Physics 11th + JEE Mechanical Properties of Fluids
Hydrostatics (Fluids at Rest)
Hydrodynamics (Fluids in Motion)
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Kumar Rohan
Physics and Mathematics
Mechanical Properties of Fluids — Complete Formula
- ⭐ – Most used in JEE
- ⚠️ – Common Mistake
- 💡 – Memory Hint
Pressure
| Concept | Formula | Symbols Meaning | SI Units | Key Notes / Tricks |
|---|---|---|---|---|
| Pressure | [P = \dfrac{F}{A}] | [P] = pressure, [F] = force, [A] = area | Pa | Force per unit area ⭐ |
| Hydrostatic Pressure | [P = \rho gh] | [\rho] = density, [g] = gravity, [h] = depth | Pa | Increases with depth ⭐ |
| Total Pressure | [P = P_0 + \rho gh] | [P_0] = atmospheric pressure | Pa | Absolute pressure |
💡 Memory Hint:
Pressure in fluid depends only on depth, not shape
Pascal’s Law
| Concept | Formula | Symbols Meaning | SI Units | Key Notes / Tricks |
|---|---|---|---|---|
| Pascal’s Law | [P_1 = P_2] | — | — | Pressure transmitted equally ⭐ |
| Hydraulic Lift | [\dfrac{F_1}{A_1} = \dfrac{F_2}{A_2}] | [F] = force, [A] = area | — | Force multiplication ⭐ |
💡 Memory Hint:
Small force → large force using area difference
Buoyancy & Archimedes’ Principle
| Concept | Formula | Symbols Meaning | SI Units | Key Notes / Tricks |
|---|---|---|---|---|
| Buoyant Force | [F_b = \rho g V] | [F_b] = buoyant force, [V] = displaced volume | N | Upward force ⭐ |
| Apparent Weight | [W’ = W – F_b] | [W] = actual weight | N | Weight reduces in fluid ⚠️ |
| Floating Condition | [\rho_{body} \leq \rho_{fluid}] | — | — | Body floats ⭐ |
💡 Memory Hint:
Buoyant force = weight of displaced fluid
Continuity Equation
| Concept | Formula | Symbols Meaning | SI Units | Key Notes / Tricks |
|---|---|---|---|---|
| Continuity Equation | [A_1 v_1 = A_2 v_2] | [A] = area, [v] = velocity | m³/s | Mass conservation ⭐ |
💡 Memory Hint:
Area ↓ → Velocity ↑
Bernoulli’s Theorem
| Concept | Formula | Symbols Meaning | SI Units | Key Notes / Tricks |
|---|---|---|---|---|
| Bernoulli Equation | [P + \dfrac{1}{2}\rho v^2 + \rho gh = \text{constant}] | [v] = velocity, [h] = height | Pa | Energy conservation ⭐ |
| Horizontal Flow | [P + \dfrac{1}{2}\rho v^2 = \text{constant}] | — | Pa | Height same |
💡 Memory Hint:
Velocity ↑ → Pressure ↓ ⚠️
Viscosity
| Concept | Formula | Symbols Meaning | SI Units | Key Notes / Tricks |
|---|---|---|---|---|
| Viscous Force | [F = \eta A \dfrac{dv}{dx}] | [\eta] = viscosity, [dv/dx] = velocity gradient | N | Opposes motion ⭐ |
| Stokes’ Law | [F = 6\pi \eta r v] | [r] = radius | N | For spherical body ⭐ |
| Terminal Velocity | [v = \dfrac{2r^2(\rho – \sigma)g}{9\eta}] | [\sigma] = fluid density | m/s | Constant speed ⚠️ |
💡 Memory Hint:
Viscosity = internal friction of fluid
Surface Tension
| Concept | Formula | Symbols Meaning | SI Units | Key Notes / Tricks |
|---|---|---|---|---|
| Surface Tension | [T = \dfrac{F}{l}] | [T] = surface tension, [l] = length | N/m | Force per unit length ⭐ |
| Energy Relation | [T = \dfrac{E}{A}] | [E] = energy, [A] = area | J/m² | Energy per unit area |
| Excess Pressure (Drop) | [\Delta P = \dfrac{2T}{r}] | [r] = radius | Pa | Single surface ⭐ |
| Soap Bubble | [\Delta P = \dfrac{4T}{r}] | — | Pa | Double surface ⚠️ |
💡 Memory Hint:
Bubble → double pressure of drop
Capillarity
| Concept | Formula | Symbols Meaning | SI Units | Key Notes / Tricks |
|---|---|---|---|---|
| Capillary Rise | [h = \dfrac{2T\cos\theta}{\rho g r}] | [\theta] = contact angle | m | Depends on radius ⭐ |
💡 Memory Hint:
Narrow tube → higher rise
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