1.2.1
Friction
Friction, Drag and Air Resistance
Friction, Drag and Air Resistance
When an object travels through a medium, it interacts with the particles in that medium. This can slow the object down or provide lift.
Friction
Friction
- Friction is the resistance to motion due to contact forces.
- Usually, an object experiences friction due to collisions with particles in air or a rough surface of a solid.
- Friction always opposes motion, meaning that it slows down moving objects.
- Friction converts kinetic energy into other types of energy, mainly heat.
- This is why brakes on a car can overheat if used too much.
Drag
Drag
- Drag is a frictional force.
- Objects that travel through a liquid or gas experience drag.
- Drag is due to collisions between the travelling object and the particles in the medium.
- The faster an object moves through a medium, the larger the drag.
- Drag is also affected by the shape of an object (how streamlined it is).
Air resistance
Air resistance
- Air resistance is a type of drag.
- Air resistance is a frictional force which opposes the motion of an object travelling through air.
Lift on a Wing
Lift on a Wing
A moving wing can experience lift. Lift is an upward force due to the collisions with air particles on the underside of the wing.
Equal and opposite force
Equal and opposite force
- Lift is a result of Newton's Third Law of Motion:
- Every action has an equal and opposite reaction.
- The wing of a plane pushes air particles downward as it flies forward.
- As a result of this downward force on the air particles, there is an equal and opposite upward force on the wing.
- This force is called lift.
- This is the basic principle of how aeroplanes fly.
Shape of the wing
Shape of the wing
- The wing is angled to maximise the amount of air it can push downwards, thereby generating the maximum force upwards.
- The wing is also smooth and slightly curved to reduce drag forces and turbulence.
1Space, Time & Motion
1.1Motion
1.2Forces
1.3Momentum & Impulse
2The Particulate Nature of Matter
2.1Thermal Concepts
3Wave Behaviour
3.1Oscillations
3.2Travelling Waves
3.3Wave Characteristics
3.4Wave Behaviour
3.5Standing Waves
3.6Simple Harmonic Motion
3.7Single Slit Diffraction
3.8Interference
3.9Doppler Effect
4Fields
4.1Circular Motion
4.2Newton's Law of Gravitation
4.3Fields
4.4Fields at Work
4.5Electric Fields
4.6Magnetic Effect of Electric Currents
4.7Heating Effect of Currents
4.8Electromagnetic Induction
4.9Power Generation & Transmission
5Nuclear & Quantum Physics
5.1Discrete Energy & Radioactivity
5.2Nuclear Reactions
5.3The Interaction of Matter with Radiation
6Measurements
6.1Measurements & Errors
6.2Uncertainties & Errors
6.3Vectors & Scalars
Jump to other topics
1Space, Time & Motion
1.1Motion
1.2Forces
1.3Momentum & Impulse
2The Particulate Nature of Matter
2.1Thermal Concepts
3Wave Behaviour
3.1Oscillations
3.2Travelling Waves
3.3Wave Characteristics
3.4Wave Behaviour
3.5Standing Waves
3.6Simple Harmonic Motion
3.7Single Slit Diffraction
3.8Interference
3.9Doppler Effect
4Fields
4.1Circular Motion
4.2Newton's Law of Gravitation
4.3Fields
4.4Fields at Work
4.5Electric Fields
4.6Magnetic Effect of Electric Currents
4.7Heating Effect of Currents
4.8Electromagnetic Induction
4.9Power Generation & Transmission
5Nuclear & Quantum Physics
5.1Discrete Energy & Radioactivity
5.2Nuclear Reactions
5.3The Interaction of Matter with Radiation
6Measurements
6.1Measurements & Errors
6.2Uncertainties & Errors
6.3Vectors & Scalars
Unlock your full potential with Seneca Premium
Unlimited access to 10,000+ open-ended exam questions
Mini-mock exams based on your study history
Unlock 800+ premium courses & e-books