This is a comprehensive lesson on atomic theory designed for the AQA GCSE specification. The starter is a recap crossword on atomic structure (assumed knowledge). The lesson then takes a chronological journey from the ancient Greeks to alchemy to the Enlightenment and then the 1800s/ early 1900s where Rutherford et al developed the modern model of the atom. The theory activity works really well with all ability and shows that there is little or no evidence to support the early cubic model but there lots of evidence to support the GCSE Bohr model. The lesson finishes with a 6 mark question that is peer marked using a marking grid. Please rate this resource and leave feedback.

This lesson forms part of the chemistry GCSE atomic structure scheme of work for the new 2016 AQA specification. The starter is a fun kinsthetic activity where students put element cards into groups. These cards are available to buy from Royal Society for Chemistry. A link is included on the slide. Alternatively students could make a pack of element fact cards for homework and bring them to lesson for the starter activity. Students are then introduced to Dobereiner and Newlands. They watch a 3 minute YouTube video about Mendeleev and answer the questions provided. Students then consider that Mendeleev missed group 8/0 elements and swapped iodine / tellurium so that the group 7 elements are all non-metals (i.e. why de not always put elements in order of increasing atomic weight). There is an activity where students consider the good and bad things about each scientists methodology and write an explanation for why we now use Mendeleevs table. Finally there is an exam question plenary. Please rate this resource and leave feedback.

This is a lesson for A level chemistry on fuel cells. It begins with getting students to consider whether hydrogen would be a good source of energy to power cars for the future. Required learning from previous lessons is electrode potentials and half cells. The hydrogen balloon demo could be shown at the start to get students to appreciate that a lot of energy is released in a short amount of time from a small amount of fuel. Hydrogen produces the most amount of energy per gram for any chemical fuel. Students then draw a diagram to show how the standard electrode potential of an oxygen half cell could be determined - i.e. use a H+ reference electrode in one beaker and connect using a salt bridge to another beaker with O2- ions and O2 gas being bubbled through and using platinum as the electrode. Students then learn that O2 gas is reduced in the presence of H2O (i.e. bubbled through water) to OH- ions not O2- ions. This forms the basis of the hydrogen fuel cell where oxygen is bubbled in to one beaker with a platinum (or carbon) electrode, hydrogen is bubbled into another beaker with a platinum (or carbon) electrode and a salt bridge is attached between the beakers. Students could carry out this practical in pairs by using balloons filled with hydrogen and oxygen and allowing the gases to escape under water in the 250ml beakers. Filter paper soaked in sodium hydroxide could act as the salt bridge. Students then compare different types of fuel cell and write overall equations. There is a 5 mark exam question that can be used as an end of lesson plenary or homework. Please rate this resource and leave feedback.

This is a thorough set of lesson resources designed to promote engagement, pace and sustained student progress through a 60 minute GCSE lesson on the evolution of the atmosphere. The lesson has been designed for the updated 2016 specification for exam board AQA and topic 4.9 Chemistry of the atmosphere. This is the first of a series of lessons on the atmosphere. Please read the lesson plan and lesson PowerPoint. The hook is students considering what pieces of information are needed to work out if life exists on other planets. Students may then consider the Drake equation (in the PPT) and the key question "what is the link between the evolution of the atmosphere and the evolution of life?". There is an Ammonium Dichromate volcano demo (see RSC link in lesson plan). The main activity is where students create a storyboard using detailed lamented sheets and then peer assess using a marking grid that suits higher and lower ability groups. Please rate this resource and leave feedback.

This is is a lesson for GCSE chemistry that matches the AQA new 2016 specification section 4.1 - atomic structure and the periodic table. The lesson begins with a fun film characters starter. There is then a discussion on how elements are made in supernovae. Students then consider rules for naming compounds and how to write formulae. They then then write the formulae for 12 substances. The challenge is to write empirical formulae. The lesson concludes with a consideration of how some of the chemicals are harmful to fish such as Nemo. Titanium dioxide in suntan cream causes water and oxygen in seawater to react to form hydrogen peroxide that is toixc to fish. Answers are included. Please rate this resource and leave feedback.

This is a fun KS3 chemistry tarsia for acids and alkalis. There are 16 triangles with 18 pairs of questions and answers that make a parallelogram. I suggest that the A4 tarsia is printed on card and then the outline is cut out. Students can then quickly cut out the individual triangles. Included are the following topics: indicator, pH meter, pH of different substances, formula of HCl and water. The software is free to download but there is not currently a version for Mac computers.

This is a thorough set of structured resources on mass spectrometry . The starter is a fun Just a Minute literacy activity that recaps GCSE understanding of mass spectrometry. There is then a highly structured series of slides that discuss how bond enthalpy (bond strength) data can be used to determine which bonds in a molecule will break. Slide 14 (bond enthalpy data) can be printed as a handout for the students to use for the grade C task. The grade B/A task is where students identify molecules from their mass spectrometry spectra. The mass spectra to be identified can be laminated and students can annotate the laminates using whiteboard pens. The answers and a markscheme is provided on the PowerPoint. Please rate this resource and leave feedback.

This is a lesson for A level chemistry on electrochemical cells. It starts with students constructing a fruit cell and combing four of these cells to make a battery that powers a light bulb . These are made from a whole lemon, piece of clean copper, piece of clean zinc, electrical wires, crocodile clips and light bulb. This could be shown as a demo if there is not much time. Students offer explanations as to how this works. They are introduced to the theory behind how batteries work, what a half cell is and notation for writing half cells and E-cell. The hydrogen / H+ / platinum reference electrode is then introduced as a standard that is used to compare the voltage different half cells. Reinforce the idea that platinum is used because it a very unreactive electrical conductor. Students then use the electrode potentials table (go through this) to write the voltage and reactions for different combinations of half cells. This could be set as homework instead. The lesson finishes with an exam question plenary. Please rate this resource and leave feedback.

This GCSE chemistry lesson has been designed for the 2016 specification for AQA. The lesson begins with a recap of addition and condensation polymers. It then moves on to covering the key biochemical points that students need to know for GCSE chemistry and deliberately leaves out GCSE biology content. The lesson then moves on to students comparing the strength of their own bioplastics from the previous lesson with nylon. If students make the bioplastics in this lesson then allow at least 2 days for the bioplastic to dry before testing it. The lesson concludes with students analysing their data. Please rate this resource leave feedback.

This is a thorough set of revision resources for GCSE chemistry revision on the fossil fuels topic - AQA topic 4.7 organic chemistry in the 2016 specification. Please rate this resource and leave feedback.

This GCSE chemistry lesson on transitions metals has been designed to meet the AQA 2016 specification and is part of the 4.1 atomic structure scheme of work. The lesson starts with a recap of the order of the reactivity series and asks students to put lithium and rubidium in this series using prior knowledge from reactions of the alkali metals (required prior learning). Students are then introduced to the key question for the lesson - this is revisited at the end. Students then watch a 4 minute video about the SR71 Blackbird (YouTube link is on the slide). This is the worlds fastest jet powered plane that is no longer used by the American military and flew at speeds of up to mach 3.2. Students then write on post it notes three properties that metals used to make this plane should have. If they struggle they could choose 3 properties from the data sheet. These are put on the whiteboard with their names on the notes and one student comes to the front to read out 3 post it notes. The teacher could compare the reactivity of iron filings and potassium with water (RSC practical link is included and can also be found online). Students then answer a few questions that require analysis of the data sheet. This is an important exam skill. They then use these answers to write an extended 6 mark question and then peer mark this using the student friendly marking grid. There is an optional 4 person role play task included in a separate PowerPoint for longer lessons or classes that are good with group work. The lesson menu can be printed and used with weaker students. Please rate this resource and leave feedback.

This is a lesson for Senior High School Chemistry on fuel cells. It begins with getting students to consider whether hydrogen would be a good source of energy to power cars for the future. Required learning from previous lessons is electrode potentials and half cells. The hydrogen balloon demo could be shown at the start to get students to appreciate that a lot of energy is released in a short amount of time from a small amount of fuel. Hydrogen produces the most amount of energy per gram for any chemical fuel. Students then draw a diagram to show how the standard electrode potential of an oxygen half cell could be determined - i.e. use a H+ reference electrode in one beaker and connect using a salt bridge to another beaker with O2- ions and O2 gas being bubbled through and using platinum as the electrode. Students then learn that O2 gas is reduced in the presence of H2O (i.e. bubbled through water) to OH- ions not O2- ions. This forms the basis of the hydrogen fuel cell where oxygen is bubbled in to one beaker with a platinum (or carbon) electrode, hydrogen is bubbled into another beaker with a platinum (or carbon) electrode and a salt bridge is attached between the beakers. Students could carry out this practical in pairs by using balloons filled with hydrogen and oxygen and allowing the gases to escape under water in the 250ml beakers. Filter paper soaked in sodium hydroxide could act as the salt bridge. Students then compare different types of fuel cell and write overall equations. There is a 5 mark exam question that can be used as an end of lesson plenary or homework. Please rate this resource and leave feedback.

This is a lesson for Senior High School Chemistry on electrochemical cells. It starts with students constructing a fruit cell and combing four of these cells to make a battery that powers a light bulb . These are made from a whole lemon, piece of clean copper, piece of clean zinc, electrical wires, crocodile clips and light bulb. This could be shown as a demo if there is not much time. Students offer explanations as to how this works. They are introduced to the theory behind how batteries work, what a half cell is and notation for writing half cells and E-cell. The hydrogen / H+ / platinum reference electrode is then introduced as a standard that is used to compare the voltage different half cells. Reinforce the idea that platinum is used because it a very unreactive electrical conductor. Students then use the electrode potentials table (go through this) to write the voltage and reactions for different combinations of half cells. This could be set as homework instead. The lesson finishes with an exam question plenary. Please rate this resource and leave feedback.

This is a comprehensive set of differentiated lesson resources that cover polar covalent bonding. Within the lesson are Pauling electronegativity values that can be used to determine the extent of covalent bonding between two atoms. The lesson begins with a recap of ionic and covalent bonding definitions from GCSE. There is then a discussion on electronegativity differences between atoms. Students then carry out the kinesthetic task where put different comments about bonding on a scale from pure covalent to pure ionic. This scale can be printed on A3 paper. The comments can be printed on A4 paper. There is then a peer editing question task and plenary exam questions with markschemes. Please rate this resource and leave feedback.

This is a lesson written for the AQA 2016 chemistry specification that covers the following: the three types of bonding, the reaction of sodium chlorine demo, how to work out the charge on an ion by comparing the number of protons and electrons, why ions form (stable octet) and how to work out the formula on an ionic compound using a method that I have created called 'WiSC'. The lesson concludes with a differentiated plenary. Please take the time to carefully look through this presentation before the lesson as there a lot of animations that carefully sequence different concepts. Please rate this resource and leave feedback.

This forms part of the chemistry scheme of work for the new 2016 specification. The homework task is set in advance so that students can mark their homework as a starter activity. There is an optional starter activity to show students as they walk in which is a recap of what atoms and elements are. The video is the worlds smallest video created by IBM. It shows atoms of an element moving around - the key point being that atoms of a particular element are identical. The first activity looks at understanding how to work out the number of subatomic particles. Students are then introduced to the concept of isotopes. The next activity looks at electron shells the more able students are introduced to ions. The lesson finishes with an exam question plenary. Please rate this resource and leave feedback.

This is a fully differentiated tarsia puzzle for conjugating French ER verbs in the present tense. It is a fun kinesthetic way of revising verb conjugation. It gets students to more fully understand spoken and written language by helping them appreciate that 'I play' is the same as 'I am playing' . This sort of revision activity is particularly useful for boys. There are 18 pairs of questions and answers written in 16 triangles. When properly assembled a large equilateral triangle is formed. Answers are provided as well an 'easy start' that provides 4 of the 16 triangles as a starting point for weaker students. The 'group 1 metals A4 2 page' is an A4 tarsia that has 8 triangles per page. I suggest that these are printed on card and students cut them out. They are great for AFL. end of lesson plenary or plenary. If the writing of the A4 tarsia is too small then use the medium version.

This is a lesson designed for the updated 2016 GCSE chemistry specification for AQA and was not previously included in additional science. Please rate this resource and leave feedback.

This is a lesson for the new 2016 AQA GCSE specification that forms part of the atomic structure scheme of work. Included in the lesson are links to RSC practical advice. Answers to the worksheet are provided. Please rate this resource and leave feedback.

This is a comprehensive set of information worksheets for revising Middle school Chemistry. It covers these topics: atoms and elements, periodic table, compounds, metals and non-metals, mixtures, solutions, acids and alkalis, physical changes, chemical changes, filtration, distillation, chromatography, structure of the Earth, composition of the atmosphere and the rock cycle. There is a simplified version of the periodic table that I have created. The pages are scaled to fit A4 paper.