Spark Science provides high quality science educational resources for secondary school teachers.
From dual-coding, literacy and reading tasks, dyslexic friendly backgrounds, and continual Assessment for Learning (AfL) tasks embedded into all our lessons, Spark lessons will increase engagement, participation and understanding for your students.
Spark Science provides high quality science educational resources for secondary school teachers.
From dual-coding, literacy and reading tasks, dyslexic friendly backgrounds, and continual Assessment for Learning (AfL) tasks embedded into all our lessons, Spark lessons will increase engagement, participation and understanding for your students.
A comprehensive, engaging, challenging and interactive lesson package designed with non-science/non-chemistry specialist teachers in mind!
This lesson contains:
Lesson powerpoint - including teacher notes and answers in “notes” section
Student led lesson worksheet
Teacher answer sheet
Lesson resources contain:
In-built challenge tasks throughout
In-built scaffolded learning for lower abilities
Various activites to assess progress and understanding that you can tailor to fit any class or available resources
Objectives:
Students will be able to…
Identify elements in chemical formula (using a periodic table)
Count the number of atoms in formulas containing subscripts
Count the number of atoms in formulas containing multipliers
This lesson contains a student led lesson sheet, with the focus being on students learning through doing and practicing skills and identifying patterns and reasons themselves. Resources and slides ask students the key questions and develops ideas and concepts from the ground up and address common issues, mistakes and misconceptions.
This lesson contains AFL tasks which require mini-whiteboards, but can be adapted if these are not available.
This lesson is designed for AQA combined and triple chemistry.
This lesson builds on the previous lesson (Introduction to Electrolysis) where students looked at the basic set up for electrolysis and predicted which ion would be attracted to which electrode and why.
This lesson introduces the keywords anode, cathode, anion, cation, as well describing if ions gain or lose electrons at an electrode and are oxidised/reduced.
**Lesson Objectives: **
Identify anions and cations
Explain the movement of metal and non-metal ions to the anode and cathode
Describe and explain what happens to ions at the anode and cathode
Identify if an element is being oxidised or reduced at the electrode
This Lesson Contains:
Complete lesson powerpoint with teaching guidance in notes section, complete answers for all tasks, mini-whiteboard AFL assessment quizzes, animations to describe the movement of ions and the gain or loss of electrons in electrolysis
A printable cheat sheet for students explaining definitions and which ion is attracted to which electrode (editable and PDF)
This lesson is designed for AQA GCSE Chemistry and introduces electrolysis as a way of extracting metals from ores/metal compounds.
Lesson Objectives:
Name the parts of the electrolysis practical
Carry out a basic practical for the electrolysis of copper chloride
Predict the products of the electrolysis of a molten salt
Explain why we use electrolysis to extract metals
This Lesson Contains:
Lesson Powerpoint, including all answers and powerpoint notes to aid delivery and challenge tasks and mini-whiteboard AFL quiz
Blank electrolysis diagram handout for printing (editable and PDF)
Student worksheet/table (editable and PDF)
Complete answers
Practical risk assessment and instructions
A full lesson designed for GCSE chemistry AQA specification.
This lesson covers the case study of the extraction of aluminium oxide, the role of cryolite, what happens to the aluminium and oxide ions at the electrodes, and the need for the replacement of the positive electrode.
This lesson contains
A lesson powerpoint including all useful youtube video links, interactive plenary multiple choice quiz, electroplating challenge task and complete answers.
A guided reading activity with quesitons and complete answer sheet (PDF and editable versions)
An alternative information hunt sheet to be used with videos and/or the AQA GCSE Chemistry textbook, with complete answers (PDF and editable versions)
Video clip to aid in completion of both sheets
Lesson Objectives
State two reasons why extracting aluminium oxide from its ore is expensive
Describe why cryolite is added to aluminium oxide during electrolysis
Describe and explain what happens to ions at the positive and negative electrode (and give relevant half equations (Higher only))
Explain why the positive electrode must continually be replaced
A comprehensive, engaging, challenging and interactive lesson package designed with non-science/non-chemistry specialist teachers in mind!
This lesson contains:
Lesson powerpoint - including teacher notes and answers in “notes” section
Student led lesson worksheet (including practical worksheet)
Teacher answer sheet
Practical risk assessment/order form
Lesson resources contain:
In-built challenge tasks throughout
In-built scaffolded learning for lower abilities
Various activites to assess progress and understanding that you can tailor to fit any class or available resources
Objectives:
Students will be able to…
Describe what a pure substance is
Identify examples of pure substances in every day life
Identify pure substances from particle diagrams and examples
Carry out a practical investigation to identify pure substances
This lesson contains a student led lesson and practical which focuses on students learning through discussion and investigation.
Resources and slides ask students the key questions and develops ideas and concepts from the ground up and address common issues, mistakes and misconceptions.
This lesson contains AFL tasks which require mini-whiteboards, but can be adapted if these are not available.
A comprehensive, complete, engaging and challenging set of lessons and activities to teach students the basics of elements, compounds, mixtures and chemical formulas. This scheme/package is designed with non-science/non-chemistry specialist teachers in mind!
Lessons included in this bundle:
Elements and Compounds
Chemical Formulas
Counting atoms in a Formula
Pure Substances
Mixtures
Included in each lesson:
Lesson powerpoint - including teacher notes and answers in “notes” section
Student-led lesson worksheet
Teacher answer sheet
Lesson resources contain:
In-built stretch and challenge tasks throughout
In-built scaffolded learning for lower abilities
Various AFL activities to assess progress and understanding that you can tailor to fit any class or available resources (these include “think, pair, share”, molymod activities, mini-whiteboard quizzes)
Relevant risk assessments for any practical work (updated as of March 2023)
By the end of the topic, students will:
Know what an “element” and a “compound” is
Describe the difference between an element and a compound
Know what an “atom” and a “molecule” are
Describe the difference between an atom and a molecule
Draw/make particle diagrams and models to represent elements, compounds, single atoms and molecules
Understand why scientists use chemical symbols to represent elements
Identify simple elements from their chemical symbols
Identify elements in a chemical formula
Classify chemical formulas as elements or compounds
Count the number of atoms in a basic formula
Identify elements in a chemical formula
Count the number of atoms in formulas containing subscripts
Count the number of atoms in formulas containing multipliers
Describe what a pure substance is
Identify examples of pure substances in everyday life
Identify pure substances from particle diagrams and examples
Carry out a practical investigation to identify pure substances
Describe what a mixture is
Give examples of mixtures in everyday life
Identify mixtures from particle diagrams and examples
Draw/make models representing mixtures
A comprehensive, engaging and interactive lesson package designed with non-science/non-chemistry specialist teachers in mind!
This lesson contains:
Lesson powerpoint - including teacher notes and answers in “notes” section
Student led lesson worksheet
Teacher answer sheet
Elements, Compounds and Mixtures printable decision tree
Lesson resources contain:
In-built challenge tasks throughout
In-built scaffolded learning for lower abilities
Various activites to assess progress and understanding that you can tailor to fit any class or available resources
Objectives:
Students will be able to…
Describe what a mixture is
Give examples of mixtures in every day life
Identify mixtures from particle diagrams and examples
This lesson contains a student led lesson sheet, with the focus being on students learning through doing, practicing skills and identifying patterns and reasons themselves. Resources and slides ask students the key questions and develops ideas and concepts from the ground up and address common issues, mistakes and misconceptions.
This lesson contains AFL tasks which require mini-whiteboards and molymods, but can be adapted if these are not available.
A comprehensive, engaging, challenging, and interactive lesson package designed with non-science/non-chemistry specialist teachers in mind.
This lesson covers content from GCSE AQA Chemistry and Combined Science Trilogy.
It covers the properties, structure and bonding in graphite and diamond, as well as explaining the key properties of diamond and graphite (electrical conductivity, melting point, hardness) to its structure and bonding.
This lesson contains:
Lesson powerpoint - including teacher notes, delivery instructions and answers in “notes” section
Bank of exam style questions on graphite and diamond taken from past AQA papers with mark schemes (PDF and editable versions)
Printable images of graphite and diamond for students to annotate (PDF and editable versions)
Lesson resources contain:
In-built challenge tasks throughout
AFL mini-whiteboard tasks throughout
In-built scaffolded learning for lower abilities and alternative task for lower ability classes
Colour coding throughout to aid EAL, SEN and other learners
Various activites to assess progress and understanding that you can tailor to fit any class or available resources
Full answers to all questions (mostly automated into slides to make it easier for you to deliver)
Objectives:
Students will be able to…
State some properties of diamond and graphite
Compare the properties of diamond and graphite
Compare the structure and bonding in diamond and graphite
Explain the similarities and differences in the properties of diamond and graphite in terms of structure and bonding
A lesson resource for teaching the possible applications, advantages and disadvantages of nanoparticles and nanotechnology.
Lesson/Resource Outcomes:
State possible uses of nanoparticles
Describe advantages of using nanoparticles
Describe some of the possible risks of using nanoparticles
Resource contains
Student worksheet (pdf and word doc)
Complete answer sheet (pdf and word doc)
5 A4/A3 printable information/newspaper article sheets (Reading level 3-4) on the uses of nanoparticles in medicine, electronics, cosmetics, clothing and catalysts
Exam question set on nanotechnology & mark schemes
A comprehensive, engaging, challenging and interactive lesson package designed with AEN students and non-science/non-chemistry specialist teachers in mind!
This lesson contains:
Lesson powerpoint - including teacher notes and answers in “notes” section
Student led lesson worksheet
Teacher answer sheet
Practical and Demonstration Risk Assessments
Lesson resources contain:
In-built challenge tasks throughout
In-built scaffolded learning for lower abilities
AFL activities to assess progress and understanding that you can tailor to fit any class or available resources
Objectives:
Students will be able to…
Predict whether a chemical reaction under given conditions will get lighter, heavier or stay the same mass
Explain why some chemical reactions might appear to get lighter
Explain why some chemical reactions might appear to get heavier
This lesson contains a student led lesson sheet, with the focus being on students learning through doing, practicing skills and identifying patterns and reasons themselves. Resources and slides ask students the key questions and develops ideas and concepts from the ground up and address common issues, mistakes and misconceptions.
A full lesson covering how students can calculate relative formula mass.
This lesson is suitable for students studying AQA Trilogy Combined Science (higher and foundation) and AQA Triple chemistry (higher and foundation)
Lesson Objectives
Recall how to count the number of atoms in a formula
Recall what relative atomic mass is
Define what relative formula mass is
Calculate the relative formula mass of a chemical using a periodic table
Lesson includes
Lesson powerpoint - including recap of how to count atoms in a formula an how to find relative atomic mass on a periodic table, worked examples with answers, and BINGO plenary practice game
Optional worksheet with answers (PDF and editable word version)
A lesson pack covering negative non-metal ion tests (halide, sulfate and carbonate).
This resource is designed for the AQA Triple Chemistry required practical from “Chemical Analysis”, and is relevant to higher and foundation students.
Lesson Objectives
Carry out simple precipitate tests to identify halide, sulfate and carbonate ions
Describe how to carry out precipitate tests to test for halide, sulfate and carbonate ions, including the names of any important reactants
Write balanced symbol and ionic equations for the reactions taking place in precipitation reactions
This resource contains:
Lesson powerpoint - including starter activity, practical instructions, tables, challenge task, multiple choice quiz plenary, and full answers
Student worksheet - including practical instructions, tables, and practical quesitons (PDF and editable word versions)
Student worksheet answers (PDF and editable word versions)
Risk assessment/order form - containing up to date CLEAPPS guidance as of Oct 2023.
This bundle contains the lessons, powerpoints and all relevant resources for teaching the Separate Science GCSE Chemistry AQA content on electrochemical cells and fuel cells.
This bundle contains 3-4 lessons of content including:
Lesson 1: What are Electrochemical Cells?
Lesson Objectives:
Describe what an electrochemical cell is and what we use it for
Describe how to make an electrochemical cell
Identify factors which affect the size of the voltage produced by an electrochemical cell
This lesson contains:
Lesson powerpoint
Student practical investigation
Teacher notes on how to deliver lesson slides/content and answers
Lesson 2: How do Electrochemical Cells Work?
Lesson Objectives:
Recall the definitions for oxidation and reduction
Identify which elements are oxidised and reduced in an electrochemical cell
(H) – write half equations for oxidation and reduction taking place in electrochemical cells
Explain why alkaline/non-rechargeable batteries eventually stop working
This lesson contains:
Lesson powerpoint, containing animation about how electrochemical cells produce electrical current and the reactions that take place within it
Student exam questions (23 marks worth) from AQA syllabus with mark scheme
Teacher notes on how to deliver lesson slides/content and answers
Lesson 3/4: What are Fuel Cells?
Lesson Objectives:
Describe, in basic terms, how a hydrogen fuel works
(Higher only) write balanced half equations for the reactions taking place inside a hydrogen fuel cell
Describe advantages and disadvantages of hydrogen fuel cells
Evaluate the use of hydrogen fuel vehicles compared to electric and petrol vehicles
Lesson resources include:
Lesson powerpoint with printable diagrams for students
Explanations of half equations from fuel cell (both acid cell (not AQA) and alkaline cell (AQA) version) and balancing them
Relevant video links
6 marker question and mark scheme
Exam question pack on fuel cells and energy
Plenary AFL multiple choice quiz and debate activity
This lesson is the first lesson in the Year 8 “Working as a Scientist” topic.
It covers what accurate and precise data means/looks like, as well as the difference between a prediction and a hypothesis.
This lesson is designed with formative assessment in mind and a large use of hand/finger voting and mini-whiteboards for AFL feedback.
It contains all answers to the tasks and is great for a non-specialist science teacher.
Lesson Objectives:
Write a hypothesis from variables
Describe the difference between accurate and precise
I will work scientifically to:
Identify variables in a practical
Identify data that is accurate and precise
This lesson contains:
Powerpoint - including quizzes to test understanding, student questions to answer, challenge tasks throughout, and full answers. The powerpoint also uses colour-coding to help support AEN and EAL students follow and understand concepts in the lesson.
This is the last lesson in the Year 8 “Working as a Scientist 2” Topic.
It covers types of evidence, sources of bias in research and evidence, the process of peer-reviewing and what things we should look for when deciding whether evidence (and the conclusions drawn from it) is good.
This lesson is an interactive lesson filled with student activities and participation, including finger voting, class discussions/debates, and mini-whiteboard tasks.
This lesson is designed to be “click and teach” and will require very little planning by the teacher, and with teacher delivery notes and all answers built into the slides it is perfect for non-specialists and those a little uncertain about the lesson content.
Lesson Resources contain:
Lesson powerpoint including class discussions, finger voting AFL tasks, whiteboard AFL tasks, discussion slides, careers links, plenary task, student summary questions, and full answers throughout
Lesson outcomes:
Describe how to assess sources of evidence
Identify possible sources of bias
Describe what a peer-review is
This is the 5th lesson in the “Working as a Scientist 2” Year 8 topic.
This lesson teaches students how to identify relationships in graphs using the line of best fit and how to describe trends in graphs. It also covers the ways we can improve our confidence in graphs/data, how to deal with outliers, and how to read values from a graph using the line of best fit.
It is a comprehensive lesson, with large amounts of student participation on mini-whiteboards (so loads of chances for AFL and intervention if needed). The lesson can be lenghtened or shortened with slides cut out depending on student ability and prior knowledge.
Students can then practice their skills independently by drawing and analysing their own graph on the student worksheet.
Lesson resources:
Lesson powerpoint with all answers built in automatically, various mini-whiteboard AFL tasks for students, discussion activities, scaffolding and dual coding to support lower ability/EAL/AEN students.
Student worksheet PDF
Student worksheet answers PDF
Lesson objectives:
Identify linear and directly proportional relationships
Take readings from a graph using a line of best fit
Describe how to improve confidence in conclusions made from graphs
For this lesson you will need mini-whiteboards
A full lesson outlining the basic GCSE structure of the atom, the position and charges of the subatomic particles inside it. A part of the course which is sometimes difficult to teach in a fun and interactive/discovery based way, this lesson will help students to discover information and make connections themselves. Students will hopefully not only learn the charges and masses and positions of subatomic particles, but gain an appreciation of scale and relative mass, as well as understand some of the reasons behind the structure of the atom and the reason we draw it the way we do.
This lesson includes:
Powerpoint - including key notes, delivery tips, modelling ideas, interactive class activities and key hinge/get-them-thinking questions, tips on dealing with common misconceptions
Multiple choice interactive plenary activity
Full answers
Lesson Objectives
Describe what a subatomic particle is
Describe the structure of an atom in terms of subatomic particles
Give the positions, relative mass and charge of the three subatomic particles
This resource contains a worksheet where students can practice drawing ionic bonding for a range of examples.
Examples get harder as the sheet progresses. First questions are structured with electron shells and brackets drawn for them.
Resource contains PDF copy and an editable PPT version.
Fully drawn answer sheet attached at the end of each document.
A resource for AS and A-Level students to help practice naming and drawing alkanes, alkenes, alcohols and haloalkanes using the IUPAC naming system. Students can practice structural, displayed and skeletal formula drawing as well as naming in this booklet.
All answers included.
Designed for the UK curriculum (OCR, AQA, Edexcel)
