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Angstromology Introduction to Nanotechnology Foothill College
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Page 1: Angstromology

Angstromology

Introduction to NanotechnologyFoothill College

Page 2: Angstromology

Overview

• Nanoscale definitions

• Scale and dimension (not just small)

• Working at the angstrom level– Nanotechnology – the last 200 years

• Nanotechnology – the next 100 years– Beyond nano – to pico scale and beyond

• Innovation in the quantum universe

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Nano Definitions

• Design, engineer, manufacture, or …

• Control a process– at the nanoscale dimension

• Atom by atom precise manipulation

• Functionalize and monetize properties at the nanoscale dimension

• ‘Bottom up manufacturing’ self-assembly

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Traditional Nanotechnology

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Nano Definitions Further

• Nanotechnology is the study, design, creation, synthesis, manipulation, and application of functional materials, devices, and systems through control of matter and energy at the nanometer scale (1–100 nanometers, one nanometer being equal to 1 × 10−9 of a meter).

• Exploitation of novel phenomena, including the properties of matter, energy, and information at the molecular, atomic, and sub atomic levels.

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LEONARD MANDEL (at left) and co-workers at the University of Rochester gather around a parametric down-converter, an unusual crystal that converts any photon striking it into two photons with half as much energy. Mandel's group pioneered the use of the device in tests of quantum mechanics.

New experiments - real and imagined - are probing ever more deeply into the surreal quantum realm

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Nanoscale Paradigm

Miniaturizationfrom thetop down

Moore’s Law 20th Century

Quantum propertiesfrom the bottom up

Moore’s Law 21st Century

Concept by Hilary Lackritz

1950 – 2000Era of materials

2000 – 2050Era of quanta

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Scale and Dimension

• Quantum scale dimension– Small things– Short times– Small numbers– Low probabilities

• Heisenberg and Plank got it right– Heisenberg uncertainty principle

• Things happen differently at nanoscale

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What could be nanotechnology?

• Chemistry

• Viral self-assembly

• Cellular process

• Nuclear fission

• Quantum computing

• Squeezed light

• Molecular tweezers

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Chemistry

• Precision placement (yes)

• Molecule by molecule (maybe)

• Working with moles (a lot)

• Surface chemistry (always)

• Particles and colloids (if small enough)

• Chemists guide atoms and molecules to particular places (with help from nature)

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Chemical Reaction

CO and O2 Reacting to Form CO2

Works in the gas phase but not on a surface!

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Surface Femtochemistry

http://www.physik.fu-berlin.de/~femtoweb/newfemtos/surffemto/coox.php

COads + Oads ---- on transition metal surface ----> CO2 gas

Although the reaction cannot be initiated by conventional heating, excitation with a femtosecond pulse triggers the oxidation of CO on a ruthenium surface, leading to the formation of CO2.

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Surface Femtochemistry

Sketch illustrating that only desorption occurs when the system is excited thermally, due to the lower energy required for CO-desorption than for O- activation. Under laser excitation, the 1.8 eV barrier for O-activation is overcome by coupling to the hot electrons, so that CO2 is formed.

http://www.physik.fu-berlin.de/~femtoweb/newfemtos/surffemto/coox.php

Page 14: Angstromology

Potential energy surface for the CO/O/Ru(0001) system, constructed from spectroscopic data, assuming Morse potentials. Lines are the result of preliminary trajectory calculations. Going up, the O-CO distance increases, whereas the Ru-O distance remains constant: CO desorbs. To the right, the O-CO distance decreases (CO approaches oxygen), while O moves away from Ru: CO2 is formed and moves away from the surface. Thermally, only the pathway up is

accessible. Upon femtoseond excitation, regions of the potential energy surface become accessible that are inaccessible under thermal activation: The system is directed into new reactive regions.

Surface Femtochemistry

http://www.physik.fu-berlin.de/~femtoweb/newfemtos/surffemto/coox.php

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Dendrimers

• Dendrimers– Branching– Stepwise growth– Globular nature– Functionalization

• Engineer like a protein– Surface energy / shape

• Can be grafted to C60 buckyballs / modified

• Controlling a processhttp://www.dendritech.com/

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Generation 2 PAMAM Dendrimer

http://www.dendritech.com/

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Cellular Processes

• DNA

• Micro RNAs

• Proteins

• Ribosomes

• Enzymes

• Lipid bilayer

• Ion channels

Page 20: Angstromology

http://www.geosciences.unl.edu/~dbennett/

PhotochemistryBio-Nano Energy

In cyclic photophosphorylation electrons from ferredoxin (Fd) are shuttled into the cytochrome b6f complex which then pumps protons out of the stroma into the thylakoid lumen. The resulting

gradient can be used to drive ATP syntheses by the chloroplast ATP synthase.

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Protein Capturing Light

http://www.cat.cc.md.us/~gkaiser/biotutorials/photosyn/photon.html

Photosynthesis moves EM energy into life through carbon

Page 22: Angstromology

Protein Pumps and Energy

http://www.cat.cc.md.us/~gkaiser/biotutorials/photosyn/

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Self Assembly

• Crystals

• Proteins

• Viruses

• Fractals

• Self-assembly is a process– Nature has harnessed it– Nanotechnology will harness it

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Self Assembly

• Follows statistical thermodynamics

• Crystal growth follows symmetry rules

• Seen in molecular monolayers

• Building process for viral caspids

• Interaction of matter and information

• Use nature to guide manufacturing– Control and guide novel structures

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Molecular Self Assembly

Figure1: 3D diagram of a lipid bilayer membrane - water molecules not represented for clarity

http://www.shu.ac.uk/schools/research/mri/model/micelles/micelles.htm

Figure 2: Different lipid model -top : multi-particles lipid molecule

-bottom: single-particle lipid molecule

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Viral Self-Assembly

http://www.virology.net/Big_Virology/BVunassignplant.html

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Bio-Nano Convergence

Jonathan Trent NASA - Ames

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Nuclear Fission

• Fission at the pico scale

• Assembling a critical mass

• Creating a chain reaction– Controlling the number of events– Neutrons and the uranium U235 isotope

• Unleashes the power of a star– Required an understanding of the atom

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Nuclear Fission

Page 30: Angstromology

Thin Film Deposition

• Layer by layer deposition– Most thin film layers are 10 to 1000A thick– Deposition can occur one monolayer at a time

• Atom by atom nucleation– Clusters of atoms influence each other– Ordering process can occur very quickly

• Tailored properties based on process– Optical, electrical, and magnetic– Interfacial chemistry can be critical

Page 31: Angstromology

Thin Film Deposition

http://www.fmf.uni-freiburg.de/projekte/pg_cluster/projekt_cluster/eci/eci_sim_e.html

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Atomic Spectroscopy

• Energy and matter

• AES / LEEDS

• SEM / EDX

• ESCA / XPS

• XRF / EXAFS

• SIMMS

Page 33: Angstromology

Photoelectric Effect

http://hypertextbook.com/physics/modern/photoelectric/

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Quantum Computing

Three trapped 112Cd+ ions exhibit four different normal modes of oscillation in an asymmetric Paul trap

http://monroelab2.physics.lsa.umich.edu

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Qubit Computing

• Qubit states• 00, 01, 10, 11• Qubit algorithms• New thinking• New problems

Centre for Quantum Computinghttp://www.qubit.org/

Page 36: Angstromology

Uncertain Computing

• Quantum world is based in probabilities

• Quantum states can be either 1 or 0, or in some cases – both!

• Leverage uncertainty and ultra density for unimaginable speed:

• > 1022 transistors• > 1015 clock speed

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Nano-Bio-Info

Nano

Bio Info

Sel

f ass

embl

y

Mic

roar

rays

, Bio

ME

MS

Quantum

computing

nanoelectronic devices

Digital cellsDNA computinginsilico biology

Concept by Robert Cormia

Page 39: Angstromology

Nano-Bio

• Using protein / viral complexes and DNA to self-assemble devices, and novel function, into biomechanical systems

Earth’s early nanostructures ~ 2 billion years ago

Page 40: Angstromology

Digital Cells – Bio Informatics

http://www.ee.princeton.edu/people/Weiss.php

Modeling life as an information system

Page 41: Angstromology

Nature as a Computer

• Biological systems like DNA and RNA especially appear to be more than networks of information.

• RNA itself can be seen as a molecular decision network

Page 42: Angstromology

Nanoelectronics

• Pushing semiconductors to the edge

• Electrons moving too fast, or ‘confined’

• Band gap theory

• Quantum tunneling effects

• Semiconduction has always been ‘nano’– Now we are deliberately doing it

Page 43: Angstromology

Nanoelectronics

Flux-qubit systems

Mesoscopic quantum systems SEM picture of a "persistent-current qubit" sample. The inner loop which contains three Josephson junctions is the qubit. The outer loop, containing two junctions, is a SQUID which measures the qubit's state. microwave pulses of variable length and amplitude to coherently manipulate the quantum state of the loop. The readout by the Squid was also pulsed and revealed quantum-state oscillations with high fidelity.

http://vortex.tn.tudelft.nl/research/fluxqubit/fluxqubit.html

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Quantum Tunneling

• Breaking the quantum barrier– Quantum Tunneling in nanoelectronics– Macroscopic Quantum Coherence

• Meeting the particle / wave head on

• It can be a problem or a property– Clock speeds on the edge of tunneling– Or a way to store ‘information in energy’

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Quantum Tunneling Transistor

http://www.aip.org/png/html/tunnel.htm http://www.sandia.gov/media/quantran.htm

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Quantum Dots

• Quantum confinement– Energy and information states

• Small atomic assemblies

• Used in solar collection devices– With very high quantum efficiencies

• Applications in memory storage

• Applications in quantum computing

Page 47: Angstromology

Quantum Dots

Quantum dots are small devices that contain a tiny droplet of free electrons. They are fabricated in semiconductor materials and have typical dimensions between nanometers to a few microns. The size and shape of these structures and therefore the number of electrons they contain, can be precisely controlled; a quantum dot can have anything from a single electron to a collection of several thousands. The physics of quantum dots shows many parallels with the behavior of naturally occurring quantum systems in atomic and nuclear physics. As in an atom, the energy levels in a quantum dot become quantized due to the confinement of electrons. Unlike atoms however, quantum dots can be easily connected to electrodes and are therefore excellent tools to study atomic-like properties. There is a wealth of interesting phenomena that have been measured in quantum dot structures over the past decade.

http://qt.tn.tudelft.nl/research/qdots/

Page 48: Angstromology

Carbon Nanotubes

• Like graphite but all coiled up

• Typically 10 Angstroms in diameter

• Two key parameters control properties– M/N ratio determines electrical conductivity

• SWNT and MWNT– Transistors, heat sinks, hydrogen storage

• Carbon fibers have come a long way!

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Carbon Nanotube Structures

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Nanotubes / Nanohorns

The electrical properties of nanotubes / nanohorns can change, depending on their molecular structure. The "armchair" type has the characteristics of a metal; the "zigzag" type has properties that change depending on the tube diameter—a third have the characteristics of a metal and the rest those of a semiconductor; the "spiral" type has the characteristics of a semiconductor.

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Nanotube Properties

http://nanotech-now.com/nanotube-buckyball-sites.htm

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Self Assembled Nanostructures?

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Nanoscale Emergence

• We live in an ‘emergent’ universe– Billiard balls vs. fuzzy functions– Quantum rules have ‘leveled out’

• Ensembles act in Newtonian physics• In smaller networks of 1,000s of atoms

– Atoms influenced by the quantum world

• The trick is to tap the inner rules of nature, and design them into our world

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Nanoscale Emergence

Billiard ballsFuzzy functions

Angstroms (10-8 cm) Microns / meters

AtomsElectronsQuanta

DustRainRocks

Emergent properties

Quantum properties

Concept by Robert Cormia

Page 55: Angstromology

What Really Defines ‘Nano’?

• Working at the ‘quantum scale’ – Working in small numbers– Working in small dimensions– Working in small time scales

• Let the universe drive – but we steer– Self assembly, quantum computing

• Trapping nano properties at the macro scale – tailoring key physical properties

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Nanoscale Dimension - EMI

Mass

Energy Information

Forc

esS

elf-assembly

Quantum states

Concept by Robert Cormia

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Nanoscale Dimension - EMI

• Matter• Energy• Information

• Forces• Quantum states• Self assembly

Force – interaction of matter and energyQuantum states – interaction of energy and informationSelf assembly – interaction of matter and information

Nanotechnology touches the ‘inner universe’

Page 58: Angstromology

Nanoscale Engineering @ EMI

• Energy– Tunneling in quantum devices, band gaps

• Mass– Melting points, strength, self-assembly

• Information– Quantum computing / genetic algorithms

• Real nanotechnology occurs @ EMI

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Summary

• Everything is small – big is an illusion• Small is necessary, but not sufficient

– Small just gets you to the quantum world

• Design, engineer, and / or manufacture– Or control a quantum mechanical process

• Functionalize and monetize at ‘small’– Nanoscience and nanotechnology @EMI

• Let the quantum universe help us out

Page 60: Angstromology

Orders of Scale• Giga – billion, 10 e9• Mega – million, 10 e6• Kilo – thousand, 10 e3• Macro – referring to big or visible• Milli – 10 e-3

• Micro – referring to small, also 10 e-6

• Nano – 10 e-9

• Pico – 10 e-12

• Femto – 10 e-15