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Physics-

General

Easy

Question

Spherical wavefronts shown in figure, strike a plane mirror. Reflected wavefront will be as shown in

The correct answer is:

Related Questions to study

The figure shows the interference pattern obtained in a double–slit experiment using light of wavelength 600nm.

The third order bright fringe is

The figure shows the interference pattern obtained in a double–slit experiment using light of wavelength 600nm.

The third order bright fringe is

physics-General

The optical path length followed by ray from point A to B given that laws of reflection are obeyed as shown in figure is

The optical path length followed by ray from point A to B given that laws of reflection are obeyed as shown in figure is

physics-General

The optical path length followed by ray from point A to B given that laws of refraction are obeyed as shown in figure

The optical path length followed by ray from point A to B given that laws of refraction are obeyed as shown in figure

physics-General

parallel

In the figure an arrangement of young's double slit experiment is shown. A parallel beam of light of wavelength $blank to the power of ´ end exponent lambda to the power of ´ end exponent$ (in medium $n subscript 1 end subscript$ ) is incident at an angle $blank to the power of ´ end exponent theta to the power of ´ end exponent$ as shown. Distance $S subscript 1 end subscript O equals S subscript 2 end subscript O$ . Point 'O' is the origin of the coordinate system. The medium on the left and right side of the plane of slits has refractive index $n subscript 1 end subscript$ and $n subscript 2 end subscript$ respectively. Distance between the slits is d. The distance between the screen and the plane of slits is D Using $D equals 1 m comma d equals 1 m m comma theta equals 30 to the power of ring operator end exponent comma lambda equals 0.3 m m comma n subscript 1 end subscript equals fraction numerator 4 over denominator 3 end fraction comma n subscript 2 end subscript equals fraction numerator 10 over denominator 9 end fraction comma$ answer the following

The y-coordinate of the point where the total phase difference between the interefering waves is zero, is

In the figure an arrangement of young's double slit experiment is shown. A parallel beam of light of wavelength $blank to the power of ´ end exponent lambda to the power of ´ end exponent$ (in medium $n subscript 1 end subscript$ ) is incident at an angle $blank to the power of ´ end exponent theta to the power of ´ end exponent$ as shown. Distance $S subscript 1 end subscript O equals S subscript 2 end subscript O$ . Point 'O' is the origin of the coordinate system. The medium on the left and right side of the plane of slits has refractive index $n subscript 1 end subscript$ and $n subscript 2 end subscript$ respectively. Distance between the slits is d. The distance between the screen and the plane of slits is D Using $D equals 1 m comma d equals 1 m m comma theta equals 30 to the power of ring operator end exponent comma lambda equals 0.3 m m comma n subscript 1 end subscript equals fraction numerator 4 over denominator 3 end fraction comma n subscript 2 end subscript equals fraction numerator 10 over denominator 9 end fraction comma$ answer the following

The y-coordinate of the point where the total phase difference between the interefering waves is zero, is

physics-General

Statement–1: Two point coherent sources of light S1 and S2 are placed on a line as shown. P and Q are two points on that line. If at point P maximum intensity is observed then maximum intensity should also be observed at Q

Statement–2: In the figure of statement 1, the distance |S₁ P – S₂ P| is equal to distance |S₂Q – S₁Q|.

Statement–1: Two point coherent sources of light S1 and S2 are placed on a line as shown. P and Q are two points on that line. If at point P maximum intensity is observed then maximum intensity should also be observed at Q

Statement–2: In the figure of statement 1, the distance |S₁ P – S₂ P| is equal to distance |S₂Q – S₁Q|.

physics-General

In an interfrence arrangement similar to Young's double- slit experiment, the slits $S subscript 1 end subscript & S subscript 2 end subscript$ are illuminated with coherent microwave sources, each of frequency 106 Hz. The sources are synchronized to have zero phase difference. The slits are separated by a distance d = 150.0 m and screen is at very large distance from slits. The intensity I(q) is measured as a function of $theta$ , where $theta$ is defined as shown. Screen is at a large distance. If $I subscript 0 end subscript$ is the maximum intensity then I ( $theta$ ) for $0 less or equal than theta less or equal than 90 to the power of ring operator end exponent$ is given by:

In an interfrence arrangement similar to Young's double- slit experiment, the slits $S subscript 1 end subscript & S subscript 2 end subscript$ are illuminated with coherent microwave sources, each of frequency 106 Hz. The sources are synchronized to have zero phase difference. The slits are separated by a distance d = 150.0 m and screen is at very large distance from slits. The intensity I(q) is measured as a function of $theta$ , where $theta$ is defined as shown. Screen is at a large distance. If $I subscript 0 end subscript$ is the maximum intensity then I ( $theta$ ) for $0 less or equal than theta less or equal than 90 to the power of ring operator end exponent$ is given by:

physics-General

parallel

In an interfrence arrangement similar to Young's double- slit experiment, the slits $S subscript 1 end subscript & S subscript 2 end subscript$ are illuminated with coherent microwave sources, each of frequency 106 Hz. The sources are synchronized to have zero phase difference. The slits are separated by a distance d = 150.0 m and screen is at very large distance from slits. The intensity I(q) is measured as a function of $theta$ , where $theta$ is defined as shown. Screen is at a large distance. If $I subscript 0 end subscript$ is the maximum intensity then I ( $theta$ ) for $0 less or equal than theta less or equal than 90 to the power of ring operator end exponent$ is given by:

In an interfrence arrangement similar to Young's double- slit experiment, the slits $S subscript 1 end subscript & S subscript 2 end subscript$ are illuminated with coherent microwave sources, each of frequency 106 Hz. The sources are synchronized to have zero phase difference. The slits are separated by a distance d = 150.0 m and screen is at very large distance from slits. The intensity I(q) is measured as a function of $theta$ , where $theta$ is defined as shown. Screen is at a large distance. If $I subscript 0 end subscript$ is the maximum intensity then I ( $theta$ ) for $0 less or equal than theta less or equal than 90 to the power of ring operator end exponent$ is given by:

physics-General

A parallel beam of light $left parenthesis lambda equals 5000 text Å end text right parenthesis$ is incident at an angle $alpha equals 30 to the power of ring operator end exponent$ with the normal to the slit plane in a young’s double slit experiment. Assume that the intensity due to each slit at any point on the screen is $I subscript 0 end subscript$ . Point O is equidistant from $S subscript 1 end subscript & S subscript 2 end subscript$ . The distance between slits is 1mm.

A parallel beam of light $left parenthesis lambda equals 5000 text Å end text right parenthesis$ is incident at an angle $alpha equals 30 to the power of ring operator end exponent$ with the normal to the slit plane in a young’s double slit experiment. Assume that the intensity due to each slit at any point on the screen is $I subscript 0 end subscript$ . Point O is equidistant from $S subscript 1 end subscript & S subscript 2 end subscript$ . The distance between slits is 1mm.

physics-General

A long narrow horizontal slit lies 1 mm above a plane mirror. The interference pattern produced by the slit and its image is viewed on a screen $capital sigma$ distant 1m from the slit. The wavelength of light is 600 nm. Then the distance of the first maxima above the mirror is equal to $left parenthesis d less than D right parenthesis$

A long narrow horizontal slit lies 1 mm above a plane mirror. The interference pattern produced by the slit and its image is viewed on a screen $capital sigma$ distant 1m from the slit. The wavelength of light is 600 nm. Then the distance of the first maxima above the mirror is equal to $left parenthesis d less than D right parenthesis$

physics-General

parallel

Two parallel beams of light of wavelength $lambda$ inclined to each other at angle $theta left parenthesis much less-than less than 1 right parenthesis$ are incident on a plane at near normal incidence. The fringe width will be :

Two parallel beams of light of wavelength $lambda$ inclined to each other at angle $theta left parenthesis much less-than less than 1 right parenthesis$ are incident on a plane at near normal incidence. The fringe width will be :

physics-General

M₁ and M₂ are two plane mirrors which are kept parallel to each other as shown. There is a point 'O' on perpendicular screen just infront of 'S'. What should be the wavelength of light coming from monchromatic source 'S'. So that a maxima is formed at 'O' due to interference of reflected light from both the mirrors. [Consider only 1st reflection]. $left square bracket D greater than greater than d comma d greater than greater than lambda right square bracket$

M₁ and M₂ are two plane mirrors which are kept parallel to each other as shown. There is a point 'O' on perpendicular screen just infront of 'S'. What should be the wavelength of light coming from monchromatic source 'S'. So that a maxima is formed at 'O' due to interference of reflected light from both the mirrors. [Consider only 1st reflection]. $left square bracket D greater than greater than d comma d greater than greater than lambda right square bracket$

physics-General

An interference is observed due to two coherent sources 'A' & 'B' having phase constant zero separated by a distance 4 $lambda$ along the y - axis where $lambda$ is the wavelength of the source. A detector D is moved on the positive x - axis. The number of points on the x - axis excluding the points , $x equals 0 & x equals infinity$ sat which maximum will be observed is

An interference is observed due to two coherent sources 'A' & 'B' having phase constant zero separated by a distance 4 $lambda$ along the y - axis where $lambda$ is the wavelength of the source. A detector D is moved on the positive x - axis. The number of points on the x - axis excluding the points , $x equals 0 & x equals infinity$ sat which maximum will be observed is

physics-General

parallel

In the figure shown, a parallel beam of light is incident on the plane of the slits of Young's double slit experiment. Light incident on the slit, $S subscript 1 end subscript$ passes through a medium of variable refractive index $mu equals 1 plus a x$ (where 'X' is the distance from the plane of slits as shown), up to a distance ' $lambda$ ' before falling on $S subscript 1 end subscript$ . Rest of the space is filled with air. If at 'O' a minima is formed, then the minimum value of the positive constant a (in terms of l and wavelength ' $lambda$ ' in air) is:

In the figure shown, a parallel beam of light is incident on the plane of the slits of Young's double slit experiment. Light incident on the slit, $S subscript 1 end subscript$ passes through a medium of variable refractive index $mu equals 1 plus a x$ (where 'X' is the distance from the plane of slits as shown), up to a distance ' $lambda$ ' before falling on $S subscript 1 end subscript$ . Rest of the space is filled with air. If at 'O' a minima is formed, then the minimum value of the positive constant a (in terms of l and wavelength ' $lambda$ ' in air) is:

physics-General

Two coherent light sources each of wavelength $lambda$ are separated by a distance 3 $lambda$ . The total number of minima formed on line AB which runs from - $infinity$ to + $infinity$ is

Two coherent light sources each of wavelength $lambda$ are separated by a distance 3 $lambda$ . The total number of minima formed on line AB which runs from - $infinity$ to + $infinity$ is

physics-General

Which of the following has no co-ordinate bond?

Which of the following has no co-ordinate bond?

chemistry-General

parallel

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