Chemistry SL
6
Chapters
243
Notes
Chapter 1 - Models Of The Particulate Nature Of Matter
Chapter 2 - Models Of Bonding & Structure
Unlocking Atomic Bonds: Dive Into Ionic, Covalent & Metallic Structures
Unlocking The Secrets Of Chemical Bonds: A Comprehensive Guide
Unraveling Ionic Compounds: Sodium Chloride & Copper(II) Sulfate Insights
Unveiling Sodium's Secrets: Atoms vs. Ions Explained!
Understanding Ionic Charges: The Role of Main Group Elements
Unveiling Ionic Bonds: The Magic Of Cations & Anions
Unlocking Bond Types: How Electronegativity Decides Ionic Character
Mastering Polyatomic Ions: Tips & Strategies!
Unlocking Patterns in Naming Ionic Compounds
Unlocking Ionic Compounds: Discover Their Formulas Today!
Understanding Ionic Lattices: Dive Into Compound Properties
Unlocking Lattice Enthalpy: Measuring Ionic Bond Strength
Unlocking Ionic Compounds: Properties, Volatility & Solubility
Unlocking Covalent Bonds: From H2 to O2 Structures
Unlocking Electronegativity: Decoding Covalent Bonds
Mastering Lewis Formulas: The Key to Molecular Structures
Understanding Bond Order: From Hydrogen to Carbon Bonds
Unlocking Coordination Bonds: The Heart of Molecular Connections
Unlocking The Secrets Of Coordination Bonds In Transition Metals
Unlocking Molecular Geometry: Dive Into VSEPR Model!
Unlock Linear Geometry: Dive Into Electron Domains
Trigonal Planar Geometry: Unraveling Bonding Domains
Unlocking Tetrahedral Geometry: From Bonding Domains to Molecular Shapes
Understanding Multiple Bonds: Their Influence on Molecular Geometry
Unlocking Bond Polarity: Why It Matters & How It Works
Unraveling Molecular Polarity: Key Aspects & Impacts
Unlocking Covalent Network Structures!
Unlocking Carbon's Secrets: Explore Its Allotropes!
Unlocking Silicon's Secrets: A Contrast With Carbon
Explore Intermolecular Forces: Structure 2.2.8
Unlocking London Dispersion Forces Secrets
Explore Dipole-Induced Dipole Forces!
Unlock the Secrets of Dipole-Dipole Forces!
Unlocking The Secrets Of Hydrogen Bonding!
Unlock Covalent Substances Secrets!
Unlocking the Mysteries of Covalent Compounds!
Unlock Chromatography Secrets: A Guide
Unlock the Secrets of Paper Chromatography!
Unlock Advanced Sensitivity: Explore TLC Methods!
Unlock Chromatography Success: Decipher RF Values!
Unlock The Mysteries Of Resonance In Molecules!
Unlock the Secrets of Delocalization!
Unlock The Secrets Of Benzene And Resonance!
Unlocking Benzene: Insights into Its Unique Structure
Unlock Benzene's Chemical Mysteries!
Unlock Expanded Octets: Structure & VSEPR
Master Expanded Octet Lewis Formulas!
Unlock Molecular Geometry Secrets!
Unlock Chemistry: Understand Formal Charge 2.2.14!
Unraveling Sigma & Pi Bonds: Structure Insights!
Unlock The Secrets Of Sigma & Pi Bonds!
Explore Intriguing Pi Bonds & Molecular Theories!
Explore Carbon's Bonding Secrets: Hybridization
Unlock the Secrets of sp2 Hybridization!
Explore SP Hybridization: Uncover the Mysteries!
Explore Atom Hybridization Beyond Carbon!
Unlock Hybridization & Geometry Mastery!
Unlocking Ethanoate Ion Secrets: Hybridization & Delocalization!
Explore Metallic Structures: Insight Into Bonding
Unlock The Secrets Of Metallic Bonding!
Explore Metallic Properties: A Detailed Insight
Unlock Metallic Bond Strength Secrets!
Explore Transition Element Bonding: Structure 2.3.3
Explore the Bonding Continuum: Structure 2.4.1
Unlocking Material Properties: Bond Types Explained
Explore Triangular Bonding Diagrams!
Unlocking Silicon: A Metalloid Marvel!
Explore Magnesium Iodide: Ionic & Covalent Secrets!
Explore Aluminum Chloride: Ionic & Covalent Properties!
Unlock Alloys Secrets: Structure & Properties!
Unlock The Strength: Alloys vs. Pure Metals
Explore Wonders of Alloy Science!
Explore the Intricacies of Polymers 2.4.4
Unlock the Secrets of Polymer Structures!
Uncover the Secrets of Polymers!
Plastic's Challenge: Recycling, Degradation, And The Environment
Unlocking The Secrets Of Addition Polymerization: Ethene To PVC
Unveiling Condensation Polymers: The Creation Of Nylon & Cellulose
Discover the Magic of Polymer Creation: Monomer ABAB Pattern
Understanding Condensation Polymerization: 3-Hydroxypentanoic Acid & Proteins
Unlocking Life's Secrets: Hydrolysis & Condensation in Biology
Chapter 3 - Classification Of Matter
Chapter 4 - What Drives Chemical Reactions?
Chapter 5 - How Much, How Fast & How Far?
Chapter 6 - What Are The Mechanisms Of Chemical Change?
Chemistry SL
Chapter 2 - Models Of Bonding & Structure
Explore Wonders of Alloy Science!
531 words
3 mins read
Last edited on 5th Nov 2024
Table of content
Quick facts🔥
- Alloys are mixtures of metals that have properties different from their constituent elements.
- NaK is a sodium-potassium alloy that's a liquid at room temperature and is used as a nuclear reactor coolant.
- Memory metals return to their original shape upon heating and are used for objects that get deformed through use (e.g., spectacle frames).
- Steel is an alloy of iron and carbon, harder and stronger than pure iron, ideal for construction and tools. Varieties depend on the carbon and other elements content.
- Bronze is an alloy of copper and tin, harder than copper, and resistant to corrosion. Used in shipbuilding, tools, and artifacts.
- Brass is an alloy of copper and zinc, highly malleable, used in musical instruments and door handles due to its acoustic and antimicrobial properties.
What's the deal with steel?
- Pure iron can be easily deformed, but when alloyed with carbon, it becomes steel, which is much harder and stronger.
- Steel is used for various applications, from construction to tools.
- The carbon content affects steel's hardness: the more carbon, the harder the steel.
- Steels with 0.3% to 0.6% carbon by mass are known as medium steels.
- The hardness of medium steels is measured using the Vickers hardness test, where higher values mean greater hardness.
💡 Real-World Example: A high-carbon steel knife blade is very sharp and can keep its edge for a long time but can be brittle and prone to chipping. In contrast, a low-carbon steel blade is softer and less likely to chip but doesn't retain a sharp edge as long.
Rust - the arch-nemesis of iron & steel
- Rust is a problem because it turns iron into hydrated iron(III) oxide, which lacks metal's valuable properties.
- Rust also flakes off, reducing the metal volume and exposing more iron to corrosion.
- This has economic implications as large steel-containing structures (ships, bridges) need rust protection.
- Rust protection methods include barrier methods (painting, oiling) and sacrificial methods (galvanizing).
💡 Real-World Example: The Eiffel Tower in Paris is repainted every seven years with approximately 60 tons of paint to protect it from rust.
Unlock the Full Content! 
Dive deeper and gain exclusive access to premium files of Chemistry SL. Subscribe now and get closer to that 45 🌟
Chemistry SL
Chapter 2 - Models Of Bonding & Structure
Explore Wonders of Alloy Science!
531 words
3 mins read
Last edited on 5th Nov 2024
Table of content
Quick facts🔥
- Alloys are mixtures of metals that have properties different from their constituent elements.
- NaK is a sodium-potassium alloy that's a liquid at room temperature and is used as a nuclear reactor coolant.
- Memory metals return to their original shape upon heating and are used for objects that get deformed through use (e.g., spectacle frames).
- Steel is an alloy of iron and carbon, harder and stronger than pure iron, ideal for construction and tools. Varieties depend on the carbon and other elements content.
- Bronze is an alloy of copper and tin, harder than copper, and resistant to corrosion. Used in shipbuilding, tools, and artifacts.
- Brass is an alloy of copper and zinc, highly malleable, used in musical instruments and door handles due to its acoustic and antimicrobial properties.
What's the deal with steel?
- Pure iron can be easily deformed, but when alloyed with carbon, it becomes steel, which is much harder and stronger.
- Steel is used for various applications, from construction to tools.
- The carbon content affects steel's hardness: the more carbon, the harder the steel.
- Steels with 0.3% to 0.6% carbon by mass are known as medium steels.
- The hardness of medium steels is measured using the Vickers hardness test, where higher values mean greater hardness.
💡 Real-World Example: A high-carbon steel knife blade is very sharp and can keep its edge for a long time but can be brittle and prone to chipping. In contrast, a low-carbon steel blade is softer and less likely to chip but doesn't retain a sharp edge as long.
Rust - the arch-nemesis of iron & steel
- Rust is a problem because it turns iron into hydrated iron(III) oxide, which lacks metal's valuable properties.
- Rust also flakes off, reducing the metal volume and exposing more iron to corrosion.
- This has economic implications as large steel-containing structures (ships, bridges) need rust protection.
- Rust protection methods include barrier methods (painting, oiling) and sacrificial methods (galvanizing).
💡 Real-World Example: The Eiffel Tower in Paris is repainted every seven years with approximately 60 tons of paint to protect it from rust.
Unlock the Full Content!
Dive deeper and gain exclusive access to premium files of Chemistry SL. Subscribe now and get closer to that 45 🌟
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