Written Report (Inorganic Chem _ PhyChem).pdf

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INORGANIC CHEMISTRY Chemical Change of Matter - occurs when a
substance undergoes a chemical reaction and
Matter - anything that takes up space and can be forms one or more new substances with different
weighed. In other words, matter has volume and chemical properties.
mass.
THE ATOMIC THEORY
States of Matter A scientific theory that explains the nature of matter
by stating that all matter is composed of discrete
Solid - particles are tightly packed with minimal
units called atoms.
movement, resulting in low kinetic energy. Solids
have a definite shape, mass, and volume, and do
The development of atomic theory has evolved
not conform to the shape of their container.
over time as scientific understanding has
Liquid - particles are more loosely packed than in progressed.
solids, allowing them to flow around each other.
This gives liquids an indefinite shape, enabling Atomic Models
them to conform to the shape of their container.
Solid Sphere (John Dalton, 1803)
Gasses - particles have a lot of space between Atoms are invisible and atoms of
them and high kinetic energy. Gasses have no elements are identical. Compounds
definite shape or volume and will spread out are combinations of atoms.
indefinitely if unconfined.

Plasma - is likely the most common state of matter Plum Pudding / Thomson Model (J.J. Thomson,
in the universe, as seen in stars like the sun. 1904)
Plasma consists of highly charged particles with
extremely high kinetic energy. Electrons are scattered throughout a
spherical cloud of positively charged
Bose-Einstein Condensate - occurs at extremely particles.
low temperatures, near absolute zero. In this state,
a group of atoms is cooled to such low
temperatures that they occupy the same quantum Nuclear / Rutherford Model (Ernest Rutherford,
state, behaving as a single quantum entity with 1911)
unique properties. Atom is mainly empty space with a
positively charged center. Electrons
Classifications of Matter
revolve a predictable path.

Planetary / Bohr’s Model (Niels Bohr, 1913)
Negatively charged electrons revolve
around the positively charged nucleus
at a fixed orbit.

Properties of Matter Quantum (Erwin Schrodinger, 1926)
Electrons are found in clouds of
probability called orbitals. Exact
location is impossible to determine.
Still widely accepted as the most
accurate model of the atom.

Atomic Structure

Physical Change of Matter - is a change in the
form or physical properties of a substance, without
a change in its chemical composition.
 Subatomic
Discovered Electric Charge Mass
Pierre and Marie Curie → Discovered the
Particle elements radium and polonium
Electron J.J. −19 −31
(e-) Thomson − 1. 602×10 9. 11×10
Henry Moseley → Determined that atomic number,
Proton Ernest −19 −21
(p+) Rutherford 1. 602×10 1. 673×10 not atomic weight, is the correct basis for ordering
Neutron James −21
elements in the Periodic Table.
0 1. 675×10
(no) Chadwick
Johann Döbereiner → Identified the Law of Triads
Atomic Symbol for elements with similar properties, where the
atomic weight of the middle elements of the triad
was roughly the average of the other two elements.

John Newlands → Proposed the Law of Octaves,
observing that every eighth element had similar
properties when elements were arranged by atomic
weight.

Lothar Meyer → Independently developed a
periodic table similar to Mendeleev's, recognizing
the periodic trend between atomic volume and
atomic weight.

Number of protons = Atomic number Robert Boyle → Defined elements as pure
Number of electrons = Number of protons substances that cannot be broken down into
Number of neutrons = Mass number - simpler substances, laying the groundwork for
Atomic number modern chemistry.

Atomic Properties Antoine Lavoisier → Known as the "Father of
Metallic Property - ability Modern Chemistry", he developed a modern
of an atom to donate an system of naming chemical substances, identified
electron and named oxygen and hydrogen, and established
the Law of Conservation of Mass.
Atomic Size - average
distance between the PARTS OF THE PERIODIC TABLE
nucleus and the valence
Groups → Vertical columns on the Periodic Table;
electron
elements in the same group share similar valence
electrons and chemical characteristics.
Reactivity – tendency of
an atom to react Periods → Horizontal rows on the Periodic Table;
elements in the same period have the same
Ionization Energy – number of electron shells.
energy required to remove an electron from an
atom Valence Electrons - Determines how a particular
atom reacts (Same number of valence electrons =
Electron Affinity – change in energy when a Reacts in the same similar manner)
gaseous atom/ion gains an electron
Main Group Elements → Elements in Groups 1A
Electronegativity – ability of an atom to attract or to 8A. Also known as representative elements.
gain electrons
Transition Elements → Elements in Groups 3 to
THE PERIODIC TABLE OF ELEMENTS 12. Characterized by their ability to form multiple
oxidation states and have colored compounds.
SIGNIFICANT CONTRIBUTIONS
Classifications of Elements:
Dmitri Mendeleev → Started the development of
the periodic table, arranging elements by increasing 1. Metals
atomic mass which led to the modern Periodic Usually shiny, very dense, high
Table structure. melting points.
Can be stretched into thin wires
Antoine Bequerel → First discovered radioactivity. (ductile), hammered into thin sheets
 (malleable), and are excellent elements are used in electronics, lasers, and strong
conductors of heat and electricity. magnets.
In chemical reactions, they readily
lose electrons to form positive ions. Actinides → Radioactive elements, many of which
All are solid at room temperature are synthetic. Uranium and thorium are notable for
except for mercury. their use in nuclear energy.

2. Nonmetals Significant Elements:
Brittle, dull, low melting points.
Hydrogen → A nonmetal, diatomic gas (H₂)
Poor conductors of heat and
that can act like an alkali metal by losing
electricity.
one electron or like a halogen by gaining
In chemical reactions, they tend to
one electron.
gain electrons, forming negative
Oxygen → A highly reactive non-metal,
ions.
essential for combustion and respiration.
Forms oxides with most elements and is the
3. Metals (or Semimetals)
most abundant element in the Earth's crust.
Exhibit both properties of metals and
Carbon → Can form stable bonds with itself
nonmetals
and other elements, creating a vast array of
Semiconductors: Can conduct
organic compounds. The backbone of
electricity better than insulators but
organic chemistry and life.
not as well as conductors
Elemental Composition of the Earth and the
Human Body:

CHARACTERISTICS OF ELEMENTS

Alkali Metals (Group 1) → Highly reactive metals
due to their larger atomic radii and low ionization
energies. Soft, silvery, and can be easily cut.

Alkaline Earth Metals (Group 2) → Reactive
metals, but less so than alkali metals. They
commonly form compounds like oxides and
hydroxides.

Transition Metals (Groups 3-12) → Characterized
by their ability to form complex ions and are
effective catalysts.

Halogens (Group 7A/17) → Highly reactive
nonmetals, known for forming salts when reacting PERIODIC TRENDS IN ATOMIC PROPERTIES
with metals. Unique group because it includes all
states of matter at room temperature and notable Atomic Radius → Increases as you move down,
for containing 4 out of seven diatomic elements (F2, Decreases as you move across (left to right).
Cl2, Br2, I2)
Atomic size increases down a group due to added
Noble Gases (Group 8A/18) → Inert, colorless, electron shells, expanding the electron cloud.
and odorless gasses with a complete valence Across a period, it decreases as the increased
electron shell, making them extremely stable and number of protons in the nucleus exerts a stronger
mostly non-reactive. They are used in lighting and pull on the electrons, reducing the atomic radius.
as inert atmospheres in chemical reactions.

Lanthanides → Rare earth metals, known for their
magnetic and phosphorescent properties. These
 most reactive nonmetal as it is not found in nature
as a free element and reacts explosively with many
substances.

Electronegativity → Increases as you move up
and across (left to right) TYPES AND NAMING OF COMPOUNDS

Fluorine remains the most electronegative element. Nomenclature Prefixes
Noble gasses, however, have an electronegativity
rating of 0 due to their inherent stability, preventing Number Prefix Number Prefix
them from forming bonds with other atoms.
1 mono- 6 hexa-

2 di- 7 hepta-

3 tri- 8 octa-

4 tetra- 9 nona-

5 penta- 10 deca-

A. Ionic Compounds → Formed by the transfer of
electrons between metals and nonmetals.
Ionization Energy → Increases as you move up
and across (left to right) Steps for Naming Ionic Compounds (Monatomic
Ions):
Depends on how tightly electrons are held by the
nucleus; electrons closer to the nucleus are more Example: MgBr2
tightly bound and require more energy to be
removed. 1. Name of Metal Ion: The ion’s name (Mg2+)
is given in the periodic table as magnesium.
Electron Affinity → Increases as you move up 2. Name the non-metal ion by ending the
and across (left to right) element name with the suffix “ide”: The
nonmetal ion is Br (Bromine). By changing
Electron affinity generally becomes more negative the name to end with the suffix “ide”, it gives
across a period as atoms more readily accept “bromide”.
electrons to complete their valence shell, and 3. Write the name of the compound:
becomes less negative down a group due to Magnesium bromide
reduced nuclear attraction on added electrons.
Steps for Naming Ionic Compounds (Transition
Metallic Character → Increases as you move Metal + Nonmetal):
down, Decreases as you move across (left to right)
Example: FeCl3
Refers to how easily an element can lose an
electron. Cesium is the most reactive metal, 1. Identify the Transition Metal and
reacting explosively with water and igniting Nonmetal: Determine which transition metal
spontaneously in air. Francium, located below (Fe) and nonmetal (Cl) are present in the
cesium in the alkali metal group, is so rare that its compound.
properties are largely unobserved. 2. Determine the Charges of the Ions:
Transition metals can form cations with
Nonmetallic Character → Increases as you move different charges. Find the charge of the
up and across (left to right) transition metal ion (3+) from the formula of
the compound and the charge of the
Refers to the tendency of an element to gain nonmetal ion (1-).
electrons in chemical reactions. Fluorine is the
 3. Write the Metal Name: Start with the name Named by combining the names of the cation and
of the transition metal which is “Iron”. the anion (e.g., KNO₃ is potassium nitrate).
4. Specify the Metal Ion Charge: Indicate the
charge of the transition metal ion using a G. Organic Compounds → Compounds primarily
Roman numeral in parentheses immediately made of carbon and hydrogen atoms, often
after the metal name. In this case, it will give containing oxygen, nitrogen, and other elements.
“Iron (III)” Named based on the number of carbon atoms and
5. Name the Nonmetal: Follow the metal the types of bonds (e.g., CH₄ is methane, C₂H₄ is
name with the name of the nonmetal which ethene).
is “Chloride”
6. Write the name of the compound: Iron (III) QUANTUM CHEMISTRY
chloride
Quantum Chemistry → a branch of chemistry that
B. Covalent (Molecular) Compounds → Formed studies and explains the behavior of subatomic
by the sharing of electrons between nonmetals. particles like electrons and light.

Steps for Naming Covalent Compounds: IV.I ELECTRONIC STRUCTURE OF THE ATOM

Example: SiCl4 Electromagnetic Radiation → has oscillating
electric and magnetic fields in planes perpendicular
1. Name the first element: The first element to each other in the direction of propagation.
is Si thus, silicon.
2. Name the second element by ending the
element name with the suffix “ide”: The
second element is Cl thus it gives chloride.
3. Add prefixes to the atom names to
indicate the number of each atom in the
compound: Silicon is one atom (no prefix)
while chlorine has four atoms which gives
“tetrachloride”
4. Write the name of the compound: Silicon
tetrachloride

C. Polyatomic Ions → Ions made up of multiple Characterization of Electromagnetic Waves
atoms bonded covalently but carrying an overall · Wavelength (𝛌) → distance between
charge. Common polyatomic ions include sulfate two consecutive peaks or troughs; in
(SO₄²⁻) and ammonium (NH₄⁺). Compounds meters (m)
containing these ions are named by combining the · Amplitude → distance from origin to
names of the cation and polyatomic ion (e.g., crest
Na₂SO₄ is sodium sulfate). · Frequency (f) → number of
waves/cycles that pass a point per unit
D. Acids → Compounds that release H⁺ ions in time; in per seconds (s-1) or Hertz (Hz)
solution. · Speed (v) → v = 𝛌f; shows the inverse
relationship of frequency and
a. Binary acids (containing hydrogen and one wavelength
other element) are named with the "hydro-" −8 𝑚
→ speed of light =3 × 10
prefix and "-ic" suffix (e.g., HCl is 𝑠
𝑚
hydrochloric acid). → speed of sound =343 𝑠
b. Oxyacids (containing hydrogen, oxygen,
and another element) are named based on
Max Planck → postulated that light and other
the polyatomic ion; "-ate" becomes "-ic acid"
electromagnetic waves can be quantized and were
and "-ite" becomes "-ous acid" (e.g., H₂SO₄
emitted in terms of discrete packets of energy
is sulfuric acid).
called Quanta
ℎ𝑣
E. Bases → Compounds that release OH⁻ ions in →𝐸 = ℎ𝑓 = λ
; Planck’s Constant (h) = or
solution. Named by stating the metal cation CONST 06 (for Canon F-789SGA)
followed by "hydroxide" (e.g., NaOH is sodium
hydroxide). Rydberg’s Equation → use to quantify the
wavelength when the atom transitions from the
F. Salts → Ionic compounds formed from the
neutralization reaction between an acid and a base.
excited phase to ground phase after exposure to IV.III ELECTRON AS A WAVE
heat/flame.
→
1
= 𝑅𝐻(
1
2 −
1
2 ) ; Rydberg’s Constant (R) = Louis de Broglie → postulated that electrons can
λ 𝑛𝑓 𝑛𝑖
also behave as waves
or CONST 16 (for Canon F-789SGA), and nf and ni →λ=
ℎ
=
ℎ
; m or me is the mass of object
𝑚𝑣
are the final and initial energy levels, respectively 2𝑚𝑒𝑞𝑒𝑉

or electron (CONST 03), v is the velocity, qe is the
charge of the electron (CONST 23) and V is the
voltage
*CONST for Canon F-789SGA

IV.IV QUANTUM NUMBERS

Quantum Mechanical Model → used to
distinguish the probability of finding electrons in 3D
space according to mathematical function

Nodes → regions in space without electron density

Quantum Numbers → address of electrons in an
atom
Quantum Number Definition
Atomic Spectrum of Hydrogen → result of Principal (n = 1, 2, 3 Main energy level or
excitation of the atoms and releasing the excess … 7) the distance of
energy by emitting light of various wavelengths electrons from the
(Hydrogen Spectrum Series) nucleus
Azimuthal (ls = 0, lp = Energy subshells or
Hydrogen Spectrum Series
1, ld = 2, lf = 3 the shape of the
Final Energy Level Series orbitals
(nf)
Magnetic (ml = -l to Number of orbitals in
1 Lyman +l) subshell or the
2 Balmer possible orientation of
3 Paschen orbitals in space
4 Brackett Spin (ms = -½, Movement of
5 Pfund counterclockwise, electrons around its
6 Humphreys downward or ½, own axis
clockwise, upward)
IV.II LIGHT AS A PARTICLE
2
Maximum number of orbitals in shell: 𝑛
Albert Einstein → concluded that when photons
are shone at a metal surface, some electrons can 2
be knocked off in the metal structure Maximum number of electrons in shell: 2𝑛
(Photoelectric Effect)
IV.V ELECTRON CONFIGURATION
Kinetic Energy (KE) → energy that will drive away
electrons from the metal surface Electron Configuration → arrangement of
1 2 electrons in the orbitals of an atom
→ 𝐾𝐸 = 2
𝑚𝑣 ; m is the mass of the electron and
v is the velocity of the electrons

Work Function (𝝓) → minimum energy to remove
electrons from the metal surface
→ ϕ = ℎ𝑓0 ; Planck’s Constant (h) = or CONST
06 (for Canon F-789SGA) and f0 is the minimum or
threshold frequency

Energy of Incident Light (ETotal) →
𝐸𝑇𝑜𝑡𝑎𝑙 = ϕ + 𝐾𝐸
Aufbau Principle → also called the building up 1. Electrostatic
principle; orbitals are filled with electron in Interactions between charged
increasing energy molecules.
2. Induction
Hund’s Rule of Maximum Multiplicity → the most This type of interaction arises when
stable arrangement of electrons in subshells is the there is induction of a dipole in the
one with more parallel spins molecule.
→ in same energy orbital, upward electrons should 3. Dispersion
be filled up first before the downward electrons These are also called London forces
or Van der Waals forces and exist
Pauli’s Exclusion Principle → no two electrons mostly in covalent molecules.
can have the same set of four quantum numbers 4. Hydrogen bonds
an interaction between the Hydrogen
Ground State → lowest energy arrangement of and an electronegative element
electrons in the orbital of an atom where there is no electron exchange
leading to weak bonding between
Excited State → allowed arrangements other than molecules
the ground state
Octet rule and Lewis structure
Valence Electron → electrons with the highest
principal quantum number Lewis Electron Dot Symbols
20th century
Core Electrons → electrons closer to the nucleus Gilbert N. Lewis (1875–1946)
used for predicting the number of bonds
Valence Electron Configuration → all the number formed by most elements in their
of electrons of the highest energy level compounds.
Each Lewis dot symbol consists of the
Isoelectronic → Species with the same electron chemical symbol for an element surrounded
configuration by dots that represent its valence electrons.

Notations of Electron Configuration Octet Rule
1. Condensed → the usual electron states that atoms tend to gain, lose,
configurations or share electrons in order to
2. Expanded → all electrons of every achieve a stable configuration with
subshells are expanded with two eight valence electrons.
electrons each
3. Noble Gas → simplified condensed Octet Rule Exceptions:
electron configuration using the previous
nearest noble gas to the element Expanded octet
- elements that can accommodate
CHEMICAL BONDS more than eight electrons in their
valence shell, such as elements
Chemical bond: from the third period onwards.
The driving force for chemical bonding is to Incomplete octet
attain stable electronic configuration. - elements that have fewer than eight
A chemical bond may be formed either by electrons in their valence shell, such
electron transfer or electron sharing. as hydrogen and helium.
Odd number octet
Types of chemical bonds - elements that have an odd number
1. Ionic Bond of valence electrons, such as
Metal - Nonmetal nitrogen. Therefore, all of these
2. Covalent Bond options deviate from the octet rule.
Nonmetal - Nonmetal
3. Hydrogen Bond Molecular geometry
Hydrogen - Electronegative atom - the three-dimensional arrangement of all the
4. Metallic Bond atoms in a given molecule.
Metal - Metal - Note that the type of bonds – single, double,
or triple – doesn’t influence the geometry of
Types of Interactions: a molecule.
 Butene
Molecular = C4H8
4 Carbon atoms
Steric number - the number of domains attached to 8 Hydrogen atoms
a central atom (atoms and lone pairs)
Empirical = CH2
Polarity 4 C= 1C
- in a bond is caused by electronegativity 8H 2H
differences between the bonded atoms.
- Electronegativity can be found in periodic If the ratio of atoms in the molecular formula can’t
table be simplified any further, the empirical formula
becomes the same as the molecular formula.
Polar (∆EN > 0.5)
Nonpolar (∆EN < 0.5) Percentage Composition - the percent by mass of
each element in a compound
The greater the difference in electronegativity, the
greater the polarity. %𝑚𝑎𝑠𝑠 =
𝑚𝑎𝑠𝑠 𝑜𝑓 𝑒𝑙𝑒𝑚𝑒𝑛𝑡
𝑥 100
𝑚𝑎𝑠𝑠 𝑜𝑓 𝑐𝑜𝑚𝑝𝑜𝑢𝑛𝑑

Intermolecular Forces of Attraction (IMFA) Example: H2O

Mass of compound = 18.02
Molecules Gas Liquid Solid Mass of H2 = 2.02
Mass of O2 = 16
IMFA Weak Strong Very
Strong
2.02
% Hydrogen = 18.02
𝑥100 = 11. 2%
16
Gas molecules have weak IMFAs % Oxygen= 𝑥100 = 88. 8%
18.02
are highly compressible and have low
densities Chemical Reactions - involve the interaction of
chemicals to form new substances
Liquid molecules have stronger IMFAs
are slightly compressible and have high represented by a chemical equation
densities The left side of the equation represents the
reactants; the right side represents the
Solid molecules have very strong IMFAs products.
are almost incompressible and have high Stoichiometric coefficients indicate the
densities relative amounts of reactants and products
in the reaction.
STOICHIOMETRY Compound states are indicated by symbols:
(l) for liquid, (s) for solid, (g) for gas, and
Mole - a mole represents a quantity of a number,
(aq) for an aqueous solution.
the same way a “dozen” does.
1 dozen = 12 Types of Chemical Reactions
23
1 mole = 6.022 𝑥 10 = Avogadro’s Number
1. Combination Reaction - two or more
Molecular and Empirical Formula substances combine to form one product.
General Formula: A + B → AB
Molecular Formula - how many atoms of Patterns for Combination Reactions
each element are in a compound Metal + Nonmetal → Binary Compound
Nonmetal + Oxygen → Nonmetal Oxide
Empirical Formula - the simplest or most Metal + Water → Metal Hydroxide (base)
reduced ratio of atoms in a compound Nonmetal oxide + Water → Oxyacid (acid)
Metal oxide + Nonmetal oxide → salt
2. Decomposition Reaction - a compound is They are not fully consumed because there
decomposed to form two or more substances are more of them than needed to react with
General Formula: AB △→ A + B the limiting reagent.
Patterns for Decomposition Reactions Excess reactants are often left over after the
Hydrates △→ salt + water reaction ends.
IA Bicarbonates △→ Carbonates + H2O (g)
+ CO2 How to Determine the Limiting and Excess
IIA Bicarbonates △→ Metal oxide + H2O (g) Reactant:
+ CO2
Carbonates △→ Metal oxide + CO2 1. Write the Balanced Equation: Ensure the
Chlorates △→ Chlorine + Oxygen chemical equation for the reaction is
Metal oxide △→ Metal + Oxygen balanced.
Water △→ Hydrogen + Oxygen 2. Convert Quantities to Moles: Convert the
masses or volumes of the reactants to
3. Displacement Reaction - more active metal can moles.
displace a less active metal, while a less active 3. Calculate the Mole Ratio: Use the
one can’t displace the more active. balanced equation to find the mole ratio
General form: AY + B → BY + A; where A and B between the reactants.
are metals based on its activity series 4. Compare the Mole Ratio to Determine the
4. Metathesis (Double Displacement Reaction) - Limiting Reactant:
the positive ions exchange partners with the ○ Calculate how much of each
negative ions to form two new compounds. reactant is required based on the
General Form: AY + BX → BY + AX mole ratio.
All neutralization reactions involving acids ○ Identify which reactant runs out first
and bases are actually metathesis by comparing the actual amounts
reactions. available to the required amounts.
Any carbonate, either in the solid state or This reactant is the limiting reactant.
aqueous solution, reacts with acid to form 5. Calculate the Amount of Product
water, carbon dioxide gas, and salt. Formed: Use the amount of the limiting
5. Neutralization Reaction reactant to determine the amount of product
Acid + Base → Salt + Water formed.
Metal oxide + acid → Salt + Water 6. Determine the Excess Reactant: Subtract
Nonmetal oxide + Base → salt + water the amount of the excess reactant that
Ammonia + Acid → Ammonium salt actually reacts from the total amount
available to find how much of it is left over.
Chemical Stoichiometry
SOLUTION
Stoichiometry - used to describe the quantitative
relationships between the reactants and products in A homogeneous mixture consisting of solute and
a chemical reaction. solvent.
Solute Solvent
Present in small Does not change its
amount phase in the formation
Dissolved substance of solution
Dissolving medium
Limiting Reactant
Solubility factors
The reactant that is completely consumed
during a chemical reaction. 1. Nature of Solute and Solvent
It determines the maximum amount of A solute can only be dissolved in a solvent when
product that can be formed. they are alike. A general rule is “like dissolves like”
Once the limiting reagent is used up, the
reaction stops, even if other reactants are 2. Temperature
still available. For solid and liquid: solute increases when
temperature is increased.
Excess Reactant
For a gaseous: solute to a liquid solvent decreases
The reactant(s) that remain after the as temperature increases.
reaction has completed.
3. Pressure Normality
The effect of pressure is only applicable for the
𝑒𝑞𝑢𝑖𝑣𝑎𝑙𝑒𝑛𝑡𝑠 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑒
solubility of gasses in liquids. The higher the 𝑁𝑜𝑟𝑚𝑎𝑙𝑖𝑡𝑦 (𝑁) = 𝐿 𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛
= 𝑛𝑀
pressure of a gas, the more soluble it is.
Equivalents per Mole
Types of solution
1. Unsaturated Solution - solvent can still dissolve 𝑛 ( ) = 𝑛𝑢𝑚𝑏𝑒𝑟 𝑜𝑓 𝐻 , 𝑂𝐻 , 𝑜𝑟 𝑒
𝑒𝑞
𝑚𝑜𝑙
+ − −

the solute

2. Saturated Solution - if a solvent can’t no longer INTRODUCTION TO CHEMICAL EQUILIBRIUM
dissolve a given solute at a given temperature
Chemical Equilibrium → Chemical reactions tend
3. Supersaturated Solution - if the solvent can’t to move towards a dynamic equilibrium in which
dissolve the solute and need to be heated for it to both reactants and products are present but have
be dissolved no further tendency to undergo net change.

Equilibrium Law → Describes the relationship
Solubility rules in Water at 25 deg C
between the concentrations of reactants and
products in a chemical reaction at equilibrium. It is
Insoluble
Soluble Compounds expressed by the equilibrium constant (K)
Compounds
All nitrates, All carbonates, Equilibrium Constant (KC) → Ratio of the
bicarbonates, phosphates, concentration of products to the concentration of
chlorates chromates, the reactants, each raised to their respective
and compounds and sulfides except stoichiometric coefficients.
containing alkali metal that of alkali metal
ions and ammonium ions and ammonium Additionally:
ion. ion.
All halides except that All hydroxides except Kc represents the equilibrium constant
of Ag+, Hg2 2+ and Pb2+ that of alkali metal ions measured in moles per liter (concentration).
𝑐 𝑑
All sulfates except that and Ba++ 𝐾𝑐 =
[𝐶] [𝐷]
𝑎 𝑏
[𝐴] [𝐵]
of Ag+, Ca++, Sr++, Ba++
and Pb++
Kp represents the equilibrium constant
calculated using the partial pressures of
gasses.
Concentrations of Solutions 𝑐 𝑑
[𝑝𝐶] [𝑝𝐷]
𝐾𝑝 = 𝑎 𝑏
[𝑝𝐴] [𝑝𝐵]
Weight/Weight Percent

𝑤 𝑚𝑎𝑠𝑠 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑒 Relationship Between Kc and Kp:
% 𝑤
= 𝑚𝑎𝑠𝑠 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛
×100 𝐾𝑝
𝐾𝑐 = ∆𝑛
(𝑅𝑇)
Weight/Volume Percent

𝑤 𝑚𝑎𝑠𝑠 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑒 (𝑔)
where ∆n = (total moles of gas on the
% 𝑉
= 𝑣𝑜𝑙𝑢𝑚𝑒 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛 (𝐿)
×100 product side) - (total moles of gas on the
reactant side)
Parts per Million (ppm)

μ𝑔 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑒 𝑚𝑔 𝑠𝑜𝑙𝑢𝑡𝑒
Characteristics of Equilibrium Constant
𝑝𝑝𝑚 = 𝑔 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛
= 𝐿 𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛
1. Changes in concentration, pressure,
Parts per Billion (ppm) temperature, or the presence of inert
gasses can shift the equilibrium but do not
𝑛𝑔 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑒 μ𝑔 𝑠𝑜𝑙𝑢𝑡𝑒
𝑝𝑝𝑏 = 𝑔 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛
= 𝐿 𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛 change the equilibrium constant itself.
2. The equilibrium constant is related to the
Molarity
standard free energy change (△G°) by the
𝑚𝑜𝑙 𝑠𝑜𝑙𝑢𝑡𝑒 equation: △G° = -RT ln Kequ.
𝑀𝑜𝑙𝑎𝑟𝑖𝑡𝑦 (𝑀) = 𝐿 𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛 3. The equilibrium constant for the reverse
reaction is the reciprocal of the original
Molality 1
constant, i.e., Krev = 𝐾𝑒𝑞𝑢.
𝑚𝑜𝑙 𝑠𝑜𝑙𝑢𝑡𝑒
𝑀𝑜𝑙𝑎𝑙𝑖𝑡𝑦 (𝑚) = 𝑘𝑔 𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛
 4. If the stoichiometry of the reaction changes, NUCLEAR CHEMISTRY AND NUCLEAR
the equilibrium constant is raised to the ENERGY
power corresponding to the change.
5. For a reaction A + B ⇌ C + D with constant NUCLEAR BINDING ENERGY AND NUCLEAR
K, if the equation is multiplied by 4, the STABILITY
equilibrium constant becomes K4.
6. In stepwise reactions leading to final Nuclear Binding Energy → the energy required to
products, the net equilibrium constant is the separate a nucleus into neutrons and protons,
product of each individual step’s equilibrium which are held with strong nuclear forces
constant, K = K₁ × K₂ × K₃. 2
→ 𝐸 = ∆𝑚𝑐 ; Dm is the mass defect (difference of
7. For reactions with a common product, the the total mass of individual particles in the atom
equilibrium constant remains unchanged, and the actual mass of the atom) and c is the
but higher concentrations of the common speed of light
product can decrease the concentration of
other products. Radioactivity → emission of protons, neutrons,
and electromagnetic waves from the nucleus of an
FACTORS AFFECTING CHEMICAL
unstable atom
EQUILIBRIUM AND ITS RESPONSE

Le Chatelier’s Principle → If a system at Radioactive Decay → process of losing energy
equilibrium is subjected to a change in through light emission of an unstable nucleus
concentration (C), pressure (P), or temperature (T),
the system will adjust itself to counteract the Nuclear Stability → determines whether the atom
disturbance and restore a new equilibrium. will undergo radioactive decay

Summary of Le Chatelier’s Principle: Stable Unstable
Even number of > 84 protons
Change in
Value of protons and neutrons
Change Equilibrium
Factor
to System
Equilibrium Reason
Constant Magic number of Neutron to proton
Position
(Kc) protons and neutrons: ratio > 1
Extra 2, 8, 20, 28, 50 82,
Shifts away
concentration
Increase from No change 126
needs to be
substance
used up
Need to
C
produce more
TYPES OF RADIOACTIVE DECAY
Shifts
of substance
Decrease toward No change
to make up for
substance
what was
Types of Radioactive Decay
removed 4 4
1. Alpha Decay →𝑎2 or 𝐻𝑒2
Shift For gas:
towards side Pressure → emission of alpha particles
Increase with fewer increase = No change
moles of Volume
→ it has a positive charge, very low
gas decrease penetrating power and very high ionizing
P
Shift For gas: power.
towards side Pressure 0 0
Decrease with more decrease = No change 2. Beta Decay → β−1 or 𝑒−1
moles of Volume
gas increase → emission of beta particles
Shifts away Extra heat / → it has a negative charge, intermediate
Increase from heat / energy must Yes
energy be used up
penetrating and ionizing power.
0
More heat / 3. Gamma Emission → γ0
T Shifts energy needs
Decrease
towards to be
Yes
→ it has a no charge, very high
heat / produced to
energy make up for
penetrating power and very low ionizing
the loss power.
Rates of both 0 0
forward and
4. Positron Emission → β+1 or 𝑒+1
Catalyst reverse 0 0
and Inert - No Shift reactions are No change 5. Electron Capture → γ0 and 𝑒−1
Gasses increased by
the same
amount
KINETICS OF DECAY

Half-life (t1/2) → also called as the decay time
→ uses the concept of first-order reaction to
determine the time wherein the sample has lost half
of its content.
First-order Half-life Activity
Reaction
𝑁 𝑙𝑛 2 = 𝑘𝑡 1 𝑎 = 𝑘𝑁
𝑙𝑛 𝑁0
=− 𝑘𝑡
2

→ N is the remaining amount after time t, N0 id the
initial amount, t is the time lapsed and k is the
decay constant

NUCLEAR REACTORS

Nuclear Reactors → contains and control nuclear
fission (splitting apart of atoms) that release energy
in the form of heat

Uranium-235 → a common nuclear fuel which is
capable of producing nuclear reaction and it can
readily undergo fission

Parts of Nuclear Reactor
1. Core → contains the fuel elements and
moderator; it is where the nuclear
reaction occurs
2. Moderator → reduces speed of
neutrons; usually light-water
3. Control Rods → control the rate of
nuclear reaction by adsorbing excess
neutrons; made up of Cadmium and
Boron
4. Steam Generator → a heat exchanger
that is used to produce the steam
PHYSICAL CHEMISTRY pressure exerted by the gasses on the
container can result in an explosion.
GAS LAWS 𝑃1 𝑃2
In equation: 𝑇1
= 𝑇2
, where 𝑃1 and 𝑃2 are the
Ideal Gas Law - also known as the general gas initial and final pressure and 𝑇1 and 𝑇2 are the initial
equation
and final temperature.
Equation of a hypothetical ideal gas which is
a good approximation of the behavior of Combined Gas Law
many gasses under many conditions. The combined gas law is the law which combines
States that the product of the pressure and Charles’s law, Gay-Lussac’s law and Boyle’s law.
the volume of one gram molecule of an
ideal gas is equal to the product of the The simultaneous variations of volume with
absolute temperature of the gas and the temperature and pressure complete the relationship
universal gas constant. In equation: PV = among P, V, and T of any gas.
nRT Formula:

Ideal Gas Law Units Combined Gas Law
−1 −1
When R = 8.314 𝐽 𝑚𝑜𝑙 𝐾 then: P is P = pressure
3 𝑃𝑉 T = temperature in kelvin
in pascals (Pa), V is in 𝑚 , and T is in Kelvin 𝑘 = 𝑇
V = volume
(K)
−1
k = constant (units of energy
When R = 0.08206 𝐿 𝑎𝑡𝑚 𝐾 then: P is divided by temperature)
in atm, V is in L, and T is in Kelvin (K) When two substances are compared in two
different conditions, the law can be stated as:
Boyle’s Law - the pressure of a given mass of gas Pi = initial pressure
is inversely proportional to its volume, provided the Vi = initial volume
𝑃𝑖𝑉𝑖 𝑃𝑓𝑉𝑓
temperature remains constant. = Ti = initial temperature
𝑇𝑖 𝑇𝑓
When a gas is compressed (volume is Pf = final pressure
reduced), its pressure increases, and when Vf= final volume
a gas is expanded (volume is increased), its Tf = final temperature
pressure decreases.
In equation: 𝑃1𝑉1 = 𝑃2𝑉2, where 𝑃1 is the
KINETIC MOLECULAR THEORY
initial pressure exerted by the gas, 𝑉1 is the
initial volume occupied by the gas, 𝑃2 is the Attempts to explain the properties of gases and
gas laws
final pressure exerted by the gas, and 𝑉2 is
the final volume occupied by the gas First proposed by Bernoulli (1738) and extended
by Clausius, Maxwell, Boltzmann, Vander Waals
Charles’ Law - the volume of an ideal gas is and Jeans
directly proportional to the absolute temperature at 1. Gases are composed of minute discrete particles
constant pressure. called molecules.
When a gas is heated, its volume will
expand given that the pressure is held 2. The molecules within a container are believed to
steady, and when the gas is cooled, the be in ceaseless chaotic motion during which they
volume will contract. collide with each other and with the walls of the
𝑉1 𝑉2 container.
In equation: 𝑇1
= 𝑇2
, where 𝑉1 and 𝑉2 are
3. The molecular collisions must involve no energy
the initial and final volumes of the gas and loss due to friction thus all molecular collisions are
𝑇1 and 𝑇2 are initial and final absolute perfectly elastic.
temperatures, measured in Kelvin.
4. The absolute temperature is proportional to their
average kinetic energy.
Gay-Lusaac’s Law - the pressure exerted by a gas
is proportional to the temperature of the gas when 5. The molecules do not exert any force of
the mass is fixed, and the volume is constant. attraction or repulsion on one another except during
When a pressurized aerosol can (such as a collisions.
deodorant can or a spray-paint can) is
heated, the resulting increase in the 6. The volume of the particles is negligible
compared with the total volume of the gas.
Molecular Velocity of Gases Reduced Volume 𝑉𝑟 =
𝑉
𝑉𝑐
Most Probable Velocity
COMPRESSIBILITY FACTOR
2𝑅𝑇
𝑣𝑚𝑝 = 𝑀
Compressibility Factor (Z) → A dimensionless
Average Velocity factor that describes how much a real gas deviates
from ideal behavior. It indicates the ability of a gas
8𝑅𝑇
𝑣 = π𝑀 to be compressed at a certain condition.

Root Mean Square Velocity 𝑃𝑉
𝑍= 𝑅𝑇
(P2-190 Perry’s 9th Ed.)
3𝑅𝑇 𝑉𝑎𝑐𝑡𝑢𝑎𝑙 𝑃𝑉𝑎𝑐𝑡𝑢𝑎𝑙
𝑣𝑟𝑚𝑠 = 𝑀
𝑍= 𝑉𝑖𝑑𝑒𝑎𝑙
= 𝑅𝑇

Collision Properties For ideal gasses, Z=1. Deviations from 1 indicate
the extent to which a real gas deviates from ideal
Number of collisions each gas molecule encounters
behavior due to interactions and finite volume.
per second:
2
2π𝑑 𝑣𝑁𝐴 Z VALUE DOMINATING FAVORS EXAMPLE
𝑠 = 𝑉
FORCES

1 (Ideal) - - -
Mean Free Path
>1 Repulsive Expansion H2
The mean distance traveled by a gas molecule
between two successive collisions. 1 f>P Repulsive Expansion
Critical Constant → Conditions wherein the