Gravitation
Universal gravitation, g and weight, buoyancy (NCERT Ch. 10).
Gravitation
What you'll learn
- Universal Law of Gravitation — Newton's formula; what G is.
- The difference between G (universal constant) and g (acceleration due to gravity).
- Why objects fall with the same acceleration regardless of mass.
- Buoyancy and Archimedes' Principle — why things float or sink.
Key concepts
Universal Law of Gravitation (Newton, 1687)
Every object in the universe attracts every other object with a force that is directly proportional to the product of their masses and inversely proportional to the square of the distance between them.
F = G × m₁ × m₂ / r²
| Symbol | Meaning | Value/Unit |
|---|---|---|
| F | Gravitational force | N |
| G | Universal gravitational constant | 6.674 × 10⁻¹¹ N·m²/kg² |
| m₁, m₂ | Masses of two objects | kg |
| r | Distance between centres | m |
- G is the same everywhere in the universe.
- Discovered by Cavendish (1798) experimentally.
- This law explains: falling objects, Moon's orbit, tides, planetary motion.
Key relationships:
- Double the mass of one object → F doubles.
- Double the distance → F reduces to 1/4 (inverse square law).
- Triple the distance → F reduces to 1/9.
Why the Moon orbits Earth
- Earth's gravity pulls Moon inward (centripetal force).
- Moon's tangential velocity prevents it from falling → it orbits.
- Same principle: Earth orbits Sun; satellites orbit Earth.
Free fall and acceleration due to gravity (g)
- Free fall: motion of an object under gravity alone (no other force).
- All objects fall with the same acceleration in vacuum regardless of mass.
- Proof: F = GMm/r² and F = ma → a = GM/r² (m cancels out!)
- g = acceleration due to gravity near Earth's surface = 9.8 m/s² ≈ 10 m/s².
g = GM_Earth / R_Earth²
Where M_Earth = 6 × 10²⁴ kg, R_Earth = 6.4 × 10⁶ m.
g varies with location:
| Location | g value | Reason |
|---|---|---|
| Poles | Slightly higher | Earth is flatter at poles → closer to centre |
| Equator | Slightly lower | Earth bulges at equator → farther from centre |
| Mountains | Lower | Greater distance from Earth's centre |
| Moon | 1.63 m/s² (1/6 of Earth) | Moon's mass is much less |
| Deep mines | Slightly lower | Less mass below |
Weight vs Mass
| Mass | Weight | |
|---|---|---|
| Definition | Amount of matter | Force of gravity on the object |
| Formula | — | W = mg |
| Unit | kg | N (Newtons) |
| Constant? | Yes — same everywhere | Changes with location (varies with g) |
| Zero gravity | Has mass | Weightless (W = 0) |
- A 70 kg person on Earth: W = 70 × 9.8 = 686 N.
- Same person on Moon: W = 70 × 1.63 = 114 N (1/6 of Earth weight).
- In space (g ≈ 0): W ≈ 0 → weightlessness.
Equations of motion under gravity
Using kinematic equations with a = g (downward):
| Situation | Equation |
|---|---|
| Object falling (downward +ve) | v = u + gt; s = ut + ½gt²; v² = u² + 2gs |
| Object thrown upward | Replace g with −g; at max height, v = 0 |
| Time to reach max height | t = u/g |
| Max height | H = u²/2g |
Buoyancy
- Buoyant force (upthrust): upward force exerted by a fluid (liquid or gas) on an object immersed in it.
- Direction: always upward (opposite to gravity).
- Cause: pressure increases with depth → pressure on bottom face > pressure on top face → net upward force.
Factors affecting buoyant force:
- Volume of fluid displaced (greater volume submerged → greater buoyant force).
- Density of the fluid (denser fluid → greater buoyant force).
- Does NOT depend on the mass or density of the object itself.
Archimedes' Principle
When an object is immersed in a fluid (fully or partially), it experiences an upward buoyant force equal to the weight of the fluid displaced.
Buoyant force = weight of fluid displaced = ρ_fluid × V_displaced × g
Legend: Archimedes (287–212 BC) discovered this while stepping into a bath — shouted "Eureka!" (I have found it!) as he realised displaced water volume equals submerged volume.
Applications:
- Ship design: steel is denser than water, but a ship's hull traps air → average density < water → floats.
- Submarines: fill ballast tanks with water (increase density → sink); pump out water (decrease density → rise).
- Hot air balloon: hot air is less dense than cold air → balloon floats.
- Lactometer: measures density of milk (detects adulteration).
- Hydrometer: measures density of liquids (battery acid, alcohol).
- Life jackets: low-density material → large buoyant force.
Sinking vs floating
| Condition | What happens |
|---|---|
| Object density > fluid density | Sinks (weight > buoyant force) |
| Object density = fluid density | Neutral buoyancy (floats submerged) |
| Object density < fluid density | Floats (partially submerged; buoyant force = weight) |
- Iron: density 7874 kg/m³ > water 1000 kg/m³ → iron sinks.
- Wood: density ~500–900 kg/m³ < water → wood floats.
- Ice: density 917 kg/m³ < water → ice floats (about 90% submerged).
Quick check
- State the Universal Law of Gravitation. Write the formula.
- What is the difference between G and g?
- Why does a feather and a hammer fall at the same rate in vacuum?
- State Archimedes' Principle. Why does a ship float even though it's made of steel?
- A 5 kg stone is dropped from a height. Find: (a) its weight (b) velocity after 3 s of free fall (g = 10 m/s²).
Open the Practice tab for graded questions on Gravitation.
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