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Physics-

General

Easy

Question

The “ $K subscript alpha end subscript$ ” X-rays emission line of tungsten occurs at l = 0.021 nm. The energy difference between K and L levels in this atom is about

0.51 MeV
1.2 MeV
59 keV
13.6 eV

The correct answer is: 59 keV

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In a characteristic X– ray spectra of some atom superimposed on continuous X– ray spectra:

In a characteristic X– ray spectra of some atom superimposed on continuous X– ray spectra:

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When a hydrogen atom, initially at rest emits, a photon resulting in transition n = $5 rightwards arrow n$ = 1, its recoil speed is about

When a hydrogen atom, initially at rest emits, a photon resulting in transition n = $5 rightwards arrow n$ = 1, its recoil speed is about

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Electron in a hydrogen atom is replaced by an identically charged particle muon with mass 207 times that of electron. Now the radius of K shell will be

Electron in a hydrogen atom is replaced by an identically charged particle muon with mass 207 times that of electron. Now the radius of K shell will be

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Consider the following electronic energy level diagram of H-atom: Photons associated with shortest and longest wavelengths would be emitted from the atom by the transitions labelled:

Consider the following electronic energy level diagram of H-atom: Photons associated with shortest and longest wavelengths would be emitted from the atom by the transitions labelled:

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In a photoelectric experiment, electrons are ejected from metals X and Y by light of intensity I and frequency f. The potential difference V required to stop the electrons is measured for various frequencies. If Y has a greater work function than X; which one of the following graphs best illustrates the expected results?

In a photoelectric experiment, electrons are ejected from metals X and Y by light of intensity I and frequency f. The potential difference V required to stop the electrons is measured for various frequencies. If Y has a greater work function than X; which one of the following graphs best illustrates the expected results?

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In a photoelectric experiment, the potential difference V that must be maintained between the illuminated surface and the collector so as just to prevent any electron from reaching the collector is determined for different frequencies f of the incident illumination. The graph obtained is shown. The maximum kinetic energy of the electrons emitted at frequency f₁ is

In a photoelectric experiment, the potential difference V that must be maintained between the illuminated surface and the collector so as just to prevent any electron from reaching the collector is determined for different frequencies f of the incident illumination. The graph obtained is shown. The maximum kinetic energy of the electrons emitted at frequency f₁ is

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$text If end text I equals stretchy integral subscript 1 divided by e end subscript superscript e end superscript vertical line l o g invisible function application x vertical line fraction numerator d x over denominator x to the power of 2 end exponent end fraction text , end text$ then I equals

$text If end text I equals stretchy integral subscript 1 divided by e end subscript superscript e end superscript vertical line l o g invisible function application x vertical line fraction numerator d x over denominator x to the power of 2 end exponent end fraction text , end text$ then I equals

$integral fraction numerator e to the power of x end exponent left parenthesis x minus 1 right parenthesis left parenthesis x minus l n invisible function application x right parenthesis over denominator x to the power of 2 end exponent end fraction$ dx is equal to

$integral fraction numerator e to the power of x end exponent left parenthesis x minus 1 right parenthesis left parenthesis x minus l n invisible function application x right parenthesis over denominator x to the power of 2 end exponent end fraction$ dx is equal to

$integral x to the power of 3 end exponent square root of fraction numerator 1 plus x to the power of 2 end exponent over denominator 1 minus x to the power of 2 end exponent end fraction end root d x equals A square root of 1 minus x to the power of 4 end exponent end root minus B x to the power of 2 end exponent square root of 1 minus x to the power of 4 end exponent end root plus C s i n to the power of negative 1 end exponent invisible function application x to the power of 2 end exponent plus D comma text end text$ then A+B+C is equal to

$integral x to the power of 3 end exponent square root of fraction numerator 1 plus x to the power of 2 end exponent over denominator 1 minus x to the power of 2 end exponent end fraction end root d x equals A square root of 1 minus x to the power of 4 end exponent end root minus B x to the power of 2 end exponent square root of 1 minus x to the power of 4 end exponent end root plus C s i n to the power of negative 1 end exponent invisible function application x to the power of 2 end exponent plus D comma text end text$ then A+B+C is equal to

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A body of mass 10 kg is moving with a constant velocity of 10 m/s. When a constant force acts for 4 seconds on it, it moves with a velocity 2 m/sec in the opposite direction. The acceleration produced in it is :

A body of mass 10 kg is moving with a constant velocity of 10 m/s. When a constant force acts for 4 seconds on it, it moves with a velocity 2 m/sec in the opposite direction. The acceleration produced in it is :

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A particle moves along the sides AB, BC, CD of a square of side 25m with a velocity of 15 ms^–1 Its average velocity is :

A particle moves along the sides AB, BC, CD of a square of side 25m with a velocity of 15 ms^–1 Its average velocity is :

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Acceleration–time graph of a body is shown. The corresponding velocity–time graph of the same body is :

Acceleration–time graph of a body is shown. The corresponding velocity–time graph of the same body is :

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The graph of displacement u/s time is,

Its corresponding velocity–time graph will be :

The graph of displacement u/s time is,

Its corresponding velocity–time graph will be :

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Figure (i) and (ii) below show the displacement–time graphs of two particles moving along the x–axis. We can say that :
i)
ii)

Figure (i) and (ii) below show the displacement–time graphs of two particles moving along the x–axis. We can say that :
i)
ii)

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The displacement versus time graph for a body moving in a straight line is shown in figure. Which of the following regions represents the motion when no force is acting on the body :

The displacement versus time graph for a body moving in a straight line is shown in figure. Which of the following regions represents the motion when no force is acting on the body :

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