chapter 3 introduction to nanophysics

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Chapter 3Introduction to Nanophysics

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Introduction to Nanophysics

Chapter 3

Forces and InteractionsA Closer Look at FluidicsThe Wave Nature of LightPractical Applications

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Section 1: Forces and Interactions

Introduction to Nanophysics 13

Forms of EnergyElectrical ForcesQuantum PhysicsThe Polar Nature of Water

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Four Fundamental Forces Act Upon All Matter

Forces and Interactions 13

GravityElectromagneticWeak Nuclear Strong Nuclear

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Relative Influence of Forces Changes with Scale

Forces and Interactions 13

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Forces in a Hydrogen Atom

Forces and Interactions 13

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Electrical Forces

Forces and Interactions 13

Atoms and Molecules− Electrostatic interactions

• Chemical bonds• Hydrogen bonds

− Polarizability• Van der Waals interactions

Electromagnetic Radiation− X-rays− UV rays

Physiological Electrical Signals− Nervous system (e.g., brain, nerves)− Muscles (e.g., heartbeat)

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Energy is Required or Released when Particles Interact with Forces

Forces and Interactions 13

Energy Vocabulary− Mechanical work (w): force applied over a distance− Heat (q): change in thermal energy reservoir during a physical,

chemical, or biological process (q=ΔH when pressure is constant)− Entropy (S): measure of the number of ways objects can interact− Gibbs free energy (ΔG)

• Relationship among enthaply (ΔH), entropy (ΔS), temperature (T)− ΔG = ΔH – TΔS

− ΔG < 0 spontaneous process (additional energy not required)− ΔG = 0 equilibrium situation− ΔG > 0 non-spontaneous process

At the nanoscale, energy can flow between internal energy, in the form of chemical bonds, and useable energy or heat (ΔH).

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Quantum Physics Model of Matter

Forces and Interactions 13

Matter Is Composed of Atoms and Molecules− Atoms are composed of elementary particles− Molecules are composed of atoms

Electrostatic Interactions Predominate − Within molecules and atoms− Among molecules and atom

Quanta− Electrons are confined to regions of space;

therefore their energy is restricted to discrete values

− Transitions between energy levels occurs in discrete increments

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Quantum Physics Model of Matter

Forces and Interactions 13

Atoms Are Composed of Elementary Particles− Central nucleus with two particle types:

• Neutrons (no charge)• Positively charged protons

− Negatively charged electrons found around and about the nucleus

Electrons Are In Constant Motion− Individual electrons localized into regions of

space with defined energy− Electron transitions occur in defined

increments (energy is quantized)

Fluctuating, Non-Uniform Charge Distribution Surrounds the Atom

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Quantum Physics Model of Matter

Forces and Interactions 3 1

Molecules Are Composed of Atoms− Relative location of atomic nuclei give shape

to the molecule

Electrons Are In Constant Motion− Electrons are shared among atoms in the

molecule in covalent bonds− Covalent bonds between nuclei have shapes,

locations, energies• σ-bonds, π-bonds• molecular orbitals

Fluctuating, Non-Uniform Charge Distribution Surrounds the Molecule

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Quantum Physics Model of Matter

Forces and Interactions 13

Electrostatic Interactions − A predominant force among molecules− Origin: fluctuating, non-uniform charge

distribution surrounding the molecule

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Water Molecule10 Electrons− 8 from O − 1 from each H

10 Protons− 8 from O nucleus− 1 from each H nucleus

Forces and Interactions 13

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Water MoleculeElectric DipolePartial Negative Charge at Oxygen ApexPartial Positive Charge at Hydrogens

Forces and Interactions 13

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Section 2: A Closer Look at Fluidics

Introduction to Nanophysics 23

Cohesion and Surface TensionHydrophobicityAdhesive Forces and Capillary ActionViscosityLaminar and Turbulent Flow

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Cohesion and Surface Tension

A Closer Look at Fluidics 23

Properties of Liquids− Liquid molecules move (Brownian

motion)− Liquid phase molecules are attracted

to:• Each other (cohesion)• Surrounding surfaces (adhesion)• Surrounding atmosphere

Surface Tension− Measures the difference between a

liquid molecule’s attraction to other liquid molecules and to the surrounding fluid

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Cohesion and Surface Tension

A Closer Look at Fluidics 23

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Surfaces

A Closer Look at Fluidics 23

Hydrophilic Surface Hydrophobic Surface

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Cohesion and Surface Tension

A Closer Look at Fluidics 23

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Contact Angle

A Closer Look at Fluidics 23

Hydrophilic Surface Hydrophobic Surface Super Hydrophobic Surface

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Super Hydrophobic Surface

A Closer Look at Fluidics 23

Lotus Leaf

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Adhesive Forces and Capillary Action

A Closer Look at Fluidics 23

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Fluid Flow in Channels

A Closer Look at Fluidics 23

Laminar Flow− Molecules moving in one direction,

longitudinally

Turbulent Flow− Molecules moving in random

directions with net longitudinal flow

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Viscosity Coefficient η

A Closer Look at Fluidics 23

Viscosity− Fluid “thickness”− Quickness or slowness of fluid flow− Measure of force applied to cross-sectional area of fluid for a

period of time

Volume of Fluid Flowing through a Pipe

Velocity of a Sphere Falling through the Fluid

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Laminar and Turbulent Flow

A Closer Look at Fluidics 23

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Forces Acting on Pen Tip in DPN

A Closer Look at Fluidics 23

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Section 3: The Wave Nature of Light

Introduction to Nanophysics 33

Electromagnetic Radiation, Wavelengths, and EnergyReflection, Refraction, and Wave InterferenceDiffraction and Diffraction GratingsNanoscale Diffraction with X-rays

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Electromagnetic Spectrum

The Wave Nature of Light 33

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Young’s Double Slit Experiment

The Wave Nature of Light 33

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Young’s Double Slit Experiment, Continued

The Wave Nature of Light 33

Particle Wave

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Young’s Double Slit Experiment, Continued

The Wave Nature of Light 33

n λ = d sin θ ≈ d (x / L)

TOP FRONT

x

n = 2

n = 1

n = 2L

dθ

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Reflective Diffraction

The Wave Nature of Light 33

n∙λ = d∙(sin θi + sin θd)

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X-Ray Diffraction

The Wave Nature of Light 33

Bragg law: n∙λ = 2∙d∙sin θ

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Section 4: Practical Applications

Introduction to Nanophysics 43

Keeping Things CleanA Miniature LaboratoryProtein SensorsLight Under Control

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Keeping Things Clean

Practical Applications 43

Lotus Leaf

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Keeping Things Clean

Practical Applications 43

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A Miniature Laboratory

Practical Applications 43

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Protein Sensor Concept

43Practical Applications

Idea− Create a visible light diffraction grating with known periodicity and

ridge height− Coat grating surface with an affinity label for a target protein − Characterize the diffraction wavelength at specific viewing angles− Expose coated grating to biological sample containing target

protein; isolate protein coated diffraction grating− Monitor changes in wavelength as a function of protein binding

Technological Challenges− Ridge material compatibility (substrate, affinity label, target

protein solutions) − Detecting small changes in diffraction wavelength − Cost effectiveness

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Protein Sensors

Practical Applications 43

Lipid Grating Biosensor− Illuminate a nanotechnology grating with white light. Detect

intensity changes in the diffracted light upon analyte binding with 5 nm detection limits

Grating Fabrication with Dip Pen NanolithographyEnabling DPN Technology− Multilayer phospholipid ink

• Self-assembling phospholipid (e.g., DOPC)• Biofunctional phospholipid affinity label for analyte

− Precision patterning on PMMA substrates• 500 to 700 nm ridge spacing, ≤ 80 nm ridge height

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Light Under Control

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Photonic Crystals− 1-D to 3-D nanoscale voids for

storage of photons

Active Research Areas− Materials for information storage

devices− Read/write mechanisms

Practical Applications