Lesson 3

1. Lesson 3 • Explain the terms monochromatic and coherent. • Identify laser light as a source of coherent light. • Outline the mechanism for the production of laser light (students should be familiar with the term population inversion). • Outline an application of the use of a laser; medical applications, communications, bar-code scanners, laser disks, surveying, welding and machining metals, drilling tiny holes in metals, production of CDs, reading and writing CDs, DVDs, etc.

2. Lasers

3. Monochromatic?

4. Monochromatic light Mono chromatic light has a very narrow range of frequencies (i.e. it is only made of light of one colour)

5. Coherent light?

9. Lasers - How do they work?

10. Spontaneous emission An atom in an excited (high energy level) state will eventually fall back to a less excited state, emitting a photon of light. This is called spontaneous emission.

11. Spontaneous emission Many atoms producing the same spontaneous emission at random may produce monochromatic light, but the phases of all the waves will be different, they will travelling in different directions, and their polarisation will be different.

12. Stimulated emision • The emission is stimulated by another photon. The photon that is emitted in the same direction and is in phase with the incident photon.

13. Population inversion • Stimulated emission is the basis of the laser, but you need many more atoms in the excited state than the ground state. This is called population inversion. It is achieved by pumping. Most atoms in ground state Most atoms in excited state (population inversion)

14. Metastable states To achieve population inversion we must have metastable states. These are excited states where electrons stay for unusually long times.

15. Metastable states Normally an electron in an excited state will make the transition to a lower state in a time of 10-7s. In contrast an electron may stay in a metastable state for 10-3s.

16. Helium-Neon laser

17. Helium-Neon laser • The helium is used to create population inversion in the neon. An electric field is used to excite the Helium to a metastable state 20.61 eV above its ground level. When this metastable helium atom collides with a neon atom it excites the neon atom to a 20.66 eV metastable state. The extra 0.05 eV comes from the helium’s kinetic energy and the helium atom is now back in its ground state.

18. Helium-Neon laser The neon atoms transition to a 18.7 eV state, giving out photons of λ = 632.8 nm. These photons are reflected by mirrors at the ends of the laser tube causing stimulated emission in other metastable neon atoms.

19. Helium-Neon laser One of the mirrors is semi transparent, allowing the monochromatic, coherent, directional and very intense laser beam to emerge.

20. Uses of lasers

21. Destroying tumours

22. Reattaching damaged retinas The laser damages part of the tissue so that the resulting scar “welds” the retina back into place.

23. Unblocking arteries and heart valves

24. Cutting and sealing nerves in neurosurgery

25. Correcting myopia in cornea operations

26. Welding

27. Cutting and drilling metals

28. Compact discs

29. Measuring distances

30. Reading barcodes

31. Optical fibre communication

32. Laser guided “smart” weapons

33. Questions Page 605 questions 4, 6, 7, 8, 9 and 10.