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ATOMIC STRUCTURE: ELECTRON CONFIGURATION
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ATOMIC STRUCTURE:ELECTRON CONFIGURATION

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Atom , of all matter, consists of 3 fundamental particles:• Electrons• Protons• Neutrons Nucle

us

Shell

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How do electron organise themselves in an atom?

BOHR MODELIn the Bohr model, electrons are viewed as particles traveling along circular orbits of fixed radius

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QUANTUM MECHANICAL MODEL

•Electrons are viewed as waves rather than particles

•These waves are considered to be spread out through a region of space called an orbital.

Quantum mechanic model

An orbital: quantum mechanical equivalent of electron location

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Wave function: a mathematical description of a wave

Schrödinger equation: HΨn=EnΨn

H: complex mathematical operatorE: energyΨ: wave function of electron

Further reading can be found in ‘Chemistry for Engineering Students’

Schrödinger equation: describes the energy of electrons

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What can we see when we solve Schrödinger equation for an atom?

Ψ: wave function of electron is very complicated

From the wave function, we can get mathematical equation for atomic orbital, to describe this:

Quantum numbers:

Primary quantum number (n)

Secondary quantum number (l)

Magnetic quantum number (ml)

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1. Primary quantum number (n) = shell• defines the shell in which a particular orbital is found• must be a positive integer (n = 1, 2, 3, 4, 5,……) When n=1: first shell

n=2: second shell

When number of electron >1 in a shell:• Repulsion between negative charges

Energy difference between orbital in a shell

2. Secondary quantum number (l) = subshell• provides a way to describe energy different

between the orbitals• l : 0, 1, 2, 3, …., n-1

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3. Magnetic quantum number (ml):Possible values: from – l to +l

Under normal conditions, atoms can be specified by n and l. Under magnetic field:

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Have you ever seen these orbitals?1s 2s 2p 3s 3p 3d 4s 4p 4d 4f etc.

Quantum numbers: n and l

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How many electrons can occupy an orbital?

The Pauli exclusion principle states that: no two electrons in an atom may the same set of four quantum numbers: n, l, ml and ms.

THE SPIN QUANTUM NUMBER (MS).When placed in a strong magnetic field, electrons behave like tiny magnets.

Spin up+1/2

Spin down-1/2

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How many electron can occupy an orbital?

2 electrons

p

d

f

Maximum occupied electrons

s

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Electron configuration

• Fill orbitals with lowest energy – highest energy: the aufbau principle

1H 3Li

1s2 2s1

1s1

• Hund’s rule: within a subshell, electrons occupy orbitals individually whenever possible.

2p6C

1s

2s

2p

Highest energy

lowest energy

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Electron configuration

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Some examples

8O

15P

79Au

56Ba

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The Periodic Table and Electron Configuration

• Electron of the highest energy orbital comes from the same subshell

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Periodic trends in Atomic properties

Atomic size: explore the trends in the periodic table• within a group• within a period

Decrease

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Atomic size:• within a group: numbers of shell increases

increase in atomic size and radii.

2

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Atomic size:• within a period ????

+ -Attraction

+ +Repulsion

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+Attraction

Repulsion

Only attraction force

+-

-+ +

Carbon

Hydrogen

Attraction

Repulsion

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Carbon

Attraction Repulsion

Shielding: the masking of the nuclear charge by other electrons

Effective nuclear charge= Attraction - repulsion

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Atomic size:• within a period:

Increase in atomic number (positively charge nuclear)

increase in the attraction forces (effective nuclear charge) between nucleus and electrons

decrease in atomic size

+ -Attraction

+ +Repulsion

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Ionisation( or Ionization) energy

Ionisation energy: the energy required to remove an electron from an atom, forming a cation

First Ionisation energy: the amount of energy needed to induce the reaction

X(gas) X+(gas) + e-

Second Ionisation energy: the amount of energy needed to induce the reaction

X+(gas) X2+(gas) + e-

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Ionisation( or Ionization) energy

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Electron affinity : the energy required to add an electron to an atom, forming an anion

X(gas) + e- X-(gas) Ionisation energy: always positiveElectron affinity : could be negative or positive

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• If X- NOT stable:

Requireenergy

X(gas) + e- X-(gas)

• If X- stable: X(gas) + e- X-(gas)

Release energy

Negative amount of energy

Negative electron affinity

Positive electron affinity

Most electron affinity values are negative

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