Porous alumina used as an evaporation mask to grow quantum dots. Thermally Evaporated Nano-Dots: Gold

OU NanoLab/NSF NUE/Bumm & Johnson SAMPLE:~20nm thick Fe dots on GaAs(100). ION BEAM:500 eV Ar +, 0.05 mA/cm 2 Time = 17 min. PILLARS:Width 50 nm, Height 50 nm X-SECT. VIEWTOP DOWN VIEWOBLIQUE VIEW Note: No Fe remaining. Ion Etched Array of GaAs Nano-Pillars

OU NanoLab/NSF NUE/Bumm & Johnson  Collaboration with Dr. Shen Zhu of Marshall Space Flight Center. SAMPLE:~20nm thick Fe catalyst dots on 100nm Ti/Si GROWTH:CVD using Methane gas at 500 Torr, 800 o C NANOTUBES:Multi-walled tubes, ~10s of microns long TOP DOWN VIEW Evaporated Catalyst Dots For Carbon Nanotube Growth

OU NanoLab/NSF NUE/Bumm & Johnson Conclusions  Arrays of 50 nm wide trenches in Si and GaAs by atom-beam and sputter etching.  Arrays of 50 nm dots of various materials onto substrates by evaporation and sputtering.  Arrays of nano-pillars in Si and GaAs by etching nano-dot arrays. Future  Make pores smaller (to 5 nm) using sulfuric acid electrolytes and low temp. anodization.  Seed for carbon nanotube growth.  Explore optical, electrical, and magnetic properties of nanostructures.  Explore ways to transfer single or arbitrary dot/trench patterns.  Fabricate such nanostructures in situ in multichamber MBE system. Fabricated ordered, arrays of nanostructures using porous alumina templates as masks:

OU NanoLab/NSF NUE/Bumm & Johnson NanoLab Class: AAO Templated Structures Fabricate AAO Masks: –Ordered and Disordered Oxalic Masks (50 nm/100 nm). –Ordered film: 15 hr first anodization. –Disordered film: 1 hr first anodization. Lift-Off onto Silicon and Quartz substrates. –Silicon substrates for SEM characterization. –Quartz substrates for UV-Vis characterization. Thermally Evaporate Gold onto all Samples –Must be done one sample at a time, because alignment is critical. Characterize Samples –AFM -both samples –SEM of Au dots on Silicon. –UV-Vis of Au dots on Quartz.