The main presentation is a PowerPoint with animated sequences showing the structure of the Rutherford-Bohr atomic model Support Material Readme (instructions for whole lesson) Learning Outcomes (PowerPoint) Starter Activity (PowerPoint and Worksheet) Main Activity (PowerPoint with worksheets and answer sheets) Lesson Notes (hand-out) Plenary Activity (PowerPoint and worksheet) It is intended for all science teachers but particularly those who are not physics specialists. It is, primarily, aimed at 14 to 16 year old pupils but can also be used at a higher level as a precursor to a more in-depth study of this topic. Normally, the activities would fill a 60 minute lesson but could be spread over two lessons if needs be. If you buy this resource, please print the Readme document as it contains the instructions and details of the files included. Learning Outcomes The learning outcomes are based on Bloom’s taxonomy of hierarchical classification: knowledge, comprehension, application, analysis, synthesis and evaluation. The lesson title and learning outcomes are: How Does Atomic Number Dictate Position In The Periodic Table? Learning Outcomes Knowledge to state the properties of sub-atomic particles to define atomic number and mass number Comprehension to state the difference between group number and period number Analysis to calculate the number of neutrons from the mass number and atomic number Differentiation The activities have varying degrees of differentiation; please refer to the Readme document.

The main presentation is a PowerPoint with animated sequences showing the effect of balanced and unbalanced forces on a racing car. Support Material Readme (instructions for whole lesson) Learning Outcomes (PowerPoint) Starter Activity (PowerPoint and Worksheet) Main Activity (PowerPoint with worksheets and answer sheets) Lesson Notes (hand-out) Plenary Activity (PowerPoint and worksheet) It is intended for all science teachers but particularly those who are not physics specialists. It is, primarily, aimed at 14 to 16 year old pupils but can also be used at a higher level as a precursor to a more in-depth study of this topic. Normally, the activities would fill a 45 to 60 minute lesson. If you buy this resource, please print the Readme document as it contains the instructions and details of the files included. Learning Outcomes The learning outcomes are based on Bloom’s taxonomy of hierarchical classification: knowledge, comprehension, application, analysis, synthesis and evaluation. The lesson title and learning outcomes are: Can an object move if the forces acting on it are balanced? Learning Outcomes Knowledge to to identify the forces acting on a moving object to describe the effect of balanced and unbalanced forces on moving and stationary objects Analysis To calculate the size and direction of a resultant force Differentiation The activities have varying degrees of differentiation; please refer to the Readme document.

The main presentation is a PowerPoint with animated sequences showing how current behaves in a series circuit. Support Material Readme (instructions for whole lesson) Learning Outcomes (PowerPoint) Starter Activity (PowerPoint and Worksheet) Main Activity (PowerPoint with worksheets and answer sheets) Lesson Notes (hand-out) Plenary Activity (PowerPoint and worksheet) It is intended for all science teachers but particularly those who are not physics specialists. It is, primarily, aimed at 11 to 14 year old pupils but can also be used at a higher level as a precursor to a more in-depth study of this topic. Normally, the activities would fill a 45 to 60 minute lesson. If you buy this resource, please print the Readme document as it contains the instructions and details of the files included. Learning Outcomes The learning outcomes are based on Bloom’s taxonomy of hierarchical classification: knowledge, comprehension, application, analysis, synthesis and evaluation. The lesson title and learning outcomes are: How does electricity work in a series circuit? Learning Outcomes Knowledge to identify the parts of a filament lamp to describe the energy transfers that take place in a filament lamp to state the number of charge carriers (electrons) at any point in a series circuit Differentiation The activities have varying degrees of differentiation; please refer to the Readme document.

The main presentation is a PowerPoint with animated sequences showing the radioactive decay series of uranium 238. Support Material Readme (instructions for whole lesson) Learning Outcomes (PowerPoint) Starter Activity (PowerPoint and Worksheet) Main Activity (PowerPoint with worksheets and answer sheets) Lesson Notes (hand-out) Plenary Activity (PowerPoint and worksheet) It is intended for all science teachers but particularly those who are not physics specialists. It is, primarily, aimed at 14 to 16 year old pupils but can also be used at a higher level as a precursor to a more in-depth study of this topic. Normally, the activities would fill a 45 to 60 minute lesson but could be spread over two lessons if needs be. If you buy this resource, please print the Readme document as it contains the instructions and details of the files included. Learning Outcomes The learning outcomes are based on Bloom’s taxonomy of hierarchical classification: knowledge, comprehension, application, analysis, synthesis and evaluation. The lesson title and learning outcomes are: Why does uranium turn into lead in 4.5 billion years? Learning Outcomes Knowledge to recognise the effect that radioactive decay has on the atomic number and the mass number of a radioisotope Analysis to calculate the change in atomic number and mass number due to alpha and beta emissions Differentiation The activities have varying degrees of differentiation; please refer to the Readme document.

The main presentation is a PowerPoint with animated sequences showing the conditions under which the nucleus of a large atom can be split by absorbing a neutron. Support Material Readme (instructions for whole lesson) Learning Outcomes (PowerPoint) Starter Activity (PowerPoint and Worksheet) Main Activity (PowerPoint with worksheets and answer sheets) Lesson Notes (hand-out) Plenary Activity (PowerPoint and worksheet) It is intended for all science teachers but particularly those who are not physics specialists. It is, primarily, aimed at 14 to 16 year old pupils but can also be used at a higher level as a precursor to a more in-depth study of this topic. Normally, the activities would fill a 45 to 60 minute lesson but could be spread over two lessons if needs be. If you buy this resource, please print the Readme document as it contains the instructions and details of the files included. Learning Outcomes The learning outcomes are based on Bloom’s taxonomy of hierarchical classification: knowledge, comprehension, application, analysis, synthesis and evaluation. The lesson title and learning outcomes are: How is it possible to split the nucleus of an atom? Learning Outcomes Comprehension to recognise the forces acting in the nucleus of an atom to explain the processes involved in nuclear fission Differentiation The activities have varying degrees of differentiation; please refer to the Readme document.

The main presentation is a PowerPoint with animated sequences showing the differences between solids, liquids and gases. Support Material Readme (instructions for whole lesson) Learning Outcomes (PowerPoint) Starter Activity (PowerPoint and Worksheet) Main Activity (PowerPoint with worksheets and answer sheets) Lesson Notes (hand-out) Plenary Activity (PowerPoint and worksheet) It is intended for all science teachers but particularly those who are not physics specialists. It is, primarily, aimed at 14 to 16 year old pupils but can also be used for younger pupils as a precursor to a more in-depth study of this topic. Normally, the activities would fill a 45 to 60 minute lesson. If you buy this resource, please print the Readme document as it contains the instructions and details of the files included. Learning Outcomes The learning outcomes are based on Bloom’s taxonomy of hierarchical classification: knowledge, comprehension, application, analysis, synthesis and evaluation. The lesson title and learning outcomes are: What Is The Difference Between Solids, Liquids and Gases? Learning Outcomes Knowledge to describe the arrangement and motion of particles in solids, liquids and gases. to state the properties of solids, liquids and gases. Differentiation The activities have varying degrees of differentiation; please refer to the Readme document.

The main presentation is a PowerPoint with animated sequences showing how light is refracted as it changes speed at a boundary Support Material Readme (instructions for whole lesson) Learning Outcomes (PowerPoint) Starter Activity (PowerPoint and Worksheet) Main Activity (PowerPoint with worksheets and answer sheets) Lesson Notes (hand-out) Plenary Activity (PowerPoint and worksheet) It is intended for all science teachers but particularly those who are not physics specialists. It is, primarily, aimed at 14 to 16 year old pupils but can also be used at a higher level as a precursor to a more in-depth study of this topic. Normally, the activities would fill a 45 to 60 minute lesson but could be spread over two lessons if needs be. If you buy this resource, please print the Readme document as it contains the instructions and details of the files included. Learning Outcomes The learning outcomes are based on Bloom’s taxonomy of hierarchical classification: knowledge, comprehension, application, analysis, synthesis and evaluation. The lesson title and learning outcomes are: How is it possible to tell the difference between diamond and glass? Learning Outcomes Knowledge to describe how the change in speed of light at a boundary affects its direction to recognise that light slows down by different amounts in different transparent materials Analysis to calculate the change in direction of light at different boundaries Differentiation The activities have varying degrees of differentiation; please refer to the Readme document.

The main presentation is a PowerPoint with animated sequences using a crossbow to show how strain energy is calculated Support Material Readme (instructions for whole lesson) Learning Outcomes (PowerPoint) Starter Activity (PowerPoint and Worksheet) Main Activity (PowerPoint with worksheets and answer sheets) Lesson Notes (hand-out) Plenary Activity (PowerPoint and worksheet) It is intended for all science teachers but particularly those who are not physics specialists. It is, primarily, aimed at over 16 year old pupils but could also be used for younger pupils. Normally, the activities would fill a 45 to 60 minute lesson. If you buy this resource, please print the Readme document as it contains the instructions and details of the files included. Learning Outcomes The learning outcomes are based on Bloom’s taxonomy of hierarchical classification: knowledge, comprehension, application, analysis, synthesis and evaluation. The lesson title and learning outcomes are: How do crossbows work? Learning Outcomes Comprehension To state the relationship between: energy, force and extension force, the spring constant and extension energy, the spring constant and extension Analysis to calculate the strain energy stored in a stretched object Differentiation The activities have varying degrees of differentiation; please refer to the Readme document.

The main presentation is a PowerPoint with animated sequences showing how a variable resistor controls current. Support Material Readme (instructions for whole lesson) Learning Outcomes (PowerPoint) Starter Activity (PowerPoint and Worksheet) Main Activity (PowerPoint with worksheets and answer sheets) Lesson Notes (hand-out) Plenary Activity (PowerPoint and worksheet) It is intended for all science teachers but particularly those who are not physics specialists. It is, primarily, aimed at 11 to 14 year old pupils but can also be used at a higher level as a precursor to a more in-depth study of this topic. Normally, the activities would fill a 45 to 60 minute. If you buy this resource, please print the Readme document as it contains the instructions and details of the files included. Learning Outcomes The learning outcomes are based on Bloom’s taxonomy of hierarchical classification: knowledge, comprehension, application, analysis, synthesis and evaluation. The lesson title and learning outcomes are: How do Dimmer Switches Work? Learning Outcomes Knowledge to state how a variable resistor can control the total resistance of a circuit to state how the total resistance of a circuit affects the current flowing through the components Differentiation The activities have varying degrees of differentiation; please refer to the Readme document.

The main presentation is a PowerPoint with animated sequences showing how a polar orbiting satellite produces an image of the Earth. Support Material Readme (instructions for whole lesson) Learning Outcomes (PowerPoint) Starter Activity (PowerPoint and Worksheet) Main Activity (PowerPoint with worksheets and answer sheets) Lesson Notes (hand-out) Plenary Activity (PowerPoint and worksheet) It is intended for all science teachers but particularly those who are not physics specialists. It is, primarily, aimed at 14 to 16 year old pupils but can also be used for younger pupils as a precursor to a more in-depth study of this topic. Normally, the activities would fill a 45 to 60 minute lesson. If you buy this resource, please print the Readme document as it contains the instructions and details of the files included. Learning Outcomes The learning outcomes are based on Bloom’s taxonomy of hierarchical classification: knowledge, comprehension, application, analysis, synthesis and evaluation. The lesson title and learning outcomes are: How do Spy Satellites Work? Learning Outcomes Knowledge to describe the motion of polar orbiting satellites relative to the rotation of the Earth and the Sun to list the uses of polar orbiting satellites Comprehension to explain how polar orbiting satellites produce a two dimensional image of the three dimensional Earth Differentiation The activities have varying degrees of differentiation; please refer to the Readme document.

The main presentation is a PowerPoint with animated sequences showing the processes involved in changing from a solid to a liquid to a gas Support Material Readme (instructions for whole lesson) Learning Outcomes (PowerPoint) Starter Activity (PowerPoint and Worksheet) Main Activity (PowerPoint with worksheets and answer sheets) Lesson Notes (hand-out) Plenary Activity (PowerPoint and worksheet) It is intended for all science teachers but particularly those who are not physics specialists. It is, primarily, aimed at 14 to 16 year old pupils but can also be used for younger pupils as a precursor to a more in-depth study of this topic. Normally, the activities would fill a 45 to 60 minute lesson. If you buy this resource, please print the Readme document as it contains the instructions and details of the files included. Learning Outcomes The learning outcomes are based on Bloom’s taxonomy of hierarchical classification: knowledge, comprehension, application, analysis, synthesis and evaluation. The lesson title and learning outcomes are: What processes are involved when substances change state? Learning Outcomes Knowledge to define the processes whereby substances change state to recognise the connection between particle motion and state Differentiation The activities have varying degrees of differentiation; please refer to the Readme document.

The main presentation is a PowerPoint with animated sequences showing how, with a sufficient amount of fissile radioisotopes a nuclear chain reaction can take place. Support Material Readme (instructions for whole lesson) Learning Outcomes (PowerPoint) Starter Activity (PowerPoint and Worksheet) Main Activity (PowerPoint with worksheets and answer sheets) Lesson Notes (hand-out) Plenary Activity (PowerPoint and worksheet) It is intended for all science teachers but particularly those who are not physics specialists. It is, primarily, aimed at 14 to 16 year old pupils but can also be used at a higher level as a precursor to a more in-depth study of this topic. Normally, the activities would fill a 45 to 60 minute lesson but could be spread over two lessons if needs be. If you buy this resource, please print the Readme document as it contains the instructions and details of the files included. Learning Outcomes The learning outcomes are based on Bloom’s taxonomy of hierarchical classification: knowledge, comprehension, application, analysis, synthesis and evaluation. The lesson title and learning outcomes are: What is a nuclear chain reaction? Learning Outcomes Knowledge to describe the different fissile properties of uranium-238 and uranium-235 to outline the conditions for a nuclear chain reaction Differentiation The activities have varying degrees of differentiation; please refer to the Readme document.

The main presentation is a PowerPoint with animated sequences showing how how radiation can lead to the ionization of atoms. Support Material Readme (instructions for whole lesson) Learning Outcomes (PowerPoint) Starter Activity (PowerPoint and Worksheet) Main Activity (PowerPoint with worksheets and answer sheets) Lesson Notes (hand-out) Plenary Activity (PowerPoint and worksheet) It is intended for all science teachers but particularly those who are not physics specialists. It is, primarily, aimed at 14 to 16 year old pupils but can also be used at a higher level as a precursor to a more in-depth study of this topic. Normally, the activities would fill a 45 to 60 minute lesson. If you buy this resource, please print the Readme document as it contains the instructions and details of the files included. Learning Outcomes The learning outcomes are based on Bloom’s taxonomy of hierarchical classification: knowledge, comprehension, application, analysis, synthesis and evaluation. The lesson title and learning outcomes are: How can radiation change the properties of an atom? Learning Outcomes Knowledge to state the different types of ionizing radiation and their relative ionizing strengths to state the dangers of ionizing radiation Comprehension to explain the process of physical ionization Differentiation The activities have varying degrees of differentiation; please refer to the Readme document.

The main presentation is a PowerPoint with animated sequences showing how a voltage is induced across a coil of wire as a magnetic field cuts through it. Support Material Readme (instructions for whole lesson) Learning Outcomes (PowerPoint) Starter Activity (PowerPoint and Worksheet) Main Activity (PowerPoint with worksheets and answer sheets) Lesson Notes (hand-out) Plenary Activity (PowerPoint and worksheet) It is intended for all science teachers but particularly those who are not physics specialists. It is, primarily, aimed at 14 to 16 year old pupils but can also be used at a higher level as a precursor to a more in-depth study of this topic. Normally, the activities would fill a 45 to 60 minute lesson but could be spread over two lessons if needs be. If you buy this resource, please print the Readme document as it contains the instructions and details of the files included. Learning Outcomes The learning outcomes are based on Bloom’s taxonomy of hierarchical classification: knowledge, comprehension, application, analysis, synthesis and evaluation. The lesson title and learning outcomes are: How Can electricity Be Generated Using Magnetism? Learning Outcomes Knowledge to describe the effect a magnetic field has on a conductor to identify the factors that determine the size of the induced voltage in a conductor Differentiation The activities have varying degrees of differentiation; please refer to the Readme document.