Atomic Theory Lecture 1 PDF

Summary

This lecture provides an introduction to atomic theory. It includes information on historical models of the atom and related information like recommended readings. The document may be lecture notes for a course in chemistry or physics, especially at the undergraduate level.

Full Transcript

PL1001

Pharmaceutical Chemistry

ATOMIC THEORY

Lecture 1

Dr Alberto Di Salvo
Recommended reading

Chemistry and Chemical Reactivity by John C. Kotz; Paul M.
Treichel; John Townsend.

Available in the library in paperback (7th edition, 2 copies and 8th edition, 2
copies) and as an e-book.

All general chemistry textbooks have a section on atomic theory.
What comes to mind when we think about an atom?

Flaw: an orbit is defined as a curved path followed by a planet (a very large
body) in space.
Recently

actual “picture” of atomic orbitals obtained with a Field Emission Electron
Microscope

s orbital on the left hand side and p orbital on the right hand side

first ever image of atomic orbitals

Adapted from I. M. Mikhailovskij et al, Physical Review B 2009, 80, 165404
Atomic theory timeline

A B C D E

A – Greek (400 BC) and Dalton’s (1803) model

B – Thomson’s model (1904)

C – Rutherford’s model (1911)

D – Bohr’s model (1913)

E – Modern atomic model (quantum mechanics)
Greek model

The universe is composed of
two elements: the atoms and
the void in which they exist and
move.

Democritus
Dalton’s model

1) All matter is made of atoms. Atoms are
indivisible and indestructible.

2) All atoms of a given element are identical
in mass and properties.

3) Compounds are formed by a combination
of two or more different kinds of atoms.

4) A chemical reaction is a rearrangement of
John Dalton
atoms.
Thomson’s model

Discovered the first sub-
atomic particle – the
corpuscle (electron).
Joseph John Thomson

Atoms are uniform
spheres of positively
charged matter (dough)
in which electrons
(resins) are embedded.
Rutherford’s model

Discovered the second
sub-atomic particle – the
nucleus.
Ernest Rutherford

Most of the atomic mass is concentrated in the
positively charged nucleus.

The negatively charged electrons, smaller in size,
orbit around the nucleus like in a small scale
cosmic model.
Bohr’s model

1) Electrons rotate around the nucleus in orbits
that have a set size and energy.

2) The energy of the orbit is related to its size. The
lowest energy is found in the smallest orbit.

3) Radiation is absorbed or emitted when an
electron moves from one orbit to another.

Niels Bohr
Modern atomic model

Quantum mechanics
(wave-particle) theory.

Erwin Schrödinger

Werner Heisenberg

1) Bohr’s orbits (energy levels or shells) are quantised and take the name
of orbitals (valid solutions of Schrödinger’s equation).

2) Orbitals are regions (of space) where electrons are likely to be found
(Heisenberg’s Uncertainty Principle).
 Conceptual contributions
timeline
Electron
Indivisible Electron Nucleus Orbit
Cloud
Greek X
Dalton X
Thomson X
Rutherford X X
Bohr X X X
Modern X X X
Electron vs Golf ball
The wavelength of a moving body is inversely
proportional to its momentum.

momentum = mass (kg) x velocity (m/s)

Louis de Broglie
Property Electron Golf ball
h Mass (kg) 9.11x10-31 0.01
𝜆=
𝑚𝑣 Velocity (m/s) 100 100
Momentum (kg m/s) 9.11x10-29 1
Wavelength (m) 7.27x10-6 6.626x10-34
h= Planck’s constant Large λ Small λ
(6.626 x 10-34 J s)
Mechanics theory Quantum Classical

The motion of large bodies is better described by classical
mechanics, while the motion of particles is better described by
quantum mechanics.
Electromagnetic radiation
Electromagnetic radiation
Waves have a frequency

Use the Greek letter “nu”, , for frequency, and
units are “cycles per second” or Hertz (s-1).

Waves have a wavelength “lambda” - 

All radiation:  = c
c = velocity of light = 3.00 x 108 m/s
Long wavelength = small frequency
Short wavelength = high frequency
Electromagnetic radiation – worked example

Red light has  = 700 nm. Calculate the frequency.

All radiation:  = c
Where C = 3.00 x 108 m/s (velocity of light)

1. Convert the wavelength into meters
700 −7
λ= 9
=7.00 𝑥 10 𝑚
1 𝑥 10

2. Calculate the frequency

8
3.00 𝑥 10 14 − 1
ν= =4.29 𝑥 10 𝑠
7.00 𝑥 10− 7
Energy of a radiation

Energy of radiation is proportional to frequency

E
E == hh ·· Max Planck
h = Planck’s constant = 6.626 x 10-34 J·s

Light
Light with
with large
large  (small
(small )) has
has aa small
small E.
E.

Light
Light with
with aa short
short  (large
(large )) has
has aa large
large E.
E.
E λ
↓ ↓ ↑
↑ ↑ ↓
Electromagnetic radiation

Short wavelength
high frequency
high energy

Long wavelength
low frequency
low energy
Electromagnetic Spectrum
Energy quantisation
E
E == hh ··

The relationship between the temperature of a black body and the
intensity of energy it emits as radiation follows a stepwise relationship.
Each of these steps is called quantum.
Photoelectric effect
E
E == nh
nh
The outcome of this experiment demonstrates the particle nature of light.
Photoelectric effect
E
E == nh
nh
Classical theory stated that E of
ejected electron should steadily
increase with an increase in light
intensity (not observed!)

No e- is ejected until light of a
certain minimum E is used.
Albert Einstein
Number of e- ejected (n) depends
on light intensity.
Photoelectric effect

Experimental observations can be
explained on the basis that light
consists of particles called PHOTONS
of discrete (quantised) energy.

PROBLEM:
PROBLEM: CalculateCalculate thethe energy
energy of
of 11 mole
mole
of
of photons
photons of
of red
red light.
light.
 == 700
700 nm
nm
== 4.29 x 10 14 sec-1
14
4.29 x 10 sec-1
Energy of Radiation – worked example
Energy of 1 mole of photons of red light.

E = h·
= (6.63 x 10-34 J·s)(4.29 x 1014 s-1)
= 2.85 x 10-19 J per photon

E per mol = (energy of a photon x n photons in a mole)
(2.85 x 10-19 J/ph)(6.02 x 1023 ph/mol)
= 172 kJ/mol

This is in the range of energies that can break chemical
bonds.