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NEWTON’S LAWS OF MOTION
QCAA Physics Grade 11-12 Study Guide
Physics | QCAA | Grade 11, 12
π· NEWTON’S LAWS OF MOTION – COMPLETE STUDY NOTES (QCAA aligned, Grade 11–12)
Newton’s Laws of Motion (Grade 11 Physics)
πΆ 1. Introduction to Newton’s Laws
Newton’s Laws describe how forces affect motion. They form the foundation of classical mechanics.
π A force is a push or pull that can:
Change speed
Change direction
Change shape (in some cases)
Unit of force:
\( 1 \, N = 1 \, kg.ms^{-2} \)
πΆ 2. Newton’s First Law – Law of Inertia
π· Statement
An object remains at rest or moves with constant velocity unless acted upon by a net external force.
π· Mathematical Form
\( \Sigma F = 0 \Rightarrow a = 0 \)
\( \Sigma F \) = net force
-
If net force is zero → no acceleration
π· What is Inertia?
Inertia is the tendency of an object to resist changes in its motion.
π· Types of Inertia
-
Inertia of Rest
→ Object resists starting motion -
Inertia of Motion
→ Object resists stopping -
Inertia of Direction
→ Object resists change in direction
π· Examples
Passenger jerks backward when a bus starts
Seatbelts prevent forward motion during braking
A book stays at rest unless pushed
π· Key Concept: Equilibrium
When:
\( \Sigma F = 0 \)
Two types:
-
Static equilibrium → object at rest
-
Dynamic equilibrium → moving with constant velocity
πΆ 3. Newton’s Second Law – Force and Acceleration
π· Statement
The acceleration of an object is directly proportional to the net force and inversely proportional to its mass.
π· Mathematical Form
\( \Sigma F = m a \)
Where:
\( F \) = net force (N)
\( m \) = mass (kg)
\( a \) = acceleration (m/s²)
π· Key Insights
Larger force → greater acceleration
Larger mass → smaller acceleration
-
Acceleration is in the direction of net force
π· Vector Form (Important)
\( \vec{F} = m \vec{a} \)
π This means:
Direction matters
Components must be resolved
π· Free Body Diagrams (FBD)
A Free Body Diagram shows all forces acting on an object.
Steps to Draw FBD:
Represent object as a point/box
Draw all forces acting on it
Label forces clearly
Choose coordinate axes
π· Common Forces
| Force | Symbol | Direction |
|---|---|---|
| Weight | \( mg \) | Downward |
| Normal | \( N \) | Perpendicular to surface |
| Friction | \( f \) | Opposes motion |
| Tension | \( T \) | Along string |
| Applied | \( F \) | Given direction |
π· Example (Step-by-Step)
A 2 kg object is pushed with 10 N force.
\( a = \dfrac{F}{m} = \dfrac{10}{2} = 5 , \text{m/s}^2 \)
π· Important Extension
If multiple forces act:
\( \Sigma F = F_1 + F_2 + ... \)
Resolve into components:
\( \Sigma F_x = m a_x \)
\( \Sigma F_y = m a_y \)
πΆ 4. Newton’s Third Law – Action and Reaction
π· Statement
For every action, there is an equal and opposite reaction.
π· Mathematical Representation
\( \vec{F}_{AB} = - \vec{F}_{BA} \)
π· Key Features
-
Forces occur in pairs
Equal in magnitude
Opposite in direction
-
Act on different objects
π· Examples
-
Walking:
Foot pushes ground backward
Ground pushes you forward
-
Rocket propulsion:
Gases pushed downward
Rocket moves upward
-
Gun recoil:
Bullet forward
Gun backward
π· Important Clarification
❗ Action-reaction forces do not cancel out because:
-
They act on different bodies
πΆ 5. Linking All Three Laws
| Law | Key Idea |
|---|---|
| First Law | Defines inertia and equilibrium |
| Second Law | Quantifies force and motion |
| Third Law | Explains force interactions |
πΆ 6. Problem-Solving Strategy (QCAA Focus)
π· Step-by-Step Approach
Identify all forces
Draw Free Body Diagram
Choose coordinate system
Resolve forces into components
-
Apply:
\( \Sigma F = ma \) Solve algebraically
Check units and direction
πΆ 7. Common Mistakes
❌ Ignoring friction or normal force
❌ Forgetting direction (vector
nature)
❌ Confusing action-reaction pairs
❌ Not resolving
forces on inclined planes
❌ Assuming motion means net force ≠ 0
πΆ 8. Neurological Learning Insight π§
-
Concept of inertia strengthens intuitive physics reasoning
-
Drawing FBDs improves visual-spatial processing
-
Repeated force analysis builds logical sequencing skills
π Tip: Practice converting real-life situations into force diagrams.
πΆ 9. Quick Summary
-
First Law:
\( \Sigma F = 0 \Rightarrow \text{no acceleration} \) -
Second Law:
\( \Sigma F = ma \) -
Third Law:
\( \text{Action = – Reaction} \)
QCAA-aligned study notes on Inertia and its Types, including applications, examples, and higher-order thinking skills (HOTS).
π· INERTIA – COMPLETE STUDY NOTES
πΆ 1. What is Inertia?
Inertia is the natural tendency of an object to resist any change in its state of motion.
This includes resistance to:
Starting motion
Stopping motion
Changing direction
π· Key Idea (Newton’s First Law)
\( \Sigma F = 0 \Rightarrow \text{State of motion remains unchanged} \)
π If no net force acts:
Object at rest → stays at rest
Moving object → continues with constant velocity
π· Factor Affecting Inertia
-
Mass is the measure of inertia
π More mass → more inertia → harder to change motion
πΆ 2. Types of Inertia
π· A. Inertia of Rest
πΆ Definition
The tendency of an object to remain at rest unless acted upon by an external force.
πΆ Everyday Examples
A book remains on the table until pushed
Dust particles come out when a carpet is beaten
Passenger jerks backward when a bus starts
πΆ Applications
-
Beating carpets → removes dust due to inertia of rest
-
Shaking tree branches → fruits fall off
-
Starting engines smoothly → reduces sudden jerk
πΆ Explanation
When the supporting object moves suddenly:
-
The object tends to stay in its original position (rest)
Hence relative motion is observed
π· B. Inertia of Motion
πΆ Definition
The tendency of a moving object to continue moving with the same velocity unless acted upon by an external force.
πΆ Everyday Examples
Passenger jerks forward when a bus stops
A rolling ball continues moving on a smooth surface
A cyclist keeps moving even after stopping pedaling
πΆ Applications
-
Seat belts → prevent forward motion during braking
-
Braking systems → designed to overcome inertia
-
Runways in airports → long distances needed to stop planes
πΆ Explanation
When motion is suddenly opposed:
-
The object tends to keep moving forward
External force (friction/brakes) is needed to stop it
π· C. Inertia of Direction
πΆ Definition
The tendency of an object to resist changes in its direction of motion.
πΆ Everyday Examples
Passengers lean sideways when a car turns
A stone tied to a string moves in a circle
Planets revolve around the Sun
πΆ Applications
-
Banking of roads → helps vehicles turn safely
-
Centrifuges → separate substances using circular motion
-
Sports (cricket, football) → controlling direction of motion
πΆ Explanation
Changing direction requires a centripetal force:
-
Without it → object continues in straight line (due to inertia)
πΆ 3. Comparison of Types of Inertia
| Type | State | Resists |
|---|---|---|
| Inertia of Rest | At rest | Starting motion |
| Inertia of Motion | Moving | Stopping motion |
| Inertia of Direction | Moving | Change in direction |
πΆ 4. Higher Order Thinking Skills (HOTS) Applications
π· 1. Conceptual Analysis
❓ Why do passengers fall sideways when a bus turns?
π Due to inertia of direction:
Body wants to continue in straight line
Bus changes direction → imbalance occurs
π· 2. Real-Life Problem Solving
❓ Why are heavy trucks harder to stop than bicycles?
π Because:
-
Truck has greater mass → greater inertia of motion
Requires larger braking force
π· 3. Critical Thinking
❓ If friction is removed completely, what happens to a moving object?
π It will:
Continue moving forever with constant velocity
-
Demonstrates pure inertia of motion
π· 4. Application-Based Question
❓ Why do we bend forward while running on a curved track?
π To:
Counteract inertia of direction
Maintain balance by adjusting center of mass
π· 5. Experimental Thinking
❓ How would you demonstrate inertia of rest at home?
π Example experiment:
Place a coin on a card over a glass
-
Flick the card → coin falls into glass
✔ Shows object tends to remain at rest
πΆ 5. Common Misconceptions
❌ “Objects need force to keep moving”
✔ Truth: Force is needed to
change motion, not maintain it
❌ “Heavier objects fall faster due to inertia”
✔ Truth: Falling depends
on gravity, not inertia alone
❌ “Inertia is a force”
✔ Truth: Inertia is a property,
not a force
πΆ 6. Neurological Learning Insight π§
-
Understanding inertia builds intuitive physics reasoning
-
Real-life examples strengthen long-term conceptual memory
-
Visualizing motion improves brain’s spatial processing ability
π Tip: Always connect inertia with real-life motion experiences
πΆ 7. Quick Summary
Inertia = resistance to change in motion
-
Depends on mass
-
Three types:
Rest
Motion
Direction
-
Linked to:
\( \Sigma F = 0 \)
