Having taught in the UK and abroad, I've experienced teaching many different syllabi including SABIS, AQA, WJEC and Cambridge. I develop resources to help teachers model key concepts, provide practice for students and include answers to help students self-assess their work. Planning for a 27 lesson week can be stressful to say the least, so I hope you find my resources useful. Thank you for choosing my lesson/s, I hope they enrich your teaching practice and make your life easier.
Having taught in the UK and abroad, I've experienced teaching many different syllabi including SABIS, AQA, WJEC and Cambridge. I develop resources to help teachers model key concepts, provide practice for students and include answers to help students self-assess their work. Planning for a 27 lesson week can be stressful to say the least, so I hope you find my resources useful. Thank you for choosing my lesson/s, I hope they enrich your teaching practice and make your life easier.
This PowerPoint resource is a comprehensive teaching tool designed to help students understand the reactivity of metals and the principles behind displacement reactions. It provides an interactive approach to exploring the reactivity series, predicting chemical reactions, and balancing equations.
Key learning objectives include:
Understanding the reactivity series and deducing the order of metal reactivity based on reactions with oxygen, water, and acids.
Defining and identifying displacement reactions and predicting where they will occur.
Practising writing word equations and balanced chemical equations for observed reactions.
The resource includes engaging starter activities, such as completing reaction equations and extending them into balanced formulas, to activate prior knowledge. Detailed explanations of the reactivity series are provided, including how it relates to electron loss, reaction vigor, and practical applications. Students are guided through the concept of displacement reactions with worked examples and are encouraged to test their knowledge through questions and practice problems.
Designed high school chemistry lessons, this resource is aligned with common exam board specifications. The ‘.pptx’ file format ensures compatibility and allows teachers to customize the content to suit their needs. Interactive elements, like mnemonic devices for remembering the reactivity series and hands-on exercises, make this resource highly engaging and effective for learning.
This PowerPoint has been enhanced for clarity and engagement, making it an invaluable asset for teaching the reactivity series and displacement reactions in chemistry.
This PowerPoint resource provides a comprehensive guide to understanding the chemistry of metal and acid reactions, focusing on ionic equations, oxidation, and reduction. It is designed to help students analyze reactions in terms of electron transfer and write accurate equations to represent these processes.
Key learning objectives include:
Describing reactions between metals and acids using ionic equations.
Determining and explaining which species are oxidized and reduced in a reaction using the principles of electron transfer.
Writing net ionic equations and corresponding half-equations for redox reactions.
The resource begins with engaging starter activities, such as identifying reaction products and writing word and balanced equations. It then introduces the concept of ionic equations, emphasizing the role of spectator ions and the importance of splitting reactions into their ionic components. Students are guided through the process of writing net ionic equations step by step, supported by worked examples for clarity.
The concept of redox reactions is explained using the OILRIG mnemonic (Oxidation Is Losing, Reduction Is Gaining). Students learn to identify oxidizing and reducing agents and write half-equations for reactions like magnesium with hydrochloric acid or iron with nitric acid. Practice exercises and detailed answers are included to reinforce understanding.
This ‘.pptx’ file is ideal for high school chemistry lessons and aligns with most exam board specifications. Fully editable, it can be tailored to suit different teaching needs. This resource has been enhanced for clarity and engagement, making it a valuable tool for mastering metal and acid reactions.
This PowerPoint resource is a comprehensive guide for teaching students how to identify and write the names and chemical formulae of salts formed during reactions between metals and acids. It provides clear explanations, worked examples, and practice exercises, making it an ideal teaching tool for high school chemistry classes.
Key learning objectives include:
Naming salts based on the metal and acid involved in a reaction.
Writing word equations for reactions between metals and acids.
Determining the chemical formulae of salts using ion charges and balancing charges correctly.
The resource begins with a starter activity to engage students and activate prior knowledge. It then explains the general reaction between a metal and acid, producing a salt and hydrogen gas. Students are introduced to the definition of a salt and learn how to name salts formed from different acids, such as hydrochloric acid (producing chlorides), sulfuric acid (producing sulfates), and nitric acid (producing nitrates).
Step-by-step guidance is provided for writing chemical formulae, including balancing ion charges and using brackets for polyatomic ions. Worked examples cover common salts like sodium chloride and magnesium nitrate, followed by practice problems to consolidate learning. The resource also challenges students to write balanced chemical equations, both word and symbolic, for various reactions.
This ‘.pptx’ file is fully editable, allowing customization for different curricula or class needs. This resource has been refined for clarity and user engagement, making it an invaluable resource for teaching the chemistry of salts and reactions involving metals and acids.
This PowerPoint resource is a complete instructional tool designed to teach students about energy changes in chemical reactions. The resource focuses on drawing and interpreting reaction profile diagrams for exothermic and endothermic reactions, defining activation energy, and explaining its role in chemical processes.
It includes clear learning objectives, engaging starter activities, and interactive tasks to reinforce understanding. Students will explore the differences between exothermic and endothermic reactions, learn how to label key features on reaction profiles, and understand how catalysts influence activation energy. The resource also covers key concepts like energy release, absorption, and bond breaking and forming.
Designed for high school chemistry lessons, this resource aligns with common science curricula and is ideal for interactive teaching, individual practice, or group work. It includes definitions, worked examples, gap-fill exercises, and review questions to assess understanding. Students are encouraged to draw diagrams, identify energy changes, and label components to deepen their comprehension.
This ‘.pptx’ file is fully editable and compatible with most presentation software, allowing teachers to customize content to suit specific classroom needs. The resource has been designed for clarity and engagement, ensuring it remains an effective teaching aid for energy concepts in chemistry.
This PowerPoint is an essential teaching aid for understanding energy calculations in chemistry. It guides students through calculating energy changes using bond energies and determining whether a reaction is exothermic or endothermic.
The resource covers key learning objectives: explaining why bond breaking is endothermic and bond making is exothermic, analyzing reactions in terms of energy transfer, and performing accurate energy change calculations using the correct units (kJ/mol). It includes definitions, worked examples, and practice problems to reinforce understanding. Starter activities prompt students to review concepts like activation energy, reaction profiles, and the energy changes associated with chemical processes.
Students will work with bond energy values to calculate energy changes in various reactions, such as combustion and synthesis. They will also interpret the significance of negative and positive energy changes, linking them to exothermic and endothermic processes. The resource highlights the importance of bond energy in understanding chemical reactivity and energy conservation.
This ‘.pptx’ file is fully editable, enabling teachers to adapt the content to specific curricula or student needs. It’s ideal for high school chemistry lessons and is aligned with many science specifications. This resource has been refined for clarity and engagement, ensuring its relevance as a tool for teaching energy changes in chemical reactions.
This PowerPoint presentation guides students through a required practical on preparing a pure, dry sample of copper sulfate crystals. It is designed to help secondary school students develop practical skills and a deeper understanding of neutralization reactions and crystallization processes, aligning with key chemistry curriculum objectives.
The lesson begins with clear learning objectives, including writing a method for producing a soluble salt from an insoluble base and understanding the purpose of each procedural step. Starter activities reinforce key concepts, such as writing word and balanced symbol equations for salt formation reactions.
Key topics and activities include:
Practical Methodology: A detailed, step-by-step guide to reacting copper oxide with sulfuric acid, including warming the acid, adding the base until in excess, filtering the mixture, and evaporating the solution to form crystals.
Safety Considerations: Emphasizes the importance of safety, including wearing goggles, handling acids and bases cautiously, and using equipment like Bunsen burners correctly.
Scientific Concepts: Explains the principles behind the reaction, such as why copper oxide is added in excess (to ensure all the acid reacts) and how slow evaporation results in larger, purer crystals.
Interactive Learning: Encourages students to write their own methods, answer practical questions, and adapt the method for other salts, such as magnesium sulfate.
This resource is presented as a PowerPoint file (.pptx) and includes videos, questions, and guided tasks to enhance understanding. Updated content ensures it meets curriculum standards, making it an invaluable tool for teaching essential practical skills in chemistry.
This PowerPoint presentation designed to teach students the fundamental concepts of heat energy changes during chemical reactions. It is a valuable resource for educators covering thermochemistry or introductory chemistry topics in their curriculum.
The presentation begins with engaging starter activities to prompt critical thinking, such as identifying units of energy and temperature, recognizing signs of chemical reactions, and determining the appropriate graphs for data types. These activities set the stage for the main content while reviewing key concepts.
Key learning objectives are outlined, including defining exothermic and endothermic reactions, distinguishing between the two based on temperature changes in the surroundings, and providing real-life examples of each type. The resource uses accessible language and visuals to explain these concepts. For instance, “Exothermic” is broken down to mean “Exit Heat,” where energy is released, causing the surroundings to heat up. Conversely, “Endothermic” is described as “Enter Heat,” where energy is absorbed, resulting in a cooling effect.
The presentation includes numerous examples of exothermic and endothermic processes, such as:
Exothermic: Combustion, neutralization reactions, oxidation, and single-use/reusable hand warmers.
Endothermic: Sports ice packs, thermal decomposition, and sherbet reactions.
Interactive slides encourage students to identify temperature changes and classify reactions as exothermic or endothermic. Real-world applications, such as self-heating cans and sports ice packs, are explained in detail, making the material relatable and engaging.
The resource also includes review questions and tables for students to complete, consolidating their understanding of reaction types and their practical implications. The PowerPoint file format (.pptx) ensures ease of use and compatibility for teachers. This presentation is an excellent tool for teaching energy changes in chemical reactions, combining theory with practical applications for an engaging learning experience.
This PowerPoint presentation provides a detailed exploration of Earth’s atmosphere, its historical evolution, and the processes that have shaped its composition. It is designed for secondary school students and aligns with key chemistry and earth science curriculum standards.
The lesson begins with clear learning objectives, such as describing the composition of the current atmosphere and explaining how it has evolved from the early atmosphere. A starter activity encourages students to identify the gases present in the air, laying a foundation for deeper discussions.
Key topics covered include:
The Early Atmosphere: Explains the formation of Earth’s early atmosphere through volcanic activity, detailing the presence of gases like carbon dioxide, nitrogen, and water vapor. The resource highlights the absence of oxygen and discusses the cooling of Earth, leading to the formation of oceans.
Role of Photosynthesis: Describes how algae and later plants transformed the atmosphere by reducing carbon dioxide levels and increasing oxygen through photosynthesis. Balanced chemical equations illustrate this process.
Carbon Storage: Explores how carbon dioxide became locked in sedimentary rocks, fossil fuels, and dissolved in oceans. Examples include the formation of limestone, coal, and crude oil.
Modern Atmospheric Composition: Presents the percentages of gases like nitrogen, oxygen, and carbon dioxide in the current atmosphere, connecting their stability to ecological processes.
Interactive elements include diagram completions, review questions, and exam-style tasks to ensure comprehension. The resource also addresses scientific theories and the evidence supporting our understanding of Earth’s atmospheric evolution.
Available as a PowerPoint file (.pptx), this resource is updated to remain relevant and is ideal for educators seeking to deliver engaging, structured, and informative lessons on Earth’s atmosphere and its changes over time.
PowerPoint that covers the following learning objectives:
Define the mass of an object.
Measure mass of an object using a mass balance.
Includes questions, pictures, instructions and a practical in which the students have to use mass balances to measure the mass of up to 20 objects.
There are questions that ask students to add masses of objects together, substract masses and work out the difference.
The results table, questions and space for answers are on the worksheet.
This is for a primary/early secondary class.
If you could spare 5 minutes, please review this resource, to help my online presence grow! :)
PowerPoint that covers the following learning objectives:
Measure the temperature of a substance.
Plot a graph of temperature vs. time.
In this investigation, students will compare how a large beaker of hot water and a small beaker of hot water cool down differently. They will form a research question, hypothesis, fill in table of results, plot line graphs and form a conclusion.
PowerPoint includes research question, hypothesis, method, graphs and conclusion.
If you could spare 5 minutes, please review this resource, to help my online presence grow! :)
This focused resource bundle provides a comprehensive overview of covalent bonding and the unique structures it creates. Designed for secondary school chemistry students, this four-lesson series explores simple and giant covalent molecules, connecting their structure and bonding to their fascinating properties and real-world applications. Updated on 3rd December 2024, it is an essential resource for teaching these key chemistry concepts.
The bundle includes:
Covalent Bonding: A foundational lesson explaining how atoms share electrons to form covalent bonds, with examples of single, double, and triple bonds.
Simple Covalent Molecules – Structure and Properties: Examines how bonding and intermolecular forces influence the boiling points, solubility, and conductivity of substances like water and methane.
Giant Covalent Structures – Diamond, Graphite, and Silicon Dioxide: A detailed exploration of these allotropes, their unique properties, and applications, from diamond’s hardness to graphite’s conductivity and silicon dioxide’s industrial uses.
Graphene and Fullerenes: A dive into modern materials science, introducing graphene’s remarkable strength and conductivity and fullerenes’ potential uses in technology and medicine.
How to use:
Each lesson includes thought-provoking starter questions, detailed explanations, diagrams, and structured activities to engage students and reinforce learning. Exam-style questions and real-world examples help students connect theory to practice. This bundle is ideal for teachers seeking an interactive and curriculum-aligned approach to teaching covalent bonding and structures, ensuring students understand not only the science but also the significance of these materials in everyday life and cutting-edge technology.
Lesson 1 - Covalent Bonding
Lesson 2 - Simple Covalent Molecules - Structure and Properties
Lesson 3 - Giant Covalent Structures - Diamond, Graphite and Silicon Dioxide
Lesson 4 - Graphene and Fullerenes
Elevate your chemistry teaching with this ionic bundle, a comprehensive package of PowerPoints designed to guide students through the fundamentals of ionic bonding and the unique properties of ionic compounds. This bundle is perfect for middle and high school science educators aiming to deliver engaging lessons with hands-on activities and assessments.
What’s Included:
Clear explanations on how ions form from atoms.
Interactive activities such as drawing ions and dot-and-cross diagrams for ionic compounds.
Examples featuring elements from Groups 1, 2, 6, and 7.
Step-by-step guidance on understanding electrostatic forces of attraction.
Real-world examples of ionic bonding (e.g., sodium chloride, magnesium oxide).
Explore the giant lattice structure of ionic compounds.
Understand why ionic compounds have high melting/boiling points.
Practical tasks to solidify knowledge.
Practical experiment to test electrical conductivity of ionic compounds in solid, molten, and aqueous states.
Safety guidelines for lab work and step-by-step experiment instructions.
Quiz on Bonding and Structure (Lessons 1–4) - 24-mark assessment covering ionic bonding, properties of ionic compounds, and practical applications. Includes marking scheme for quick and effective grading.
Why Choose This Bundle?
Interactive and Practical: Combines theory with hands-on experiments to engage students.
Comprehensive Coverage: Covers key concepts from ionic bonding to the properties of ionic compounds.
Assessment Ready: Quiz and activities ensure students grasp and retain concepts.
Empower your students to master ionic bonding and its properties with this all-in-one teaching bundle!
This versatile teaching bundle is a must-have for secondary-level chemistry educators, featuring five meticulously crafted PowerPoint presentations. Each resource delves into essential aspects of reaction kinetics, ensuring students develop a thorough understanding of key concepts such as rates of reaction, collision theory, activation energy, and the effects of various factors on reaction rates.
What’s Included:
Lesson 1 - Rates of Reaction:
Defines key terms like reactants, products, and reaction rate.
Explores methods for measuring reaction rates with engaging activities such as graph plotting and data analysis.
Includes exam-style questions, starter tasks, and a plenary for comprehensive learning.
Lesson 2 - Surface Area:
Focuses on how surface area influences reaction rates.
Includes practical calculations, structured activities, and video-based alternatives for experiments.
Lesson 3 - Effect of Temperature:
Explains how temperature affects reaction rates using collision theory and activation energy concepts.
Features PhET simulations, practice questions, and particle diagrams to enhance understanding.
Lesson 4 - Concentration and Pressure:
Explains the impact of concentration and pressure on reaction rates, supported by collision theory.
Offers real-world examples, online simulations, and student-centered activities.
Lesson 5 - Catalysts:
Introduces the definition, function, and real-world applications of catalysts.
Covers reaction profiles and environmental benefits.
Each resource is updated (December 2024) with modern examples, interactive elements, and enhanced visuals for better engagement. The bundle is provided in PowerPoint format (.pptx), ensuring compatibility with most devices and platforms. This comprehensive package supports curriculum standards and fosters critical thinking, making it ideal for classroom and independent learning.
This GCSE chemistry resource bundle provides a thorough and accessible introduction to electrolysis, guiding students step by step through its principles, processes, and practical applications. It features five engaging lessons that cover everything from foundational concepts to required practical skills, ensuring students are well-prepared for exams.
The bundle includes:
Introduction to Electrolysis: Explains the basics of electrolysis, including how ionic compounds conduct electricity and the role of electrodes in separating elements.
Electrolysis of Molten Compounds: Demonstrates how electrolysis works with molten ionic compounds, providing clear examples and practice opportunities.
Electrolysis of Aluminium Oxide: Explores the extraction of aluminum using electrolysis, linking the process to real-world applications in industry.
Electrolysis of Aqueous Solutions: Teaches students how to predict the products of electrolysis in solutions, with diagrams and step-by-step explanations.
Required Practical: Electrolysis: Offers a detailed guide to the required practical, with instructions, safety considerations, and tips for accurately recording and analyzing results.
How to use: Each lesson includes clear explanations, diagrams, and exam-style questions to help students understand and apply key concepts. The practical lesson ensures students are confident in carrying out experiments and understanding their results. Perfect for GCSE chemistry teachers, this bundle provides a structured approach to teaching electrolysis while making it engaging and relevant to students.
Lesson 1 - Introduction to Electrolysis
Lesson 2 - Electrolysis of Molten Compounds
Lesson 3 - Electrolysis of Aluminium Oxide
Lesson 4 - Electrolysis of Aqueous Solutions
Lesson 5 - Required Practical Electrolysis
This resource bundle offers six meticulously crafted lessons to help students excel in quantitative chemistry. Designed for secondary school learners, it provides clear explanations, practical examples, and interactive activities, making it ideal for teaching, independent study, or revision.
What’s Included:
Conservation of Mass:
Explore how mass remains unchanged during chemical reactions. Practical examples and engaging exercises ensure students grasp this core principle.
Ar, Mr, and Calculating Percentage Mass of an Element in a Compound:
Learn to calculate relative atomic mass (Ar) and molecular mass (Mr), and determine the percentage composition of elements within compounds.
The Mole and Calculations Involving Mass, Moles, and Molar Mass:
Simplify the concept of the mole with worked examples that show how to calculate the mass, number of moles, and Ar/Mr, supported by ample practice questions.
Reacting Masses in Equations:
Use balanced chemical equations to determine the masses of reactants and products, connecting theory with real-world applications.
Counting Atoms, Writing, and Balancing Equations:
Help students confidently write and balance chemical equations while understanding the role of coefficients and subscripts in counting atoms.
Concentration of Solutions:
Dive into solution chemistry with lessons on calculating concentration, mass, and volume, supported by examples and real-life contexts like dilutions and mixing solutions.
Why Choose This Bundle?
Each lesson includes starter activities, exam-style questions, and step-by-step worked examples.
Topics are aligned with GCSE chemistry curricula, ensuring comprehensive coverage of key quantitative skills.
Flexible usage: Perfect for guided teaching, revision sessions, or targeted intervention.
File Type: PowerPoint (.pptx)
Updated: December 2024 – New lessons on concentration and balancing equations have been added.
Equip your students with the tools they need to confidently tackle quantitative chemistry and achieve success in their exams and beyond!
Lesson 1 Counting Atoms, Writing Equations and Balancing Equations
Lesson 2 - Conservation of Mass
Lesson 3 - Ar, Mr and Calculating % Mass of an Element in a Compound
Lesson 4 - The Mole and Calculating Number of Moles, Mass or Ar/Mr
Lesson 5 - Reacting Masses in Equations
Lesson 6 - Concentration of Solutions
This GCSE chemistry resource bundle provides a comprehensive overview of crude oil, hydrocarbons, and their significance in everyday life. Designed to align with GCSE chemistry curricula, it features five engaging lessons that cover the composition, properties, and uses of hydrocarbons, along with key industrial processes. This bundle is perfect for teaching or revising these vital topics.
The bundle includes:
Crude Oil, Hydrocarbons, and Alkanes: Introduces the formation of crude oil, the structure and properties of hydrocarbons, and the classification of alkanes as saturated hydrocarbons.
Fractional Distillation, Fractions, and Uses of Fractions: Explains the fractional distillation process, how it separates crude oil into useful fractions, and the applications of these fractions in everyday life.
Properties of Hydrocarbons: Examines the physical and chemical properties of hydrocarbons, including boiling points, viscosity, and flammability, with links to their molecular structure.
Combustion of Hydrocarbons: Covers complete and incomplete combustion, the products formed, and the environmental implications of burning hydrocarbons.
Cracking Hydrocarbons: Explores the process of cracking, how it breaks down long-chain hydrocarbons into more useful smaller ones, and the importance of alkenes in the chemical industry.
How to use:
Each lesson includes starter activities, detailed explanations, diagrams, and exam-style questions to ensure students fully understand key concepts. Teachers can use this bundle for structured lessons or revision sessions. It provides a clear and engaging approach to learning about hydrocarbons, preparing students for exams while connecting classroom theory to real-world applications.
Lesson 1 - Crude Oil, Hydrocarbons and Alkanes
Lesson 2 - Fractional Distillation, Fractions and Uses of Fractions
Lesson 3 - Properties of Hydrocarbons
Lesson 4 - Combustion of Hydrocarbons
Lesson 5 - Cracking Hydrocarbons
This is a comprehensive collection of interactive PowerPoint lessons designed for secondary-level science students. This engaging resource guides learners through essential chemistry topics, focusing on mixtures, pure substances, and various separation techniques, aligning with key science curriculum standards.
Lesson 1: Solutions introduces the concept of solutions, explaining solutes, solvents, and the particle model of dissolution. Students explore real-world examples and conduct hands-on activities to reinforce their understanding, including the conservation of mass during dissolution.
Lesson 2: Solubility explains solubility, identifying soluble and insoluble substances, and the impact of temperature on solubility. The lesson features graph-based analysis and a practical experiment to investigate temperature effects, helping students develop analytical skills.
Lesson 3: Filtration explores the separation of mixtures using filtration. Students learn about insoluble solids, filtrate, and residue through relatable examples like muddy water and coffee. The lesson includes a hands-on experiment and reflective questions to solidify key concepts.
Lesson 4: Separating Salt from Rock Salt focuses on evaporation and crystallization. Students follow a practical demonstration to extract salt, applying techniques like filtration and evaporation. Activities include step-by-step tasks, fill-in-the-gaps exercises, and review questions.
Lesson 5: Simple Distillation introduces evaporation and condensation processes for separating mixtures. Students learn to label apparatus diagrams, understand the role of condensers, and explore real-world applications through engaging questions and demonstrations.
Lesson 6: Fractional Distillation builds on simple distillation, explaining the separation of miscible liquids based on boiling points. Students sequence the process, label diagrams, and tackle challenge questions that highlight the role of the fractionating column.
Lesson 7: Pure Substances, Mixtures, and Formulations helps students distinguish between pure and impure substances, elements, and compounds. Real-world examples, such as mineral water and toothpaste, illustrate formulations, with activities that analyze boiling and melting points.
Lesson 8: Chromatography introduces chromatography as a separation technique for soluble substances like inks and dyes. Students conduct a practical experiment, calculate Rf values, and analyze chromatograms to identify pure substances and mixtures.
This bundle includes eight fully editable PowerPoint presentations (.pptx), each featuring starter activities, interactive tasks, practical experiments, and practice questions to assess understanding. Updated with modern visuals and examples as of December 2024, it supports hands-on learning, critical thinking, and real-world applications. Perfect for science educators, this resource ensures a thorough and engaging exploration of chemistry topics, making it ideal for classroom teaching, revision, or independent study.
This comprehensive resource bundle provides an in-depth exploration of chemical bonding and the structure and properties of compounds, ideal for secondary school students studying chemistry. Updated on 20th December 2024, it covers nine detailed lessons, taking learners on a journey from the fundamentals of ionic and covalent bonding to advanced topics like fullerenes and graphene.
The bundle includes:
Atoms into Ions: Exploring how and why atoms gain or lose electrons to achieve stability, making it an essential tool for understanding ionic bonding.
Ionic Bonding: Introducing the basics of ionic bonding, how ions form, and their role in compound stability.
Structure of Ionic Compounds: Exploring lattice structures, explaining why ionic compounds have high melting points and can conduct electricity when molten or dissolved.
Properties of Ionic Compounds: A detailed look at the physical and chemical properties of ionic substances.
Metallic Bonding: Understanding the ‘sea of electrons’ model and why metals are strong, malleable, and conductive.
Covalent Bonding: Breaking down how atoms share electrons to form molecules, including single, double, and triple bonds.
Structure and Properties of Simple Covalent Molecules: Examining how molecular structures affect boiling points, solubility, and conductivity.
Giant Covalent Structures: Focusing on diamond, graphite, and silicon dioxide, analyzing their properties and real-world applications.
Fullerenes and Graphene: Delving into cutting-edge materials science with these unique carbon allotropes, their remarkable properties, and potential uses.
How to use: Each lesson includes engaging starter activities, detailed explanations, and review questions to ensure student comprehension. This bundle is perfect for teachers seeking a structured, curriculum-aligned approach to teaching bonding and materials science. With clear progression, interactive activities, and real-world examples, it’s designed to inspire curiosity and deepen understanding of key chemistry concepts.
Updated in December 2024 to include Atoms into Ions.
Lesson 1 - Atoms into Ions
Lesson 2 - Ionic Bonding
Lesson 3 - Structure of Ionic Compounds
Lesson 4 - Properties of Ionic Compounds
Lesson 5 - Metallic Bonding
Lesson 6 - Covalent Bonding
Lesson 7 - Structure and Properties of Simple Covalent Molecules
Lesson 8 - Giant Covalent Structures
Lesson 9- Fullerenes and Graphene
