chapters 4 and 5 introduction to nanophysics and nanochemistry:the nanoscopic and macroscopic worlds

Chapters 4 and 5

Introduction to Nanophysics and Nanochemistry:The nanoscopic and macroscopic worlds

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What does history have to do with science?

Those who cannot learn from history are doomed to repeat it.

George Santayana

The Nanoscopic World: Introduction

2

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What is science?

A search for truth

(and what is truth?)

A methodical form to seek knowledge

A coherent body of knowledge in a certain area

A way to increase the knowledge of humanity

An experience that increases our awareness of the way things are

The Nanoscopic World: Introduction

3

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What is science?

“We find ourselves in a bewildering world. We want to make sense of what we see around us and to ask: What is the nature of the universe? What is our place in it and where did it and we come from? Why is it the way it is?” 

From A Brief History of Time

by Stephen Hawkins

The Nanoscopic World: Introduction

4

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How does it work?

from Thomas Kuhn in The Structure of Scientific Revolution

Paradigm: “… accepted examples of scientific practice [that] provide models from which spring particular coherent traditions of scientific research.”

“… normal-scientific research is directed to the articulation of those phenomena and theories that the paradigm already supplies.”

“New and unsuspected phenomena, …are repeatedly uncovered by scientific research… “

“… characteristic shifts in the scientific community’s conception of its legitimate problems and standards… [did not occur] from some methodologically lower to some higher type.“

“…considerations that lead can lead scientist to reject an old paradigm in favor of a new… appeal to the individual’s sense of the appropriate and the aesthetic.”

The Nanoscopic World: Introduction

5

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How we go about it?

Underlying principles

Matter is composed of atoms and molecules.

Atoms differ by their atomic number; molecules differ by the atoms that form them and by their molecular structure.

The behavior of matter depends on the physical and chemical properties of the atoms and molecules that compose it.

The Nanoscopic World: Introduction

6

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How did the Greeks go about it?

:

Greek word meaning indivisible.

Democritus

All that exists is atoms in the void.

Plato

Atoms have different geometries that give a substance its characteristics.

The Nanoscopic World: Introduction

7

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Table of elements

Moderns

The Nanoscopic World: Introduction

Greeks

8

Earth Wind

Fire Water

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Processes

Greeks• Substances are made of

combinations of the four elements

• Substances behave according to the combination of the four elements

• The elements move according to their nature

The Nanoscopic World:

Inrtoduction

Moderns• Substances are made of

elements in the periodic table

• Substances behave according to the elements that compose them

• Energies and forces determine the movement and reactivity of the elements

9

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Agenda

Introduction

The Nanoscopic World−Matter and energy−Atoms−Nanoscale particles

The Macroscopic World−Intermolecular forces−Properties of liquids−Applications

The Nanoscopic World:

Introduction

10

The Nanoscopic World:

Matter and Energy

Introduction to Nanophysics and Nanochemistry

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The Nanoscopic World:

Matter and Energy

12

What is matter?

?

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How do we perceive matter?

States (or phases) of matter: Solid, liquid, gaseous

Classification of matter:

The Nanoscopic World:

Matter and Energy

13

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Explanation of matter

States (or phases) of matter:

The Nanoscopic World:

Matter and Energy

14

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Explanation of matter

Classification of matter

The Nanoscopic World:

Matter and Energy

15

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Definitions

What is energy?

Capacity to perform work.

What is work?

Force applied through a distance.

What is force?

Exerted energy.

Mass times acceleration.

The Nanoscopic World:

Matter and Energy

16

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Mechanical energy

For a moving object

Kinetic Energy

K = ½mv2

Potential Energy (Work)

U (or V) = - W =

Law of conservation of energy

K + U = 0

E = K + U

The Nanoscopic World:

Matter and Energy

17

2

1

x

xF(x)dx

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1st Law of Thermodynamics

Change in energy of a system of particles

E = q + w

w: work

w =

q: heat transferred

Heat

Kavg = (3/2)RT

The Nanoscale World:

Matter and Energy

18

V2

V1p(V)dV

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Electromagnetic spectrum

The Nanoscopic World:

Matter and Energy

19

= c/: wave length: frecuencyc: constant of the speed of light

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Theories of light

Interference

The Nanoscopic World:

Matter and Energy

20

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Properties of light

Diffraction

The Nanoscopic World:

Matter and Energy

21

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Properties of light

Reflection diffraction

The Nanoscopic World:

Matter and Energy

22

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Properties of light

X-ray diffraction

The Nanoscopic World:

Matter and Energy

23

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Theories of light

Light particles

The Nanoscopic World:

Matter and Energy

24

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Theories of light

Light particles

The Nanoscopic World:

Matter and Energy

25

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Theories of light

Photoelectric effect

Energy of a photon

Ef = h

h: constante de Planck

Kinetic energy of the electron

Ke = h -

: Binding energy of electron to the metal

Relativistic effects

Ef = h = mc2

The Nanoscopic World:

Matter and Energy

26

The Nanoscopic World:

Atoms

Introduction to Nanophysics and Nanochemistry

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Atom structure

Bohr atom

The Nanoscopic World:Atoms

28

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Wave particle duality

Interference

The Nanoscopic World:

Atoms

29

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Wave particle duality

De Broglie relation

Wave properties

For light

For an electron

The Nanoscopic World:

Atoms

30

2f mc

hchE

c

mch

mvh

mch

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Modern model of the atom

31

The Nanoscopic World:

Atoms 14

Helium Atom−2 Neutrons and 2 protons in the nucleus

−2 Electrons moving about the nucleus

An Element Is an Atom with a Unique Chemical Identity

The Presence of 2 Protons in the Nucleus Is Unique to the Helium Atom−# Neutrons changes — helium isotopes

−# Electrons changes — helium ions

−# Protons changes — not helium!

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Ions

The Nanoscopic World:

Atoms

32

Net charge = # of protons - # of electrons

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Mathematics of the atom

Schödinger equation

One dimension

Operators

Hamiltonian

Simplified equation

The Nanoscopic World:

Atoms

33

(x)E(x)Vdx

(x)dm8π

h2

2

2

2

ˆ

(x)E(x)V(x)K ˆˆ

VKH ˆˆˆ

EH

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Atomic Spectra

The Nanoscopic World:

Atoms

34

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Interpretation of atomic spectra

The Nanoscopic World:

Atoms

35

Energy levels

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Atomic orbitals

• Electron probability density

The Nanoscopic World:

Atoms

36

Region around a nucleus where the probability of finding an electron is 90%

Orbital:

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Atomic orbitals

37

The Nanoscopic World:

Atoms 14

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Electron configuration

The Nanoscopic World:

Atoms

38

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Periodic Table of the Elements

39

The Nanoscopic World:

Atoms 14

Metals NonmetalsMetalloids

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Periodic Trends: Atomic Number (Number of Protons in Nucleus)

40

The Nanoscopic World:

Atoms 14

Increasing atomic number

Incr

easi

ng a

tom

ic n

um

ber

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Periodic Trends: Atomic Size

41

The Nanoscopic World:

Atoms 14

Increasing atomic size

Incre

asin

g a

tom

ic size

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Periodic trends: Ionization energy

The Nanoscopic World:

Atoms

42

Increasing ionization energy

Incr

easi

ng ioniz

ati

on

en

erg

y

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Periodic Trends: Electronegativity

43

The Nanoscopic World:

Atoms 14

Increasing electronegativity

Incr

easi

ng

ele

ctro

negati

vit

y

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Molecular Geometry

The Nanoscopic World:

Atoms

44

The Nanoscopic World:

Nanoscale particles

Introduction to Nanophysics and Nanochemistry

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Agenda

The Nanoscopic World:

Introduction

46

Introduction

The Nanoscopic World−Matter and energy−Atoms−Nanoscale particles

The Macroscopic World−Intermolecular forces−Properties of liquids−Applications

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Refresher

The Nanoscopic World:

Nanoscale particles

47

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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Ionic compounds

The Macroscopic World:

Nanoscale particles

48

Na + ½ Cl2 → [ Na+ + Cl– ] → NaCl

Ca + Cl2 → [ Ca+2 + Cl– + Cl– ] → CaCl2

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Covalent bond formation

The Macroscopic World:

Atoms

49

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Molecules

The Macroscopic World:

Nanoscale particles

50

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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Polymers

The Macroscopic World:

Nanoscale particles

51

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Dendrimers

The Macroscopic World:

Nanoscale particles

52

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SAM

Self-Assembled Monolayers

The Macroscopic World:

Nanoscale particles

53

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Metal nanoparticles

The Macroscopic World:

Nanoscale particles

54

Properties

− 1 to >100 nm

− Uniform size distribution

− Easily modified surface properties

Gold particles

− Are red, not gold

− Inert in biological organisms

− Can be functionalized with SAM

Silver nanoparticles

− have antibacterial effect

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Metal nanoparticles

The Macroscopic World:

Nanoscale particles

55

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Quantum dots

The Macroscopic World:

Nanoscale particles

56

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Energy level revisited

The Macroscopic World:

Nanoscale particles

57

Semiconductors

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Carbon allotropes

The Macroscopic World:

Nanoscale particles

58

Carbon Nanotube

C60

Fullerene

The Macroscopic World:

Intermolecular Forces

Introduction to Nanophysics and Nanochemistry

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Polarity of bonds

The Macroscopic World:

Intermolecular forces

60

Electronegativity−3.5 Oxygen

−2.1 Hydrogen

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Polarity

The Macroscopic World:

Intermolecular forces

61

Dipole

Ions

Induced Dipole

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Intermolecular forces

The Macroscopic World:

Intermolecular forces

62

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The Macroscopic World:

Intermolecular forces

63

Hydrogen bonding

Ice

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Hydrogen bonding in DNA

The Macroscopic World:

Intermolecular forces

64

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Energetics

The Macroscopic World:

Intermolecular forces

65

Energy of interaction− 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): 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).

The Macroscopic World:

Properties of liquids

Introduction to Nanophysics and Nanochemistry

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Liquids

The Macroscopic World:

Properties of liquids

67

Properties of Liquids− Brownian motion

− Cohesion and adhesion forces

− Interaction with surfaces

− Surface tension

− Capillary action

− Fluidity

− Viscosity

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Forces of interaction

The Macroscopic World:

Properties of liquids

68

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Surfaces

The Macroscopic World:

Properties of liquids

69

Hydrophilic Surface Hydrophobic Surface

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Liquid surfaces

Surface Tension− Measures the difference between a liquid molecule’s attraction to other

liquid molecules and to the surrounding fluid (above).

The Macroscopic World:

Properties of liquids

70

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Capillary action

The Macroscopic World:

Properties of liquids

71

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To flow or not to flow

The Macroscopic World:

Properties of liquids

72

Viscosity−Resistance to flow

−Quickness or slowness of fluid flow

Volume of Fluid Flowing through a Pipe

Velocity of a Sphere Falling through the Fluid

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Fluidity

The Macroscopic World:

Properties of liquids

73

Laminar Flow− Molecules moving in one direction,

longitudinally

Turbulent Flow− Molecules moving in random directions

with net longitudinal flow

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Fluidity

The Macroscopic World:

Properties of liquids

74

The Macroscopic World:

Applications

Introduction to Nanophysics and Nanochemistry

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Cleaning up

The Macroscopic World:

Applications

76

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Carbon nanotubes

The Macroscopic World:

Applications

77

Exploring Uses− Enclose atoms and molecules

− Enclose other carbon nanotubes

− Application in batteries for electric vehicles

− Used as a “frictionless” axle and bearing in a nanomotor

− Changeable electric properties

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Solar cells

The Macroscopic World:

Applications

78

Current and Potential Applications− Alternatives to silica

− Improve efficiency in light absorbance

− Thin and flexible films

− Cost reduction

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Miniature laboratory

The Macroscopic World:

Applications

79

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Nanocatalyst

The Macroscopic World:

Applications

80

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Nanocatalyst

The Macroscopic World:

Applications

81

Encapsulated Enzyme Particles−Isolatable

−Enhanced stability• From thermal denaturation• From proteolytic enzymes

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Drug delivery

The Macroscopic World:

Applications

82

β-cyclodextran camptothecin

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Protein sensors

The Macroscopic World:

Applications

83

Process− 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

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Biological sensor

The Macroscopic World:

Applications

84

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Other apps

The Macroscopic World:

Applications

85

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

storage of photons

Active Research Areas− Materials for information storage

devices

− Read/write mechanisms