By the end of the lesson learners will be able to:
Identify the 6 types of joints.
Describe how these joints allow movement.
Explain why some people are hypermobile or double jointed.
By the end of the lesson learners will be able to:
Identify the bones that make up the skeletal system.
Describe how muscles and bones interact.
Explain why a lack of food can affect a person’s structure and strength.
By the end of the lesson learners will be able to:
Identify the 8 energy stores.
Describe how energy can be transferred.
Justify the type of energy transfer within a system.
By the end of the lesson learners will be able to:
Identify the forces working during a crash.
Describe how the reduce the crashing force.
Explain why crumple zones and slower driving cause less damage during a crash.
By the end of the lesson learners will be able to:
Identify thinking and braking distances.
Describe how to calculate stopping distance.
Explain why the braking and thinking distances can change.
By the end of the lesson learners will be able to:
Identify the effect of force.
Describe how to calculate force.
Explain why mass and acceleration affects force.
By the end of the lesson learners will be able to:
Identify the effect of force.
Describe how to calculate force.
Explain why mass and acceleration affects force.
By the end of the lesson learners will be able to:
State the main components of the respiratory system.
Describe the function of the alveoli.
Explain why alveoli are specialised for gas exchange.
By the end of the lesson learners will be able to:
State the main components of the respiratory system.
Describe the mechanism of inspiration and exhalation.
Explain why choking and asthma affect an individual.
By the end of the lesson learners will be able to:
Identify the levels of organisation in a multicellular organism.
Describe how organisms use specific systems to survive.
Explain why one of these systems failing could affect the entire organism.
By the end of the lesson learners will be able to:
State what is meant by unicellular and multicellular.
Describe the functions of vacuoles within a unicellular organism.
Explain why unicellular organisms are able to survive without additional cells.
By the end of the lesson learners will be able to:
State what’s produced when an unstable atom breaks down.
Describe what is meant by half-life.
Explain why atoms with a high radioactivity will have a short half-life.
By the end of the lesson learners should be able to:
State the formula for speed.
Describe what’s shown in a distance-time graph
Explain why the gradient is the same as the speed on a distance-time graph.
Includes a simulation where you can use your webcam / student’s webcams to model distance time graphs based on movement toward / away from the screen.
By the end of the lesson learners will be able to:
State Newton’s First law.
Calculate Resultant Forces.
Explain why changing in speed requires a force.
By the end of the lesson learners will be able to:
Identify acceleration, constant velocity and deceleration on a velocity-time graph.
Describe how to calculate distance travelled using a velocity-time graph.
Compare the movement of two objects on a velocity-time graph.
By the end of the lesson learners should be able to:
State the equation for acceleration
Describe how to measure the acceleration of an object.
Explain why a change in acceleration indicates a change in direction
By the end of the lesson learners will be able to:
State the law of conservation of energy.
Describe what’s meant by energy efficiency.
Create Sankey diagrams.
By the end of the lesson learners should be able to:
Use groups and periods to identify specific elements.
Describe how elements are placed in the periodic table.
Compare the older version which included gaps with the modern periodic table.