Over 200 resources available for KS3-KS4 Science, KS5 Chemistry and Whole School! Lesson resources are suitable for live lessons in school, remote teaching at home or independent student study. It’s your choice how you use them 😊 Don’t forgot to explore my free resources too!
Over 200 resources available for KS3-KS4 Science, KS5 Chemistry and Whole School! Lesson resources are suitable for live lessons in school, remote teaching at home or independent student study. It’s your choice how you use them 😊 Don’t forgot to explore my free resources too!
A structured KS5 lesson (Part 2 of 2) including starter activity, AfL work tasks and practice questions on Standard Electrode & Cell Potentials
By the end of this lesson KS5 students should be able to:
LO1: To use the term standard electrode potential E⦵ including its measurement using a hydrogen electrode
LO2: To calculate a standard cell potential by combining two standard electrode potentials
LO3: To predict the feasibility of electrode potentials to modern storage cells
The teacher will be able to check students have met these learning objectives through mini AfL tasks for students to complete
All tasks have worked out answers, which will allow students to self assess their work during the lesson
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons, including using your own lesson PowerPoints, is a fundamental skill of a qualified/unqualified teacher that will be assessed during the scenarios outlined above
A well structured lesson including starter activity, AfL work tasks on metal oxides. Suitable for AQA GCSE Chemistry or Combined Science
By the end of this lesson KS4 students should be able to:
Identity that metals react with oxygen to form metal oxides
Explain reduction and oxidation by loss or gain of oxygen
Identify metal oxides as bases or alkalis
The teacher will be able to check students have met these learning objectives through mini AfL tasks for students to complete
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons, including using your own lesson PowerPoints, is a fundamental skill of a qualified/unqualified teacher that will be assessed during the scenarios outlined above
3 Full Lesson Bundle which covers the Kinetics chapter from the OCR AS Level Chemistry Specification (may also suitable for the AQA and Edexcel Spec- see Learning Objectives below to confirm)
Lesson 1: Collision Theory & Rates of Reaction
**1. To explain the effect of concentration (including pressure of gases only) on the rate of reaction in terms of the frequency of collisions
**2. To calculate the rate of reaction using the gradients of a concentration-time graph
**3. To describe the techniques and procedures used to investigate reaction rates including the measurement of mass, gas volumes and concentration
Lesson 2: Catalysts
**1. To explain the effect of concentration (including pressure of gases only) on the rate of reaction in terms of the frequency of collisions
**2. To calculate the rate of reaction using the gradients of a concentration-time graph
**3. To describe the techniques and procedures used to investigate reaction rates including the measurement of mass, gas volumes and concentration
Lesson 3: The Boltzmann Distribution
**1. To draw a labelled diagram of the Boltzmann distribution
**2. To explain qualitatively the Boltzmann distribution and its relationship with activation energy
**3. To explain how temperature changes and catalytic behaviour effect the proportion of molecules exceeding the activation energy and hence the reaction rate using Boltzmann distributions
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons including using your own lesson PowerPoints is a fundamental skill of a qualified/unqualified teacher that will be reviewed during these scenarios outlined above
5 Full Lessons on Energetics in AS Level Chemistry. See below for the lesson objectives
Lesson 1: Enthalpy and Reactions
LO1: To explain that some chemical reactions are accompanied by enthalpy changes that are exothermic or endothermic
LO2: To construct enthalpy profile diagrams to show the difference in the enthalpy of reactants compared with products
LO3: To qualitatively explain the term activation energy, including use of enthalpy profile diagrams
**Lesson 2: Enthalpy Changes **
LO1: To know what standard conditions are
LO2:To understand the terms enthalpy change of combustion, neutralisation and formation
LO3:To construct balanced symbol equations based on the terms enthalpy change of combustion, neutralisation and formation.
Lesson 3: Bond Enthalpies
LO1: To explain the term average bond enthalpy
LO2:To explain exothermic and endothermic reactions in terms of enthalpy changes associated with the breaking and making of chemical bonds
LO3:To apply average bond enthalpies to calculate enthalpy changes and related quantities
**Lesson 4: Calorimetry **
LO1:To determine enthalpy changes directly from appropriate experimental results, including use of the relationship q=mcΔT
LO2:To know the techniques and procedures used to determine enthalpy changes directly using a coffee cup calorimeter
LO3:To know the techniques and procedures used to determine enthalpy changes indirectly using a copper calorimeter
**Lesson 5: Hess’ Law & Enthalpy Cycles **
LO1: To state Hess’ Law
LO2: To calculate the enthalpy change of a reaction from enthalpy changes of combustion using Hess’ Law
LO3:To calculate the enthalpy change of a reaction from enthalpy changes of formation using Hess’ Law
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons, including using your own lesson PowerPoints, is a fundamental skill of a qualified/unqualified teacher that will be assessed during the scenarios outlined above
Student friendly personalised learning checklist for OCR A level Chemistry (H432)
This resource includes key specification statements for papers 1-3
This resource is one Excel document with tabs for:
Module 2: Foundations in Chemistry
Module 3: Periodic Table and Energy
Module 4: Core Organic Chemistry
Module 5: Physical Chemistry and Transition Elements
Module 6: Organic Chemistry and Analysis
The exam paper number linked to each topic can be found in the left hand corner of each checklist to aid student exam revision.
5 Full Lesson Bundle on Analysis from the OCR A Level Chemistry specification. Please review the learning objectives below.
Lesson 1: Chromatography
To interpret one-way TLC chromatograms in terms of Rf values
To interpret gas chromatograms in terms of:
(i) retention times
(ii) the amounts and proportions of the components in a mixture
To understand the creation and use of external calibration curves to confirm concentrations of components.
Lesson 2: Qualitative Analysis of Organic Functional Groups
To recall qualitative analysis of organic functional groups on a test-tube scale
To design qualitative analysis tests to distinguish between two or more organic compounds
Lesson 3: Carbon-13 NMR Spectroscopy
To analyse a carbon-13 NMR spectrum of an organic molecule to make predictions about:
The number of carbon environments in the molecule
The different types of carbon environment present from chemical shift values
Possible structures for the molecule
Lesson 4: Proton NMR Spectroscopy (Part 1)
To analyse proton NMR spectra of an organic molecule to make predictions about:
The number of proton environments in the molecule
The different types of proton environment present from chemical shift values
Lesson 5: Proton NMR Spectroscopy (Part 2) (includes combined techniques)
To analyse proton NMR spectra of an organic molecule to make predictions about:
The different types of proton environment present from chemical shift values
The relative numbers of each type of proton present from the relative peak areas using integration traces or ratio numbers when required
The number of non-equivalent protons adjacent to a given proton from the spin-spin splitting pattern, using the n+1 rule
Possible structures for the molecule
Note: 2 Exam Questions on Combined Techniques are also included in lesson 5!
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A practical lesson on the theory on precipitation and ligand substitution reactions of transition metals.
By the end of the practical lesson students should be able to:
LO1: To make observations of the reactions of Cu2+, Fe2+, Fe3+, Mn2+ and Cr3+ in aqueous sodium hydroxide and ammonia
LO2: To construct ionic equations for the redox reactions that take place
**
This lesson should be completed after students have made flashcard/notes on the theory lesson so that they are able to answer the practical questions (see ‘Precipitation and Ligand Substitution Reactions’ in my TES Shop for this lesson) **
Students are encouraged to continue to use their flashcards following this lesson to improve their recall on this topic
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons including using your own lesson PowerPoints is a fundamental skill of a qualified/unqualified teacher that will be reviewed during these scenarios outlined above
A complete lesson including starter activity, AfL work tasks, main work tasks and homework (all with answers included) on Synthetic Routes in Organic Synthesis (A level -Yr13)
By the end of this lesson KS5 students should be able:
i) To identify individual functional groups for an organic molecule containing several functional groups
ii) To predict the properties and reactions of organic molecules containing several functional groups
iii) To create multi-stage synthetic routes for preparing organic compounds
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons including using your own lesson PowerPoints is a fundamental skill of a qualified/unqualified teacher that will be reviewed during these scenarios outlined above
A structured A level Chemistry lesson including starter activity, AfL work tasks and lesson slides with answers on the rate determining step
By the end of this lesson KS5 students should be able to:
To explain and use the term rate determining step
To deduce possible steps in a reaction mechanism from the rate equation and the balanced equation for the overall reaction
To predict the rate equation that is consistent with the rate determining step
A structured Year 13 KS5 lesson ( lesson 1 of 2) on Concentration-Time Graphs. This lesson includes starter activity, worked examples and main work task. This lesson is part of the Year 13 topic on Rates which is also discussed in Year 12
By the end of this lesson KS5 students should be able to:
To know the techniques and procedures used to investigate reaction rates
To calculate reaction rates using gradients from concentration-time graphs
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons, including using your own lesson PowerPoints, is a fundamental skill of a qualified/unqualified teacher that will be assessed during the scenarios outlined above
A structured KS5 lesson including starter activity and AfL work tasks with answers included on Standard Electrode & Cell Potentials (Part 1 of 2)
By the end of this lesson KS5 students should be able:
**To describe techniques and procedures used for the measurement of :
**i) Cell potentials of metals or non-metals in contact with their ions in aqueous solution
**ii) Ions of the same element in different oxidation states in contact with a Pt electrode
The teacher will be able to check students have met these learning objectives through mini AfL tasks for students to complete
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons, including using your own lesson PowerPoints, is a fundamental skill of a qualified/unqualified teacher that will be assessed during the scenarios outlined above
A structured KS5 lesson including starter activity and AfL work tasks on Storage and Fuel Cells
**By the end of this lesson KS5 students should be able to:
**LO1: To understand the application of the principles of electrode potentials to modern storage cells
**LO2: To explain that a fuel cell uses the energy from a reaction of a fuel with oxygen to produce a voltage
**LO3: To derive the reactions that take place at each electrode in a hydrogen fuel cell
The teacher will be able to check students have met these learning objectives through mini AfL tasks for students to complete
All tasks have worked out answers, which will allow students to self assess their work during the lesson
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons, including using your own lesson PowerPoints, is a fundamental skill of a qualified/unqualified teacher that will be assessed during the scenarios outlined above
5 Full Lesson Bundle which covers the lessons on aromatic compounds from the OCR A Level Chemistry Specification. See below for the lesson objectives
Lesson 1: Benzene and its Structure
To describe the Kekulé model of benzene
To describe the delocalised model of benzene in terms of P orbital overlap forming a delocalised π system
To compare the Kekulé model of benzene and the delocalised model of benzene
To explain the experimental evidence which supports the delocalised model of benzene in terms of bond lengths, enthalpy change of hydrogenation and resistance to reaction
Lesson 2: Naming Aromatic Compounds
State the IUPAC name of substituted aromatic compounds
Construct the structure of aromatic compounds based on their IUPAC names
Analyse the correct numbering system for di and trisubstituted aromatic compounds
Lesson 3: The Reactions of Benzene
To understand the electrophilic substitution of aromatic compounds with:
(i) concentrated nitric acid in the presence of concentrated sulfuric acid
(ii) a halogen in the presence of a halogen carrier
(iii) a haloalkane or acyl chloride in the presence of a halogen carrier (Friedel–Crafts reaction) and its importance to synthesis by formation of a C–C bond to an aromatic ring
To construct the mechanism of electrophilic substitution in arenes
Lesson 4: Phenols
To recall and explain the electrophilic substitution reactions of phenol:
with bromine to form 2,4,6-tribromophenol
(ii) with dilute nitric acid to form a mixture of 2-nitrophenol and 4-nitrophenol
(j) To explain the relative ease of electrophilic substitution of phenol compared with benzene, in terms of electron pair donation to the π-system from an oxygen p-orbital in phenol
To understand the weak acidity of phenols shown by its neutralisation reaction with NaOH but absence of reaction with carbonates
Lesson 5: Directing Groups in Aromatic Compounds
To understand the 2- and 4-directing effect of electron- donating groups (OH, NH2) and the 3-directing effect of electron-withdrawing groups (NO2) in electrophilic substitution of aromatic compounds
To predict the substitution products of aromatic compounds by directing effects in organic synthesis
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons including using your own lesson PowerPoints is a fundamental skill of a qualified/unqualified teacher that will be reviewed during these scenarios outlined above
7 Full Lesson Bundle + A Bonus Revision Lesson which covers the Kinetics (How Fast?) chapters from the OCR A Level Chemistry Specification (also suitable for the AQA and Edexcel Spec- see Learning Objectives below)
Lesson 1: Order of Reactants
Lesson 2: The Rate Equation
Lesson 3&4 Concentration-Time Graphs
Lesson 5: Initial Rates and Clock Reactions
Lesson 6: The Rate Determining Step
Lesson 7: The Arrhenius Equation
Lesson 8: Revision Lesson
Learning Objectives:
Lesson 1:
LO1: To recall the terms rate of reaction, order, overall order and rate constant
LO2: To describe how orders of reactants affect the rate of a reaction
LO3: To calculate the overall order of a reaction
Lesson 2:
LO1: To determine the order of a reactant from experimental data
LO2: To calculate the rate constant, K, from a rate equation
LO3: To calculate the units of the rate constant
Lesson 3&4:
LO1: To know the techniques and procedures used to investigate reaction rates
LO2: To calculate reaction rates using gradients from concentration-time graphs
LO3: To deduce zero & first order reactants from concentration-time graphs
LO4: To calculate the rate constant of a first order reactant using their half-life
Lesson 5:
LO1: To determine the rate constant for a first order reaction from the gradient of a rate- concentration graph
LO2: To understand how rate-concentration graphs are created
LO3: To explain how clock reactions are used to determine initial rates of reactions
Lesson 6:
LO1: To explain and use the term rate determining step
LO2: To deduce possible steps in a reaction mechanism from the rate equation and the balanced equation for the overall reaction
LO3: To predict the rate equation that is consistent with the rate determining step
Lesson 7:
LO1: Explain qualitatively the effect of temperature change on a rate constant,k, and hence the rate of a reaction
LO2: To Know the exponential relationship between the rate constant, k and temperature, T given by the Arrhenius equation, k = Ae–Ea/RT
LO3: Determine Ea and A graphically using InK = -Ea/RT+ InA derived from the Arrhenius equation
Lesson 8:
This is an engaging KS5 revision lesson the Kinetics topic in A Level Chemistry (Year 13)
Students will be able to complete three challenging question rounds on kinetics covering:
Measuring Reaction Rates
Orders of reactants
Concentration-time graphs
Rate-concentration graphs
Clock Reactions
Initial rates
Arrhenius Equation
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons, including using your own lesson PowerPoints, is a fundamental skill of a qualified/unqualified teacher that will be assessed during the scenarios outlined above
A structured KS5 lesson including starter activity and AfL work tasks and main work tasks with answers on Dynamic Equilibrium and Le Chatelier’s Principle
By the end of the lesson students should be able to:
To explain the term dynamic equilibrium
To apply le Chatelier’s principle to homogeneous equilibria in order to deduce qualitatively the effect of a change in temperature, pressure or concentration on the position of equilibrium
To explain why catalysts do not change the position of equilibrium
To explain the importance to the chemical industry of a compromise between chemical equilibrium and reaction rate in deciding the operational conditions
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons, including using your own lesson PowerPoints, is a fundamental skill of a qualified/unqualified teacher that will be assessed during the scenarios outlined above
A complete lesson including starter activity, AfL work tasks and main work tasks (all with answers included) on the reactions and uses of esters. Suitable for AQA A level Chemistry
By the end of this lesson KS5 students should be able to:
To describe some common uses of esters
To construct equations for the hydrolysis of esters in acidic or alkaline conditions
To describe how soap and biodiesel are made and can write equations for these reactions for specified animal fats/ vegetable oils
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons including using your own lesson PowerPoints is a fundamental skill of a qualified/unqualified teacher that will be reviewed during these scenarios outlined above
A structured KS5 lesson including starter activity and AfL work tasks Ions & The Periodic Table. All tasks have answers included.
By the end of this lesson KS5 students should be able to:
To predict the ionic charge of ions based on the position of the element in the periodic table
To recall the names of common atomic and molecular ions
To be able write the formula of ionic compounds
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons including using your own lesson PowerPoints is a fundamental skill of a qualified/unqualified teacher that will be reviewed during these scenarios outlined above
A complete lesson including starter activity, mini AfL work tasks with answers, main work tasks with answers for a KS5 lesson on Atomic Structure & Isotopes.
By the end of the lesson students should be able to:
To describe the atomic structure of an atom
To describe atomic structure in terms of protons, neutrons and electrons for atoms and ions, given the atomic number, mass number and any ionic charge
To define the term isotopes and to identify the atomic structure of isotopes in terms of protons, neutrons and electrons
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons including using your own lesson PowerPoints is a fundamental skill of a qualified/unqualified teacher that will be reviewed during these scenarios outlined above
A structured Year 13 KS5 lesson ( lesson 2 of 2) on Concentration-Time Graphs. Lesson includes starter activity, worked examples and Afl quiz
By the end of this lesson KS5 students should be able to:
To deduce zero & first order reactants from concentration-time graphs
To calculate the rate constant of a first order reactant using their half-life
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons, including using your own lesson PowerPoints, is a fundamental skill of a qualified/unqualified teacher that will be assessed during the scenarios outlined above
A structured KS5 lesson including starter activity, AfL work tasks and main work task all with answers on Born Haber Cycles
By the end of this lesson KS5 students should be able to:
1.To construct Born Haber Cycle diagrams for ionic compounds from enthalpy change values
2.To calculate the value for lattice enthalpy from Born Haber Cycle diagrams
3.To calculate other enthalpy change values from Born Haber Cycle diagrams
All tasks have worked out answers, which will allow students to self assess their work during the lesson
Declaimer: Please refrain from purchasing this popular resource for an interview lesson or a formal observation. This is because planning your own lessons, including using your own lesson PowerPoints, is a fundamental skill of a qualified/unqualified teacher that will be assessed during the scenarios outlined above