Matter & Chemical Change - Unit A PDF

Summary

This document provides an overview of matter and chemical change, including safety symbols, WHMIS, MSDS, the scientific method, types of knowledge, classifying knowledge, and physical and chemical properties.

Full Transcript

Matter & Chemical Change
Unit A
Safety Symbols
Two different systems of safety symbols have been developed to warn users
of potential hazards
HSHS WHMIS
What does the acronym stand Household Safety Hazard Workplace Hazardous Materials
for? Symbols Information System

Where is it used? For household products (the In labs & industry (people with
average consumer) some understanding of
chemistry)
Number of symbols 3 10
Colour coded? Yes, three shapes and colours No, all symbols are in diamonds
are used to indicate degree of and are printed in red, except
hazard one
HSHS: Household Safety Hazard Symbols
Each hazard symbol displays the degree of hazard by the shape and
color of the border
CAUTION WARNING DANGER

Yellow inverted triangle Orange diamond Red octagon

LOWEST HAZARD HIGHEST HAZARD
The symbol inside describes the type of hazard.
Example – A skull (poison) inside a red octagon requires only 1g of poison to kill
a 200lb man.
A skull in an orange diamond requires 5g to kill the same man.
A skull in a yellow triangle requires 30g.
WHMIS: Workplace Hazardous Materials
Information System

Note: WHMIS was recently updated, so your textbook is NOT current.
WHMIS - purpose
To ensure that all work places across Canada that work with
hazardous chemicals have a standardized way for handling
and labeling toxic chemicals.
Provides:
○ hazard identification
○ product classification
ways of safely storing and organizing chemicals
○ labeling methods & material safety data sheets
○ standardized worker training and education
 MSDS: Material Safety
Data Sheets
MSDS sheets are provided by the
manufacturer & identify the
chemical & physical hazards
associated with each substance
including:
melting
boiling points
toxicity
health effects
first aid
spill and clean up procedures.
 The Scientific Method
Models are supported by the
scientific method which test
hypotheses by making predictions
about the outcome of an experiment
is performed.

The results then provide support or VERY
refutation of the hypothesis. SIMPLIFIED!

https://www.youtube.com/watch?v=i8wi0QnYN6s
 Types of Knowledge
Empirical knowledge: observable
knowledge (operational)

Theoretical knowledge: explains or
describes scientific observations, not
observable (conceptual)

We use interpretation as an indirect form Ice Island?
of knowledge that builds on a concept to
further describe or explain an observation.
Classifying Knowledge
Qualitative observation:
○ describes QUALITIES of matter or changes in matter
○ changes in color, state, odor

Example:
Mg (magnesium) is an
odorless, silver-gray solid that
burns with bright white light.
Classifying Knowledge
Quantitative observations:
○ Involves a QUANTITY of matter that can be measured
○ Mass
○ Volume
○ Number of moles

Example
A 5 cm strip of Mg ribbon
burned for 3 s leaving 2 mm
of ribbon in the tongs.
 Quantitative VS. Qualitative

https://www.youtube.com/watch?v=-S2EiPD4-W0
 CHEMISTRY

The study of substances,
their structures, their
properties, and the
changes that can occur to
them
Physical properties
Describe the physical appearance and composition of a substance.
Property Description
boiling point temperature of boiling (or condensing)
melting point temperature of melting (or freezing)
malleability can be flattened into sheets without crumbling
ductility can be stretched into wires without breaking
colour colour (or colourless)

state solid, liquid, or gas at room temperature
solubility ability to dissolve (usually in water)
crystal formation formation of crystals, appearance of crystals
conductivity ability to conduct heat or electricity
magnetism magnetic attraction between objects
Physical Change
A change in size, shape, or state. It still retains all other physical properties.

Ex. Melting ice
 Chemical Properties
Describe the reactivity of a substance.
Property Description
ability to burn combustion (causing flame, heat and light)
flash point temperature needed to ignite a flame
behaviour in air tendency to break down, react, tarnish
reaction with water tendency to corrode or dissolve

reaction with acids corrosion, sometimes bubble formation

reaction to heat tendency to melt or decompose
reaction to red and blue blue 🡪 red - acid
litmus red 🡪 blue - base
no colour change - neutral
Chemical Change
A change from one substance to another substance.

Ca O S2 Ca S O2
NOTE: in both physical and chemical changes there is Conservation of Mass.
 MATTER = Anything that has mass and occupies
space.

A chemist is most interested in the structure and
properties of matter and the changes that occur in
matter.

EXAMPLES:

1. Digestion – biochemistry

2. Oil or Gas 🡪 plastics – petrochemical engineering

3. Corrosion – chemical engineer

4. Pollution - environmental biologistmatter
Classification of Matter
Pure Substances
All particles of the same substance are
the same (all particles have the same
chemical and physical properties)

2 types of Pure substance
○ Element – all of these are found on
the periodic table. (e.g., sulfur)
○ Compound – 2 or more chemically
combined elements (e.g.,. NaCl, H2O)

**Note the 2 different types of
chemical bonding.
Mixtures
Combination of pure substances (not chemically combined)
4 types
1. Solutions – homogenous mixture (same parts)
Looks similar throughout
Soft drinks (sugar is dissolved)
2. Mechanical Mixture – (heterogeneous)
○ You can see all parts clearly
○ E.g.. soil

*Note the different parts
3. Suspension –
(heterogeneous)
○ The parts are in
different states
○ E.g., Mud – soil (solid) &
water (liquid)
4. Colloid -(heterogeneous)
○ Similar to suspension but not easy to separate.
○ Colloids look a lot like solutions.
If you filter both (solution and colloid) a solution will pass through
but a colloid will leave behind chunks if one of the phases was a
solid.
E.g., Milk, paint, ink…
 OBSERVING CHANGES IN MATTER
Physical Changes
When a substance changes from one state to another
Physical changes are reversible

Chemical Changes
Chemical changes occur when two or more substances
react and form a new substance
The new substances have different properties than
the original substances
CHEMICAL REACTIONS
- There are two parts to a chemical reaction;
1. Reactants (Left side) – the materials present at the start of a reaction
2. Products (Right side) – the new materials produced by the reaction

Direction of Reaction
EVIDENCE OF REACTION
- When chemical reactions occur, a new substance forms and evidence of the
reaction may include one or more of the following:
- A colour change
- The formation of an odour
- The formation of a solid or a gas (bubbles)
- The release or absorption of heat
 Food Chemistry

Various physical & chemical
techniques have been used to
enhance and preserve our food.

The most common way food goes bad
(spoils) is when bad bacteria occur
in too large a number.
METHODS FOR PRESERVING FOOD

Heating and Freezing
Heating (cooking)- temporarily sterilizes
food (kills the bacteria)
Freezing (storage) – halts the growth of
bacteria

Salting (beef jerky)
Salt removes water, by osmosis, from the
food and the bacteria in it. This changes
the taste of the food but kills the
bacteria.
METHODS FOR PRESERVING FOOD
Fermentation – This process uses beneficial bacteria
(lactobacilli) to create a natural preservative (lactic acid).
Sauerkraut was made because it lasted long and had vitamin C to fight off
Scurvy.
Alcoholic beverages are also made this way.
METHODS FOR PRESERVING FOOD
Smoking – smoking your meat or fish introduces antioxidants that
help control the number of bacteria.
 Chemistry Through the Ages
Metallurgy → science of producing and using metals
○ Gold
○ Copper
○ Bronze
○ Iron
Knew the HOW but not the WHY or WHAT

Aristotle → attempted to answer “What is matter?”

Alchemy → turning cheap metals into gold
○ Experimenting with matter
○ Led to discovery of mercury, acids, improved lab equipment
 Model of the Atom Key Features Why the model was rejected/
modified

Dalton’s Billiard Ball Model

Thomson’s Plum Pudding
Model

Rutherford’s Saturn Model
 Model of the Atom Key Features Why the model was rejected/
modified

Bohr Model

Current Model:

Quantum Mechanical Model
RECAP: Model of an Atom
https://www.youtube.com/watch?v=xazQRcSCRaY
TedEd: The 2,400-year search for the atom

Timeline Assignment: due Friday (midnight) via Google Classroom.

You should be able to complete up to p. 6 of your workbook.
 The Periodic Table
https://www.youtube.com/watch?v=rz4Dd1I_fX0
ORGANIZATION
Elements are arranged by increasing atomic number.
ATOMIC NUMBER = NUMBER of PROTONS!

EXAMPLE:
C = 6 protons
U = 92 protons
The Elements
There are about 90 naturally occurring elements, and another 25
synthetic elements.
Based on their properties…
elements can be divided into 3 classes
Metals
Non- Metals
Metalloids
Elements are arranged based on similar properties.
LEFT and RIGHT of the
“staircase line”.
LEFT of the line have
properties of METALS.
RIGHT of the line have
properties of
NONMETALS.
(Normally opposite of
metals!)
Along the staircase line
are METALLOIDS
Organization
The periodic table is organized into rows and columns.
Each horizontal line (or row) is called a period.
Represents electron arrangement.
Organization
Each vertical column forms a group (or family) of elements numbered 1
to 18.
The chemical families are groups of elements that have similar chemical
and physical properties.
Arrangement
Organized by atomic number (# of protons) and chemical properties
These have similar physical and chemical properties. You must know the
following 4:

Alkali metals (group 1) Halogens (group 17) second
–soft, shiny & reactive (vigorous last
with water). –Reactive non- metals
–Have one extra electron –Missing one electron
(valence electron) Noble Gases (group 18) last
Alkaline-earth Metals (group 2) –Non reactive
–Shiny and reactive but not soft –Full outer shell or energy
–Have 2 extra electrons level
The 4 Groups you need to know:
GROUP 1 – ALKALI METALS
They are soft, shiny and silver in colour
They are the most reactive elements
Francium is the most reactive metal

https://www.youtube.com/watch?v=jx0eQbBDeG8
GROUP 2 – ALKALINE EARTH METALS
Shiny and silver in colour, but not soft
Second most reactive group
Called “Alkaline" earth metals because they
form "alkaline“ (Basic, OH-) solutions when they
react with water,
GROUP 17 – HALOGENS
These elements are poisonous and react readily
Colored non-metallic elements, colour gets
deeper as you move down the group
Fluorine is the most reactive non-metal
GROUP 18 – (INERT) NOBEL GASES
These elements are very unreactive
Periodic Table
Colouring activity

Textbook pages are
incorrect, the correct
pages are: 30-31
Atomic Theory
An atom is the smallest part of an element that still has the
properties of that element.
A Closer Look at your Table:
Proton/Neutron/Electron Numbers
The Atom has the same # of protons and electrons.
Atomic Number = number of protons and electrons.
Number of Neutrons = Atomic Mass – Atomic number
 Mass number is protons + neutrons.
(n = m.n. – p)
Differs from Atomic Mass by a miniscule amount.
Number of protons and distribution of electrons give atoms
their distinctive chemical and physical properties

Particle Symbol Charge Mass Location

Proton p+ 1+ 1.7x10-24g Nucleus
(atomic
number)

Neutron n0 0 1.7x10-24g Nucleus

Electron e- 1- 9.1x10-28g Surrounding
nucleus
(in orbitals or
energy
levels)
 Energy Levels of Electrons Valence electrons – the
electrons in the
outermost energy level

Orbits or
Energy * Maximum number of
Levels electrons held by each
Energy levels energy level
can be empty,
partly filled or
completely
filled!
Bohr Diagrams
Bohr Diagrams
Bohr Diagrams
Bohr Diagrams
Bohr Diagrams
Bohr Diagrams
Bohr Diagrams - Try Yourself

https://www.youtube.com/watch?v=wy83UlGQpWw
Noble Gases

Noble gases have full
energy levels… these
atoms are happy and
stable!
What about all the other elements?
Other elements however, do not, so they will form IONS (charged particles).
Valence Electrons ATOM IONS

-e in outer energy level
Cation = + charge
Anion = - charge
 Formation of Ions
Recall: An atom of any element is
neutral, so the number of protons
equals the number of electrons.
An ion is a an atom (or a group of
atoms) that has a positive or negative
electric charge.
The formation of an ion is called
ionization, and is the result of an atom
either gaining or losing electrons.
Cations are positively charged ions.
- They are formed when a metal atom loses
valence electrons (electrons in the outermost
energy level).
- As a result, the ion has MORE protons than
electrons
Anions are negatively charged ions.
- They are formed when a non-metal atom
accepts electrons into its outer energy level.
- As a result, the ion has MORE electrons than
protons.
 Example: Fluorine

The fluorine atom is
neutral but unstable. Its outer energy level is
now full and, therefore,
The fluorine atom will
is stable.
gain an electron.
Although stable, the
Fluorine atom is
charged (it has gained
one extra electron) and
is referred to as an Ion.
 * Remember the
Example: Oxygen electron
numbers for
each energy
level (2,8,8,18)
 * Remember the
Example: Lithium electron
numbers for
each energy
level (2,8,8,18)
Example: Calcium
Review: Ionization
The number of p never changes but, … in a reaction, an atom
will become more (+) or more (-) depending on whether it gains or
loses e-’s.
ATOMS ARE NEUTRAL! …but unstable
IONS ARE CHARGED!! … but stable
The Octet Rule
- The octet rule says that atoms bond in
such a way as to have eight electrons in
their valence energy levels.
- Atoms tend to be stable with full outer
energy levels.

https://www.youtube.com/watch?v=4OKy782ePKM
- Atoms gain or lose electrons so that they have the same number of electrons as the
nearest noble gas.
- This explains why some atoms will react with each other and form compounds and
others will not.
Example:

Li = 1
valence e- F=7
valence e- Mg = 2
valence e-
IONS are the solution!
Metals and non-metals can find a mutual solution to their electrons
problem!
Multivalent Elements

Some metal atoms, form stable ions with more than one charge.
Example: copper atoms will lose EITHER one or two electrons.

These elements are called multivalent, and the first charge given on the
periodic table is the most common.
The Atomic Mass Unit
Mass of atom too small to use a unit like grams (g).
Instead, we use atomic mass unit (amu).
An atom of carbon-12 was assigned an exact mass of
12.00 amu.
The Atomic Mass Unit
Then the relative masses of all other atoms is determined
by comparing each to the mass of an atom of carbon-12.

Example: an atom twice as heavy has a mass of
24.00 amu = twice as heavey ~ Mg
6.00 amu = half as heavey ~ Li
NITROGEN has:
– 7 protons
– 7 neutrons
therefore its mass number is equal to 14 amu
… but the atomic mass on the periodic table is
14.01 amu.
WHY?
Isotopes:
–elements that have the same atomic number
but a different mass number!
 Isotopes
Isotopes are different types of atoms
of the same element.

Can’t change # protons as that
changes the element
Can’t change the # of e- as that
turns it into an ion
Only thing left is the # of
neutrons.

Isotope and Element difference = weight
Atomic mass = protons + neutrons BUT … the number of neutrons
does not have to be constant.
# of Neutrons for any given atom can vary!
EXAMPLE:
“H” can have 1, 2, or 3 neutrons.
“F” can have 9, 10, or 11 neutrons
Uses for isotopes
The isotopes of hydrogen deuterium (2 neutrons) and
(tritium = 3 neutrons) is used for nuclear power generation and nuclear
weapons production

https://www.youtube.com/watch?v=h7vyKDcSTaE&t=221s
Isotope Notation
 Example:
There are 3 naturally occurring isotopes of carbon:

***The bottom
number is
sometimes not
written because
you can determine
the atomic number
from the symbol.
Atomic mass of an element on
the periodic table is called the
atomic molar mass.
Value is calculated as the
average mass of all of the
isotopes of an element,
taking the percent abundance
into account.
Example:
Isotopes of hydrogen:
Review: Isotopes

Isotopes are atoms from the same element that contain different
numbers of neutrons.
Ex. This means that Bromine usually has 45 neutrons , however it
can sometimes exist as an isotope with 44 neutrons

The atomic symbol is sometimes shown with the
mass number and the atomic number. Using this
format, the isotopes for bromine are:
Build An Atom - Simulator
https://phet.colorado.edu/sims/html/build-an-atom/latest/build-an-atom_en.html

Use this simulator to explore the relationships between atoms, ions,
isotopes and the various subatomic particles (protons, neutrons,
electrons) for different elements. Review Bohr models and how to
use them to represent atoms, ions, and isotopes.

Challenge yourself to play the “games”. Good way to check your
own knowledge!
WORKBOOK PROGRESS
This is the end of Part 1.
You should be able to complete your first Chemistry workbook.