Upgrade to get full access
Kumar Rohan
Physics and Mathematics
Mechanical Properties of Solids — Complete Formula
- ⭐ – Most used in JEE
- ⚠️ – Common Mistake
- 💡 – Memory Hint
Stress
| Concept | Formula | Symbols Meaning | SI Units | Key Notes / Tricks |
|---|---|---|---|---|
| Stress | [\text{Stress} = \dfrac{F}{A}] | [F] = force, [A] = area | Pa | Force per unit area ⭐ |
| Longitudinal Stress | [\dfrac{F}{A}] | [F] = normal force, [A] = cross-sectional area | Pa | Acts along length |
| Shear Stress | [\dfrac{F}{A}] | [F] = tangential force | Pa | Causes change in shape ⚠️ |
| Bulk Stress | [\dfrac{\Delta P}{1}] | [\Delta P] = change in pressure | Pa | Equal in all directions |
💡 Memory Hint:
Stress = internal restoring force per unit area
Strain
| Concept | Formula | Symbols Meaning | SI Units | Key Notes / Tricks |
|---|---|---|---|---|
| Longitudinal Strain | [\dfrac{\Delta L}{L}] | [\Delta L] = change in length, [L] = original length | — | Dimensionless ⭐ |
| Shear Strain | [\theta] | [\theta] = angular deformation | rad | Small angle approx ⚠️ |
| Volume Strain | [\dfrac{\Delta V}{V}] | [\Delta V] = change in volume | — | Used in bulk modulus |
💡 Memory Hint:
Strain = relative deformation
Hooke’s Law
| Concept | Formula | Symbols Meaning | SI Units | Key Notes / Tricks |
|---|---|---|---|---|
| Hooke’s Law | [\text{Stress} \propto \text{Strain}] | — | — | Valid within elastic limit ⭐ |
| Linear Form | [\text{Stress} = Y \times \text{Strain}] | [Y] = Young’s modulus | Pa | Straight-line graph |
💡 Memory Hint:
Valid only in elastic region ⚠️
Elastic Moduli
| Concept | Formula | Symbols Meaning | SI Units | Key Notes / Tricks |
|---|---|---|---|---|
| Young’s Modulus | [Y = \dfrac{F L}{A \Delta L}] | [L] = original length | Pa | For length change ⭐ |
| Bulk Modulus | [K = -\dfrac{\Delta P}{\Delta V / V}] | [\Delta P] = pressure change | Pa | Negative sign important ⚠️ |
| Shear Modulus | [G = \dfrac{\text{Shear Stress}}{\text{Shear Strain}}] | — | Pa | Shape change |
💡 Memory Hint:
- Y → length
- K → volume
- G → shape
Relation Between Elastic Constants
| Concept | Formula | Symbols Meaning | SI Units | Key Notes / Tricks |
|---|---|---|---|---|
| Relation | [Y = 2G(1 + \nu)] | [\nu] = Poisson’s ratio | Pa | Important ⭐ |
| Alternate | [Y = 3K(1 – 2\nu)] | — | Pa | Used in numericals ⭐ |
💡 Memory Hint:
All constants are interrelated
Poisson’s Ratio
| Concept | Formula | Symbols Meaning | SI Units | Key Notes / Tricks |
|---|---|---|---|---|
| Poisson’s Ratio | [\nu = -\dfrac{\text{Lateral Strain}}{\text{Longitudinal Strain}}] | [\nu] = Poisson’s ratio | — | Usually between 0 and 0.5 ⭐ |
💡 Memory Hint:
Stretch → width decreases
Energy Stored in Stretched Wire
| Concept | Formula | Symbols Meaning | SI Units | Key Notes / Tricks |
|---|---|---|---|---|
| Elastic Potential Energy | [U = \dfrac{1}{2} \times \text{Stress} \times \text{Strain} \times \text{Volume}] | — | J | Energy stored ⭐ |
| Alternate Form | [U = \dfrac{1}{2} \dfrac{F \Delta L}{1}] | [\Delta L] = extension | J | Work done in stretching |
💡 Memory Hint:
Energy = area under stress–strain graph
Breaking Stress
| Concept | Formula | Symbols Meaning | SI Units | Key Notes / Tricks |
|---|---|---|---|---|
| Breaking Stress | [\sigma = \dfrac{F_{max}}{A}] | [F_{max}] = breaking force | Pa | Maximum stress before breaking ⭐ |
💡 Memory Hint:
Material fails beyond breaking stress
Sign in with Google