A PPT (02+) with animated sequences demonstrating how the safety fuse requires a connection to earth in order for it melt during a fault. During animations a bar appears under the navigation buttons that wipes across until the animation has finished; it can be paused. For the buttons to work, the macro security level has to be set to medium. This is very easy and only needs to be done once; it will not compromise your computer. Select then then select. This is for ver. 2002; it might be different for later versions. COMMENTS WILL BE MUCH APPRECIATED

A PPT (02+) with animated sequences showing the major components and demonstrating how wind turbines turn the energy of the wind into electricity. During animations a bar appears under the navigation buttons that wipes across until the animation has finished; it can be paused. For the buttons to work, the macro security level has to be set to medium. This is very easy and only needs to be done once; it will not compromise your computer. Select then then select. This is for ver. 2002; it might be different for later versions. COMMENTS MUCH APPRECIATED

The main presentation is a PowerPoint with animated sequences showing the sizes and distances of the objects in the Solar System to scale, using two diagrams. 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 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 meant by the term solar system? Learning Outcomes Knowledge to identify the objects, and their order, in the Solar System to state the composition of the objects in the Solar System to identify the trends/patters in the Solar System 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 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 the rotation of the Earth results in night and day. 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 with 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: Why Do We Have Night And Day? Learning Outcomes Knowledge to describe the Earth’s 24 hour cycle and how this results in day and night to recognise the effect that the tilt of the Earth’s axis has on the northern and southern hemispheres Analysis to compare the relative times of day in different parts of the World. 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 the workings and purpose of electromagnetic relays. 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. 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 a low current be used to switch a high current? Learning Outcomes Knowledge to identify the components in an electromagnetic relay Comprehension to explain the workings of an electromagnetic relay 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 seismic activity reveals the layered structure 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. Normally, the activities would fill a 45 to 60 minute lesson but could be spread over two lessons if need 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 the Earth’s structure and how is it known? Learning Outcomes Knowledge to identify and describe the layered structures within the Earth Comprehension to explain how the outer core’s structure is known through seismic activity Differentiation The activities have varying degrees of differentiation; please refer to the Readme document.

The main presentation is a PowerPoint with animated sequences showingthe motions and relative sizes of the Sun, the Earth and the Moon. 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: What are the motions and relative sizes of the Sun, the Earth and the Moon? Learning Outcomes Knowledge to describe the main features of the Sun, the Earth and the Moon to describe the movement of the Sun, the Earth and the Moon 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.

The main presentation is a PowerPoint with animated sequences showing the relationship between voltage and current across a fixed resistance. 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 The Relationship Between Current, Voltage And Resistance? Learning Outcomes Knowledge to identify the components needed to investigate Ohm’s Law and to draw the circuit diagram to describe the effect that voltage has on current to describe the effect that heat has on resistance of conductors and semi-conductors Analysis to use Ohm’s Law to calculate voltage, current and resistance Differentiation The activities have varying degrees of differentiation; please refer to the Readme document.

A PPT (02+) with animated sequences demonstrating how the safety fuse requires a connection to earth in order for it melt during a fault. During animations a bar appears under the navigation buttons that wipes across until the animation has finished; it can be paused. For the buttons to work, the macro security level has to be set to medium. This is very easy and only needs to be done once; it will not compromise your computer. Select then then select. This is for ver. 2002; it might be different for later versions. COMMENTS WILL BE MUCH APPRECIATED