🌟 Total Internal Reflection (TIR)

1 🔍 Quick Refresher on Refraction

Light slows down (and bends) when it moves from one material to another. The refractive index tells us “how much slower.” For two media 1 and 2, the indices obey \( n_{21}\,n_{12}=1 \) (Equation 9.11) :contentReference[oaicite:14]{index=14}.

• Optical density (decided by light-speed) can differ from mass density—turpentine is optically denser than water even though it’s physically lighter! :contentReference[oaicite:15]{index=15}
• A ray through a glass slab emerges parallel to itself but sideways-shifted. The bottom of a water tank looks raised for the same reason. :contentReference[oaicite:16]{index=16}

2 ✨ What Is Total Internal Reflection?

Send a beam from an optically denser material to a rarer one (for example, water → air). As you tilt the beam:

1. It first refracts away from the normal (angle r gets bigger). :contentReference[oaicite:17]{index=17}
2. At a special critical angle \( i_c \), the refracted ray skims along the surface (r = 90°). :contentReference[oaicite:18]{index=18}
3. Go beyond \( i_c \): refraction vanishes; the whole beam bounces back—Total Internal Reflection! 💡 :contentReference[oaicite:19]{index=19}

2.1 📐 Maths Behind TIR

Snell’s law gives the two handy relations:

\[ \sin i_c = n_{21}\tag{9.12} \] :contentReference[oaicite:20]{index=20}\[ n_{12}=\frac{1}{\sin i_c} \] :contentReference[oaicite:21]{index=21}

(Here \( n_{21}=n_2/n_1<1 \) because medium 2 is rarer.)

3 📊 Critical Angles You Should Know

Material (to Air)	Refractive Index	\( i_c \) (degrees)
Water	1.33	48.8°
Crown glass	1.52	41.1°
Dense flint glass	1.62	37.3°
Diamond 💎	2.42	24.4°

(Table 9.1) :contentReference[oaicite:22]{index=22}

4 🧪 DIY Demo (Fun & Safe)

Fill a beaker with slightly milky water, shine a laser pointer sideways, and watch the beam zig-zag as it bounces inside—perfect live TIR! 🌈 Just don’t stare into the beam. :contentReference[oaicite:23]{index=23}

5 🚀 Cool Uses & Natural Appearances

• Right-angle & Porro prisms: flip or turn images by 90°/180° with almost zero loss. Perfect for binoculars! :contentReference[oaicite:24]{index=24}
• Optical fibres: a light pulse bounces thousands of times inside the core, carrying internet data or guiding a doctor’s endoscope. Even bends are okay as long as the bounce angle stays > \( i_c \). 🚑 :contentReference[oaicite:25]{index=25}
• “Light-pipe” toys & lamps: the same fibres make decorative fountains of coloured light. 🎇 :contentReference[oaicite:26]{index=26}

6 🎯 High-Yield NEET Nuggets

1. TIR occurs only when light tries to move from denser to rarer medium and \( i \gt i_c \).
2. Remember the formula \( \sin i_c = n_{21} \); quick way to compute critical angles.
3. Diamond’s tiny \( i_c \) (≈ 24°) explains its brilliant sparkle—a favourite MCQ fact.
4. Prisms and optical fibres rely on near-100 % reflection efficiency of TIR (far better than mirrors).

Keep shining and bouncing those rays! ✨