Atomic Structure Chapter 1 PDF

Summary

This document is a lecture presentation about atomic structure. The presentation covers a range of topics including different models (Bohr, Schrodinger, Rutherford etc) of atomic structure, calculations and explanations.

Full Transcript

COLLEGE OF
ENGINEERING
Department of Mechanical and
Industrial Engineering

ATOMIC STRUCTURE

Smallest unit of matter
 Lesson Plan
Introduction to Atom, elements, compounds and mixtures.
Various Theories of Atomic structure
Bohr Model [Numerical on transitions], Somerfield Model
Schrodinger Model
Dual nature of electron (De Broglie) [Evidences, examples]
Heisenberg Uncertainty Principle [Evidences, examples]
Concept of atomic orbitals
Quantum Numbers
Pauli’s Exclusion Principle
Hund’s Rule
Numerical (Energy levels, electronic configuration)
 Let’s Refresh
Atom: An atom is the smallest particle of an element that can exist
and still have properties of element. Atoms consist of principally
three fundamental particles (building blocks of atoms): electrons,
protons and neutrons.
Ions: are charged particles carrying either a negative or a positive
charge. Ions are called as Cation (+) or Anion (-)
Molecule: A molecule is formed when the atoms of the same or
different elements combine.
Identify the names of fundamental
particles that makes protons,
neutrons & electrons.
 Rutherford model

In 1911 Ernest Rutherford, carried out an
experiment to test Thomson’s Plum Pudding

Rutherford Experiment: involved directing 𝛼
model.

He expected the 𝛼 particles to travel through the
particles at a thin sheet of metal foil.

foil with, at the most, very minor deflections in
their paths.

3/7/2021 5
Gold Foil Experiment

6
Observation Conclusion
⮚ Most of the space inside the atom is
⮚ Most of the alpha particles passed
empty
undeflected through the foil
⮚ As only few positively charged particles
⮚ A small fraction was deflected by were deflected, this shows that positive
charge is not spread uniformly inside the
small angles
atom

⮚ Very few alpha particles (1 in ⮚ Volume occupied by nucleus is
negligibly small as compared to the size
20,000) bounced back by getting
of the atom.
deflected by 180ᵒ
 Rutherford model
(Limitations)
Examine the failure of Rutherford
model.
Rutherford was
unable to explain the
stability of atom.
Did not explain about
the arrangement of
electrons around the
nucleus and energies
of these electrons
 Bohr’s model
Positive charge at the nucleus. Who was Neils Bohr? In
Electrons revolve around the nucleus which year he founded this
model?
in a fix orbits.
These orbits/energy levels are
quantized. (?)
Electrons don’t lose energy in these
orbits.
Certain amount of energy (How
much ?) is required for electron to
move to higher energy level.
After 10-5 sec it loses same energy and
come back to previous state.
 Describe Limitations

The Bohr Model considers electrons to have both a known
radius and orbit, which is impossible as the electrons are
continuously moving.

The Bohr Model is very limited in terms of size of the atom.

The Bohr Model does not account for the fact that accelerating
electrons do not emit electromagnetic radiation.

This model could not explain the ability of atoms to form
molecules by chemical bonds.
 Remember

According to the Bohr model of the which orbit has the
minimum energy?
1.K
2.L
3.M
4.N
 Calculate
What is the change in energy when the electron
relaxes from n=3 to n=2?

Calculate the
energy required by
an electron to jump
from level 1 to
level 4?
 Somerfield model

He suggested
that each shell
is made of
subshells.
Like 2nd shell is
made up of 1s
and 1p
subshell.
Evaluate how Sommerfield model was different from
Bohr model?
 Schrodinger Model

In 1926 Erwin Schrödinger, an Austrian
physicist, developed electron cloud
model.
Schrödinger combined the
mathematical equations for the behavior
of waves (with the de Broglie equation)
to generate a mathematical model for
the distribution of electrons in an atom.
This mathematical equations describe
the possibility of finding an electron
in a certain position.
 Schrodinger Model…

This model can be portrayed as
a nucleus surrounded by an
electron cloud.
Where the cloud is most dense,
the probability of finding the
electron is greatest, and
conversely, the electron is less
likely to be in a less dense area
of the cloud.
Describe Schrodinger Electron cloud
Model
 Evaluate

1. How Bohr model
is different from
electron cloud
model? (2 points)
2. How negative
cloud density is
related with
probability of
finding of
electrons?
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 De Broglie
In 1924 de Broglie (In 1929 he won Nobel award for
his PhD thesis) reasoned that if light wave can
behave like a stream of particles (photons) then
perhaps electrons can possess wave properties.
He said an electron bound to the nucleus behave like
a stationary wave (a wave which do not travel).
de Broglie reason lead to the conclusion that wave
particle duality exists for particles. And he presented
the formula:
λ = h/mv [h Plank’s constant, m is particle mass, v is
particle velocity]
 De Broglie…..
Significance of de-Broglie equation: Its true for all
particles. But NOT significant for big particles or we can
say in our daily life, it is not observable.
Its significant for subatomic particles like electrons,
protons etc.
Verification of de-Broglie equation.
i. Particle nature (Photoelectric effect)
ii. Wave nature (Davison Germer experiment)
Video on Wave nature of particle
https://www.youtube.com/watch?v=MTuyEn-ngIQ
 Solved Example

If an electron is moving with a velocity of 2*10 6 m/s, find
the wavelength of the electron.
Given Data:
Velocity of the electron, v =2×106 ms-1
Mass of electron, m =9.1×10-31 Kg
Planck’s Constant, h = 6.62607015×10 −34 Js
The de-Broglie wavelength is given by λ = h/mv
= 6.62607015×10−34 /(2×106)(9.1×10-31 )
λ = 0.364×109m

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 Now You Calculate
If Ahmed kicked a football of 0.3 kg with a speed of 300
m/s, then calculate the wavelength associated with the
football. Also comment on the answer.
What is given data here?

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 Heisenberg
Uncertainty
In our daily we can precisely determine and predict the
instant position as well as velocity of a body.
But in case of small particles like electrons it’s position
and velocity at a given instant can not be determined
with absolute accuracy. It is called Heisenberg
uncertainty principle.
It’s a direct consequence of the dual nature of matter
and radiation.
Mathematically Δx * Δp ≥ h/4π
Here, Δx is uncertainty in position, Δv, is uncertainty in
velocity, m is mass, h is planks constant.
 Understand, Evaluate, Analyze
Learn, why it is impossible to observe Heisenberg principle in daily
life?

How Bohr’s model fail in Heisenberg principle?
Why electron can not exist inside nucleus? Collect
argument, & evidences
 Solved Example
Uncertainty of the position of a particle with mass =
3.0×10−30 kg is 2.0×10−10 m. If the uncertainty in momentum is 60% of
the momentum, what is the speed of this particle?
Given Data???
Solution:
The momentum of the particle is, p=mv, Here, v is the speed of the
particle.
As per Uncertainty principle: Δx⋅Δp≥h4π
Since, Δp=60%  0.6p  p=0.6mv;
Δx⋅(0.6mv)=h/4π
2.0×10−10×0.6×3×10−30×v =6.626×10−34 J.s/4π
v≈1.5×105m/s

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 Now you calculate
Position of a chloride ion on a material can be determined
to a maximum error of 1μm. If the mass of the chloride ion
is 5.86 × 10-26Kg, what will be the error in its velocity
measurement?
Answer 9*10-4 m/s
More problems at
Heisenberg Uncertainty Principle - Detailed Explanation, Fo
rmula and Derivation, (byjus.com)

Problem 2 is given here for you to solve.

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 Concept of Atomic Orbital
ORBIT ORBITAL

It is a region of space around the
It is well-defined circular path nucleus where the probability of
followed by electron around nucleus. finding an electron is maximum.

It represents two dimensional It represents three dimensional motion
motion of electron around nucleus. of electron around nucleus.

The maximum no. of electrons in an The maximum no. of electrons in an
orbit is 2n2. orbital is 2.

Orbit is circular in shape. Orbitals have different shapes.
Shapes of Orbitals

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 Quantum Numbers

Quantum Numbers: Exact location and energy state
of an electron. [Full profile of an electron]
n = Principal quantum number. Tell about main energy
level. Always integer
l = Subsidiary quantum number. Tell about sub energy
level within main energy level. Values range from 0 to
(n-1)
ml = Magnetic quantum number. Tell about orientation
of orbital in space. Values range from +l to – l including
zero.
ms = Spin quantum number. Tell about spin state of an
electron. [+1/2, -1/2]
 Examples

How write “l” and “ml” values?
▪ For n=4, ‘l’ values will be 0,1,2 & 3
▪ If l=0 🡪 s orbital 🡪 ml = 0
▪ If l=1 🡪 p orbital 🡪 ml = -1,0,+1
▪ If l=2 🡪 d orbital 🡪 ml = -2,-1,0,+1,+2
▪ If l=3 🡪 f orbital 🡪 ml = -3,-2,-
1,0,+1,+2,+3

▪ Write all quantum numbers for 3p 1
electron.
Test your
understanding
 Test your understanding

Write all quantum number for following electrons:
2s1 (n=2, l=0, ml = 0, ms = +1/2)
2p3 (n=2, l = 1, ml= -1, 0, +1; ms = +1/2, +1/2, +1/2 )
3d6
4d2
 Aufbau Principle
The orbitals of lower energy are
filled in first with the electrons and
only then the orbitals of high energy
are filled.
(n+l) rule: Electron will prefer the
orbital where value of n+l is
smaller.
If n+l values are same then electron
will prefer to enter in orbital with
smaller n value.
For example electrons will enter in
3p and then in 4s. After that 3d.
 Examples

Why is electronic configuration of Cr and Cu are special?
 Test your understanding
A. Write full electronic
configuration for following
elements:
Z= 12 and Z= 36
B. Another way to write
configuration in short in
Noble gas notations.
Write for
Z=12, and Z= 20
 Pauli’s exclusion Principle
This principle was formulated by Austrian
physicist Wolfgang Pauli in 1925 for electrons.
It is impossible for two electrons of a poly-electron
atom to have the same values of the four quantum
numbers.
For example, if two electrons reside in the
same orbital, and if their n, ℓ, and mℓ values are the
same, then their ms must be different, and thus the
electrons must have opposite half-integer spins of 1/2
and −1/2.
 Hund’s Rule of maximum
multiplicity

Every orbital in a subshell is singly occupied with
one electron before any one orbital is doubly
occupied, and all electrons in singly
occupied orbitals have the same spin.