SCH3U0
Chemical Reactions
Types of Reactions
Synthesis
- 2 different molecules/atoms
combine to produce a compound
Decomposition
- Reactant broken down into
2 or more products
Single Displacement
- Element reacts with a compound
and displaces the 2nd element to
form a new compound and an element
Double Displacement
Precipitation Reaction
Always has a solid and
an aqueous product
Neutralization Reactions
Base + Acid 🡲 Salt + Water
Combustion
- Burning of hydrocarbons
- Complete combustion produces CO2 and H2O
Nomenclature
Set of rules for
naming compounds
Balancing Chemical Equations
Polyatomics and diatomic molecules
Stoichiometry
Moles
*The unit used to measure
amounts of any substance.
1 Mole (or "mol) is
~6.02 x 10^23
**Avogadro's Constant**
Formulas
# of moles = mass(g)/Molar mass(g/mol)
or n=m/M
# of moles = # of entities/Avogadro's constant
or n = N/Na
Percent Composition (%)
% composition =
(Mass of individual element/total mass) x 100
Empirical & Molecular Formula
Empirical or 'Simplest'
Formula for a compound in the
smallest whole number ratio
Molecular
Actual ratio for formula
of a compound
Stoich Problems
Find mass of either reactant(s) or products
Use formulas:
(n = m/M) and (n = N/Na)
Limiting/Excess Reagent
Given both reactants' masses
To determine which reactant
will be consumed first
Divide moles of each reactant
by coefficient of reactant to find # of "cycles"
Reactant with more cycles is excess
reactant with less is limiting
Percent Yield
Tells us how 'efficient' a reaction was
Theoretical Yield:
Calculated or 'expected' amount
of product formed
% Yield = Actual/Theoretical
Actual Yield:
Actual amount
of product formed
Molar Ratio:
Moles of unknown/moles of known
Chemical Trends & Bonding
Periodic Trends
Atomic Radius
Half of distance from nucleus to valence
Factors affecting size
# of shells/energy levels
Shielding effect -
multiple energy levels
Strength of attraction
of valence electrons
Increases 🡳 and 🡰
PERIODIC LAW:
When elements are arranged by increasing atomic number, they fall into categories with similar chemical/physical properties
Bonding
Lewis-Dot Bonding/Structures
Bonding Capacity
related to # of valence electrons
Groups (1-3) = # of group
Groups (4-8) = 8 - # of valence electrons
Intramolecular
Covalent Bonds
1. Hydrogen bonding
2. Dipole-dipole
3. London forces
Intermolecular
Ionic Bonds
Polar Covalent Bond
An uneven distribution of charges
due to unequal sharing of electrons
For a molecule to be polar,
it must be:
- Containing a polar bond
- Molecule does not have symmetry
Gases & Atmospheric Chemistry
Background/Intro
States of substances depend
on the forces between the particles
If the forces are strong - solid
If the forces are weak - Liquid or gas
Gasses are the only
compressible state
Kinetic Molecular Theory
Gas particles are in constant
motion and have perfectly elastic
collisions
(in closed systems)
Multiple collisions increase pressure
Pressure = force/area
Can be measured in:
Kilopascals (kPa)
Pascals (Pa)
Atmospheres (atm)
Millimeters of Mercury (mmHg)
Torrs
Boyle's Law
The volume of a gas varies
inversely with with pressure
(at a constant temp)
P1V1 = P2V2
Shampoo bottle exploded
on plane -
Altitude increases, pressure decreases,
making the volume increase
Charles' Law
The volume of a fixed amount
of gas varies directly with
the temperature of the gas
(constant pressure)
V1/T1 = V2/T2
Calculations always done in Kelvin
Temperature
The more kinetic energy the particles
have, the higher the temperature
Temperature recorded in 3 ways:
Celsius (C)
Fahrenheit (F)
Kelvin (K)
K = C + 273
Absolute Zero:
Theoretical Temperature where
all matter would freeze.
Absolute Zero is "-273 C" or "0 K"
Gay-Lussac Law
The pressure of a gas varies
directly with the temperature
of the gas.
(At a constant volume)
P1/T1 = P2/T2
The "Ideal" Gas Law
Pressure multiplied by volume
is equal to the number of moles
times the universal gas constant
and temperature
PV = nRT
R = 8.31 kPa*L/mol*K
STP is
Standard Temperature and Pressure
STP = 273K and 101.3 kPa
SATP is
Standard Ambient
Temperature and Pressure
---------------
SATP = 298K and 100 kPa
Gas Stoich
Expanding to include pressure and temperature into regular stoichiometry problems.
Formulas needed:
PV = nRT
Dalton's Law of Partial Pressure
Partial Pressure is used to
determine the concentration
or fraction in a mixture
P(total) = P1 + P2 + P3...
The pressure that each gas
in a mixture exerts is it's partial pressure
Solutions & Solubility
Characteristics of solutions
Homogenous Mixture
- Can be separated into components
- Looks the same throughout
Transparent (Clear if aqueous)
May be slightly coloured
Polar molecules dissolve in polar
non-polar dissolve in non-polar
Saturated Solution -
No more solute can be dissolved
at the given temperature
Unsaturated Solution -
Solute less than fully saturated
Particles cannot be clearly seen
Cannot be filtered
Components of a solution
Solute
Substance being dissolved into a solvent
(sugar, salt, etc.)
Solvent
Medium in which solute is being dissolved
(water, alcohol, etc.)
Percentage Concentrations
3 types
Mass/Mass % (m/m)
Volume/Volume % (v/v)
Mass/Volume % (m/v)
Used for various purposes in industries
that use different standards
Other Concentrations
ppm (parts per million) =
- 1 g/m3
- 1 g/1000L
- 1 mg/L
- 1 mg/kg
Concentration
Molar Concentration Formula
Concentration = # of moles/volume
or (c = n/v)
How much of solute in a solution
in terms of moles per litre(mol/L) or "M".
Creating Solutions
From a solid
Creating 500 mL of a
mol/L of NaOH
- Place measured amount of solid in flask
- add approx. 250 mL of
distilled water to flask
- Cap and invert to mix
- Add 250 mL or more to reach the fill line
- Cap and invert to mix
- Obtain 500mL volumetric flask
Dilutions
Diluting a stock solution of HCL(aq)
- Obtain 1000mL volumetric flask
- Add approx. 500 mL of distilled water
to volumetric flask
- Measure and add 250 mL of HCL (aq)
to volumetric flask
- Cap and invert to mix
- Add 250mL or more of distilled water
up to the fill line
- Cap and invert to mix
Dilution Formula:
C1V1 = C2V2
Precipitation Reaction
Two liquids mix, one solid (precipitate)
Chemical Equations
1) Balanced chemical equation
2) Ionic Equation
Each Ion separated
3) Net Ionic Equation
'Spectator Ions' removed
Spectator Ions are ions that don't
appear on both sides of the equation
Stoich and Solutions
Formulas:
C = n/v
c1v1 = c2v2
n = m/M
Expanding to include concentrations
and volume into regular stoichiometry problems