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 complete lesson including starter activity, mini AfL work tasks with answers, main work tasks with answers for a KS5 lesson on naming organic compounds
By the end of the lesson students should be able to:
Know the IUPAC rules for naming alkanes and alkenes
Know the IUPAC rules for naming aldehyde, ketones and carboxylic acids
Construct structural or displayed formulae from named organic compounds and name organic compounds from the structural or displayed formulae
Students will be able to take rich notes on naming organic compounds, building on their KS4 knowledge on this topic
The teacher will be able to quickly assess students’ understanding of the how to name organic compounds by carrying our mini AfL tasks either on mini white boards or in students’ books
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 lesson slides on the properties of alkenes. This lesson is an introduction to the chapter on alkenes. This lesson follows the OCR specification.
By the end of the lessons students should be able:
1)To know the general formula of alkenes
2)To explain the shape and bond angle around each carbon atom of a C=C bond
3)To describe how π and σ bonds are formed in alkenes**
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 the acid dissociation constant Ka
By the end of this lesson KS5 students should be able to:
To understand the acid dissociation constant, Ka, as the extent of acid dissociation
To know the relationship between Ka and pKa
To convert between Ka and pKa
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 Bronsted Lowry Acids and Bases
By the end of this lesson KS5 students should be able to:
To describe the difference between a BrØnsted Lowry acid and base
To identify conjugate acid-base pairs
To explain the difference between monobasic, dibasic and tribasic acids
To understand the role of H+ in the reactions of acids with metals and bases (including carbonates, metal oxides and alkalis), using ionic equations
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 Mass Spectrometry in Organic Chemistry. Suitable for OCR AS Chemistry.
By the end of the lesson, students should be able to:
Use a mass spectrum of an organic compound to identify the molecular ion peak and hence to determine molecular mass
2)Perform analysis of fragmentation peaks in a mass spectrum to identify parts of structures
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 and plenary quiz on Transition Metals & Their Compounds. All answers included
**By the end of this lesson KS5 students should be able to:
To know the electron configuration of atoms and ions of the d-block elements of Period 4 (Sc–Zn), given the atomic number and charge
2.To understand the elements Ti–Cu as transition elements
To illustrate, using at least two transition elements, of:
(i) the existence of more than one oxidation state for each element in its compounds
(ii) the formation of coloured ions
(iii) the catalytic behaviour of the elements and their compounds and their importance in the manufacture of chemicals by industry
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 reviewed during these scenarios outlined above
A structured KS5 lesson including starter activity, AfL work tasks and main work task all with answers on Periodicity: Melting Points
By the end of this lesson KS5 students should be able to:
To describe the trend in structure from giant metallic to giant covalent to simple molecular lattice
To explain the variation in melting points across period 2 & 3 in terms of structure and bonding
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 12 KS5 lesson including starter activity and AfL work tasks on The Boltzmann Distribution. Suitable for OCR Specification (AS Chemistry)
By the end of this lesson KS5 students should be able to:
**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
A complete lesson including starter activity, risk assessment and post practical plenary questions on Chemistry Required Practical :Preparing a pure, dry sample of a soluble salt from an insoluble oxide or carbonate
Lesson includes lab report for students to fill in
By the end of this lesson KS4 students should be able to:
→ Describe a practical procedure for producing a salt from a solid and an acid
→ Explain the apparatus, materials and techniques used for making the salt
→ Describe how to safely manipulate apparatus and accurately measure melting points
This lesson should be taught as a practical 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 and lesson slides on mass changes when gases are in reactions. Suitable for AQA GCSE Chemistry and combined science (higher and foundation)
The lesson begins with a short starter task (DO NOW) on gases in reactions
Then by the end of this lesson KS4 students should be able to:
To relate mass, volume and concentration
To calculate the mass of solute in solution
To relate concentration in mol/dm3 to mass and volume
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
Lesson 3 of 3 on Redox Reactions in AS Chemistry. This lesson focuses on FORMING REDOX EQUATIONS. This lesson includes starter activity, mini AfL work tasks with answers, main work tasks with answers (NOTE: Lesson 1, 2 and 3 are available as a bundle resource). This topic is also likely to be recapped in Year 13 when students are introduced to redox reactions and electrode potentials
By the end of the lesson students should be able to:
Identify what substance has been reduced or oxidised in a redox reaction
Construct balanced half equations by adding H+ and H2O
Construct full ionic redox equations from half equations
Students will be able to take rich notes on this topic
The teacher will be able to quickly assess students’ understanding of forming redox equations by carrying our mini AfL tasks either on mini white boards or in students’ books
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 on initial rates and clock reactions
By the end of this lesson KS5 students should be able to:
To determine the rate constant for a first order reaction from the gradient of a rate- concentration graph
To understand how rate-concentration graphs are created
To explain how clock reactions are used to determine initial rates of reactions
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 (Part 1 of 2) including starter activity, AfL work tasks and practice questions with answers on Group 2 Elements
By the end of this lesson KS5 students should be able to:
Know group 2 elements lose their outer shell s2 electrons to form +2 ions
State and explain the trend in first and second ionisation energies of group 2 elements and how this links to their relative reactivities with oxygen, water and dilute acids
Construct half equations of redox reactions of group 2 elements with oxygen, water and dilute acids and to identify what species have been oxidised and reduced using oxidation numbers
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 (lesson 1 of 2) including starter activity, AfL work tasks and practice questions with answers on Redox Reactions. Suitable for Year 13 OCR A Level Chemistry
**By the end of this lesson KS5 students should be able to:
LO1: To identify the oxidation numbers of elements in ions and compounds
LO2: To construct half-equations from redox equations
LO3: To explain and use the terms oxidising agent and reducing agent
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 structured KS5 lesson including starter activity, AfL work tasks and practice questions with answers on Gibbs Free Energy (Part 1)
By the end of this lesson KS5 students should be able:
To explain that the feasibility of a process depends upon ΔG being negative which in turn depends upon ΔS, ΔH and the T of the system
To recall the Gibbs’ Equation and calculate ΔG, ΔH, ΔS or T
To calculate ΔG, ΔH, ΔS or T using the Gibbs’ Equation
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
6 Full Lesson Bundle covering the first 6 chapters in the OCR A Level Chemistry Chapter on Energy
Lesson 1: Lattice Enthalpy
**By the end of the lesson students will:
Explain the term lattice enthalpy
Understand the factors that determine the size of lattice enthalpy
Explain the terms standard enthalpy change of formation and first ionisation energy**
Lesson 2: Born-Haber Cycles
**By the end of the lesson students will:
**1. Construct Born Haber Cycle diagrams for ionic compounds from enthalpy change values
**2. Calculate the value for lattice enthalpy from Born Haber Cycle diagrams
**3. Calculate other enthalpy change values from Born Haber Cycle diagrams
Lesson 3: Enthalpy Changes of Solution & Hydration
**By the end of the lesson students will:
**1. Define the terms enthalpy change of solution and hydration
**2. Construct enthalpy cycles using the enthalpy change of solution of a simple ionic solid
3. Qualitatively explain the effect of ionic charge and ionic radius on the exothermic value of lattice enthalpy and enthalpy change of hydration
Lesson 4: Entropy
**By the end of lesson students will:
**1. Know that entropy is a measure of the dispersal of energy in a system, which is greater the more disordered a system
**2. Explain the difference in entropy of solids, liquids and gases
**3. Calculate the entropy change of a reactant based on the entropies provided for the reactants and products
Lesson 5: Gibbs Free Energy (Part 1)
**By the end of the lesson students will:
**1. Explain that the feasibility of a process depends upon ΔG being negative which in turn depends upon ΔS, ΔH and the T of the system
**2. Recall the Gibbs’ Equation and calculate ΔG, ΔH, ΔS or T
**3.Calculate ΔG, ΔH, ΔS or T using the Gibbs’ Equation
Lesson 6: Gibbs Free Energy (Part 2)
By the end of the lessons students will:
1. Explain that the feasibility of a process depends upon ΔG being negative which in turn depends upon ΔS, ΔH and the T of the system
2. Recall the Gibbs’ Equation and calculate ΔG, ΔH, ΔS or 3. Calculate ΔG, ΔH, ΔS or T using the Gibbs’ Equation
The teacher will be able to check students have met these learning objectives through starter activities, discussion questions, mini AfL tasks and practice questions 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
Well structured KS5 Lesson on Benzene and its structure. The lesson contains starter activities, discussion questions and mini AfL quizzes and practice questions, all with answers included
By the end of the lesson students should:
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
4.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
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
6 Full Lesson Bundle (includes a bonus lesson) on the topic of Equilibrium from the OCR A Level Chemistry specification plus an end of topic test. See below for the lessons and learning objectives
Lesson 1: Le Chatelier’s Principle
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
Lesson 2: The Equilibrium Constant Kc (Part 1)
To construct expressions for the equilibrium constant Kc for homogeneous reactions
To calculate the equilibrium constant Kc from provided equilibrium concentrations
To estimate the position of equilibrium from the magnitude of Kc
To know the techniques and procedures used to investigate changes to the position of equilibrium for changes in concentration and temperature
Lesson 3: The Equilibrium Constant Kc (Part 2)
To construct expressions for the equilibrium constant Kc for homogeneous and heterogeneous reactions
To calculate units for Kc
To calculate quantities present at equilibrium and therefore kc given appropriate data
Lesson 4: Controlling The Position of Equilibrium (Kc)
To understand and explain the effect of temperature, concentration, pressure and catalysts on Kc and controlling the position of equilibrium
Lesson 5: The Equilibrium Constant Kp
To use the terms mole fraction and partial pressure
To construct expressions for Kp for homogeneous and heterogeneous equilibria
To calculate Kp including determination of units
To understand the affect of temperature, pressure, concentration and catalysts on Kp and controlling the position of equilibrium
Lesson 6 (BONUS): Chemical Equilibirum (Practical Skills):
To understand how a titration experiment can be used to calculate the equilibrium constant, Kc
To understand how a colorimeter can be used to calculate the equilibrium constant, Kc
To analyse exam questions based on titration experiments in order to calculate out Kc
End of Topic Test:
A 45 minute end of chapter test on chemical equilibrium. The test covers content from both year 12 and 13 OCR on chemical equilibrium. A markscheme with model answers is also included which enables students self assess their answers in class with their teacher or as a homework task.
The test is based on the following learning objectives:
Apply le Chatelier’s principle to deduce qualitatively (from appropriate information) the effect of a change in temperature, concentration or pressure, on a homogeneous system in equilibrium.
Explain that a catalyst increases the rate of both forward and reverse reactions in an equilibrium by the same amount resulting in an unchanged position of equilibrium
Deduce, for homogeneous and heterogeneous reactions, expressions for the equilibrium constant Kc.
Calculate the values of the equilibrium constant, Kc (from provided or calculated equilibrium moles or concentrations), including determination of units.
Estimate the position of equilibrium from the magnitude of Kc.
Calculate, given appropriate data, the concentration or quantities present at equilibrium.
Deduce, for homogeneous and heterogeneous reactions, expressions for the equilibrium constant Kp.
Calculate the values of the equilibrium constant, Kp (from provided or calculated equilibrium moles or pressures), including determination of units.
Explain the effect of changing temperature on the value of Kc or Kp for exothermic and endothermic reactions.
State that the value of Kc or Kp is unaffected by changes in concentration or pressure or by the presence of a catalyst.
Explain how Kc or Kp controls the position of equilibrium on changing concentration, pressure and temperature
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
27 flashcards on Reaction Mechanisms from both Year 12 and 13 content. Suitable for the AQA A level Chemistry 7405 Specification
Reaction mechanisms included are:
Free Radical Substitution
Nucleophilic Substitution
Electrophilic Addition
Elimination
Electrophilic Substitution
Nucelophilic Addition
Nucelophilic Addition-Elimination
PRINTING: These can be printed as A6 flashcards (1/4 size of A4) by printing four pages per sheet
A complete lesson including starter activity, AfL work tasks and main work tasks (all with answers included) on proton NMR Spectroscopy (part 2)
NOTE: This lesson can be purchased as a bundle with proton NMR Spectroscopy (part 1)
By the end of this lesson KS5 students should be able to:
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
2 Bonus Questions on Combined Techniques are also included in this 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 reviewed during these scenarios outlined above
