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| Exam/Board Specific | IGCSE Chemistry Notes Free Download, O-Level Chemistry A* Revision, AQA GCSE Chemistry Grade 9 Notes, Edexcel iGCSE Chemistry 2026 Syllabus, Cambridge 0620/5070 Study Guide |
| Challenging Topics | How to calculate Moles simply, Organic Chemistry Isomers explained, Easy Redox Half-Equations, Electrolysis Discharge Rules, Chemical Energetics Diagrams |
| Resource Quality | Best Chemistry Lecture Notes PDF, Humanized Chemistry Revision, Ultra-Premium IGCSE Chemistry Study Material, Chemistry Notes for Top Position |
🎯 SECTION 1: THE FOUNDATIONAL ABSOLUTES (ATOMS, BONDS, & PERIODICITY)
Mastering the atom is the first step to mastering the exam. These topics are the bedrock of the entire syllabus.
1.1 Atomic Structure & The Elements (The Unseen World)
Most Searched Question: “What is the difference between an Isotope and an Ion, and how do I calculate Relative Atomic Mass ($A_r$)?”
An Atom consists of the nucleus (Protons and Neutrons) and orbiting Electrons. The Proton Number (Atomic Number) defines the element’s identity.
Isotopes are atoms of the same element (same Proton Number) with different Neutron counts (different Mass/Nucleon Numbers). They have identical chemical properties but different physical properties.
An Ion is an atom that has gained or lost electrons, acquiring a net electrical charge (e.g., $\text{Na}^+$ or $\text{Cl}^-$).
Calculating $A_r$: This is a crucial calculation, often missed. $A_r$ is the weighted average mass of all naturally occurring isotopes of an element. Our notes simplify the required formula:
| Resource Name | Core Keywords (Download Link) | Download Link (FREE PDF) |
| Atoms, Elements and Compounds | Atomic Structure, $\text{A}_r$ Calculation, Isotopes, Protons, Neutrons, Electrons | Download PDF: Atoms, Elements and Compounds |
1.2 Chemical Bonding: Structure Predicts Property
Most Searched Question: “Why does Graphite conduct electricity when it is a covalent substance? (The Major Exception)”
Bonding determines everything from a substance’s melting point to its conductivity. Our notes use clear structural comparisons:
Ionic Bonding (Metal + Non-Metal): Electrostatic attraction in a Giant Ionic Lattice. Results in high MP/BP and conductivity only when molten or aqueous.
Covalent Bonding (Non-Metal + Non-Metal): Electron Sharing.
Simple Molecular: Weak intermolecular forces (low MP/BP).
Giant Molecular: Strong covalent bonds throughout (e.g., Diamond, Silicon Dioxide) $\rightarrow$ extremely high MP/BP, very hard.
The Graphite Exception: Each carbon atom is bonded to three others in layers. The remaining valence electron is delocalized between the layers, making it a rare conductive covalent substance.
| Resource Name | Core Keywords (Download Link) | Download Link (FREE PDF) |
| Chemical Bonding | Ionic Lattice, Covalent Sharing, Metallic Sea, Giant Molecular, Graphite Conductivity, Dot-and-Cross | Download PDF: Chemical Bonding |
1.3 The Periodic Table: Predicting Chemical Behavior
Most Searched Question: “Explain the reactivity trends for Group 1 (Alkali Metals) and Group 7 (Halogens) for my IGCSE exam.”
The Periodic Table is organized by increasing Proton Number. Trends are based on atomic size and electron shells.
| Group | Trend in Reactivity | Explanation (Why?) |
| Group 1 (Metals) | Increases down the group | Outer electron is further from the nucleus, shielded by more shells, making it easier to lose (Ionization Energy decreases). |
| Group 7 (Non-Metals) | Decreases down the group | Outer shell is further away, making it harder to attract an incoming electron to complete the shell. |
| Group 0 (Noble Gases) | Inert | Full outer electron shell ($\text{s}^2\text{p}^6$), meaning they do not need to react. |
| Resource Name | Core Keywords (Download Link) | Download Link (FREE PDF) |
| The Periodic Table | Group Trends, Periodicity, Alkali Metals, Halogens, Noble Gases, Transition Metals Properties | Download PDF: The Periodic Table |
🔬 SECTION 2: THE CALCULATION CORE (MOLES, FORMULAE, ENERGETICS)
This section is where most marks are gained and lost. Our notes offer clear, calculation-focused strategies.
2.1 The Moles Concept & Stoichiometry (The Quantitative Leap)
Most Searched Question: “What is the easiest method to solve limiting reactant problems in IGCSE Chemistry?”
The Mole is the bridge between mass and the number of particles. Mastering Moles means mastering three core mole-to-quantity conversions:
Mass $\rightleftharpoons$ Moles: Use $M_r$ (Relative Formula Mass).
Volume $\rightleftharpoons$ Moles (Gases): Use $24 \text{ dm}^3$ at r.t.p.
Concentration $\rightleftharpoons$ Moles (Solutions): Use Concentration ($\text{mol}/\text{dm}^3$) and Volume ($\text{dm}^3$).
Limiting Reactant Simplification: To find the limiting reactant, simply calculate the moles of both reactants. Then, use the mole ratio from the balanced equation to see which reactant is used up first. The one used up first is the Limiting Reactant, and it dictates the maximum amount of product ($\rightarrow$ Theoretical Yield).
| Resource Name | Core Keywords (Download Link) | Download Link (FREE PDF) |
| Moles | Stoichiometry, Molar Mass, Avogadro, Limiting Reactant, Percentage Yield, Concentration, Titration Calculation | Download PDF: Moles |
2.2 Formulae and Balancing Equations
Most Searched Question: “Step-by-step guide to calculating Empirical and Molecular Formulae from percentage composition.”
This is a two-part calculation.
Empirical Formula (E.F.): The simplest ratio of atoms. Use the P-M-M-R method (Percentage $\rightarrow$ Mass $\rightarrow$ Moles $\rightarrow$ Ratio) to find this.
Molecular Formula (M.F.): The actual formula. $\text{M.F.} = (\text{E.F.})_n$, where $n = \frac{\text{Relative Molecular Mass}}{\text{Empirical Formula Mass}}$.
Balancing chemical equations is essential for Stoichiometry. Always balance $\text{C}$, then $\text{H}$, then $\text{O}$, and finally any other elements.
| Resource Name | Core Keywords (Download Link) | Download Link (FREE PDF) |
| Formula | Valency Rules, Naming Compounds, Writing Formulae | Download PDF: Formula |
| Formulae | Empirical Formula, Molecular Formula, Percentage Composition, Balancing Equations | Download PDF: Formulae |
2.3 Chemical Energetics and Reaction Rates
Most Searched Question: “How do catalysts work, and how does temperature affect the rate of reaction based on Collision Theory?”
Energetics focuses on $\Delta\text{H}$: Exothermic ($\Delta\text{H} < 0$, energy released) and Endothermic ($\Delta\text{H} > 0$, energy absorbed).
Rates of Reaction are explained by Collision Theory: molecules must collide with the correct orientation and energy ($\ge$ Activation Energy, $\text{E}_a$).
Temperature: Increasing temperature increases kinetic energy, causing more frequent collisions, and a much larger proportion of collisions to meet the $\text{E}_a$ requirement.
Catalysts: Provide an alternative reaction pathway with a lower $\text{E}_a$, allowing more successful collisions without increasing temperature.
| Resource Name | Core Keywords (Download Link) | Download Link (FREE PDF) |
| Chemical Energetics | Activation Energy, $\Delta\text{H}$, Energy Profile Diagram, Bond Energy, Exothermic/Endothermic | Download PDF: Chemical Energetics |
| Reactions | Rates of Reaction, Collision Theory, Catalyst Function, Surface Area, Concentration Effects | Download PDF: Reactions |
⚡ SECTION 3: THE A* SPECIALIST TOPICS (REDOX, ELECTROLYSIS, ORGANIC)
These topics demand application and synthesis of knowledge. Use these specialized notes to leap ahead of the competition.
3.1 Redox and Electrolysis (The Electron Transfer)
Most Searched Question: “What is the simplest way to write half-equations for reduction and oxidation at the electrodes?”
Redox is unified by the $\text{OIL RIG}$ rule: Oxidation Is Loss (of $\text{e}^-$); Reduction Is Gain (of $\text{e}^-$).
Electrolysis uses electricity to force this transfer. The challenge is product prediction:
Cathode (Reduction): Cations are reduced. If metal is below $\text{H}$ in the Reactivity Series, the metal ion is discharged. If the metal is above $\text{H}$, the $\text{H}^+$ ion is discharged ($\rightarrow \text{H}_2$ gas).
Anode (Oxidation): Anions are oxidized. If halide ions ($\text{Cl}^-$, $\text{Br}^-$, $\text{I}^-$) are present in high concentration, they are discharged. Otherwise, the $\text{OH}^-$ ion is discharged ($\rightarrow \text{O}_2$ gas).
Half-Equation Strategy:
Write the ion/molecule.
Write the product.
Balance atoms (except $\text{O}$ and $\text{H}$).
Balance charge using $\text{e}^-$ (electrons).
| Resource Name | Core Keywords (Download Link) | Download Link (FREE PDF) |
| Redox | Oxidation States, $\text{OIL RIG}$, Oxidizing Agent, Reducing Agent, Half-Equations Mastery | Download PDF: Redox |
| Electrolysis | Selective Discharge Rules, Anode/Cathode, Molten vs. Aqueous, Electroplating, Aluminum Extraction | Download PDF: Electrolysis |
3.2 Organic Chemistry (The $\text{C}$ Compounds)
Most Searched Question: “How to name Alkanes, Alkenes, Alcohols, and Carboxylic Acids correctly for IGCSE/O-Level?”
Organic Chemistry is systematic. Master the functional groups and naming conventions.
| Homologous Series | Functional Group | Suffix/Key Feature | Diagnostic Test |
| Alkanes (Saturated) | Single $\text{C-C}$ bonds | -ane | No reaction with Bromine water. |
| Alkenes (Unsaturated) | $\text{C}=\text{C}$ double bond | -ene | Turns Bromine water colorless (Addition Reaction). |
| Alcohols | Hydroxyl group ($\text{-OH}$) | -ol | Burns cleanly, can be oxidized to Carboxylic Acids. |
| Carboxylic Acids | Carboxyl group ($\text{-COOH}$) | -oic acid | Weak acid (reacts with $\text{Na}_2\text{CO}_3$ to produce $\text{CO}_2$). |
Polymerization: Understand that monomers (small units, e.g., ethene) join together in addition polymerization to form large polymers (e.g., poly(ethene)). This is a key applied topic.
| Resource Name | Core Keywords (Download Link) | Download Link (FREE PDF) |
| Organic Chemistry (Part 1) | Alkanes, Alkenes, Combustion, Cracking, Isomers, Naming Conventions | Download PDF: Organic Chemistry Part 1 |
| Organic Chem (Part 2) | Alcohols, Carboxylic Acids, Esters, Polymerization, Ethanol Production (Fermentation) | Download PDF: Organic Chem Part 2 |
🛠️ SECTION 4: PRACTICAL AND APPLIED CHEMISTRY
Practical skills and real-world application are often tested in papers 3, 4, and 6.
4.1 Acids, Bases and Salts (The Preparation Strategy)
Most Searched Question: “Explain the Titration method for preparing a soluble salt (e.g., $\text{NaCl}$) accurately.”
The Titration method is used when both the acid and base (alkali) are soluble, to ensure the final product is pure and dry.
Titration Steps:
Use a pipette to measure a fixed volume of alkali into a conical flask.
Add a few drops of indicator (e.g., methyl orange).
Add acid dropwise from the burette until the endpoint is reached (color change).
Repeat the titration without the indicator (this is the key!), using the recorded volumes to prepare the pure salt.
Gently evaporate the water and crystallize the salt.
| Resource Name | Core Keywords (Download Link) | Download Link (FREE PDF) |
| Acids, Bases and Salts | $\text{pH}$ scale, Neutralization, Titration Method, Salt Preparation (3 Methods), Alkali vs. Base | Download PDF: Acids, Bases and Salts |
4.2 Experimental Techniques and States of Matter
Most Searched Question: “What is the difference between Simple and Fractional Distillation, and when should I use each?”
Simple Distillation: Separates a solvent (liquid) from a non-volatile solute (e.g., salt from water). The difference in boiling points must be large.
Fractional Distillation: Separates two or more miscible liquids with close boiling points (e.g., ethanol/water or components of crude oil) using a fractionating column.
Purity Check: A pure substance melts sharply at a fixed temperature (e.g., water at $0^\circ\text{C}$). Impurities cause the substance to melt over a range of temperatures and at a lower melting point ($\rightarrow$ melting point depression).
| Resource Name | Core Keywords (Download Link) | Download Link (FREE PDF) |
| Experimental Techniques | Filtration, Crystallisation, Distillation (Simple/Fractional), Chromatography, Purity Tests (MP/BP) | Download PDF: Experimental Techniques |
| States of Matter (Part 1 & 2) | Kinetic Particle Theory, Diffusion Rate, Brownian Motion, Latent Heat, Changes of State | Download PDF: States of Matter Part 1 |
| Download PDF: States of Matter Part 2 |
🌍 SECTION 5: THE APPLIED WORLD (METALS AND ENVIRONMENT)
Applying Chemistry to industry and the environment is a frequent source of long-answer questions.
5.1 Metals (Extraction and Corrosion)
Most Searched Question: “Why must Aluminum be extracted by Electrolysis, but Iron can be extracted using Carbon?”
The extraction method is dictated by the Reactivity Series (See Section 1.3).
Aluminum is high on the series ($\text{Al}^{3+}$) and forms stable compounds. It cannot be reduced by carbon, so the very expensive method of Electrolysis (using molten cryolite) must be used.
Iron is lower and can be reduced by the cheaper method of heating its oxide ore with Carbon (or Carbon Monoxide) in a blast furnace.
Corrosion (Rusting): Iron requires both Oxygen and Water to rust. Sacrificial Protection (e.g., attaching a more reactive metal like Zinc) is the best method, as the more reactive metal sacrifices itself by reacting instead of the iron.
| Resource Name | Core Keywords (Download Link) | Download Link (FREE PDF) |
| Metals (Part 1) | Reactivity Series, Extraction Methods, Displacement Reactions, Alloys | Download PDF: Metals Part 1 |
| Metals (Part 2) | Rusting Conditions and Prevention, Blast Furnace Chemistry, Sacrificial Protection | Download PDF: Metals Part 2 |
5.2 Atmosphere and Water Quality
Most Searched Question: “What are the main causes and effects of Acid Rain in IGCSE/O-Level Chemistry?”
Acid Rain is primarily caused by two pollutants:
Sulfur Dioxide ($\text{SO}_2$): From burning fossil fuels containing sulfur impurities.
Nitrogen Oxides ($\text{NO}_x$): Formed when nitrogen and oxygen react under the high temperatures of car engines and power plants.
These gases dissolve in atmospheric water to form weak acids ($\text{H}_2\text{SO}_4$, $\text{HNO}_3$), which lowers the $\text{pH}$ of rain, damaging lakes, forests, and limestone buildings.
| Resource Name | Core Keywords (Download Link) | Download Link (FREE PDF) |
| Oxygen and Air | Atmospheric Composition, Air Pollutants ($\text{SO}_2$, $\text{NO}_x$, $\text{CO}$), Acid Rain Formation and Damage | Download PDF: Oxygen and Air |
| Hydrogen and Water | Water Treatment (Chlorination), Desalination, Uses of Hydrogen as a Clean Fuel | Download PDF |
🏆 FINAL A* ACCELERATOR: DOWNLOAD THE COMPLETE BUNDLE NOW
Do not wait until the last minute. The highest-achieving students use premium resources from the start. Download the entire suite of humanized, SEO-optimized lecture notes below.
| Topic Name | Core Syllabus Focus | Download Link (FREE PDF) |
| Oxygen and Air | Environmental Chemistry, Pollution | Download PDF |
| Chemical Bonding | Structure and Properties (Ionic/Covalent) | Download PDF |
| Chemical Energetics | $\Delta\text{H}$, Exothermic/Endothermic | Download PDF |
| Experimental Techniques | Separation, Purity Tests, Lab Skills | Download PDF |
| Formula | Writing Chemical Formulae (Valency) | Download PDF |
| Formulae | Empirical and Molecular Formula | Download PDF |
| Metals (Part 1) | Reactivity Series, Extraction | Download PDF |
| Metals (Part 2) | Rusting, Iron Extraction | Download PDF |
| Moles | Stoichiometry, Calculations, Yield | Download PDF |
| Organic Chemistry (Part 1) | Alkanes, Alkenes, Isomers, Naming Conventions | Download PDF |
| Reactions | Rates of Reaction, Collision Theory | Download PDF |
| Redox | Oxidation/Reduction, Half-Equations | Download PDF |
| States of Matter (Part 1) | Kinetic Theory, Diffusion, Changes of State | Download PDF |
| The Periodic Table | Group Trends, Properties of Elements | Download PDF |
| States of Matter (Part 2) | Advanced Particle Behaviour | Download PDF |
| Atoms, Elements and Compounds | Atomic Structure, Isotopes, $A_r$ | Download PDF |
| Organic Chem (Part 2) | Alcohols, Carboxylic Acids, Polymers | Download PDF |
| Acids, Bases and Salts | $\text{pH}$, Neutralization, Salt Preparation | Download PDF |
| Electrolysis | Selective Discharge, Applications | Download PDF |
| Hydrogen and Water | Water Treatment, Hydrogen Fuel | Download PDF |
