Module 1 General Chemistry PDF

Summary

This document is an introductory module on general chemistry. It discusses the different states of matter and phase changes. Also covered are atomic structure, with historical context.

Full Transcript

MODULE 1│CHEM 1

GENERAL CHEMISTRY
I. MATTER Chemical compounds always contain the exact proportion of
element in fixed ratio (by mass)
Mass + Volume Ex. H2O →2H + O, C6H12O6 = CH2O
STATES SOLID LIQUID GAS
Indefinite 3. Law of Multiple Proportion – John Dalton
Shape Definite *non- *assumes Indefinite When 2 elements form more than 1 compounds, it can be
compressible container shape *compressible expressed in a fixed whole number (by mass)
Volume Definite Ex. CO → 28g/mole, CO2 → 44g/mole
Molecular Vibration Gliding *ex. Constant C = 12g/mole
motion *2 stones water falls random O = 16g/mole

Plasma/ Ionized Gas – 4th state; most abundant state of matter. 4. Law of combining weights
Has p+ and e- (thus, greatly affected by magnetic field) Proportions by weight when chemical reaction takes place
Ex. ionized Ne light, Aurora, Stars, Sun can be expressed in small integral unit
IFA Strength most ↑ or strongest: S > L > G > P Ex. MgO → 40g/mole (100%)
Enthalpy (heat/ reaction energy): P > G > L > S Mg = 24g/mole (60%); O = 16g/mole (40%)

A. PHASE CHANGE III. ATOMIC STRUCTURE

1. Democritus – Atomos
Melting
(Solid to Liquid) “Indivisible”
*aka: Fusion, Liquefaction, Thawing
2. John Dalton – Billiard ball
Matter is made up of atoms
Freezing (Liquid to Solid) Postulates:
Elements are composed of indivisible, indestructible
atoms
Evaporation (Liquid to Gas) Atoms alike for a given element (isotopes)
Atoms of different elements differ in size, mass & other
properties (isobars)
Condensation (Gas to Liquid)
Compound are formed form 2 or more atoms at
different elements
Sublimation Atoms combined in simple numerical ratios to form
(Solid to Gas)
*moth/naphthalene balls compounds

Deposition 4. J.J. Thompson – Plum Pudding/ Raisin bread
(Gas to Solid)
*dry ice/ cardice e- in (+) framework

Recombination 5. Ernest Rutherford (discoverer of proton) – Nuclear (Gold foil/ α-
(Plasma to Gas)
*aka: Deionization scattering experiment)
atom is mostly empty; (+) particles in nucleus
Ionization (Gas to Plasma)
6. Neil Bohr – Planetary
mostly used
B. MATTER CLASSIFICATION
7. Erwin Schrodinger – Quantum/ Mechanical/ e- cloud
1. Pure substance
Modern atomic Model; estimates the probability of finding an
Element – simplest form of substance.
e- in certain position (i.e. at e-cloud/ orbital)
Compound – 2 or more chemical united (separated via
chemical means)
Atoms
2. Mixture – 2 or more substance wherein individual substance
Proton – (+) ion
identifies are retained (separated via physical means. Alcohol +
Atomic number (basis of electronic configuration)
Water via distillation)
Ernest Rutherford
Homogeneous – 1 phase; solution *clear colored
Heterogeneous – 2 phases; suspension, colloid *ex. milk
Electrons – (-) ion
p+ in uncharged state
C. CLASSIFICATION BASED ON DEPENDENT TO THE AMOUNT
negligible weight 1,836x lighter that p+
OF MATTER PRESENT
J.J. Thompson
Cathode ray tube: e- m/2 ratio
1. Extrinsic Property “Dependent”
R.A. Millikan
Length, mass/weight, volume, pressure, entropy, enthalpy,
Oil drop experiment: measure accurate charge and
electrical resistance
mass of e-
2. Intrinsic Property “Independent”
Neutrons – no charge
Density/ SpGr (water = 1g/ml or cc), viscosity (resistance to
Atomic mass (Nucleon) = p+ + n0
flow), velocity (m/sec), temperature, color
James Chadwick
II. FUNDAMENTAL CHEMISTRY LAWS
# p+ = Atomic # = 11
# n0 = Atomic mass – p+ = 23-11 = 12
1. Law of Conservation of Mass/ Matter – Antoine Lavoiser
# e- = p+ in uncharged stated: 11-1 = 10
Mass/ Matter is always constant (neither created nor
destroyed)
P
#p = 15
#n = 16
2. Law of Definite/ Constant Proportions – Joseph Proust
#e = 18
(Proust’s law)
Module 1 – General Chemistry Page 1 of 8 RJAV 2022
Find:
Atomic no. = 15
Atomic mass = 15 + 16 = 31
Charge = 15 – 18 = -3

Eugene Gold Stein – discovered anode rays
Electrochemistry – particle separation based on e-
Ex: Capillary electrophoresis – separation of compounds
based on electrophoretic mobility 4A 6A

Electrode: Anode Cathode Ionic bonding
Charge: + electrode - electrode
Undergoes: Oxidation Reduction

RED CAT ELECT IN
REDuction happens in CAThode where ELECTrons get IN
1A
VILEORA
Valence Increase, Loses e-, undergoes Oxidation, Reducing Valence shell electron pair repulsion (VSEPR) theory
agent Predicts the geometry of the molecule as well as any bonded
and unbonded electron pair
VDGEROA
Valence Decrease, Gains e-, undergoes Reduction, Oxidizing Linear (180˚) - CO2
agent (KMnO4-, Na2Cr2O7) Alkynes (Sp)

Isotopes Trigonal planar (120˚) - BF3
same p+/atomic number/ element Alkenes (Sp2)
differ in atomic mass
Non-isotopes: 19F, 127I, 31P, etc.
Main isotopes: +1: 1H, 12C, 14N, 32S, 35Cl ; +2: 16O, 79Br
Isobars
same atomic mass
differ in elements
Isomers Tetrahedral/bent (109.5˚) - CCl4 , H2O
same molecular formula Alkanes (Sp3)
differ in structure

IV. CHEMICAL BONDS * 2 bonded pair, 2 unbonded pair

Molecule – aggregate of 2 or more atoms in definite arrangement
held together by chemical bonds

Ions – with net (+) or (-) charge

Empirical formula – simplest whole number ratio (might be same Trigonal bipyramid - PF5
with MF). Ex: CH2O vs. C6H12O6

A. FORCES OF ATTRACTION

Intermolecular FA/ Van der Waals/ Electrostatic
Between molecule; weak and short-lived
Created by “molecule’s polarizability”; exerted when 2
uncharged atoms (n0) approach very closely Octahedral - SF5

H-bonding Keesom Debye London
orientation Induction Dispersion
(D-D) (D-ID) (ID-ID)
Strongest IFA > > Weakest IFA
H + S, O, N, X Water – Water – Aromatics
(electronegative Water Benzene (Benzene –
atoms) Benzene)
Dipole (D) – Polar Dashed line – away
Induced Dipole (ID) – Nonpolar Wedged line – toward
Trigonal and Octahedral – are exemption to the octet rule
Intramolecular FA
Within molecule
Covalent Ionic Valence bond theory
Sharing of e- Transfer of e- States that bonds are formed by sharing of electron from
overlapping atomic orbitals (covalent)
Nonmetal + Nonmetal Metal + Nonmetal
(Glycosidic & Peptide bond) (NaCl)
Glycosidic – ether bond S─O─S
Peptide bond – amide bond AA─peptide─AA bond

Covalent Bonding
Lone pair
Pair of valence electrons that are not shared with another atom
in covalent bond
s = spherical (sigma bond – stronger bond formed; headways
overlap)
p = dumbbell (pi bond – weaker; sideways overlap)

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Molecular orbital theory B. Multivalent (with variable charges)
States that bonds are formed from interaction of atomic orbitals +1, +2 = Hg, Cu
from molecular orbitals +1, +3 = Au
+2, +3 = Fe, Co, Ni
+3, +5 = Bi, Sb

F. POLYATOMIC IONS

A. O-containing polyatomic anions (Oxyanions)
Oxyanions Salt Oxyacid (Aq)
ClO- Hypochlorite Hypochlorous acid (HClO)
ClO2- Chlorite Chlorous acid (HClO2)
ClO3- Chlorate Chloric acid (HClO3)
ClO4- Perchlorate Perchloric acid (HClO4)
NO2- Nitrite Nitrous acid (HNO2)
NO3- Nitrate Nitric acid (HNO3)
SO32- Sulfite Sulfurous acid (H2SO3)
SO42- Sulfate Sulfuric acid (H2SO4)
PO43- Phosphate Phosphoric acid (H3PO4)
Bonding – lower energy (stable) –ate: common form
Antibonding – higher energy (unstable) –ite: -1 O to –ate form
hypo…ite -1 O to –ite form
B. REACTION TYPES per…ate +1 O to –ate form

Synthesis/ Combination/ Direct Union B. H-containing polyatomic anions
A + B → AB Monohydrogen/ bi: with 1H+ ions
Dihydrogen: with 2H+ ions
Decomposition/ Analysis Anion Salt
AB → A + B HCO3- Bicarbonate (Hydrogen carbonate)
i.e. HSO3- Bisulfite
Complete combustion: HSO4- Bisulfate
CH4 O2 CO2 + H2O HPO4-2 Biphosphate
Incomplete combustion: H2PO4-1 Dihydrogen phosphate
CH4O2 CO + C(5) + H2O
G. MOLE RELATIONSHIPS
Single Displacement
AB + X → AX + B
Avogadro’s #
1 mole = 6.022 x 1023 atoms/ molecules
Double Displacement/ Metathesis/ Exchange 𝑔
AB + CD → AC + BD 𝑀𝑊 =
𝑚𝑜𝑙
i.e.
Neutralization: Ex. Calculate the no. of NaOH atoms using Avogadro’s no. (Mass =
NaOH + HCl → NaCl + H2O 20g, MW = 40/mol)
Precipitation:
AgNO3 + NaCl → AgCl2 + NaNO3 20𝑔 6.022𝑥1023 𝑎𝑡𝑜𝑚𝑠
𝑥
40𝑔/𝑚𝑜𝑙 1 𝑚𝑜𝑙
AgCl2 – white curdy ppt.
Ans = 3.011 x 1023 atoms
C. REACTIVITY SERIES
Molarity/ Formality (M) 3N HCl or 3K HCl
Metals 𝑛 𝑠𝑜𝑙𝑢𝑡𝑒
Li > K > Ba > Ca > Na > Mg > Al > Mn > Zn > Cr > Fe > 𝑀=
Cd > Co > Ni > Sn > Pb > H2 > Cu > Ag > Hg > Pt > Au 𝐿 𝑠𝑜𝑙𝑛
Nonmetals (bases on electronegativity)
Molality (m)
F > Cl > Br > I 𝑛 𝑠𝑜𝑙𝑢𝑡𝑒
Examples: 𝑚=
Co + MgCl2 → NR 𝑘𝑔 𝑠𝑜𝑙𝑣𝑒𝑛𝑡
Zn + CuSO4 → ZnSO4 + Cu
NaBr + Cl2 → NaCl + Br Normality (N)
𝐺𝐸𝑊
𝑁= 𝑜𝑟 𝑀 𝑥 𝑓
D. NOMENCLATURE OF INORGANIC COMPOUNDS 𝐿
Factor (f)
1. Covalent compounds Acid (H): HCl = 1; H2SO4 = 2
CO: Carbon monoxide Base (OH): Al(OH)3 = 3
SiO2: Silicon dioxide Salt (M): Al2O3 = Al: 3x2 = 6; Na2SO4 = 2
N2O: Dinitrogen monoxide
CCl4: Carbon tetrachloride V. ELECTRONIC CONFIGURATION
2. Ionic compounds
Ex: Pb(NO3)4 Aufbau Principle
Classical: Plumbic nitrate Atoms may be built by progressive filling of energy of main
Stock: Lead(IV) nitrate energy sub level (i.e., levels of lower energy levels are
occupied first)
E. MONOATOMIC IONS s=2, p=6, d=10, f=14

A. Monovalent
+1 = Group 1 (H, Li, Na, K ‫ ׀‬Ag)
+2 = Group 2 (Be, Mg, Ca, Sr, Ba ‫ ׀‬Zn, Cd)
-2 = Group 6A (Oxide, Sulfide)
-1 = Group 7A (Fluoride, Chloride, Bromide, Iodide)

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Ex. Calcium = Atomic # 20; Atomic mass 40 Quantum theories
1s2 2s2 2p6 3s6 4s2
[Argon] 4s2 1. Pauli’s exclusion theory
No 2 e- will have same set of quantum number (“exclusive”
Shortcut – Noble gas:
He = 2 2. Heisenberg’s uncertainty theory
Ne = 10 Impossible to predict/ accurately determine the particle’s
Ar = 18 velocity (position & momentum)
Kr = 36
Xe = 54 3. Hund’s rule
Rn = 86 Orbitals are filled up singly before pairing up
Most stable arrangement of e- in subshells is the one with
greatest no. of parallel spins.

VI. GAS LAWS

Boyle's/Mariotte
P₁𝑽₁ = 𝑷₂𝑽₂ 𝑜𝑟 𝑷 ∝ 1𝑣
Temperature (in K)

Charles
𝑻₁ 𝑻₂
= 𝑜𝑟 𝑽 ∝ 𝑻
𝑽₁ 𝑽₂
Pressure (in atm)

Gay-Lussac's
𝑷₁ 𝑷₂
= 𝑜𝑟 𝑷 ∝ 𝑻
𝑻₁ 𝑻₂
Volume (in L)

Combined
𝑷₁𝑽₁ 𝑷₂𝑽₂
A. QUANTUM NUMBERS “fingerprints” =
𝑻₁ 𝑻₂

Principal Quantum Number (n = 1 to 7)
Ideal
main energy level; size of orbital (electron cloud), distance of e-
𝑷𝑽 = 𝒏𝑹𝑻
from nucleus 𝐿.𝑎𝑡𝑚
Ex. O2 = 1s2. 2s2. 2p4 (n=2) R = 0.08205
𝑚𝑜𝑙.𝐾
At STP
Azimuthal/ Angular Momentum (ℓ = 0 to 3) T = 273.15 K
Angular momentum & shape of orbital; subshell P = 1 atm
ℓ = 0 ─ s : sharp (spherical shape) V = 22.4 L
ℓ = 1 ─ p : principle (dumbbell shape)
ℓ = 2 ─ d : diffuse (clover leaf) Avogadro’s
ℓ = 3 ─ f : fundamental Equal volumes of different gases have same no. of moles at
Ex. O2 = ℓ = 1 STP
𝑽₁ 𝑽₂ 𝑽
= 𝑜𝑟 𝑽 ∝ 𝒏 𝑜𝑟 = 𝒌
𝒏₁ 𝒏₂ 𝒏
Magnetic Quantum Number (mℓ = -ℓ, 0, +ℓ)
k = 6.022 X 1023
Orientation of orbital in space
Ex. O2 = mℓ = -1, 0, +1
Dalton’s Law of Partial Pressures
n = 1, ℓ = 0 (s) : mℓ = 0
Total pressure in a mixture (non-interacting gases) is equal to
n = 2, ℓ = 0,1 (s,p) : mℓ = -1,0,+1 [3 degenarate orbitals] = same
energy levels the sum of the partial pressures of each gas. 𝑃𝑡 = 𝑃1 + 𝑃2 + 𝑃3
n = 3, ℓ = 0,1,2 : mℓ = -2,-1,0,+1,+2 [5 DO]
n = 4, ℓ = 0,1,2,3 : mℓ = -3,-2,-1, 0, +1,+2,+3 [7 DO] Graham’s
Rate of effusion (diffusion) and speed gas are inversely
Magnetic Spin (ms = + ½ , - ½ ) proportional to the square root of their density providing the
Magnetic moment/ Rotation temperature and pressure are same for 2 gases
Spin Diffusion – rate at which 2 gases mix
↑ = Incomplete; clockwise + ½ Effusion – rate at which gas escapes through a pinhole
↑↓ = Complete; counterclockwise = - ½ vacuum. Rate 𝑑𝑖𝑓𝑓𝑢𝑠𝑖𝑜𝑛 ∝ 1√𝑑𝑒𝑛𝑠𝑖𝑡𝑦
Ex. Oxygen = ms= + ½
Fick’s 1st Law
Diffusion rate (flux) of liquid or gas is directly proportional to the
concentration gradient (ftom high concentration to low
n ℓ mℓ ms concentration)
1 0=s 0 Henry’s Law of Gas Solubility
𝑷𝒓𝒆𝒔𝒔𝒖𝒓𝒆 ∝ 𝑺𝒐𝒍𝒖𝒃𝒊𝒍𝒊𝒕𝒚
2 0,1 = p -1,0,+1 Decrease temperature, Increase Pressure (i.e., sealed
container), more CO2 is dissolved in water.
3 0,1,2 = d -2,-1,0,+1,+2 Real/Van der Waals
𝒂𝒏𝟐
4 0,1,2,3 = f -3,-2,-1, 0, +1,+2,+3 (𝑷 + ) (𝑽 − 𝒏𝒃) = 𝒏𝑹𝒕
𝒗𝟐
an2 = internal pressure per mole
nb = incompressibility

Raoult’s
𝑷𝒔𝒐𝒍𝒖𝒕𝒊𝒐𝒏 = 𝑿𝒔𝒐𝒍𝒗𝒆𝒏𝒕 𝑷𝒔𝒐𝒍𝒗𝒆𝒏𝒕
Magnetism types: X = mole fraction
o Diagmagnetism – no unpaired e- Temperature
o Paramagnetism – at least 1 unpaired e-
Module 1 – General Chemistry Page 4 of 8 RJAV 2022
 A. TEMPERATURE Entropy (∆S) = measure of system’s thermal energy per unit
temperature; degree of disorderliness or randomness
°C = (°F – 32) / 1.8 ∆S = (+) → spontaneous; increase (irreversible) – real case
°F = (°C x 1.8) + 32 ∆S = (-) → non spontaneous; constant (reversible) – ideal case (in a
K = °C + 273.15 steady state/ equilibrium)
Absolute temperature ∆H → does not predict spontaneity
0K = absolute zero (lowest possible temperature)
3RD LAW:
VII. SOLUTION If an object reaches absolute zero temperature (0 K = -273.15 =
-459.67 °)
Solute + Solvent Entropy of perfect, solid, crystalline substance is zero at
Colligative properties (See Physical Pharmacy) absolute 0 temperature
Dependent on the amount of solute present in the solution Gibb’s free energy (∆G)
Vapor pressure lowering Thermodynamic state function that combines enthalpy and
Boiling point elevation (Ebullition) entropy
Freezing point depression ∆G = ∆H ‒ T∆S
Osmotic pressure (Π) ∆G < 0 (-) → spontaneous
∆G > 0 (+) → non spontaneous
Vapor Pressure Lowering ∆G = 0 → equilibrium (no more work to be done)
Raoult's Law : vapor pressure of a solution is dependent IX. CHEMICAL KINETICS
on the amount of nonvolatile solute added to solution

Boiling Point Elevation ∆Tb = 𝑖𝐾𝑏𝑚 Study of reaction rates and reaction mechanism

Freezing Point Depression ∆Tf = 𝑖𝐾𝑓𝑚 Reaction Rate (M/s)
Change in concentration of a reactant or product concentration
Osmotic Pressure (Π) Π=
𝑖𝑛𝑅𝑇 with time
- pressure needed to stop osmosis 𝑉
aA + bB → cC + dD
*small letters: coefficient that balance the chemical reaction
1 ∆[A] 1 ∆[B] 1 ∆[C] 1 ∆[D]
VIII. THERMODYNAMICS 𝑅𝑎𝑡𝑒 = − =− = =
𝑎 ∆t 𝑏 ∆t 𝑐 ∆t 𝑑 ∆t
Study of energy conversion/ transformation in the universe
Rate Law
Expresses relationship of the rate of reaction to the rate
A. PARTS OF THE UNIVERSE
constant (K) and concentration of reactants raised to some
power
A. System
aA + bB → cC + dD
Rate = K [A]x [B]y (xy=order of reaction)
Open System - allows exchange of energy and matter
Where x & y = order of reaction (0th, 1st, or 2nd)
Closed System - allows exchange of energy but not matter\
Isolated System "Adiabatic Walls" - does not allow exchange
A. REACTION RATE THEORIES
of both energy and matter
1. Collision Theory
B. Surrounding – everything outside the system
rate of chemical reaction is proportional to the number of
collisions per time
B. PATH DEPENDENCE
Requirements for effective collision:
Proper orientation
State Function
Activation energy (Ea) – minimum amount of energy required to
Independent (depends only on initial & final states of system)
initiate chemical reaction
Ex. Enthalpy (H), Internal energy (U), Gibb’s Free Energy (G),
Entropy (S)
2. Transition Theory
(Formation of Intermediate Complex) - rate depends on Ea
Non-State Function
required to form intermediate state (where new bonds are
Dependent
formed and old bonds are broken)
Work and Heat
B. FACTORS AFFECTING REACTION RATE (Directly
Zeroth Law
proportional)
If two systems are in thermal equilibrium respectively with a
third system, they must be in thermal equilibrium with each
Nature of Reactants
other
= ↑ reactivity ↑ reaction rate (faster)
a=c
b=c
Concentration of Reactants (except Zero order)
a=b
= ↑ concentration ↑ reaction rate
C. LAWS OF THERMODYNAMICS
Catalyst (Enzyme – Michaelis Menten Kinetics)
= ↑ reaction rate
1ST LAW: Law of conservation of Energy
Enzymes – speeds up the chemical reaction by lowering Ea
Energy is neither created nor destroyed but can be transformed
from one form to another
Surface Area
Enthalpy (H) = U, P, V
= ↑ SA ↓ particle size ↑ reaction rate ↓ reaction time
Hess' Law: ∆H is independent of reaction/steps that occurred (only
the initial and final steps is the basis)
Temperature
q = Heat
= ↑ Temp ↑ KE ↑ mobility of molecules ↑ collision ↑ reaction rate;
∆H = (+) → heat is absorbed; COLD (endothermic)
Arrhenius Equation (T, Ea, RR)
∆H = (-) → heat is released; HOT (exothermic)
X. CHEMICAL EQUILIBRIUM
2ND LAW: Law of Entropy
No way but UP
aA + bB ⇌ cC + dD
For an isolated system, Total entropy can never decrease over
time

Module 1 – General Chemistry Page 5 of 8 RJAV 2022
 A. LAW OF MASS ACTION Acids & Bases Hard Soft
Ionic radius Small Large
reaction rate proportional to the product of the concentrate of Oxidation states High Low
the reactants to the power of its coefficient in a balanced Polarizability Low High
equation Electronegativity High Low
𝐶 𝑐 𝐷𝑑 Ex. Ions of alkali & Heavy metals:
𝐾𝑒𝑞 = 𝑎 𝑏
𝐴 𝐵 alkaline earth Ag+, Au+, Hg22+/
Keq = 1: No shift (in equilibrium) metals, H+, NH4, Hg2+, Cd2+
Keq > 1: Favors product formation (to the right/ forward reaction) Ti4+, Cr3+
Keq < 1: Favors reactant formation (to the left/ backward or reverse
reaction) OH-, F-, Cl-, CO32-, H- (Hydride), I-,
CH3COO- SCN-
Le Chatelier’s Principle (# stress reliever)
If an external stress is applied to a system at equilibrium, the A. ACID-BASE FORMULA
system adjusts in such a way that stress is partially offset as
the system reaches new equilibrium Acids & Bases General Ionic equilibria
formula For Weak Acids & Bases (with
External Stressors: Equilibrium Change constant)
shift Equilibrium pH = -log[H+] pKa = -log[ka]
constant (Kc) - 25°C pOH = -log[OH-] pKb = -log[kb]
Concentration Yes No pH + pOH = 14 pKa + pKb = 14
Pressure & Volume Kw = [H+][OH-] = 1x10-14 Kw = Ka x Kb = 1x10-14
(For Gases only) *pKa is constant, while pH varies
[]–M
↑ P = shift to side
with lesser gas Yes No Ionic equilibria
moles Ex. HA (aq) + H2O (I) ↔ H2O H3O+ (aq) + A- (aq)
↓ V = shift to side [𝐻 +][𝐴−]
with greater gas 𝐾𝑎 =
[𝐻𝐴]
moles
Conjugate Base = -1H+ to subs in question
Temperature
Conjugate Acid = +1H+ to subs in question
Yes Yes
↑ T, Endo: Right
In writing Equilibrium constants:
↑ T, Exo: Left
- Aq. & gaseous reacting spp. (constant: S & L)
Catalyst No No
- Unit should be in M
XI. ACIDS AND BASES Common ion effect
Acids Bases Addition of compound having an ion in common with the dissolved
Taste Sour Bitter substance will result to:
pH 7 Equilibrium shift (either to the left or right)
+ Litmus paper Red Blue Suppressed ionization of the dissolved substance (WA or WB)
+ Metals → H2 gas (corrode pH change
-
metals)
+ Carbonates/ → CO2 gas Ex. CH3COOH – CH3COONa Mixture
-
Bicarbonates (effervescence) CH3COONa (s) → Na+ (aq) + CH3COO- (aq) - ↑ pH
+ Fat → Soap: Slippery CH3COOH (aq) ↔ H+ (aq) + CH3COO- (aq) - suppressed
(Saponification) ionization
- Henderson-Hasselbalch/ Buffer pair equation
Ex. Manuf
NaOH – Hard soap
KOH – Soft soap For buffer solutions (WA + CB or WB + CA)
HAc + Ac-
Theories Acid Base NH3 + NH4+
Arrhenius Liberates H+ Liberates OH- 𝑠𝑎𝑙𝑡
Bronsted-Lowry Donates p+ Accepts p+ Weak acids 𝑝𝐻 = 𝑝𝐾𝑎 + 𝑙𝑜𝑔
𝑎𝑐𝑖𝑑
Lewis e- pair acceptor e- pair donor 𝑏𝑎𝑠𝑒
Weak bases 𝑝𝐻 = 𝑝𝐾𝑏 + 𝑙𝑜𝑔
𝑠𝑎𝑙𝑡
Lewis Theory: *pH = pKa (@ half neutralization point)
Lewis’s acid/ Electrophile
e- loving Buffer Solution
(+) iron or metal (e- poor spp.) has the ability to resist changes in pH upon addition of small
amounts of either acid or base
Lewis’s base/ Nucleophile Weak acid and its CB (salt of WA)
(-) ion or nonmetal (e- rich spp.) Weak base and its CA (salt of WB)
Lewis’s acid (+) Lewis’s base (-) Van slyke
Ni + CO Ni CO Buffer capacity Bmax (degree or magnitude of capability to resist
Cl- + SnCl4 SnCl4 Cl- change in pH of the buffer)

Pearson's Hard and Soft Acid and Base (HSAB) XII. SOLUBILITY PRODUCT CONSTANT (Ksp)

Hard-Hard/ Soft-Soft ↑ Ksp = ↑ solubility
Thermodynamically Stronger interaction
Hard Acid + Hard Base → Ionic complexes Solubility (g/L)
Soft Acid + Soft Base → Covalent complex Number of grams of solute dissolved in in 1L of saturated
solution
Hard-Soft/ Soft-Hard
Thermodynamically Weaker interaction Molar solubility (mol/L)
Number of moles of solute dissolved in 1L of saturated solution
Module 1 – General Chemistry Page 6 of 8 RJAV 2022
Predicting formation of precipitate formation (Q ion product constant)
– computed based on initial concentration:
Q < Ksp → unsaturated
Q = Ksp → saturated
Q > Ksp → supersaturated ↓↓

Noyes Whitney equation
Dissolution rate is directly proportional to the solute surface
area, solute concentration at boundary layer, and diffusion
coefficient

XIII. ELECTROCHEMISTRY

study of the production of electricity from energy released
during spontaneous and nonspontaneous chemical reactions
1. Spontaneous
Voltaic cells/ galvanic cells Johan Wolfgang Dobereiner
REDOX reaction (Anode - Oxidation; Cathode – Reduction) "Law of Triads"
Electrons migrate from Anode → Cathode
John Newlands
2. Nonspontaneous "Law of Octaves"
Electrolytic cells: Electric current is applied to remove e- and Periods
transfer to another cell (Electroplating) Dmitri Mendeleev
"Father of Modern Periodic Table"
XIV. PERIODIC TABLE (Lothar Meyer) Atomic Mass/ Weight
Antoine Lavoisier Henry Moseley
first extensive list of elements (~ 33) "Created Modern Periodic Table"
Metals vs Nonmetals property varies with increasing atomic number
Metal Nonmetal Glenn Seaborg
Oxides Basic Acidic Discovered transuranic elements. > Uranium Actinides below
Good Reducing agent Oxidizing agents
lanthanides (exhibit radioactivity; unstable proton-to-neutron
Conductor ✓ x ratio)
Malleable ✓ Brittle
Ductile ✓ x Law of Octaves
Metallic luster ✓ X (except I2) Every 8th element similar physicochemical property when
State at RT Solid (except Hg) Solid, liquid, gas arranged according to increasing Atomic weight (Ex. H, F, Cl)

Octet rule
Hg – only liquid metal Elements (Atomic nos. 1-20) with < 8 electron “react” to
Amphoteric – can act as acid or base achieve 8 electrons (stable)
Malleable – ability to be pounced into thin sheets
Ductile – ability to be drawn into wires Valence e- – electron found in outermost shell

A. PERIODIC TABLE Group A Valence Valence/ Elements (together
e- charge with other
Elements: 118 valences, if any)
Periods (Horizontal rows): 7 1A (Alkali M) 1 +1 H, Li, Na, K, Rb, Cs,
Groups/ Family (Vertical columns): 18 Fr, NH4
Groups A: Representative elements (s & p block) 2A (Alkaline Earth M) 2 +2 Be, Mg, Ca, Sr, Ba,
Ra
Groups B: Transition elements (d block)
3A (Boron G.) 3 +3 B, Al, Ga, In, Tl
Actinides & Lanthanides: Inner transition elements (f block) 4A (Carbon G.) 4 (+/- 4) C, Si │Ge, Sn, Pb (+2,
+4)

B. PERIODIC TRENDS 5A (Nitrogen G.) 5 -3 N, P │As, Sb, Bi (+3,
+5)

Ionization energy 6A (Oxygen G./ 6 -2 O, S, Se, Te, Po
energy needed to remove outermost electron in neutral atom Chalcogens)
→↑ 7A (Halogens) 7 -1 F, Cl, Br, I, At
8A/ 0 (Inert/ Noble/ 8 0 He, Ne, Ar, Kr, Xe,
Stable Gases Rn
Electron affinity
energy given off when neutral atom gains extra electron
Group B Valence Elements
(making it more negative) →↑
1B (Coinage M.) +1 Cu (+2), Ag, Au (+3)
2B (Volatile M.) +2 Zn, Cd, Hg & Hg2
Electronegativity
3B (Scandium Subgrp) - Sc, Y, Lanthanides (La-Lu),
ability of an atom to attract electron pair to itself, forming Actinides (Ac-Ir)
covalent bond. →↑ 4B (Titanium Subgrp) - Ti, Zr, Hf
F: most electronegative (most reactive Oxidizing agent) 5B (Vanadium Subgrp) - V, Nb, Ta
O2: 2nd most electronegative 6B (Chromium Subgrp) - Cr, Mo, W
Note: Decrease – Top to Bottom; Increase – Left to Right 7B (Manganese - Mn, Tc, Re, Bh
Subgrp)
Atomic radius 8B (Iron Triad) - 1st Triad: Fe, Co, Ni (+2, +3)
½ difference between nucleus of 2 atoms ↓← 2nd Triad (Light): Rh, Ru, Pd
3rd Triad (Heavy): Os, Ir, Pt
Metallic property
New Elements
Note: Increase – Top to Bottom; Decrease – Left to Right Nihonium 113Nh

Atomic radius/ Metallic property Moscovium 115Mc
Tennessine 117Ts
Oganesson 118Og

Module 1 – General Chemistry Page 7 of 8 RJAV 2022
 XV. RADIOACTIVITY

Spontaneous emission of particles/ ionizing radiation by
unstable nuclei of heavier elements (p+-to-n0 ratio) (atomic # 92
and above: transuranic elements)

Non-SI: Curie (Ci) │1 Ci = 3.7 x 1010 decay/ sec
Discovered: Po & Ra

SI: Becquerel (Bq) │1 Bq = 1 decay/ sec

R.E.M. (roentgen equivalent in man)
Unit of radiation damage
Rad/ gray
Unit of amount of exposure to radiation

Radioactive Emissions
Radioisotopes decay RANDOMLY
Beta & Gamma can penetrate body tissue

Rays/ Mass Velocity Penetrating Prevented
Decay power by
Alpha Heaviest Slowest Low Paper
(4) (0.1 speed of
light)
Beta Light Fast Medium Al
(1/2000) (0.9 speed of
light)
Gamma No mass Fastest High Pb
& charge (speed of light)
0

A. MODES OF DECAY

Alpha (α) decay is the emission of α particle from the nucleus. For
example, polonium-210 undergoes α decay:

210 4 206 210 4 206
Po⟶ He + Pb or Po ⟶ α + Pb
84 2 82 84 2 82

Beta (β) decay is the emission of an electron from a nucleus. Iodine-
131 is an example of a nuclide that undergoes β decay:

131 0 131 131 0 131
I⟶ e + Xe or I ⟶ β + Xe
53 -1 54 53 -1 54

Gamma emission (γ emission) is observed when a nuclide is formed
in an excited state and then decays to its ground state with the
emission of a γ ray, a quantum of high-energy electromagnetic
radiation. The presence of a nucleus in an excited state is often
indicated by an asterisk (*). Cobalt-60 emits γ radiation and is used
in many applications including cancer treatment:

60 0 60
Co* ⟶ γ + Xe
27 0 27

Positron emission (β+ decay) is the emission of a positron from the
nucleus. Oxygen-15 is an example of a nuclide that undergoes
positron emission:

15 0 15 15 4 15
O⟶ e + N or O ⟶ β + N
8 +1 7 8 +1 7

Electron capture occurs when one of the inner electrons in an atom
is captured by the atom’s nucleus. For example, potassium-40
undergoes electron capture:

40 0 40
K + e ⟶ Xe
19 -1 18

Module 1 – General Chemistry Page 8 of 8 RJAV 2022