M.C.Q (1 Marks)

MCQ 11 Mark

The X-ray beam emerging from an X-ray tube:

A
Is monochromatic.
B
Has all wavelengths smaller than a certain maximum wavelength.
✓
Has all wavelengths greater than a certain minimum wavelength.
D
Has all wavelengths lying between a minimum and a maximum wavelength.

Answer

Correct option: C.

Has all wavelengths greater than a certain minimum wavelength.

The X-ray beam emerging from an X-ray tube consists of wavelengths greater than a certain minimum wavelength called cutoff wavelength.

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MCQ 21 Mark

50% of the X-ray coming from a Coolidge tube is able to pass through a 0.1mm thick aluminium foil. The potential difference between the target and the filament is increased. The thickness of the aluminium foil that will allow 50% of the X-ray to pass through will be:

A
zero
B
< 0.1mm
C
0.1mm
✓
> 0.1mm

Answer

Correct option: D.

> 0.1mm

As we increase the accelerating potential between the filament and the target, the penetrating power of the X-ray will increase. As a result, the fraction of the X-ray passing through the foil will increase. But it is given that the same fraction of the X-ray is passing. Therefore, the thickness of the aluminium foil should be increased to maintain the same fraction of the X-ray that will pass through the foil.

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MCQ 31 Mark

Visible light passing through a circular hole forms a diffraction disc of radius 0.1mm on a screen. If an X-ray is passed through the same setup, the radius of the diffraction disc will be:

A
zero
✓
< 0.1mm
C
0.1mm
D
> 0.1m

Answer

Correct option: B.

< 0.1mm

Radius of the diffraction disc is directly proportional to the wavelength of the light used for the given hole. We know that the wavelength of an X-ray is less than the wavelength of visible light. If an X-ray is passed through the same setup, the radius of the diffraction disc will be less than 0.1m.

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MCQ 41 Mark

One of the following wavelengths is absent and the rest are present in the X-rays coming from a Coolidge tube. Which one is the absent wavelength?

✓
25pm
B
50pm
C
75pm
D
100pm

Answer

Correct option: A.

25pm

Cutoff wavelength (minimum) is absent in the X-rays coming from a Coolidge tube. Hence, the 25 pm wavelength is absent.

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MCQ 51 Mark

Cutoff wavelength of $X-$rays coming from a Coolidge tube depends on the:

A
Target material.
✓
Acelerating voltage.
C
Separation between the target and the filament.
D
Temperature of the filament.

Answer

Correct option: B.

Acelerating voltage.

Cutoff wavelength $(\lambda_{\text{min}})$ is given by
$\lambda_{\text{min}}=\frac{\text{hc}}{\text{eV}}$
Here,
$h =$ Planck's constant
$c =$ Speed of light
$V =$ Accelerating voltage
$e =$ Charge of electron
Clearly, a cutoff wavelength depends on accelerating voltage. It does not depend on the target material, separation between the target and the temperature of the filament.

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MCQ 61 Mark

50% of the X-rays coming from a Coolidge tube are able to pass through a 0.1mm thick aluminium foil. If the potential difference between the target and the filament is increased, the fraction of the X-rays passing through the same foil will be:

A
0%
B
< 50%
C
50%
✓
> 50%

Answer

Correct option: D.

> 50%

The penetrating power of X-rays varies directly with the accelerating potential of the electrons (V) or the energy of the X-rays. So, if the potential difference between the target and the filament is increased, the fraction of the X-rays passing through the foil will also increase.

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MCQ 71 Mark

Consider a photon of continuous X-ray and a photon of characteristic X-ray of the same wavelength. Which of the following is/are different for the two photons?

A
Frequency.
B
Energy.
C
Penetrating power.
✓
Method of creation.

Answer

Correct option: D.

Method of creation.

Let $\lambda_1$ and $\lambda_2$ be the wavelengths of the photons of continuous and characteristic X-rays, respectively.
Given:
$\lambda_1=\lambda_2=\lambda$
Now, frequency $(\nu)$ is given by
$\nu=\frac{\text{c}}{\lambda_1}=\frac{\text{c}}{\lambda_2}$
$\Rightarrow\nu=\frac{\text{c}}{\lambda}$
Hence, the frequency of both the photons is the same.
Energy of a photon (E) is given by
$\text{E}=\text{h}\nu$
As the frequency of both the photons is the same, they will have the same energy.
The photon of the continuous X-ray and the photon of the characteristic X-ray consist of the same penetrating power.
The photon of the characteristic X-ray is created because of the transition of an electron from one shell to another. The photon of the continuous X-ray is created because of the conversion of the kinetic energy of an electron into a photon of electromagnetic radiation.

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MCQ 81 Mark

$X-$ray from a Coolidge tube is incident on a thin aluminium foil. The intensity of the $X -$ray transmitted by the foil is found to be $\mathrm{I}_0$. The heating current is increased to increase the temperature of the filament. The intensity of the $X$ ray transmitted by the foil will be:

A
zero
B
$<\mathrm{I}_0$
C
$I_0$
✓
$>I_0$

Answer

Correct option: D.

$>I_0$

We know that the intensity of an $X-$ray is directly proportional to the current through the $X-$ray tube. If the filament current is increased to increase the temperature of the filament, more electrons will be emitted from the filament per unit time. As a result, current in the $X-$ray tube will increase and consequently, the intensity of the $X-$ray will also increase.

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MCQ 91 Mark

The figure shows the intensity-wavelength relations of $X-$rays coming from two different Coolidge tubes. The solid curve represents the relation for the tube $A$ in which the potential difference between the target and the filament is $\mathrm{V}_{\mathrm{A}}$ and the atomic number of the target material is $\mathrm{Z}_{\mathrm{A}}$. These quantities are $\mathrm{V}_{\mathrm{B}}$ and $\mathrm{Z}_{\mathrm{B}}$ for the other tube. Then:

A
$\ce{V_A>V_B, Z_A>Z_B}$
✓
$\ce{V_A>V_B, Z_A}$
C
$\ce{V_AZ_B}$
D
$\ce{V_A>V_B, Z_A}$

Answer

Correct option: B.

$\ce{V_A>V_B, Z_A}$

It is clear from the figure that the $X-$ray of tube $A$ has less cutoff wavelength than the $X-$ray of tube $B$.
$\therefore\lambda_\text{A}<\lambda_\text{B}$
Using Moseley's Law,
$\ce{Z_A < Z_B}$
$\lambda\propto\frac{1}{\text{V}}$, where $V$ is the voltage applied in the $X-$ray tube.
$\therefore \ce{V_A> V_B}$

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MCQ 101 Mark

Consider a photon of a continuous X-ray coming from a Coolidge tube. Its energy comes from:

✓
The kinetic energy of the striking electron.
B
The kinetic energy of the free electrons of the target.
C
The kinetic energy of the ions of the target.
D
An atomic transition in the target.

Answer

Correct option: A.

The kinetic energy of the striking electron.

In an X-ray tube, electrons are emitted by the filament when it is heated. An electric field generated by a DC battery between the filament and the target makes the electrons hit the target atoms with a very high speed. As a result, the electrons lose their kinetic energy to eject photons, which leads to a continuous emission of X-rays.

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MCQ 111 Mark

The potential difference applied to an $X-$ray tube is increased. As a result, in the emitted radiation:

A
The intensity increases.
B
The minimum wavelength decreases.
C
The intensity remains unchanged.
✓
$B$ and $C$

Answer

Correct option: D.

$B$ and $C$

Cutoff wavelength $(\lambda_\text{min})$ is given by
$\lambda_\text{min}=\frac{\text{hc}}{\text{eV}}$
Here,
$h =$ Planck's constant
$c =$ Speed of light
$V =$ Accelerating voltage
$e =$ Charge of electron
If the potential difference applied to an $X-$ray tube $(V)$ is increased, then the minimum wavelength $($cutoff wavelength$)$ gets decreased.
Intensity is not affected by the potential difference applied.

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MCQ 121 Mark

For harder $X-$rays:

A
The wavelength is higher.
B
The photon energy is higher.
C
The frequency is higher.
✓
$B$ and $C$

Answer

Correct option: D.

$B$ and $C$

Harder $X-$rays are the $X-$rays having low wavelengths. Since the frequency varies inversely with the wavelength, hard $X-$rays have high frequency.
Energy of a photon $(E)$ is given by
$\text{E}=\frac{\text{hc}}{\lambda}$
Here,
$h =$ Planck's constant
$c =$ Speed of light
$\lambda =$ Wavelength of light.
Clearly, energy varies inversely with wavelength.
Therefore, the energy of the photon will be higher for the hard $X-$ray.

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MCQ 131 Mark

X-ray beam can be deflected:

A
By an electric field.
B
By a magnetic field.
C
By an electric field as well aa by a magnetic field.
✓
Neither by an electric field nor by a magnetic field.

Answer

Correct option: D.

Neither by an electric field nor by a magnetic field.

Since X-rays do not have any charged particles, they are not deflected by an electric field or a magnetic field.

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MCQ 141 Mark

For a given material, the energy and wavelength of characteristic $X-$rays satisfy:

A
$\text{E}(\text{K}_\alpha)>\text{E}(\text{K}_\beta)>\text{E}(\text{K})_\gamma$
B
$\lambda(\text{M}_\alpha)>\lambda(\text{K}_\beta)>\lambda(\text{K}_\alpha)$
C
$\lambda(\text{K}_\alpha)>\lambda(\text{K}_\beta)>\lambda(\text{K}_\gamma)$
✓
Both $C$ and $D$

Answer

Correct option: D.

Both $C$ and $D$

The $\text{K}_\gamma$ transition $($from the $N$ shell to the $K$ shell$)$ involves more energy than the $\text{K}_\beta$ transition $($from the $M$ shell to the $K$ shell$)$, which has more energy than the $\text{K}_\alpha$ transition $($from the $L$ shell to the $K$ shell$).$
As the energy varies inversely with the wavelength,
$\lambda(\text{K}_\alpha)>\lambda(\text{K}_\beta)>\lambda(\text{K}_\gamma)$
The $\text{M}_\alpha$ transition is due to the jumping of an electron from the $N$ shell to the $M$ shell and involves less energy than the $ \text{L}_\alpha$ transition $($from the $M$ shell to the $L$ shell$),$ which involves less energy than the $\text{K}_\alpha$ transition $($from the $L$ shell to the $K$ shell$).$
As the energy varies inversely with the wavelength,
$\lambda(\text{M}_\alpha)>\lambda(\text{L}_\alpha)>\lambda(\text{K}_\alpha)$

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MCQ 151 Mark

If the current in the circuit for heating the filament is increased, the cutoff wavelength:

A
Will increase.
B
Will decrease.
✓
Will remain unchanged.
D
Will change.

Answer

Correct option: C.

Will remain unchanged.

Cut off wavelength is given by
$\lambda_\text{min}=\frac{\text{hc}}{\text{eV}'}$
where h = Planck's constant
c = speed of light
e = charge on an electron
V = potential difference applied to the tube
Clearly, the cutoff wavelength does not depend on the current in the circuit and temperature of the filament.

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MCQ 161 Mark

The energy of a photon of a characteristic X-ray from a Coolidge tube comes from:

A
The kinetic energy of the striking electron.
B
The kinetic energy of the free electrons of the target.
C
The kinetic energy of the ions of the target.
✓
An atomic transition in the target.

Answer

Correct option: D.

An atomic transition in the target.

In an X-ray tube, electrons are emitted by the filament. These electrons are made to strike the filament by applying an electric field between the filament and the target. As a result of it, the kinetic energy of the electrons is lost to the target atoms. This energy is utilised by the target atoms to knock out an electron from the innermost shell. Consequently, the electron makes a transition from the higher energy state to this vacant shell. Due to this transition, the difference of energy of the two states gives photon of characteristic X-ray.

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MCQ 171 Mark

Mark the correct options:

A
An atom with a vacancy has smaller energy that a neutral atom.
B
K X-ray is emitted when a hole makes a jump from the K shell to some other shell.
C
The wavelength of K X-ray is smaller than the wavelength of L X-ray of the same material.
✓
B and C both.

Answer

Correct option: D.

B and C both.

d. B and C both

Explanation:
Energy of a vacant atom is higher than that of a neutral atom.
Hence, option (a) is incorrect.
K X-ray is emitted when an electron makes a jump to the K shell from some other shell. As a result, a positive charge hole is created in the outer shell. As the electron continuously moves to the K shell, the hole moves from the K shell to some other shell.
Hence, option (b) is correct.
K X-ray is emitted due to the transition of an electron from the L or M shell to the K shell and L X-ray is emitted due to the transition of an electron from the M or N shell to the L shell. The energy involved in the transition from the L or M shell to the K shell is higher than the energy involved in the transition from the M or N shell to the L shell. Since the energy is inversely proportional to the wavelength, the wavelength of the K X-ray is smaller than the wavelength of the L X-ray of the same material. Hence, option (c) is correct.
If $E_K, E_L$ and $E_M$ are the energies of K, L and M shells, respectively, then the wavelength of $\text{K}_\alpha$ X-ray $(\lambda_1)$ is given by
$\lambda_1=\frac{\text{hc}}{\text{E}_\text{K}-\text{E}_\text{L}}$
Here,
h = Planck's constant
c = Speed of light
Wavelength of the $\text{K}_\beta$ x-ray $(\lambda_2)$ is given by
$\lambda_2=\frac{\text{hc}}{\text{E}_\text{K}-\text{E}_\text{M}}$
As the difference of energies ($E_K - E_M$) is more than ($E_K- E_L$), $\lambda_2$ is less than $\lambda_1$.
Hence, option (d) is not correct.

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MCQ 181 Mark

When an electron strikes the target in a Coolidge tube, its entire kinetic energy:

A
Is converted into a photon.
B
May be converted into a photon.
C
May be converted into heat.
✓
Both $B$ and $C$

Answer

Correct option: D.

Both $B$ and $C$

When an electron strikes the target in a Coolidge tube, the kinetic energy of the electron is used in two ways. Some part of the kinetic energy is converted into a photon, while the remaining part gets converted into heat when the electron makes collisions with the atoms of the target. However, the amount of kinetic energy appearing as the photon vary from collision to collision.

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MCQ 191 Mark

If the potential difference applied to the tube is doubled and the separation between the filament and the target is also doubled, the cutoff wavelength:

A
Will remain unchanged.
B
Will be doubled.
✓
Will be halved.
D
Will become four times the original.

Answer

Correct option: C.

Will be halved.

Cut off wavelength is given by
$\lambda_{\text{min}}=\frac{\text{hc}}{\text{eV}'}$
where h = Planck's constan
c = speed of light
e = charge on an electron
V = potential difference applied to the tube
When potential difference (V) applied to the tube is doubled, cutoff wavelength
$\big({\lambda}'_\text{min}\big)$ is given by
${\lambda}'_\text{min}=\frac{\text{hc}}{\text{e}(2\text{V})}$
$\Rightarrow\lambda'_\text{min}=\frac{\lambda_\text{min}}{2}$
Cuttoff wavelength does not depend on the separation between the filament and the target.
Thus, cutoff wavelength will be halved if the the potential difference applied to the tube is doubled.

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Physics M.C.Q (1 Marks)

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