Total Internal Reflection. Find c.

1. Place a semicircular glass block flat-side outermost on a sheet of paper; trace the outline.
2. Mark a point at the midpoint of the flat edge — light enters through the curved face along a radius, so refraction occurs only at the flat face.
3. Draw the normal at that point.
4. Shine a ray of light into the curved side, aimed at the midpoint, at an angle of incidence i from the normal (measured inside the glass).
5. Mark where the refracted ray emerges on the air side; remove the block and measure the angle of refraction r.
6. Increase i step by step until the refracted ray just disappears along the surface — this is the critical angle c.
7. For i > c, observe that the ray is completely reflected inside the glass (TIR).

Analytical control: for the critical angle, sin c = 1/n. Therefore n = 1 / sin c.

• Edge of disappearance — at i ≈ c the refracted ray is very dim. Find c by approaching from both sides.
• Block alignment — the curved side must face the ray box and the light must travel along a radius so that there is no refraction at the curved face.
• Mark dimness — at high angles, the refracted ray brightens and reflects partially; the critical point is where the refracted ray just vanishes.
• Protractor reading — measure both i and r from the normal, not from the flat surface.

• Semicircular glass block
• Ray box with single-slit fitting
• Soft board, A4 paper, pins (optional)
• Sharp pencil and ruler
• Protractor (resolution ± 1°)

• 3.2.3 Total internal reflection — state that the angle of incidence equals the angle of reflection in TIR; define critical angle; recall and use the equation sin c = 1/n; describe internal reflection and TIR using both diagrams and an experimental demonstration; describe uses of optical fibres (in telecommunications and medicine).