1. Modelling synchrotron radiation using visible light Helen Lye ACER February 2007

2. Workshop activities Warning Keep direct laser light out of your eyes; Point the laser away from you and from other people; Look away from bright reflections; Set up laser equipment so that the beam is below eye level.

4. http://www.arpansa.gov.au/pubs/r hs/rhs36.pdf http://www.arpansa.gov.au/pubs/r hs/rhs36.pdf http://www.vicphysics.org/teacher s/photonics.html

6. Interference and diffraction Diffraction: spreading of a wave at right angles to the direction of travel when it passes through a gap or around a narrow object. For visible light, the spreading results in a diffraction pattern of light and dark spots or bands.

7. Interference and diffraction Interference: pattern of constructive and destructive interference formed when two or more waves intersect.

8. Examples Sound wave interference results in louder and softer sounds in particular positions relative to the sound source. Visible light interference results in light and dark regions in particular positions relative to the light source. X-ray interference results in high and low intensities of X-rays in particular positions relative to the source.

11. Single slit and two slits close together

14. Diffraction of laser light through a vertical opening of decreasing width. Note that as the opening gets narrower, the amount of diffraction in the horizontal direction increases.

16. Hexagonal hole

17. Student investigations Diffraction effects Use laser light to observe the diffraction pattern formed by different fibres. screen object laser

18. Student investigations Diffraction effects Use laser light to observe the diffraction pattern formed by different fibres. Sketch each pattern

19. Diffraction effects take any measurements that you could use to calculate the diameter of each fibre. Length Number of dark bands Distance from object to screen

20. Diffraction in two dimensions Two dimensional grids screenobject laser

22. Gauze ribbon (chiffon ribbon) diffraction pattern. STAVCON November 24 2006 Thomas Cherry lab fourth floor. Red laser level about 2m away; gauze taped to laser and hanging down.

23. Two dimensional helix model Pair of bolts or screws The laser beam must line up with the gap between the threads. Blu-tack Two bolts screen laser

24. Two dimensional helix model Pair of bolts or screws The laser beam must line up with the gap between the threads.

25. X-ray diffraction pattern of DNA

26. Quantitative measurements laser screen Gauze ribbon Count dark bands Measure width of pattern Measure distance

27. Diffraction gratings

28. When light of a single wavelength, like the 632.8nm red light from a helium-neon laser strikes a diffraction grating it is diffracted to each side in multiple orders. Orders 1 and 2 are shown to each side of the direct beam.helium-neon laser

29. While directing the 632.8 nm red beam of a helium-neon laser through a 600 lines/mm diffraction grating, a cloud was formed using liquid nitrogen. You can see the direct beam plus the first and second orders of the diffraction.helium-neon laser diffraction grating Another way to visualize the diffraction is to take a time exposure while sweeping a ground glass through the beams. This "paints in" the beams of the diffracted laser light.

30. The illustration shows the hydrogen spectrum. The hydrogen gas in a thin glass tube is excited by an electrical discharge and the spectrum can be viewed through the grating.hydrogen spectrum

31. The tracks of a compact disc act as a diffraction grating, producing a separation of the colors of white light. The nominal track separation on a CD is 1.6 micrometers, corresponding to about 625 tracks per millimeter. For red light of wavelength 600 nm, this would give a first order diffraction maximum at about 22°.compact disc

33. Data Measure the angle between the incident laser light and the normal of the CD. Measure the angle between the normal to the CD and the n=-1 order and the normal and n=1 order. Use the grating formula to determine the track spacing on the CD for each set of data

34. Diffraction pracs from http://www.ssabsa.sa.edu.au/suppo rt/science/2phy/2phy-menu.htm

35. Safe laser inspection device Explore your toothpaste Gorazd Planinˇsiˇc Faculty for Mathematics and Physics, University of Ljubljana, Slovenia and The House of Experiments, Ljubljana, Slovenia SPECIAL FEATURE: HEALTH AND BEAUTY PHYSICS EDUCATION 41 (4) www.iop.org/journals/physed

36. Figure 1. What can we find out about the iridescent pieces on the toothpaste package? Safe Laser Inspection Device made from one hemisphere of a painted Christmas ball. Diffraction patterns produced by the shiny part of a toothpaste package using red and green laser light respectively.