3.7 Diffraction

Cards (51)

Longer wavelengths experience more diffraction
The shape of a new wavefront in Huygens' Principle is the tangent to the spherical wavelets
What is a diffraction pattern?
Intensity distribution of waves
In the diffraction formula, $m$ represents the order of the minima 
True
The width of the central maximum and the spacing between the fringes depend on the wavelength and slit width
What is the condition for the general $m$ th minimum in single-slit diffraction? 
$w \sin \theta =$ $m\lambda$
Match the key concepts with their descriptions:
Wavefront Division ↔️ The slit is divided into smaller segments
Path Difference ↔️ The difference in distance traveled by waves
Destructive Interference ↔️ Minima occur when waves cancel each other
Longer wavelengths experience more diffraction than shorter wavelengths
True
The new wavefront in Huygens' Principle is the tangent to the spherical wavelets
Shorter wavelengths produce a narrower diffraction pattern
What is diffraction?
Bending of waves
What does Huygens' Principle state?
Wavelets form new wavefront
What are the two factors that affect diffraction?
Wavelength and slit width
What is the formula for the position of diffraction minima?
$\sin\theta =$ $\frac{m\lambda}{w}$
What does the diffraction pattern from a single slit consist of?
Central bright maximum
The formula for the first minimum in single-slit diffraction is $w \sin \theta =$ $\lambda$  
True
Wavefront division is a key concept in deriving diffraction minima
True
Diffraction is the bending of waves around obstacles or through openings
What does Huygens' Principle state about every point on a wavefront?
Acts as a source of wavelets
What is the diffraction pattern?
Intensity distribution of diffracted wave
The formula for the first minimum in a single-slit diffraction pattern is $\sin\theta =$ $\frac{\lambda}{w}$  
True
Match the factors with their effects on the diffraction pattern:
Wavelength ↔️ Shorter wavelengths result in narrower patterns
Slit Width ↔️ Narrower slits result in wider patterns
The position of the first minima in the diffraction pattern is given by $\sin\theta =$ $\frac{m\lambda}{w}$  
True
Match the concept with its explanation:
Wavefront Division ↔️ Slit is divided into smaller segments
Path Difference ↔️ Difference in distance traveled by waves
Destructive Interference ↔️ Minima occur when path difference is $m\frac{λ}{2}$
For the general $m$ th minimum, the formula is $w \sin θ_{m} =$ $mλ$ , where $m =$ $1, 2, 3, ...$ is an integer.
What factors affect the angle of the first diffraction minimum?
Wavelength and slit width
What are the characteristics of a diffraction pattern produced by a narrow slit?
Wider pattern with broad maxima
What is one real-world example of spectroscopy?
Chemical analysis of compounds
What does $\theta$ represent in the single-slit diffraction formula? 
Angle from central maximum
What effect does shorter wavelength have on a diffraction pattern?
Narrower diffraction pattern
What is the central feature of a diffraction pattern?
Bright central maximum
For the first minimum, the path difference between waves from the top and bottom halves of the slit must be $\frac{λ}{2}$  
True
What type of diffraction pattern does a shorter wavelength produce?
Narrower pattern
In the formula \sin\theta = \frac{m\lambda}{w}</latex>, $\theta$ represents the angle of the first minimum.
The diffraction pattern is significantly influenced by the slit width.
Visible light diffracts as much as radio waves around buildings
False
Light passing through a narrow slit bends due to Huygens' Principle 
True
Shorter wavelengths produce a narrower diffraction pattern.
What is the path difference between waves from the top and bottom halves of a slit for the first minimum?
$\frac{\lambda}{2}$
Steps to derive the formula for diffraction minima
1️⃣ Divide the slit into two halves
2️⃣ Consider the path difference between waves
3️⃣ Set the path difference to $\frac{\lambda}{2}$ for the first minimum
4️⃣ Express mathematically: $\frac{w}{2} \sin \theta =$ $\frac{\lambda}{2}$
5️⃣ Simplify to: $w \sin \theta =$ $\lambda$