Class 11 Physics: Waves Notes

Class 11 Physics: Waves Notes

Class 11 Physics: Waves Notes

1. Introduction

  • Wave: A disturbance that travels through a medium, transferring energy without transferring matter.
  • Examples: Sound waves, water waves, waves on a string.

2. Types of Waves

  1. Mechanical Waves: Require a medium to propagate (sound, water waves, string waves).
  2. Electromagnetic Waves: Do not require a medium (light, radio waves).
  3. Matter Waves: Associated with particles (de Broglie waves).

3. Classification of Mechanical Waves

  1. Based on Direction of Oscillation:
    • Transverse Waves: Oscillation perpendicular to propagation (string wave, water surface).
    • Longitudinal Waves: Oscillation along propagation (sound waves in air).
  2. Based on Dimensionality:
    • 1D, 2D, 3D waves (string, water, sound in air).

4. Characteristics of Waves

  • Wavelength (λ): Distance between two consecutive similar points (crests or troughs).
  • Frequency (f): Number of oscillations per second.
  • Time Period (T): Time for one complete oscillation, T=1fT = \frac{1}{f}T=f1​.
  • Wave Velocity (v): Speed of wave propagation, v=fλv = f \lambdav=fλ.
  • Amplitude (A): Maximum displacement from equilibrium.

5. Wave Equation

  • One-dimensional wave:

y(x,t)=Asin(kxωt)(travelling wave along +x)y(x,t) = A \sin(kx – \omega t) \quad \text{(travelling wave along +x)}y(x,t)=Asin(kx−ωt)(travelling wave along +x)

Where:

  • k=2πλk = \frac{2\pi}{\lambda}k=λ2π​ → wave number
  • ω=2πf\omega = 2\pi fω=2πf → angular frequency
  • Wave speed:

v=ωk=fλv = \frac{\omega}{k} = f \lambdav=kω​=fλ

6. Superposition of Waves

  • Principle of Superposition: When two or more waves meet, their displacements add algebraically.
  • Constructive Interference: Waves in phase → amplitude increases.
  • Destructive Interference: Waves out of phase → amplitude decreases or cancels.

7. Standing Waves

  • Formed when two waves of same frequency and amplitude travel in opposite directions.
  • Nodes: Points of zero displacement.
  • Antinodes: Points of maximum displacement.
  • Applications: Musical instruments, resonance in strings and air columns.

8. Doppler Effect

  • Definition: Change in frequency of a wave due to relative motion of source and observer.
  • Formula (for sound):

f=fv±vovvsf’ = f \frac{v \pm v_o}{v \mp v_s}f′=fv∓vs​v±vo​​

Where:

  • fff = source frequency
  • ff’f′ = observed frequency
  • vvv = speed of sound
  • vov_ovo​ = speed of observer
  • vsv_svs​ = speed of source

9. Key Points

  • Waves transfer energy, not matter.
  • Transverse vs Longitudinal: direction of oscillation differs.
  • Standing waves: nodes and antinodes important in musical instruments.
  • Wave speed depends on medium and wave type.