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Physics-

General

Easy

Question

The value of E of the given circuit is

10 V
12 V
14 V
0 V

The correct answer is: 0 V

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The resistance between A and B is

The resistance between A and B is

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The resistance between A and B is

The resistance between A and B is

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The potential difference between A & B in the given branch of a circuit is

The potential difference between A & B in the given branch of a circuit is

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In the given circuit current through the galvanometer is

In the given circuit current through the galvanometer is

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Six resistors of each 2 ohm are connected as shown in the figure The resultant resistance between A and B is

Six resistors of each 2 ohm are connected as shown in the figure The resultant resistance between A and B is

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In the following diagram, the p d across 6V cell is

In the following diagram, the p d across 6V cell is

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The effective resistance between A and B in the given circuit is

The effective resistance between A and B in the given circuit is

physics-General

In the figure shown, S is a point monochromatic light source of frequency $6 cross times 10 to the power of 14 end exponent H z$ . M is a concave mirror of radius of curvature 20 cm and L is a thin converging lens of focal length 3.75 cm. AB is the principal axis of M and L

Light reflected from the mirror and refracted from the lens in succession reaches the screen. An interference pattern is obtained on the screen by this arrangement.
If the lens is replaced by another converging lens of focal length $fraction numerator 10 over denominator 3 end fraction c m$ and the lens is shifted towards right by 2.5 cm then-

In the figure shown, S is a point monochromatic light source of frequency $6 cross times 10 to the power of 14 end exponent H z$ . M is a concave mirror of radius of curvature 20 cm and L is a thin converging lens of focal length 3.75 cm. AB is the principal axis of M and L

Light reflected from the mirror and refracted from the lens in succession reaches the screen. An interference pattern is obtained on the screen by this arrangement.
If the lens is replaced by another converging lens of focal length $fraction numerator 10 over denominator 3 end fraction c m$ and the lens is shifted towards right by 2.5 cm then-

physics-General

Consider the optical system shown in figure. The point source of light S is having wavelength equals to l. The light is reaching screen only after reflection. For point P to be 2nd maxima, the value of l would be (D>>d and d>>l)

Consider the optical system shown in figure. The point source of light S is having wavelength equals to l. The light is reaching screen only after reflection. For point P to be 2nd maxima, the value of l would be (D>>d and d>>l)

physics-General

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Statement-1 : A ray is incident from outside on a glass sphere surrounded by air as shown. This ray may suffer total internal reflection at second interface.

Statement 2 : For a ray going from denser to rarer medium, the ray may suffer total internal reflection.

Statement-1 : A ray is incident from outside on a glass sphere surrounded by air as shown. This ray may suffer total internal reflection at second interface.

Statement 2 : For a ray going from denser to rarer medium, the ray may suffer total internal reflection.

physics-General

Statement-1 : A beam of white light enters the curved surface of a semicircular piece of glass along the normal. The incoming beam is moved clockwise (so that the angle $theta$ increases), such that the beam always enters along the normal to the curved side. Just before the refracted beam disappears, it becomes predominantly red.

Statement-2 : The index of refraction for light at the red end of the visible spectrum is more than at the violet end.

Statement-1 : A beam of white light enters the curved surface of a semicircular piece of glass along the normal. The incoming beam is moved clockwise (so that the angle $theta$ increases), such that the beam always enters along the normal to the curved side. Just before the refracted beam disappears, it becomes predominantly red.

Statement-2 : The index of refraction for light at the red end of the visible spectrum is more than at the violet end.

physics-General

Statement-1: In octahedral complexes, the three orbitals (dxy, dyz, dzx) are stable and of low energy while the two orbitals $open parentheses d subscript x to the power of 2 end exponent minus y to the power of 2 end exponent end subscript d subscript z to the power of 2 end exponent end subscript close parentheses$ are unstable and have high energy.
Statement-2: In octahedral complexes, the three d-orbitals (dxy, dyz, dzx) experience less repulsion from the ligands while two d-orbitals $open parentheses d subscript x to the power of 2 end exponent minus y to the power of 2 end exponent end subscript d subscript z to the power of 2 end exponent end subscript close parentheses$ experience more repulsion from the ligands due to their shapes.

Statement-1: In octahedral complexes, the three orbitals (dxy, dyz, dzx) are stable and of low energy while the two orbitals $open parentheses d subscript x to the power of 2 end exponent minus y to the power of 2 end exponent end subscript d subscript z to the power of 2 end exponent end subscript close parentheses$ are unstable and have high energy.
Statement-2: In octahedral complexes, the three d-orbitals (dxy, dyz, dzx) experience less repulsion from the ligands while two d-orbitals $open parentheses d subscript x to the power of 2 end exponent minus y to the power of 2 end exponent end subscript d subscript z to the power of 2 end exponent end subscript close parentheses$ experience more repulsion from the ligands due to their shapes.

chemistry-General

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In the figure shown if a parallel beam of white light is incident on the plane of the slits then the distance of the only white spot on the screen from O is :[ assume $d much less-than less than D comma lambda less than d$ ]

In the figure shown if a parallel beam of white light is incident on the plane of the slits then the distance of the only white spot on the screen from O is :[ assume $d much less-than less than D comma lambda less than d$ ]

physics-General

In a Young’s double slit experiment the slits $S subscript 1 end subscript & S subscript 2 end subscript$ are illuminated by a parallel beam of light of wavelength $4000 text Å end text$ , from the medium of refractive index $n subscript 1 end subscript$ = 1.2. A thin film of thickness 1.2 $mu m$ and refractive index n = 1.5 is placed infront of $S subscript 1 end subscript$ perpendicular to path of light. The refractive index of medium between plane of slits & screen is $n subscript 2 end subscript$ = 1.4. If the light coming from the film and $S subscript 1 end subscript & S subscript 2 end subscript$ have equal intensities I then intensity at geometrical centre of the screen O is

In a Young’s double slit experiment the slits $S subscript 1 end subscript & S subscript 2 end subscript$ are illuminated by a parallel beam of light of wavelength $4000 text Å end text$ , from the medium of refractive index $n subscript 1 end subscript$ = 1.2. A thin film of thickness 1.2 $mu m$ and refractive index n = 1.5 is placed infront of $S subscript 1 end subscript$ perpendicular to path of light. The refractive index of medium between plane of slits & screen is $n subscript 2 end subscript$ = 1.4. If the light coming from the film and $S subscript 1 end subscript & S subscript 2 end subscript$ have equal intensities I then intensity at geometrical centre of the screen O is

physics-General

In a YDSE experiment two slits $S subscript 1 end subscript$ and $S subscript 2 end subscript$ have separation of d = 2 mm. The distance of the screen is D=8/5m. Source S starts moving from a very large distance towards $S subscript 2 end subscript$ perpendicular to $S subscript 1 end subscript S subscript 2 end subscript$ as shown in figure. The wavelength of monochromatic light is 500 nm. The number of maximas observed on the screen at point P as the source moves towards $S subscript 2 end subscript$ is

In a YDSE experiment two slits $S subscript 1 end subscript$ and $S subscript 2 end subscript$ have separation of d = 2 mm. The distance of the screen is D=8/5m. Source S starts moving from a very large distance towards $S subscript 2 end subscript$ perpendicular to $S subscript 1 end subscript S subscript 2 end subscript$ as shown in figure. The wavelength of monochromatic light is 500 nm. The number of maximas observed on the screen at point P as the source moves towards $S subscript 2 end subscript$ is

physics-General

parallel

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