- m=E/c2
- m=Ec2
- m=E/c
- m=Ec
No category found.
- To generate heat.
- To convert light into electrical signals.
- To reflect light.
- To amplify light.
- Creates a proton-electron pair.
- Ejects an electron, creating current.
- Increases the temperature of the material.
- Generates a magnetic field.
- Different photon energies.
- Different photon speeds.
- Different photon masses.
- Different photon charges.
- Excitation.
- Ionization.
- De-excitation.
- Fusion.
- Continuous.
- Quantized.
- Random.
- Always zero.
- It has mass, but no charge.
- It has charge, but no mass.
- It has no mass and no charge.
- It has both mass and charge.
- Photoelectric effect.
- Compton effect.
- Pair production.
- Annihilation.
- Photoelectric effect.
- Compton scattering.
- Pair production.
- Bremsstrahlung.
- Compton scattering.
- Photoelectric effect.
- Pair production.
- Rayleigh scattering.
- They have higher energy.
- They have lower frequency.
- They are larger.
- They are charged.
- Radio wave.
- Microwave.
- Visible light.
- Gamma ray.
- Activation energy.
- Work function.
- Ionization energy.
- Kinetic energy.
- Work function.
- Ionization energy.
- Binding energy.
- Threshold energy.
- It increases.
- It decreases due to absorption.
- It remains constant, but its speed changes.
- It is completely absorbed.
- The wave nature of light.
- The particle nature of light.
- The quantization of energy.
- The uncertainty principle.
- They have an electric charge.
- They have a variable speed in vacuum.
- They exert radiation pressure.
- They are deflected by magnetic fields.
- Conduction.
- Convection.
- Radiation via photons.
- Sound waves.
- Because they have different numbers of protons.
- Because their electrons occupy different, quantized energy levels.
- Because their atoms are of different sizes.
- Because their nuclei have different masses.
