Bohr Model & Electron Configuration PDF

Summary

This document explains the modern atomic theory, including the Bohr model and the quantum mechanical model. It details the arrangement of electrons in atoms and the concept of atomic orbitals.

Full Transcript

Modern Atomic Theory
Why do metals glow when heated?
 Models of the Atom
A model should explain not just
what the material is made of
(composition) but also how it is
going to behave (changes).

Rutheford’s atomic model could
not explain the chemical
properties of elements.
Basically, it couldn’t explain why
things change color when heated.
Atomic Model Timeline
Atomic Model Timeline
 The Bohr Model
Niels Bohr (1885-1962) was a Danish
physicist and a student of
Rutherford’s.

In 1913, Bohr introduced his atomic
model based on the simplest atom,
hydrogen (only 1 electron)
– Bohr proposed that an electron is
found only in specific circular paths,
or orbits, around the nucleus.
Bohr Model
 The Bohr Model
Each electron has a fixed energy
= an energy level.
– Electrons can jump from one energy
level to another.
– Electrons can not be or exist
between energy levels.
A quantum of energy is the
amount of energy needed to
move an electron from one energy
level to another energy level.
The
The degree
degree to to
which
which they
they
move
move from
from
level
level to
to level
level
determines
determines the the
frequency
frequency of of
light
light they
they give
give
off.
off.
 Bohr Model
To move from one level to
another, the electron must gain
or lose the right amount of
energy.
The higher the energy level, the
farther it is from the nucleus.
– Gain energy to move to higher
energy levels (away from nucleus)
– Lose energy to move to lower
energy levels (closer to nucleus)
 The Bohr Model
The amount of energy required to
go from one energy level to
another is the not same for the
electrons.
Higher energy levels are closer
together. This means it takes less
energy to change levels in the
higher energy levels.

The Bohr model was tested
with the hydrogen element
but failed to explain the
energies absorbed and
emitted by atoms with more
than one electron.
Did you know that an element can be identified by its emission
spectra?

– When atoms absorb energy, electrons move into
higher energy levels. These electrons then lose
energy by emitting light when they return to lower
energy levels.
Mercury Nitrogen
Fingerprints
of certain
atoms
5.3
Atomic Spectra
– When atoms absorb energy,
electrons move into higher energy
levels. These electrons then lose
energy by emitting light when
they return to lower energy
levels.
 5.3
An Explanation of Atomic Spectra
In the Bohr model, the lone electron in
the hydrogen atom can have only
certain specific energies.
–When the electron has its lowest
possible energy, the atom is in its
ground state.
–Excitation of the electron by
absorbing energy raises the atom
from the ground state to an excited
state.
–A quantum of energy in the form of
 5.3
An Explanation of Atomic Spectra
– The light emitted by an electron
moving from a higher to a lower
energy level has a frequency
directly proportional to the energy
change of the electron.
 5.3
An Explanation of Atomic Spectra
The three groups of lines in the
hydrogen spectrum correspond to
the transition of electrons from
higher energy levels to lower energy
levels.
Bohr’s Model
The Quantum Mechanical Model
Rutherford’s and Bohr’s model focused on
describing the path of the electron around the
nucleus like a particle (like a small baseball).

Austrian physicist Erwin Schrödinger
(1887–1961) treated the electron as a wave.

– The modern description of the electrons in
atoms, the quantum mechanical model,
comes from the mathematical solutions to the
Schrödinger equation.
 Electrons as Waves

EVIDENCE: DIFFRACTION PATTERNS

VISIBLE LIGHT ELECTRONS
 5.1
The Quantum Mechanical Model
The propeller blade has the same
probability of being anywhere in the blurry
region, but you cannot tell its location at
any instant. The electron cloud of an atom
can be compared to a spinning airplane
propeller.
– The quantum model determines the
allowed energies an electron can have
and how likely it is to find the electron in
various locations around the nucleus.
 5.1
The Quantum Mechanical Model
The probability of
finding an electron
within a certain
volume of space
surrounding the
nucleus can be
represented as a fuzzy
cloud.
– The cloud is more
dense where the
probability of finding
the electron is high.
 5.1
Atomic Orbitals
(fuzzy cloud) = An atomic orbital is often
thought of as a region of space in which
there is a high probability of finding an
electron.
 Quantum Mechanics

Orbital (“electron cloud”)
– Region in space where there is
90% probability of finding an e-

Orbital Radial Distribution Curve
Probability cloud
Atomic orbital
Atomic orbital

90%
 Larger atom—
s-orbitals are
More electrons
spherically shaped.
take up more space.
Smaller atom
Smaller atom—
Fewer electrons
take up less space.
p-orbitals are
“dumbell” shaped.
z-axis
p-orbitals are
“dumbell” shaped.
x-axis
p-orbitals are
“dumbell” shaped.
y-axis
p-orbitals together
x, y, & z axes.
 Shells and Orbitals and Atomic Structure
f
d
s p
Shells of
an atom
contain a
number of
stacked
orbitals
4

3

2

1
1st and 2nd level s-orbitals
and the p-orbitals all together.
Why are Atoms Spherical?

Tro, Chemistry: A Molecular
Approach
 5.1
Atomic Orbitals
Different atomic orbitals are denoted by letters. The s
orbitals are spherical, and p orbitals are dumbbell-
shaped.

Four of the five d orbitals have the same shape but different
orientations in space.
 5.1
Atomic Orbitals
The numbers and kinds of atomic orbitals
depend on the energy sublevel.
Energy # of Letter of # of # of Total
Level, n sublevels sublevels orbitals electrons electrons
per in each in energy
sublevel orbital level
 5.1
Atomic Orbitals
The numbers and kinds of atomic orbitals
depend on the energy sublevel.
Energy # of Letter of # of # of Total
Level, n sublevels sublevels orbitals electrons electrons
per in each in energy
sublevel orbital level

1 1 s 1 2 2

s 1 2
2 2 8
p 3 6

s 1 2
3 3 p 3 6 18
d 5 10

s 1 2
4 p 3 6
4 32
d 5 10
f 7 14
 5.1
Atomic Orbitals
The number of electrons
allowed in each of the first four
energy levels are shown here.
– A maximum of 2 electrons per
orbital
Use this to find
the # of electrons
in an energy level
2n2
 5.2
Electron Configurations
The ways in which electrons are
arranged in various orbitals
around the nuclei of atoms are
called electron
configurations.
– Three rules—the aufbau principle,
the Pauli exclusion principle, and
Hund’s rule—tell you how to find
the electron configurations of
atoms.
 5.2
Electron Configurations

Aufbau Principle
– According to the aufbau principle, electrons occupy the
orbitals of lowest energy first. In the aufbau diagram
below, each box represents an atomic orbital.
Pauli Exclusion Principle
– According to the Pauli exclusion principle, an atomic
orbital may describe at most two electrons. To occupy the
same orbital, two electrons must have opposite spins;
that is, the electron spins must be paired.
Hund’s Rule
– Every orbital in a sublevel is singly occupied before any
orbital is doubly occupied.
– All of the electrons in singly occupied orbitals have the
same spin (to maximize total spin).
Filling Diagram for Sublevels

Aufbau Principle
Filling Diagram for Sublevels
 Electron Configurations
The electron configuration of an atom is a
shorthand method of writing the location of
electrons by sublevel.
The sublevel is written followed by a superscript
with the number of electrons in the sublevel.
– If the 2p sublevel contains 2 electrons, it is written
2p2
 Writing Electron Configurations
First, determine how many electrons are in the
atom. Iron has 26 electrons.
Arrange the energy sublevels according to
increasing energy:
– 1s 2s 2p 3s 3p 4s 3d …
Fill each sublevel with electrons until you
have used all the electrons in the atom:
– Fe: 1s2 2s2 2p6 3s2 3p6 4s2 3d 6
The sum of the superscripts equals the atomic
number of iron (26)
 Electron Configuration Practice
Write a ground state electron
configuration for a neutral atom

K

Ne
 Electron Configuration Practice
Write a ground state electron
configuration for these ions.

O2-

Na+
 Electron Configuration Practice
An excited atom has an electron or electrons which are not
in the lowest energy state. Excited atoms are unstable
energetically. The electrons eventually fall to a lower level. *
is used to indicate an excited atom. For example: *Li 1s2
3p1. (The ground state for Li is 1s2 2s1.)

Write an excited electron configuration for the following
atoms.

*Al

*K
 5.2
Electron Configurations
Orbital Filling Diagram
 Electron Configurations
and the Periodic Table
The periodic table can be used as a guide for electron
configurations.
The period number is the value of n.
Groups 1A and 2A have the s-orbital filled.
Groups 3A - 8A have the p-orbital filled.
Groups 3B - 2B have the d-orbital filled.
The lanthanides and actinides have the f-orbital filled.
 Blocks and Sublevels
We can use the periodic table to predict which
sublevel is being filled by a particular element.
 Noble Gas Core Electron Configurations
Recall, the electron configuration for Na is:
Na: 1s2 2s2 2p6 3s1
We can abbreviate the electron configuration by
indicating the innermost electrons with the
symbol of the preceding noble gas.
The preceding noble gas with an atomic number
less than sodium is neon, Ne. We rewrite the
electron configuration:
Na: [Ne] 3s1
 Electron Configurations
Condensed Electron Configurations
Neon completes the 2p subshell.
Sodium marks the beginning of a new row.
So, we write the condensed electron configuration for
sodium as
Na: [Ne] 3s1
[Ne] represents the electron configuration of neon.
Core electrons: electrons in [Noble Gas].
Valence electrons: electrons outside of [Noble Gas].
 5.2
Exceptional Electron Configurations
Some actual electron
configurations differ from those
assigned using the aufbau
principle because half-filled
sublevels are not as stable as
filled sublevels, but they are
more stable than other
configurations.
 5.2
Exceptional Electron Configurations
Exceptions to the
aufbau principle are
due to subtle electron-
electron interactions in
orbitals with very
similar energies.
Copper has an electron
configuration that is an
exception to the
aufbau principle.