QBManager

WAVE OPTICS

283430 The intensity of each of the two slits in Young's double slit experiment is $I_{0}$ . Calculate the minimum separation between the points on the screen, where intensities are $2 I_{0}$ and $I_{0}$ . If fringe width is $b$

1

\frac{b}{5}

2

\frac{b}{8}

3

\frac{b}{12}

4

\frac{b}{4}

Explanation:

: Given,
$I_{1} = I_{2} = I_{0}$
For intensity, $I = 2 I_{o}$
$Intensity (I) = I_{max} \cos^{2} (\frac{ϕ}{2})$
$∵ I_{max} = {(\sqrt{I_{1}} + \sqrt{I_{2}})}^{2} = {(\sqrt{I_{0}} + \sqrt{I_{0}})}^{2} = 4 I_{0}$
$∴ I = 4 I_{0} \cos^{2} (\frac{ϕ}{2})$
$2 I_{0} = 4 I_{0} \cos^{2} (\frac{ϕ_{1}}{2})$
$ϕ_{1} = \frac{π}{2}$
Phase difference $= \frac{2 π}{λ} \times$ path difference
$ϕ_{1} = \frac{2 π}{λ} \times Δ x_{1}$
$ϕ_{1} = \frac{2 π}{λ} \times y_{1} \frac{d}{D}$
$\frac{π}{2} = \frac{2 π}{λ} \times y_{1} \frac{d}{D} \Rightarrow y_{1} = \frac{λ D}{4 d}$
$y_{1} = \frac{b}{4} (∵ Fringe width b = \frac{λ D}{d})$
$y_{1} = \frac{b}{4}$
$I = 4 I_{0} \cos^{2} (\frac{ϕ_{2}}{2})$
For intensity $I = I_{0}$
(given)
$I_{0} = 4 I_{0} \cos^{2} (\frac{ϕ_{2}}{2})$
$ϕ_{2} = \frac{2 π}{3}$
$ϕ_{2} = \frac{2 π}{λ} \times y_{2} \times \frac{d}{D}$
$\frac{2 π}{3} = \frac{2 π}{λ} \times y_{2} \times \frac{d}{D}$
$y_{2} = \frac{λ D}{3 d}$
$y_{2} = \frac{b}{3}$
$Δ y = y_{2} - y_{1} = \frac{b}{3} - \frac{b}{4} = \frac{b}{12}$

JIPMER-2016

WAVE OPTICS

283431 In Young's double slit experiment, the $10^{th}$ maximum of wavelength $λ_{1}$ is at a distance of $y_{1}$ from the central maximum. When the wavelength of the source is changed to $λ_{2}, 5^{th}$ maximum is at a distance of $y_{2}$ from its central maximum. The ratio $(\frac{y_{1}}{y_{2}})$ is

1

\frac{2 λ_{1}}{λ_{2}}

2

\frac{2 λ_{2}}{λ_{1}}

3

\frac{λ_{1}}{2 λ_{2}}

4

\frac{λ_{2}}{2 λ_{1}}

Explanation:

: Position of fringe from central
$y_{n} = \frac{n λ D}{d}$
For $n = 10$
$y_{10} = y_{1} = \frac{10 λ_{1} D}{d}$
For $n = 5$
$y_{5} = y_{2} = \frac{5 λ_{2} D}{d}$
Required ratio
$\frac{y_{1}}{y_{2}} = \frac{2 λ_{1}}{λ_{2}}$

AP EAMCET -2009

WAVE OPTICS

283432 In the Young's double slit experiment, the intensities at two points $P_{1}$ and $P_{2}$ on the screen are respectively $I_{1}$ and $I_{2}$ . If $P_{1}$ is located at the centre of a bright fringe and $P_{2}$ is located at a distance equal to a quarter of fringe width from $P_{1}$ , then $\frac{I_{1}}{I_{2}}$ is

1 2

2

\frac{1}{2}

3 4

4 16

Explanation:

: Let fringe width of $P_{1}$ is $β$
$y = \frac{β}{4} = \frac{λ D}{4 d}$
Path difference $(Δ x) = \frac{y d}{D}$
$= \frac{λ D}{4 d} \times \frac{d}{D}$
$= \frac{λ}{4}$
Phase difference $ϕ = \frac{2 π}{λ} \times Δ x$
$ϕ = \frac{2 π}{λ} \times \frac{λ}{4} = \frac{π}{2}$
$I_{2} = I_{1} \cos^{2} (\frac{ϕ}{2})$
$\frac{I_{1}}{I_{2}} = 2$

AP EAMCET -2009

WAVE OPTICS

283433 In Young's double slit experiment, red light of wavelength $6000 \AA$ is used and the nth bright fringe is obtained at a point $P$ on the screen. Keeping the same setting, the source of light is replaced by green light of wavelength $5000 \AA$ and now $(n + 1)$ th bright fringe is obtained at the point $P$ on the screen. The value of $n$ is

1 4

2 5

3 6

4 3

Explanation:

: Given,
$λ_{1} = 6000 \AA$
$λ_{2} = 5000 \AA$
Fringe width $(β) = \frac{n λ D}{d}$
$\frac{n λ_{1} D}{d} = \frac{(n + 1) λ_{2} D}{d}$
$n λ_{1} = (n + 1) λ_{2}$
$\frac{n + 1}{n} = \frac{λ_{1}}{λ_{2}}$
$1 + \frac{1}{n} = \frac{λ_{1}}{λ_{2}}$
$n = \frac{λ_{2}}{λ_{1} - λ_{2}}$
$n = \frac{5000}{6000 - 5000}$
$n = 5$

AP EAMCET -2016

WAVE OPTICS

283435 In a double slit experiment, the distance between slits is $5.0 mm$ and the slits are $1.0 m$ from the screen. Two interference patterns can be seen on the screen: one due to light of wavelength $480 nm$ and the other due to light of wavelength $600 nm$ . What is the separation on the screen between the third order bright fringes of the two interference patterns?

1

0.20 mm

2

0.05 mm

3

0.07 mm

4

0.09 mm

Explanation:

: Given, $d = 5 mm$
$D = 1 m = 1000 mm$
$λ_{1} = 480 nm = 480 \times 10^{- 6} mm$
$λ_{2} = 600 nm = 600 \times 10^{- 6} mm$
Separation of the third order bright fringes
$= \frac{3 λ_{2} D}{d} - \frac{3 λ_{1} D}{d}$
$= \frac{3 D}{d} (λ_{2} - λ_{1})$
$= \frac{3 \times 1000}{5} (600 - 480) \times 10^{- 6}$
$= 72 \times 10^{- 3} mm$
$= 0.072 mm .$

AMU-2013

WAVE OPTICS

283430 The intensity of each of the two slits in Young's double slit experiment is $I_{0}$ . Calculate the minimum separation between the points on the screen, where intensities are $2 I_{0}$ and $I_{0}$ . If fringe width is $b$

1

\frac{b}{5}

2

\frac{b}{8}

3

\frac{b}{12}

4

\frac{b}{4}

Explanation:

: Given,
$I_{1} = I_{2} = I_{0}$
For intensity, $I = 2 I_{o}$
$Intensity (I) = I_{max} \cos^{2} (\frac{ϕ}{2})$
$∵ I_{max} = {(\sqrt{I_{1}} + \sqrt{I_{2}})}^{2} = {(\sqrt{I_{0}} + \sqrt{I_{0}})}^{2} = 4 I_{0}$
$∴ I = 4 I_{0} \cos^{2} (\frac{ϕ}{2})$
$2 I_{0} = 4 I_{0} \cos^{2} (\frac{ϕ_{1}}{2})$
$ϕ_{1} = \frac{π}{2}$
Phase difference $= \frac{2 π}{λ} \times$ path difference
$ϕ_{1} = \frac{2 π}{λ} \times Δ x_{1}$
$ϕ_{1} = \frac{2 π}{λ} \times y_{1} \frac{d}{D}$
$\frac{π}{2} = \frac{2 π}{λ} \times y_{1} \frac{d}{D} \Rightarrow y_{1} = \frac{λ D}{4 d}$
$y_{1} = \frac{b}{4} (∵ Fringe width b = \frac{λ D}{d})$
$y_{1} = \frac{b}{4}$
$I = 4 I_{0} \cos^{2} (\frac{ϕ_{2}}{2})$
For intensity $I = I_{0}$
(given)
$I_{0} = 4 I_{0} \cos^{2} (\frac{ϕ_{2}}{2})$
$ϕ_{2} = \frac{2 π}{3}$
$ϕ_{2} = \frac{2 π}{λ} \times y_{2} \times \frac{d}{D}$
$\frac{2 π}{3} = \frac{2 π}{λ} \times y_{2} \times \frac{d}{D}$
$y_{2} = \frac{λ D}{3 d}$
$y_{2} = \frac{b}{3}$
$Δ y = y_{2} - y_{1} = \frac{b}{3} - \frac{b}{4} = \frac{b}{12}$

JIPMER-2016

WAVE OPTICS

283431 In Young's double slit experiment, the $10^{th}$ maximum of wavelength $λ_{1}$ is at a distance of $y_{1}$ from the central maximum. When the wavelength of the source is changed to $λ_{2}, 5^{th}$ maximum is at a distance of $y_{2}$ from its central maximum. The ratio $(\frac{y_{1}}{y_{2}})$ is

1

\frac{2 λ_{1}}{λ_{2}}

2

\frac{2 λ_{2}}{λ_{1}}

3

\frac{λ_{1}}{2 λ_{2}}

4

\frac{λ_{2}}{2 λ_{1}}

Explanation:

: Position of fringe from central
$y_{n} = \frac{n λ D}{d}$
For $n = 10$
$y_{10} = y_{1} = \frac{10 λ_{1} D}{d}$
For $n = 5$
$y_{5} = y_{2} = \frac{5 λ_{2} D}{d}$
Required ratio
$\frac{y_{1}}{y_{2}} = \frac{2 λ_{1}}{λ_{2}}$

AP EAMCET -2009

WAVE OPTICS

283432 In the Young's double slit experiment, the intensities at two points $P_{1}$ and $P_{2}$ on the screen are respectively $I_{1}$ and $I_{2}$ . If $P_{1}$ is located at the centre of a bright fringe and $P_{2}$ is located at a distance equal to a quarter of fringe width from $P_{1}$ , then $\frac{I_{1}}{I_{2}}$ is

1 2

2

\frac{1}{2}

3 4

4 16

Explanation:

: Let fringe width of $P_{1}$ is $β$
$y = \frac{β}{4} = \frac{λ D}{4 d}$
Path difference $(Δ x) = \frac{y d}{D}$
$= \frac{λ D}{4 d} \times \frac{d}{D}$
$= \frac{λ}{4}$
Phase difference $ϕ = \frac{2 π}{λ} \times Δ x$
$ϕ = \frac{2 π}{λ} \times \frac{λ}{4} = \frac{π}{2}$
$I_{2} = I_{1} \cos^{2} (\frac{ϕ}{2})$
$\frac{I_{1}}{I_{2}} = 2$

AP EAMCET -2009

WAVE OPTICS

283433 In Young's double slit experiment, red light of wavelength $6000 \AA$ is used and the nth bright fringe is obtained at a point $P$ on the screen. Keeping the same setting, the source of light is replaced by green light of wavelength $5000 \AA$ and now $(n + 1)$ th bright fringe is obtained at the point $P$ on the screen. The value of $n$ is

1 4

2 5

3 6

4 3

Explanation:

: Given,
$λ_{1} = 6000 \AA$
$λ_{2} = 5000 \AA$
Fringe width $(β) = \frac{n λ D}{d}$
$\frac{n λ_{1} D}{d} = \frac{(n + 1) λ_{2} D}{d}$
$n λ_{1} = (n + 1) λ_{2}$
$\frac{n + 1}{n} = \frac{λ_{1}}{λ_{2}}$
$1 + \frac{1}{n} = \frac{λ_{1}}{λ_{2}}$
$n = \frac{λ_{2}}{λ_{1} - λ_{2}}$
$n = \frac{5000}{6000 - 5000}$
$n = 5$

AP EAMCET -2016

WAVE OPTICS

283435 In a double slit experiment, the distance between slits is $5.0 mm$ and the slits are $1.0 m$ from the screen. Two interference patterns can be seen on the screen: one due to light of wavelength $480 nm$ and the other due to light of wavelength $600 nm$ . What is the separation on the screen between the third order bright fringes of the two interference patterns?

1

0.20 mm

2

0.05 mm

3

0.07 mm

4

0.09 mm

Explanation:

: Given, $d = 5 mm$
$D = 1 m = 1000 mm$
$λ_{1} = 480 nm = 480 \times 10^{- 6} mm$
$λ_{2} = 600 nm = 600 \times 10^{- 6} mm$
Separation of the third order bright fringes
$= \frac{3 λ_{2} D}{d} - \frac{3 λ_{1} D}{d}$
$= \frac{3 D}{d} (λ_{2} - λ_{1})$
$= \frac{3 \times 1000}{5} (600 - 480) \times 10^{- 6}$
$= 72 \times 10^{- 3} mm$
$= 0.072 mm .$

AMU-2013

WAVE OPTICS

283430 The intensity of each of the two slits in Young's double slit experiment is $I_{0}$ . Calculate the minimum separation between the points on the screen, where intensities are $2 I_{0}$ and $I_{0}$ . If fringe width is $b$

1

\frac{b}{5}

2

\frac{b}{8}

3

\frac{b}{12}

4

\frac{b}{4}

Explanation:

: Given,
$I_{1} = I_{2} = I_{0}$
For intensity, $I = 2 I_{o}$
$Intensity (I) = I_{max} \cos^{2} (\frac{ϕ}{2})$
$∵ I_{max} = {(\sqrt{I_{1}} + \sqrt{I_{2}})}^{2} = {(\sqrt{I_{0}} + \sqrt{I_{0}})}^{2} = 4 I_{0}$
$∴ I = 4 I_{0} \cos^{2} (\frac{ϕ}{2})$
$2 I_{0} = 4 I_{0} \cos^{2} (\frac{ϕ_{1}}{2})$
$ϕ_{1} = \frac{π}{2}$
Phase difference $= \frac{2 π}{λ} \times$ path difference
$ϕ_{1} = \frac{2 π}{λ} \times Δ x_{1}$
$ϕ_{1} = \frac{2 π}{λ} \times y_{1} \frac{d}{D}$
$\frac{π}{2} = \frac{2 π}{λ} \times y_{1} \frac{d}{D} \Rightarrow y_{1} = \frac{λ D}{4 d}$
$y_{1} = \frac{b}{4} (∵ Fringe width b = \frac{λ D}{d})$
$y_{1} = \frac{b}{4}$
$I = 4 I_{0} \cos^{2} (\frac{ϕ_{2}}{2})$
For intensity $I = I_{0}$
(given)
$I_{0} = 4 I_{0} \cos^{2} (\frac{ϕ_{2}}{2})$
$ϕ_{2} = \frac{2 π}{3}$
$ϕ_{2} = \frac{2 π}{λ} \times y_{2} \times \frac{d}{D}$
$\frac{2 π}{3} = \frac{2 π}{λ} \times y_{2} \times \frac{d}{D}$
$y_{2} = \frac{λ D}{3 d}$
$y_{2} = \frac{b}{3}$
$Δ y = y_{2} - y_{1} = \frac{b}{3} - \frac{b}{4} = \frac{b}{12}$

JIPMER-2016

WAVE OPTICS

283431 In Young's double slit experiment, the $10^{th}$ maximum of wavelength $λ_{1}$ is at a distance of $y_{1}$ from the central maximum. When the wavelength of the source is changed to $λ_{2}, 5^{th}$ maximum is at a distance of $y_{2}$ from its central maximum. The ratio $(\frac{y_{1}}{y_{2}})$ is

1

\frac{2 λ_{1}}{λ_{2}}

2

\frac{2 λ_{2}}{λ_{1}}

3

\frac{λ_{1}}{2 λ_{2}}

4

\frac{λ_{2}}{2 λ_{1}}

Explanation:

: Position of fringe from central
$y_{n} = \frac{n λ D}{d}$
For $n = 10$
$y_{10} = y_{1} = \frac{10 λ_{1} D}{d}$
For $n = 5$
$y_{5} = y_{2} = \frac{5 λ_{2} D}{d}$
Required ratio
$\frac{y_{1}}{y_{2}} = \frac{2 λ_{1}}{λ_{2}}$

AP EAMCET -2009

WAVE OPTICS

283432 In the Young's double slit experiment, the intensities at two points $P_{1}$ and $P_{2}$ on the screen are respectively $I_{1}$ and $I_{2}$ . If $P_{1}$ is located at the centre of a bright fringe and $P_{2}$ is located at a distance equal to a quarter of fringe width from $P_{1}$ , then $\frac{I_{1}}{I_{2}}$ is

1 2

2

\frac{1}{2}

3 4

4 16

Explanation:

: Let fringe width of $P_{1}$ is $β$
$y = \frac{β}{4} = \frac{λ D}{4 d}$
Path difference $(Δ x) = \frac{y d}{D}$
$= \frac{λ D}{4 d} \times \frac{d}{D}$
$= \frac{λ}{4}$
Phase difference $ϕ = \frac{2 π}{λ} \times Δ x$
$ϕ = \frac{2 π}{λ} \times \frac{λ}{4} = \frac{π}{2}$
$I_{2} = I_{1} \cos^{2} (\frac{ϕ}{2})$
$\frac{I_{1}}{I_{2}} = 2$

AP EAMCET -2009

WAVE OPTICS

283433 In Young's double slit experiment, red light of wavelength $6000 \AA$ is used and the nth bright fringe is obtained at a point $P$ on the screen. Keeping the same setting, the source of light is replaced by green light of wavelength $5000 \AA$ and now $(n + 1)$ th bright fringe is obtained at the point $P$ on the screen. The value of $n$ is

1 4

2 5

3 6

4 3

Explanation:

: Given,
$λ_{1} = 6000 \AA$
$λ_{2} = 5000 \AA$
Fringe width $(β) = \frac{n λ D}{d}$
$\frac{n λ_{1} D}{d} = \frac{(n + 1) λ_{2} D}{d}$
$n λ_{1} = (n + 1) λ_{2}$
$\frac{n + 1}{n} = \frac{λ_{1}}{λ_{2}}$
$1 + \frac{1}{n} = \frac{λ_{1}}{λ_{2}}$
$n = \frac{λ_{2}}{λ_{1} - λ_{2}}$
$n = \frac{5000}{6000 - 5000}$
$n = 5$

AP EAMCET -2016

WAVE OPTICS

283435 In a double slit experiment, the distance between slits is $5.0 mm$ and the slits are $1.0 m$ from the screen. Two interference patterns can be seen on the screen: one due to light of wavelength $480 nm$ and the other due to light of wavelength $600 nm$ . What is the separation on the screen between the third order bright fringes of the two interference patterns?

1

0.20 mm

2

0.05 mm

3

0.07 mm

4

0.09 mm

Explanation:

: Given, $d = 5 mm$
$D = 1 m = 1000 mm$
$λ_{1} = 480 nm = 480 \times 10^{- 6} mm$
$λ_{2} = 600 nm = 600 \times 10^{- 6} mm$
Separation of the third order bright fringes
$= \frac{3 λ_{2} D}{d} - \frac{3 λ_{1} D}{d}$
$= \frac{3 D}{d} (λ_{2} - λ_{1})$
$= \frac{3 \times 1000}{5} (600 - 480) \times 10^{- 6}$
$= 72 \times 10^{- 3} mm$
$= 0.072 mm .$

AMU-2013

WAVE OPTICS

283430 The intensity of each of the two slits in Young's double slit experiment is $I_{0}$ . Calculate the minimum separation between the points on the screen, where intensities are $2 I_{0}$ and $I_{0}$ . If fringe width is $b$

1

\frac{b}{5}

2

\frac{b}{8}

3

\frac{b}{12}

4

\frac{b}{4}

Explanation:

: Given,
$I_{1} = I_{2} = I_{0}$
For intensity, $I = 2 I_{o}$
$Intensity (I) = I_{max} \cos^{2} (\frac{ϕ}{2})$
$∵ I_{max} = {(\sqrt{I_{1}} + \sqrt{I_{2}})}^{2} = {(\sqrt{I_{0}} + \sqrt{I_{0}})}^{2} = 4 I_{0}$
$∴ I = 4 I_{0} \cos^{2} (\frac{ϕ}{2})$
$2 I_{0} = 4 I_{0} \cos^{2} (\frac{ϕ_{1}}{2})$
$ϕ_{1} = \frac{π}{2}$
Phase difference $= \frac{2 π}{λ} \times$ path difference
$ϕ_{1} = \frac{2 π}{λ} \times Δ x_{1}$
$ϕ_{1} = \frac{2 π}{λ} \times y_{1} \frac{d}{D}$
$\frac{π}{2} = \frac{2 π}{λ} \times y_{1} \frac{d}{D} \Rightarrow y_{1} = \frac{λ D}{4 d}$
$y_{1} = \frac{b}{4} (∵ Fringe width b = \frac{λ D}{d})$
$y_{1} = \frac{b}{4}$
$I = 4 I_{0} \cos^{2} (\frac{ϕ_{2}}{2})$
For intensity $I = I_{0}$
(given)
$I_{0} = 4 I_{0} \cos^{2} (\frac{ϕ_{2}}{2})$
$ϕ_{2} = \frac{2 π}{3}$
$ϕ_{2} = \frac{2 π}{λ} \times y_{2} \times \frac{d}{D}$
$\frac{2 π}{3} = \frac{2 π}{λ} \times y_{2} \times \frac{d}{D}$
$y_{2} = \frac{λ D}{3 d}$
$y_{2} = \frac{b}{3}$
$Δ y = y_{2} - y_{1} = \frac{b}{3} - \frac{b}{4} = \frac{b}{12}$

JIPMER-2016

WAVE OPTICS

283431 In Young's double slit experiment, the $10^{th}$ maximum of wavelength $λ_{1}$ is at a distance of $y_{1}$ from the central maximum. When the wavelength of the source is changed to $λ_{2}, 5^{th}$ maximum is at a distance of $y_{2}$ from its central maximum. The ratio $(\frac{y_{1}}{y_{2}})$ is

1

\frac{2 λ_{1}}{λ_{2}}

2

\frac{2 λ_{2}}{λ_{1}}

3

\frac{λ_{1}}{2 λ_{2}}

4

\frac{λ_{2}}{2 λ_{1}}

Explanation:

: Position of fringe from central
$y_{n} = \frac{n λ D}{d}$
For $n = 10$
$y_{10} = y_{1} = \frac{10 λ_{1} D}{d}$
For $n = 5$
$y_{5} = y_{2} = \frac{5 λ_{2} D}{d}$
Required ratio
$\frac{y_{1}}{y_{2}} = \frac{2 λ_{1}}{λ_{2}}$

AP EAMCET -2009

WAVE OPTICS

283432 In the Young's double slit experiment, the intensities at two points $P_{1}$ and $P_{2}$ on the screen are respectively $I_{1}$ and $I_{2}$ . If $P_{1}$ is located at the centre of a bright fringe and $P_{2}$ is located at a distance equal to a quarter of fringe width from $P_{1}$ , then $\frac{I_{1}}{I_{2}}$ is

1 2

2

\frac{1}{2}

3 4

4 16

Explanation:

: Let fringe width of $P_{1}$ is $β$
$y = \frac{β}{4} = \frac{λ D}{4 d}$
Path difference $(Δ x) = \frac{y d}{D}$
$= \frac{λ D}{4 d} \times \frac{d}{D}$
$= \frac{λ}{4}$
Phase difference $ϕ = \frac{2 π}{λ} \times Δ x$
$ϕ = \frac{2 π}{λ} \times \frac{λ}{4} = \frac{π}{2}$
$I_{2} = I_{1} \cos^{2} (\frac{ϕ}{2})$
$\frac{I_{1}}{I_{2}} = 2$

AP EAMCET -2009

WAVE OPTICS

283433 In Young's double slit experiment, red light of wavelength $6000 \AA$ is used and the nth bright fringe is obtained at a point $P$ on the screen. Keeping the same setting, the source of light is replaced by green light of wavelength $5000 \AA$ and now $(n + 1)$ th bright fringe is obtained at the point $P$ on the screen. The value of $n$ is

1 4

2 5

3 6

4 3

Explanation:

: Given,
$λ_{1} = 6000 \AA$
$λ_{2} = 5000 \AA$
Fringe width $(β) = \frac{n λ D}{d}$
$\frac{n λ_{1} D}{d} = \frac{(n + 1) λ_{2} D}{d}$
$n λ_{1} = (n + 1) λ_{2}$
$\frac{n + 1}{n} = \frac{λ_{1}}{λ_{2}}$
$1 + \frac{1}{n} = \frac{λ_{1}}{λ_{2}}$
$n = \frac{λ_{2}}{λ_{1} - λ_{2}}$
$n = \frac{5000}{6000 - 5000}$
$n = 5$

AP EAMCET -2016

WAVE OPTICS

283435 In a double slit experiment, the distance between slits is $5.0 mm$ and the slits are $1.0 m$ from the screen. Two interference patterns can be seen on the screen: one due to light of wavelength $480 nm$ and the other due to light of wavelength $600 nm$ . What is the separation on the screen between the third order bright fringes of the two interference patterns?

1

0.20 mm

2

0.05 mm

3

0.07 mm

4

0.09 mm

Explanation:

: Given, $d = 5 mm$
$D = 1 m = 1000 mm$
$λ_{1} = 480 nm = 480 \times 10^{- 6} mm$
$λ_{2} = 600 nm = 600 \times 10^{- 6} mm$
Separation of the third order bright fringes
$= \frac{3 λ_{2} D}{d} - \frac{3 λ_{1} D}{d}$
$= \frac{3 D}{d} (λ_{2} - λ_{1})$
$= \frac{3 \times 1000}{5} (600 - 480) \times 10^{- 6}$
$= 72 \times 10^{- 3} mm$
$= 0.072 mm .$

AMU-2013

WAVE OPTICS

283430 The intensity of each of the two slits in Young's double slit experiment is $I_{0}$ . Calculate the minimum separation between the points on the screen, where intensities are $2 I_{0}$ and $I_{0}$ . If fringe width is $b$

1

\frac{b}{5}

2

\frac{b}{8}

3

\frac{b}{12}

4

\frac{b}{4}

Explanation:

: Given,
$I_{1} = I_{2} = I_{0}$
For intensity, $I = 2 I_{o}$
$Intensity (I) = I_{max} \cos^{2} (\frac{ϕ}{2})$
$∵ I_{max} = {(\sqrt{I_{1}} + \sqrt{I_{2}})}^{2} = {(\sqrt{I_{0}} + \sqrt{I_{0}})}^{2} = 4 I_{0}$
$∴ I = 4 I_{0} \cos^{2} (\frac{ϕ}{2})$
$2 I_{0} = 4 I_{0} \cos^{2} (\frac{ϕ_{1}}{2})$
$ϕ_{1} = \frac{π}{2}$
Phase difference $= \frac{2 π}{λ} \times$ path difference
$ϕ_{1} = \frac{2 π}{λ} \times Δ x_{1}$
$ϕ_{1} = \frac{2 π}{λ} \times y_{1} \frac{d}{D}$
$\frac{π}{2} = \frac{2 π}{λ} \times y_{1} \frac{d}{D} \Rightarrow y_{1} = \frac{λ D}{4 d}$
$y_{1} = \frac{b}{4} (∵ Fringe width b = \frac{λ D}{d})$
$y_{1} = \frac{b}{4}$
$I = 4 I_{0} \cos^{2} (\frac{ϕ_{2}}{2})$
For intensity $I = I_{0}$
(given)
$I_{0} = 4 I_{0} \cos^{2} (\frac{ϕ_{2}}{2})$
$ϕ_{2} = \frac{2 π}{3}$
$ϕ_{2} = \frac{2 π}{λ} \times y_{2} \times \frac{d}{D}$
$\frac{2 π}{3} = \frac{2 π}{λ} \times y_{2} \times \frac{d}{D}$
$y_{2} = \frac{λ D}{3 d}$
$y_{2} = \frac{b}{3}$
$Δ y = y_{2} - y_{1} = \frac{b}{3} - \frac{b}{4} = \frac{b}{12}$

JIPMER-2016

WAVE OPTICS

283431 In Young's double slit experiment, the $10^{th}$ maximum of wavelength $λ_{1}$ is at a distance of $y_{1}$ from the central maximum. When the wavelength of the source is changed to $λ_{2}, 5^{th}$ maximum is at a distance of $y_{2}$ from its central maximum. The ratio $(\frac{y_{1}}{y_{2}})$ is

1

\frac{2 λ_{1}}{λ_{2}}

2

\frac{2 λ_{2}}{λ_{1}}

3

\frac{λ_{1}}{2 λ_{2}}

4

\frac{λ_{2}}{2 λ_{1}}

Explanation:

: Position of fringe from central
$y_{n} = \frac{n λ D}{d}$
For $n = 10$
$y_{10} = y_{1} = \frac{10 λ_{1} D}{d}$
For $n = 5$
$y_{5} = y_{2} = \frac{5 λ_{2} D}{d}$
Required ratio
$\frac{y_{1}}{y_{2}} = \frac{2 λ_{1}}{λ_{2}}$

AP EAMCET -2009

WAVE OPTICS

283432 In the Young's double slit experiment, the intensities at two points $P_{1}$ and $P_{2}$ on the screen are respectively $I_{1}$ and $I_{2}$ . If $P_{1}$ is located at the centre of a bright fringe and $P_{2}$ is located at a distance equal to a quarter of fringe width from $P_{1}$ , then $\frac{I_{1}}{I_{2}}$ is

1 2

2

\frac{1}{2}

3 4

4 16

Explanation:

: Let fringe width of $P_{1}$ is $β$
$y = \frac{β}{4} = \frac{λ D}{4 d}$
Path difference $(Δ x) = \frac{y d}{D}$
$= \frac{λ D}{4 d} \times \frac{d}{D}$
$= \frac{λ}{4}$
Phase difference $ϕ = \frac{2 π}{λ} \times Δ x$
$ϕ = \frac{2 π}{λ} \times \frac{λ}{4} = \frac{π}{2}$
$I_{2} = I_{1} \cos^{2} (\frac{ϕ}{2})$
$\frac{I_{1}}{I_{2}} = 2$

AP EAMCET -2009

WAVE OPTICS

283433 In Young's double slit experiment, red light of wavelength $6000 \AA$ is used and the nth bright fringe is obtained at a point $P$ on the screen. Keeping the same setting, the source of light is replaced by green light of wavelength $5000 \AA$ and now $(n + 1)$ th bright fringe is obtained at the point $P$ on the screen. The value of $n$ is

1 4

2 5

3 6

4 3

Explanation:

: Given,
$λ_{1} = 6000 \AA$
$λ_{2} = 5000 \AA$
Fringe width $(β) = \frac{n λ D}{d}$
$\frac{n λ_{1} D}{d} = \frac{(n + 1) λ_{2} D}{d}$
$n λ_{1} = (n + 1) λ_{2}$
$\frac{n + 1}{n} = \frac{λ_{1}}{λ_{2}}$
$1 + \frac{1}{n} = \frac{λ_{1}}{λ_{2}}$
$n = \frac{λ_{2}}{λ_{1} - λ_{2}}$
$n = \frac{5000}{6000 - 5000}$
$n = 5$

AP EAMCET -2016

WAVE OPTICS

283435 In a double slit experiment, the distance between slits is $5.0 mm$ and the slits are $1.0 m$ from the screen. Two interference patterns can be seen on the screen: one due to light of wavelength $480 nm$ and the other due to light of wavelength $600 nm$ . What is the separation on the screen between the third order bright fringes of the two interference patterns?

1

0.20 mm

2

0.05 mm

3

0.07 mm

4

0.09 mm

Explanation:

: Given, $d = 5 mm$
$D = 1 m = 1000 mm$
$λ_{1} = 480 nm = 480 \times 10^{- 6} mm$
$λ_{2} = 600 nm = 600 \times 10^{- 6} mm$
Separation of the third order bright fringes
$= \frac{3 λ_{2} D}{d} - \frac{3 λ_{1} D}{d}$
$= \frac{3 D}{d} (λ_{2} - λ_{1})$
$= \frac{3 \times 1000}{5} (600 - 480) \times 10^{- 6}$
$= 72 \times 10^{- 3} mm$
$= 0.072 mm .$

AMU-2013