Unit 2 Notes PDF

Summary

These notes provide an overview of atomic theory, exploring concepts such as atomic structure, the composition of atoms, different particles and the arrangement of atoms.

Full Transcript

What do we know about atoms?
1) What are atoms made of? (parts
How do you
of the atom)

know??????
2) How big (or small) are atoms?

3) Draw a picture of a simple atom
in your notebook.
We have come a long way in the
understanding of our world.

Going back to famous Greek
philosophers (500-600BC), humans
questioned how our universe works.

The original notion was the earth was
made of Earth, Wind, Fire and Water
Around 400 BC there was one
philosopher who came forward with a
new notion of the universe.

Democritus was the first to say the
world is built by smaller particles. He
called these particles “atoms”.

His ideas were not received with open
arms.
1. All elements are composed of tiny indivisible
particles called atoms.

2. Atoms of the same elements are identical.

3. Atoms of different elements can physically
mix or chemically combine together in whole
number ratios.

4. Atoms cannot be subdivided, created or
destroyed.

5. Chemical reactions occur when atoms are
separated, joined or rearranged. Atoms of
one element never change into other
elements.
 Section 1 The Atom: From
Chapter 3 Philosophical Idea to Scientific Theory

Foundations of Atomic Theory
The transformation of a substance or substances into
one or more new substances is known as a chemical
reaction.

Law of conservation of mass: mass is neither
created nor destroyed during ordinary chemical
reactions or physical changes
 Section 1 The Atom: From
Chapter 3 Philosophical Idea to Scientific Theory

Foundations of Atomic Theory,
continued
Law of definite proportions: a chemical compound
contains the same elements in exactly the same proportions
by mass regardless of the size of the sample or source of
the compound

Law of multiple proportions: if two or more different
compounds are composed of the same two elements, then
the ratio of the masses of the second element combined with
a certain mass of the first element is always a ratio of small
whole numbers
 How small is an atom?

In one copper penny there are 6.24 x 1022 atoms

To compare the earth’s population is only 6 x 109
people

If you put 100 000 000 copper atoms side by side
they would make a line only 1 cm long.

Why can’t we see Atoms?
Dalton Lied!!! Well not
exactly……his theories were investigated
further.

Atoms have since been shown to be
able to be divided into smaller
particles. (subatomic particles)

Atoms are made of three smaller,
subatomic particles.

Protons, Neutrons and Electrons
Electrons are the negatively charged
subatomic particles.

JJ Thomson (English physicist)
discovered electrons in 1897.

He discovered these by using a
cathode ray tube.

Passing electric current through
gases, then observing how the
electric beam reacts to a magnet.
Thomson tried experimented with
different gases in the tube with the
same results.

Thus concluded electrons were apart
of all atoms.

Afterwards Millikan found the charge
and mass of an electron about
1/1840 of a proton.
Video
In the 1900s scientist continued studying
nuclear chemistry.

They were using particle accelerators to
bombard atoms.

In 1932 James Chadwick was able to
detect a neutral charged subatomic
particle with the same mass of a
proton.

This particle was found to be the neutron
Now we have Protons (+ charge), Neutrons
(0 charge), and Electrons (- charge).

Where do all these pieces fit?
In 1911 Ernest Rutherford from Manchester,
England came up with the Gold Foil
Experiment.

Ernie fired Alpha Particles (double positive
charged) at a piece of gold foil.
In 1911 Ernest Rutherford from
New Zealand came up with the
Gold Foil Experiment.

Ernie fired Alpha Particles
(double positive charged) at a
piece of gold foil.
Gold Foil Experiment
Gold Foil Experiment
Discovery of the Atomic Nucleus
The results of their gold foil experiment led to the
discovery of a very densely packed bundle of matter
with a positive electric charge.

Rutherford called this positive bundle of matter the
nucleus.
 Unit 2

Composition of the Atomic
Nucleus
Except for the nucleus of the simplest type of hydrogen atom,
all atomic nuclei are made of protons and neutrons.

A proton has a positive charge equal in magnitude to the
negative charge of an electron.

Atoms are electrically neutral because they contain equal
numbers of protons and electrons.

A neutron is electrically neutral.
 Unit 2

The nuclei of atoms of different elements differ in their
number of protons and therefore in the amount of
positive charge they possess.

Thus, the number of protons determines that atom’s
identity.
 Unit 2

Atomic Number
Atoms of different elements have different
numbers of protons.

Atoms of the same element all have the
same number of protons.

The atomic number of an element is the
number of protons of each atom of that
element.
 Visual Concepts
Chapter 3

Atomic Number
 Section 3 Counting Atoms
Chapter 3

Isotopes
Isotopes are atoms of the same element
that have different masses.

The isotopes of a particular element all
have the same number of protons and
electrons but different numbers of
neutrons.

Most of the elements consist of mixtures
of isotopes.
 Section 3 Counting Atoms
Chapter 3

Mass Number
The mass number is the total number
of protons and neutrons that make up
the nucleus of an isotope.
 Visual Concepts
Chapter 3

Mass Number
 Section 3 Counting Atoms
Chapter 3

Designating Isotopes
Hyphen notation: The mass number is
written with a hyphen after the name of
the element.
uranium-235

Nuclear symbol: The superscript indicates
the mass number and the subscript
indicates the atomic number.
 Section 3 Counting Atoms
Chapter 3

Designating Isotopes,
The number of neutrons is found by subtracting the
atomic number from the mass number.

mass number − atomic number = number of
neutrons
235 (protons + neutrons) − 92 protons = 143
neutrons

Nuclide is a general term for a specific isotope of an
element.
 Unit 2

Designating Isotopes,
continued
Sample Problem A
How many protons, electrons, and neutrons are there in
the following:
37
atom of chlorine-37? Cl
17
Atom of Chlorine – 34?
235
atom of Uranium – 235 ? U

Atom of Uranium – 230? 92
 Ions

Ions are when elements gain (anions,
negative charge) or lose (cations, positive
charge) electrons.

The element stays the same, so the
number of the protons also stay the same!
1) Complete the table below

Atom Name Atomic Atomic # Protons # # Mass Nuclear
(hyphen Symbol Number electron Neutrons Number Symbol
notation)

Fe+2 30

Silver -108 46

K-1 40 -1
19 K

18 18 40
 Nuclear
Chemistry
Chapter 21
 Nuclear Chemistry
Nuclear Chemistry Deals with the study of the
nucleus.

This deals with atoms protons, neutrons and their
existence.
 Types of Radiation

Radiation

Alpha particles Beta particles Gamma particles

Radiation occurs when a nucleus is unstable and must
alter is components to obtain stability.

When we are looking at any type of radiation or
radioactive decay we must remember that matter is
conserved!
 Why Radiation?
What happens when positive and negative
charges are near each other?

What happens when the same charges are
near each other?

What holds the electrons to the atom?

What is contained in the nucleus?
 Coulombs Law

q = charge
r = radius (or distance)
k =constant
No calculations just qualitative
 Nuclear Stability
Isotopes with low fig 28.6
atomic numbers
– Stable ratio is 1
neutron to 1 proton
Isotopes with high
atomic numbers
– Stable ratio is 1.5
neutrons to 1 proton
This creates the band
of stability
 Unit 2

Forces in the Nucleus

When two protons are extremely close to each other,
there is a strong attraction between them.

The short-range proton-neutron, proton-proton, and
neutron-neutron forces that hold the nuclear particles
together are referred to as nuclear forces.

The nuclear force attraction stabilizes the “+” “+”
repulsion in the atom
 Nuclear Stability
Remember Nuclear fig 28.6
Forces.

Protons have
repulsive forces.

Close distance
between protons and
neutrons keep the
nucleus together.
 Nuclear Stability and Decay
Unstable isotopes will undergo decay to
achieve a more stable ratio of neutrons to
protons
The type of decay depends on the ratio of
neutrons to protons
– Too many neutrons. Turn neutrons to protons.
(beta decay). Or the nucleus loses mass.
(alpha decay)
– Too many protons, the atom captures
electrons and turn protons to neutrons, this
emits a positron
 Alpha particles
Helium nuclei
– Contains 2 protons and 2 neutrons
– Net charge of +2
– Has a mass of 4 amu
High mass limits penetrability
– Looks like: 42He or α
 Alpha particles in a reaction
Alpha radiation is emitted from U-238
238
92
U →23490Th + 42He
Is matter conserved?
Yes!
Now you try!
Alpha radiation is emitted from Rn-222
222 218 4
86
Rn → 84
Po+ 2
He
Is matter conserved?
Yes
 Beta particles
Fast moving electrons
formed by the decomposition of a neutron
in to a proton and the fast moving electron
They have a negligible mass
– Consequently they are more penetrating than
alpha particles
They have a charge of -1
 Beta particles in a reaction
The general reaction
1 1 0
0
n→ 1
H + -1
e
What does that mean?
A neutron is converted into a proton
So, the mass number remains the same but the atomic
number increases by one
 Beta particles in a reaction
C-14 is a beta emitter, show the decay
process
146C →147N + 0-1e
Is matter conserved?
Yes!
Now you try
4019K →
4019K → 4020Ca + 0-1e
 Gamma Rays
High energy electromagnetic radiation
given off by a radioisotope
Often emitted with alpha and beta particles
Gamma rays have no mass and no
charge, so they do not alter the atomic
number or the mass number
Gamma particles have the largest
penetration ability
 Gamma particles in a reaction
230 226 4
90
Th→ 88
Ra + 2
He + γ
– When the alpha particle is released a huge
amount of energy is also released (the
gamma particle)!
 Is the following Alpha emission or beta
emission?

234 0 234
Th --→ B + Pa
90 -1 91

238 4 234
92
U --→ 2
He + Th
90
 Warm Up
Astatine – 210 goes through alpha decay,
beta decay and alpha decay in that order
to become stable. Write the reactions that
represent this process.
 Radioactive
All nuclei with atomic numbers greater
than 83 are radioactive
These nuclei have both too many neutrons
and too many protons to be stable
– So most undergo decay
Most emit alpha particles,
 Fission
When some radioactive nuclei are
bombarded with neutrons they undergo
splitting of a nucleus into smaller
fragments called fission

Neutrons are released from fission
reaction, creating a chain reaction
 Nuclear Fission & Energy
Nuclear fission can release an enormous
amount of energy
– Ex. Fission of 1kg of U-235 release the same amount
of energy as 20,000 tons of dynamite

Energy is calculated by E=mc2
E = Energy
m = difference of mass
c = speed of light
In fusion and fission a very small amount of mass of is
converted to energy and visa versa.
 Nuclear Fusion

Fusion occurs when nuclei combine to
produce a nucleus of greater mass
Only take place at temps greater than
40,000,000˚C

Ex. 4 1
1
H + 2 0
-1
e → 4
2
He + energy
 Half Life
Half life - the amount of time it takes for ½
of a substance to decay.

Example - In one half life, 500g of a
substance will leave 250g behind. A
second half life will leave 125g. A third ½
life will leave 62.5g.
 Half Life
Sample Problem.

A substance has a half life of 10 years.
How much substance will remain after 30
years if we start with 100g?