3.9 Refraction at a plane surface

Cards (24)

Refraction is the bending of waves as they pass from one medium to another due to a change in wave speed
Order the steps involved when light passes from air to glass:
1️⃣ Light enters air
2️⃣ Light reaches the air-glass boundary
3️⃣ Wave speed decreases
4️⃣ Wavelength decreases
5️⃣ Light bends towards the normal
What is the angle of refraction when light passes from air ( $n_{1} =$ $1$ ) to glass ( $n_{2} =$ $1.5$ ) at an angle of incidence of $\theta_{1} =$ $30^\circ$ ? 
$19.5^\circ$
Order the factors influencing refraction from most to least significant:
1️⃣ Refractive index difference
2️⃣ Angle of incidence
3️⃣ Frequency
Snell's Law is represented by the formula $n_{1} \sin \theta_{1} =$ $n_{2} \sin \theta_{2}$  
True
The formula to calculate the refractive index of medium 2 is $n_{2} =$ $\frac{n_{1} \sin \theta_{1}}{\sin \theta_{2}}$  
True
Light passes from air to glass with $\theta_{1} =$ $30^\circ$ and \theta_{2} = 20^\circ</latex>. The refractive index of glass is approximately 1.46
In reflection, the angle of reflection is equal to the angle of incidence
In a denser medium, the wave speed decreases and the wavelength decreases. 
True
Snell's Law relates the refractive indices and angles of incidence and refraction when a wave passes from one medium to another.
Higher refractive index differences cause more pronounced bending of waves.
Snell's Law relates the refractive indices and angles of incidence and refraction when a wave passes from one medium to another.
Match the variable with its description:
$n_{1}$ ↔️ Refractive index of medium 1
$\theta_{1}$ ↔️ Angle of incidence
$n_{2}$ ↔️ Refractive index of medium 2
$\theta_{2}$ ↔️ Angle of refraction
If we know the refractive index of one medium and the angles of incidence and refraction, we can use Snell's Law to calculate the refractive index of the other medium
When light passes from air to glass, the angle of refraction is greater than the angle of incidence.
False
Refraction occurs when a wave passes from one medium to another with the same density.
False
Match the medium with its effect on wave speed and wavelength:
Denser medium ↔️ Decreases speed and wavelength
Less dense medium ↔️ Increases speed and wavelength
The formula for Snell's Law is $n_{1} \sin \theta_{1} =$ $n_{2} \sin \theta_{2}$  
True
Changes in frequency affect wave speed and direction, influencing the angle of refraction. 
True
Snell's Law relates the refractive indices and angles of incidence and refraction
To determine the refractive index of an unknown medium, we can rearrange Snell's Law to solve for $n_{2}$
Steps to use Snell's Law for calculations:
1️⃣ Identify given variables
2️⃣ Apply the formula
3️⃣ Rearrange and solve for the unknown variable
Match the feature with the correct phenomenon:
Direction Change ↔️ Waves bend into a different medium (Refraction)
Medium Involvement ↔️ Two media needed (Refraction)
Wave Properties ↔️ Wave speed changes (Refraction)
Match the property with the correct phenomenon:
Wave Speed ↔️ Unchanged in reflection
Wavelength ↔️ Changes in refraction
Bending ↔️ No bending in reflection
Examples ↔️ Light reflecting off a mirror (Reflection)