1. Electromagnetic Waves

2. James Clerk Maxwell Scottish theoretical physicist 1831-1879 Famous for the Maxwell- Boltzman Distribution and Maxwell’s Equations Source: en.wikipedia.org

3. Maxwell’s Equations Guass’ Law: The total electric field through a closed surface is proportional to the charge enclosed Coulomb’s Law can be derived Guass’ Law for Magnetism: The total magnetic flux through a closed surface is always zero There are no magnetic monopoles Faraday’s Law of Induction: A changing magnetic field produces an electric field (which can cause electrons to flow) Ampere’s Law: An electric current produces a magnetic field A changing electric field produces a magnetic field E – electric field strength  0 – magnetic permeability B – magnetic field strength  0 – electric permittivity  – charge density J – current density

4. Electromagnetic Waves Combining Faraday’s Law and Ampere’s Law (with correction): These are wave equations! Electric and magnetic fields can be described as a wave!

5. Electromagnetic Waves Antenna An accelerating charge will produce an electromagnetic wave (i.e. radiation) Radiation is a form of energy transfer Radiation

6. Electromagnetic Waves An electromagnetic wave consists of an electric field and magnetic field changing in time The electric field and magnetic field are perpendicular to each other and in phase Both the electric and magnetic fields are perpendicular to the direction of propagation (i.e. EM waves are transverse)

7. Electromagnetic Waves From the wave equation, the speed of an electromagnetic wave is: Where and That means that, which is the speed of light! Light is an electromagnetic wave!

8. Electromagnetic Waves At first scientists thought light travelled through a medium they called the “luminiferous ether” Michelson and Morley attempted to measure Earth’s movement through the ether They hypothesized light would travel different distances depending on the direction Earth moves through the ether

9. Electromagnetic Waves They found that there was no change in propagation distance with direction The ether did not exist! LIGHT DOES NOT NEED A MEDIUM TO PROPAGATE Even null results are significant!

10. Electromagnetic Spectrum Light, microwaves, x-rays, etc. are all electromagnetic waves with different wavelengths (and frequencies)

11. Electromagnetic Spectrum Humans perceive the wavelength of electromagnetic waves in the visible range as COLOUR 400–484 THz620–750 nmred 484–508 THz590–620 nmorange 508–526 THz570–590 nmyellow 526–606 THz495–570 nmgreen 606–668 THz450–495 nmblue 668–789 THz380–450 nmviolet FrequencyWavelengthColor

12. EM Waves in Media As EM waves travel through media other than a vacuum, the waves are constantly absorbed and re-emitted.As EM waves travel through media other than a vacuum, the waves are constantly absorbed and re-emitted. The electric field of the incident wave accelerates the electrons. Accelerating electrons produce EM waves.

13. EM Waves in Media It takes time to absorb and re-emit the EM waves causing the wave to propagate slower than it would in a vacuum. Different molecules absorb and re-emit EM waves a different rates causing differences in the speed of light in these media. Index of Refraction: n – index of refraction c – speed of light in a vacuum v – speed of light in a medium