M.C.Q (1 Marks) - Physics STD 11 Science Questions - Vidyadip

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M.C.Q (1 Marks)

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20 questions · auto-graded multiple-choice test.

MCQ 11 Mark

A positively charged particle projected towards east is deflected towards north by a magnetic field. The field may be:

✓
Towards west.
B
Towards south.
C
Upward.
D
Downward.

Answer

Correct option: A.

Towards west.

$\text{F}=\text{q}\big(\overrightarrow{\text{V}}\times\overrightarrow{\text{B}}\big)$

$\text{j}=\text{q}\big(\overrightarrow{\text{i}}\times\overrightarrow{\text{B}}\big)$
$\Rightarrow\text{B}\otimes$
⇒ The magnetic field may be down ward direction.

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MCQ 21 Mark

Let $\overrightarrow{\text{E}}$ and $\overrightarrow{\text{B}}$ denote electric and magnetic fields in a frame $S$ and $\overrightarrow{\text{E}}$ and $\overrightarrow{\text{B}}$ in another frame $S$ moving with respect to $S$ at a velocity $\overrightarrow{\text{v}}.$ Two of the following equations are wrong. Identify them.

$\text{B}_\text{y},=\text{B}_\text{y}+\frac{\text{vE}_\text{z}}{\text{c}^2}$
$\text{E}_\text{y},=\text{E}_\text{y}+\frac{\text{vB}_\text{z}}{\text{c}^2}$
$\text{B}'_\text{y}=\text{B}_\text{y}+\text{v}\text{E}_\text{z}$
$\text{E}'_\text{y}=\text{E}_\text{y}+\text{vB}_\text{z}$

A
only $A$
B
$A$ and $B$
✓
$B$ and $C$
D
None of these

Answer

Correct option: C.

$B$ and $C$

$\text{qE}=\text{qvB}$
$\Rightarrow\text{e}=\text{vB}$ By dimensionally $b\ \&$ care wrong
$\Rightarrow\text{v}\text{E}=\text{v}^2\text{B}$
$\Rightarrow\text{B}=\frac{\text{vE}}{\text{v} ^2}$

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MCQ 31 Mark

A charged particle goes undeflected in a region containing an electric and a magnetic field. It is possible that

$\overrightarrow{\text{E}}||\overrightarrow{\text{B}},\ \overrightarrow{\text{v}}||\overrightarrow{\text{E}}$
$\overrightarrow{\text{E}}$ is not parallel to $\overrightarrow{\text{B}}$
$\overrightarrow{\text{v}}||\overrightarrow{\text{B}}$ but $\overrightarrow{\text{E}}$ is not parallel to $\overrightarrow{\text{B}}$
$\overrightarrow{\text{E}}||\overrightarrow{\text{B}}$ but $\overrightarrow{\text{v}}$ is not parallel to $\overrightarrow{\text{E}}$

✓
$A$ and $B$
B
only $B$
C
$A$ and $D$
D
None of these

Answer

Correct option: A.

$A$ and $B$

$\Rightarrow\overrightarrow{\text{V}}\overrightarrow{\text{E}},\ \overrightarrow{\text{B}}\overrightarrow{\text{E}}$
In this case Magnetic force on the particle is zero $\&\ \overrightarrow{\text{V}}$ is paralle to $\overrightarrow{\text{E}}.$ So charged particle goes undeflected in a region.
$\overrightarrow{\text{E}}$ is not parallel to $\overrightarrow{\text{B}},$ But $\overrightarrow{\text{V}}$ is parallel to $\overrightarrow{\text{E}}.$

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MCQ 41 Mark

An electric current i enters and leaves a uniform circular wire of radius a through diametrically opposite points. A charged particle q moving along the axis of the circular wire passes through its centre at speed v. The magnetic force acting on the particle when it passes through the centre has a magnitude:

A
$\text{qv}\frac{\mu_0\text{i}}{2\text{a}}$
B
$\text{qv}\frac{\mu_0\text{i}}{2\pi\text{a}}$
C
$\text{qv}\frac{\mu_0\text{i}}{\text{a}}$
✓
$\text{Zero}$

Answer

Correct option: D.

$\text{Zero}$

As the current is entering and exiting from two diametrically opposite points of a circular coil, the currents in the two semicircular sections are in the opposite direction.
The fields due to the two semi-circular sections at the centre is in the opposite direction.
Hence net feild is zero.

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MCQ 51 Mark

A circular loop of area $1 \mathrm{~cm}^2$, carrying a current of $10 A$ , is placed in a magnetic field of $0.1 T$ perpendicular to the plane of the loop. The torque on the loop due to the magnetic field is:

✓
Zero
B
$10^4 \mathrm{~N}-\mathrm{m}$
C
$10^2 \mathrm{~N}-\mathrm{m}$
D
$1 \mathrm{~N}-\mathrm{m}$

Answer

Correct option: A.

Zero

$B = 0.1T$
Area $=1\ cm^2$
Net torque on the loop due to the uniform magnetic field is always zero.

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MCQ 61 Mark

Which of the following particles will describe the smallest circle when projected with the same velocity perpendicular to a magnetic field?

✓
Electron
B
Proton
C
$\mathrm{He}^{+}$
D
$\mathrm{Li}^{+}$

Answer

Correct option: A.

Electron

$\text{F}=\text{q}\text{VB}=\frac{\text{mv}^2}{\text{r}}$
$\text{r}=\frac{\text{mV}}{\text{qB}}$
charqe electron $=$ charqe of proton $=$ charqe of $\mathrm{He}^{+}=$charqe of $\mathrm{Li}^{+}$But mass of electron is Lowest.
$\therefore ($the electron so smallest $+$ circle made by$)$

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MCQ 71 Mark

A charged particle moves in a uniform magnetic field. The velocity of the particle at some instant makes an acute angle with the magnetic field. The path of the particle will be:

A
A straight line.
B
A circle.
✓
A helix with uniform pitch.
D
A helix with nonuniform pitch.

Answer

Correct option: C.

A helix with uniform pitch.

$\vec{\text{F}}=\text{q}(\vec{\text{V}}\times\vec{\text{B}})=\text{qvB}\sin\theta$
Megnetic force doesn't change the speed of the particle. It change the direction of the velocity of the particle.
V $\cos\theta$ provide the displacement of the particle in Horizontal direction & force is provide the centripetal acceleration of the particle.
So the path of the particle will be a helix with uniform pitch.

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MCQ 81 Mark

A charged particle is whirled in a horizontal circle on a frictionless table by attaching it to a string fixed at one point. If a magnetic field is switched on in the vertical direction the tension in the string.

A
Will increase.
B
Will decrease.
C
Will remain the same.
✓
May increase or decrease.

Answer

Correct option: D.

May increase or decrease.

$B=B_0 j$
The tension is the strong may increases or decreases.

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MCQ 91 Mark

A beam consisting of protons and electrons moving at the same speed goes through a thin region in which there is a magnetic field perpendicular to the beam. The protons and the electrons:

A
Will go undeviated.
B
Will be deviated by the same angle and will not separate.
✓
Will be deviated by different angles and hence separate.
D
Will be deviated by the same angle but will separate.

Answer

Correct option: C.

Will be deviated by different angles and hence separate.

$\vec{\text{F}}=\text{q}(\text{V}\times\text{B})$
Charge proton is poritive $=\mathrm{e}$
$F_p=e v B$
Charge of electron is negative $=-e$
$F_e=-e v B$
They will be deviated by different angles and Hence separate.

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MCQ 101 Mark

Which of the following particles will experience maximum magnetic force circle when projected with the same velocity perpendicular to a magnetic field?

A
Electron
B
Proton
C
$\mathrm{He}^{+}$
✓
$\mathrm{Li}^{++}$

Answer

Correct option: D.

$\mathrm{Li}^{++}$

$|\text{F}|=|\text{qVB}|$
charge of $\mathrm{Li}^{++}>$charge of $\left(\mathrm{He}^{+}\right.$, proton, electron $)$

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MCQ 111 Mark

If a charged particle moves unaccelerated in a region containing electric and magnetic fields,

$\overrightarrow{\text{E}}$ must be perpendicular to $\overrightarrow{\text{B}}$
$\overrightarrow{\text{V}}$ must be perpendicular to $\overrightarrow{\text{E}}$
$\overrightarrow{\text{V}}$ must be perpendicular to $\overrightarrow{\text{B}}$
$E$ must be equal to $v_B.$

A
Only $A$
✓
$A$ and $B$
C
Only $C$
D
$B$ and $C$

Answer

Correct option: B.

$A$ and $B$

$\Rightarrow\text{E}\perp\overrightarrow{\text{B}}\ \&\ \overrightarrow{\text{V}}\perp\overrightarrow{\text{E}}$

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MCQ 121 Mark

Two ions have equal masses but one is singly$-$ionised and the other is doubly$-$ionised. They are projected from the same place in a uniform magnetic field with the same velocity perpendicular to the field.

Both ions will move along circles of equal radii.
The circle described by the singly$-$ionised charge will have a radius that is. double that of the other circle.
The two circles do not touch each other.
The two circles touch each other.

A
Only $a$
B
Only $c$
✓
$b$ and $d$
D
All of the above

Answer

Correct option: C.

$b$ and $d$

$\text{r}=\frac{\text{mv}}{\text{qB}}$
If charge of singly ionized $= e$
Then charge of doubly ionized $= ze$
The circle described by the singly $-$ ionized charge will have a radius double that of the other circle.
The two circle touch each other because brojected from the same place.

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MCQ 131 Mark

Which of the following particles will have minimum frequency of revolution when projected with the same velocity perpendicular to a magnetic field?

A
Electron
B
Proton
C
$He^+$
✓
$Li^+$

Answer

Correct option: D.

$Li^+$

$\text{T}=\frac{2\pi\text{r}}{\text{v}\bot}\ ...(1)$
$\text{r}=\frac{\text{mv}_1}{\text{qB}}$
$\frac{\text{r}}{\text{v}\bot}=\frac{\text{m}}{\text{qB}}\ ...(2)$
from eq. $(1)\ \&\ (2)$ we get
$\text{T}=\frac{2\pi\text{m}}{\text{qB}}$
$\text{f}=\frac{1}{\text{T}}=\frac{\text{qB}}{2\pi\text{m}}$
Charge of all these particles are same but mass of $Li^+$ is Highest.
$\therefore\text{ mass}\uparrow,\ \text{f}\downarrow$

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MCQ 141 Mark

If a charged particle projected in a gravity$-$free room deflects:

There must be an electric field.
There must be a magnetic field.
Both fields cannot be zero.
Both fields can be non zero.

A
Only $A$
B
$A$ and $B$
C
$B$ and $C$
✓
$C$ and $D$

Answer

Correct option: D.

$C$ and $D$

If a charged particle is projected in a gravity free room with some velocity, then its deflection depends on whether the particle experiences electric force or magnetic force. If electric field or magnetic field is absent in the space, then the charged particle will continue to move in the same direction with the same velocity. Thus, both electric and magnetic fields cannot be zero.
If force on the charged particle due to electric field is equal and opposite to the force due to magnetic field, then
$\text{F}=\text{qE}=\text{qvB}$
$\text{v}=\frac{\text{E}}{\text{B}}$
Thus, if anyone of the two fields is non zero, the charged particle will get deflect. Therefore, the correct option is $(c)$ and $(d).$

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MCQ 151 Mark

If a charged particle at rest experiences no electromagnetic force:

A
The electric field must be zero.
B
The magnetic field must be zero.
C
The magnetic field may or may not be zero.
✓
Both $A$ and $C$

Answer

Correct option: D.

Both $A$ and $C$

Force on charged particle in an electric eld, $\text{F} = \text{qE} \ ...(1)$
Force on charged particle in a magnetic eld $\text{F} = \text{q} (\text{v}\times\text{b}) = \text{qvB} \sin\theta \ ...(2)$
Where boldface letter represent vector nature of that quantity, $q$ is charge of the particle, $v$ is the velocity of the particle $($if any$)$, and $\theta$ is the angle between velocity and magnetic eld.
From $(1), F_E = 0$ only when either $q = 0$ or $E = 0.$
Let $q \neq 0,$ and $F \neq 0,$ then we must have $E \neq 0$
From $(2),$ if $q \neq 0, v \neq 0$ and $B \neq 0$ even then $F_B$ can be 'zero' because of $\theta = 0^\circ$ or $180^\circ$

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MCQ 161 Mark

A charged particle moves along a circle under the action of possible constant electric and magnetic fields. Which of the following are possible?

A
$\text{E}=0,\ \text{B}=0$
✓
$\text{E}=0,\ \text{B}\not=0$
C
$\text{E}\not=0,\ \text{B}=0$
D
$\text{E}\not=0,\ \text{B}\not=0$

Answer

Correct option: B.

$\text{E}=0,\ \text{B}\not=0$

A charged particle moves along a circle that mean Magnetic force is provides centripetal force that causes particle is move in a circle.
So, $\text{E}=0,\ \text{B}\not=0$

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MCQ 171 Mark

An electron is moving along the positive $x-$axis. You want to apply a magnetic field for a short time so that the electron may reverse its direction and move parallel to the negative $x-$axis. This can be done by applying the magnetic field along:

A
$y-$axis.
B
$z-$axis.
✓
Both $a$ and $b$
D
$z-$axis only.

Answer

Correct option: C.

Both $a$ and $b$

$\text{F}=\text{q}(\overrightarrow{\text{V}}\times\overrightarrow{\text{B}})$
This can be done by applying the Magnetic field along $y$ axis or $z$ axis.

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MCQ 181 Mark

If a charged particle kept at rest experiences an electromagnetic force:

A
The electric field must not be zero.
B
The magnetic field must not be zero.
C
The magnetic field may or may not be zero.
✓
Both $a$ and $c$

Answer

Correct option: D.

Both $a$ and $c$

Since particle is at rest, i.e. $v=0,$
hence $Fm=0$
For electric force, $E\neq 0$

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MCQ 191 Mark

A charged particle moves in a gravity$-$free space without change in velocity. Which of the following is are possible:

$\text{E}=0,\ \text{B}=0$
$\text{E}=0,\ \text{B}\not=0$
$\text{E}\not=0,\ \text{B}=0$
$\text{E}\not=0,\ \text{B}\not=0$

A
Only $a$
B
$a$ and $b$
C
only $d$
✓
$a,b$ and $d$

Answer

Correct option: D.

$a,b$ and $d$

$\Rightarrow$ Particle move with constant velocity in ay direction. So, $B = 0, E = 0$
$\Rightarrow$ Particle move in a circle with constant speed. Magnetic force is provide the centripetal force that causes particle is move in a circle.
$\Rightarrow$ If $\text{qE = qvB}$ and Magnetic Electric force in opposite direction in this case particle also move with uniform speed.

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MCQ 201 Mark

A particle moves in a region having a uniform magnetic field and a parallel, uniform electric field. At some instant, the velocity of the particle is perpendicular to the field direction. The path of the particle will be:

A
A straight line.
B
A circle.
C
A helix with uniform pitch.
✓
A helix with nonuniform pitch.

Answer

Correct option: D.

A helix with nonuniform pitch.

$\text{F}=\text{q}\vec{\text{E}}+\text{q}(\vec{\text{V}}\times\vec{\text{B}})$
$\text{F}=\text{q}\vec{\text{E}}$ provides the acceleration in 'x' direction.
$\text{F}_2=\text{}\text{q}(\vec{\text{V}}\times\vec{\text{B}})$ provides the centripetal Force.
The path of the particle will be ahelix with nonuniform pitch.

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