Q 1 :

A magnetic field $\overrightarrow{B}=B_0\hat{j},$ exists in the region $a<x<2a$ and $\overrightarrow{B}=-B_0\hat{j},$ in the region $2a<x<3a,$ where $B_0$ is a positive constant. A positive point charge moving with a velocity $\overrightarrow{v}=v_0\hat{i},$ where $v_0$ is a positive constant, enters the magnetic field at $x=a$. The trajectory of the charge in this region can be like              [2007]

Q 2 :

An electron travelling with a speed $u$ along the positive $x$-axis enters into a region of magnetic field where $B=-B_0\hat{k}$ $(x>0).$ It comes out of the region with speed $v$ then                  [2004]

• $v=u$ at $y>0$

   

• $v=u$ at $y<0$

   

• $v>u$ at $y>0$

   

• $v>u$ at $y<0$

   

Q 3 :

For a positively charged particle moving in an $x-y$ plane initially along the $x$-axis, there is a sudden change in its path due to the presence of electric and/or magnetic fields beyond P. The curved path is shown in the $x-y$ plane and is found to be non-circular. Which one of the following combinations is possible?              [2003]

• $\overrightarrow{E}=0;\overrightarrow{B}=b\hat{i}+c\hat{k}$

   

• $\overrightarrow{E}=a\hat{i};\overrightarrow{B}=c\hat{k}+a\hat{i}$

   

• $\overrightarrow{E}=0;\overrightarrow{B}=c\hat{j}+b\hat{k}$

   

• $\overrightarrow{E}=a\hat{i};\overrightarrow{B}=c\hat{k}+b\hat{j}$

   

Q 4 :

A particle of mass m and charge $q$ moves with a constant velocity $v$ along the positive $x$-direction. It enters a region containing a uniform magnetic field $B$ directed along the negative $z$-direction, extending from $x=a$ to $x=b$. The minimum value of $v$ required so that the particle can just enter the region $x>b$ is                   [2002]

• $\frac{qbB}{m}$

   

• $\frac{q(b-a)B}{m}$

   

• $\frac{qaB}{m}$

   

• $\frac{q(b+a)B}{2m}$

   

Q 5 :

Two particles A and B of masses $m_A$ and $m_B$ respectively and having the same charge are moving in a plane. A uniform magnetic field exists perpendicular to this plane. The speeds of the particles are $v_A$ and $v_B$ respectively and the trajectories are as shown in the figure. Then                   [2001]

• $m_A{v}_A<m_B{v}_B$

   

• $m_A{v}_A>m_B{v}_B$

   

• $m_A<m_B$ and $v_A<v_B$

   

• $m_A=m_B$ and $v_A=v_B$

   

Q 6 :

An ionized gas contains both positive and negative ions. If it is subjected simultaneously to an electric field along the $+x$-direction and a magnetic field along the $+z$-direction, then                              [2000]

• positive ions deflect towards $+y$-direction and negative ions towards $-y$ direction

   

• all ions deflect towards $+y$-direction

   

• all ions deflect towards $-y$-direction

   

• positive ions deflect towards $-y$-direction and negative ions towards $+y$-direction.

   

Q 7 :

A particle of charge q and mass m moves in a circular orbit of radius r with an angular speed $\omega$. The ratio of the magnitude of its magnetic moment to that of its angular momentum depends on                 [2000]

• $\omega$ and $q$

   

• $\omega ,q$ and $m$

   

• $q$ and $m$

   

• $\omega$ and $m$

   

Q 8 :

A positive, singly ionized atom of mass number $A_M$ is accelerated from rest by the voltage 192 V. Thereafter, it enters a rectangular region of width $w$ with magnetic field ${\overrightarrow{B}}_0=0.1\hat{k}\text{ Tesla},$ as shown in the figure. The ion finally hits a detector at the distance $x$ below its starting trajectory. [Given: Mass of neutron/proton $=\left(\frac{5}{3}\right)\times {10}^{-27}\text{ kg},$ charge of the electron $=1.6\times {10}^{-19}$C]                   [2024]

Which of the following option(s) is(are) correct?

• The value of $x$ for $H^{+}$ ion is 4 cm.

   

• The value of $x$ for an ion with $A_M=144$ is 48 cm.

   

• For detecting ions with $1\le A_M\le 196$, the minimum height $(x_1-x_0)$ of the detector is 55 cm.

   

• The minimum width $w$ of the region of the magnetic field for detecting ions with $A_M=196$ is 56 cm.

   

Q 9 :

A uniform magnetic field $B$ exists in the region between $x=0$ and $x=\frac{3R}{2}$ (region 2 in the figure) pointing normally into the plane of the paper. A particle with charge $+Q$ and momentum $p$ directed along the $x$-axis enters region 2 from region 1 at point $P_1$ $(y=-R)$. Which of the following option(s) are correct?                [2017]

• For $B>\frac{2}{3}\frac{p}{QR},$ the particle will re-enter region 1.

   

• For $B=\frac{8}{13}\frac{p}{QR},$ the particle will enter region 3 through the point $P_2$ on the $x$-axis.

   

• When the particle re-enters region 1 through the longest possible path in region 2, the magnitude of the change in its linear momentum between point $P_1$ and the farthest point from the $y$-axis is $\frac{p}{\sqrt{2}}.$

   

• For a fixed B, particles of same charge Q and same velocity $v$, the distance between the point $P_1$ and the point of re-entry into region 1 is inversely proportional to the mass of the particle.

   

Q 10 :

A conductor (shown in the figure) carrying constant current $I$ is kept in the $x-y$ plane in a uniform magnetic field $\overrightarrow{B}$. If $F$ is the magnitude of the total magnetic force acting on the conductor, then the correct statement(s) is (are)                    [2015]

• If $\overrightarrow{B}$ is along $\hat{z}$, $F\propto (L+R)$

   

• If $\overrightarrow{B}$ is along $\hat{x}$, $F=0$

   

• If $\overrightarrow{B}$ is along $\hat{y}$, $F\propto (L+R)$

   

• If $\overrightarrow{B}$ is along $\hat{z}$, $F=0$

   

Q 11 :

A particle of mass M and positive charge Q, moving with a constant velocity ${\overrightarrow{u}}_1=4\hat{i}{\text{ m s}}^{-1},$ enters a region of uniform static magnetic field, normal to the $x-y$ plane. The region of the magnetic field extends from $x=0$ to $x=L$ for all values of $y$. After passing through this region, the particle emerges on the other side after 10 milliseconds with a velocity ${\overrightarrow{u}}_2=2(\sqrt{3}\hat{i}+\hat{j}){\text{ ms}}^{-1}.$ The correct statement(s) is (are)                        [2013]

• The direction of the magnetic field is $-z$ direction.

   

• The direction of the magnetic field is $+z$ direction.

   

• The magnitude of the magnetic field is $\frac{50\pi M}{3Q}$ units.

   

• The magnitude of the magnetic field is $\frac{100\pi M}{3Q}$ units.

   

Q 12 :

Consider the motion of a positive point charge in a region where there are simultaneous uniform electric and magnetic fields $\overrightarrow{E}=E_0\hat{j}$ and $\overrightarrow{B}=B_0\hat{j}.$ At time $t=0$, this charge has velocity $\overrightarrow{v}$ in the $x-y$ plane, making an angle $\theta$ with the $x$-axis. Which of the following option(s) is (are) correct for time $t>0$?                [2012]

• If $\theta =0°$, the charge moves in a circular path in the $x-z$ plane.

   

• If $\theta =0°$, the charge undergoes helical motion with constant pitch along the $y$-axis.

   

• If $\theta =10°$, the charge undergoes helical motion with its pitch increasing with time, along the $y$-axis.

   

• If $\theta =90°$, the charge undergoes linear but accelerated motion along the $y$-axis.

   

Q 13 :

An electron and a proton are moving on straight parallel paths with same velocity. They enter a semi-infinite region of uniform magnetic field perpendicular to the velocity. Which of the following statement(s) is/are true?                     [2011]

• They will never come out of the magnetic field region.

   

• They will come out travelling along parallel paths.

   

• They will come out at the same time.

   

• They will come out at different times.

   

Q 14 :

A particle of mass $m$ and charge $q$, moving with velocity $v$ enters Region II normal to the boundary as shown in the figure. Region II has a uniform magnetic field $B$ perpendicular to the plane of the paper. The length of the Region II is $\ell$. Choose the correct choice(s).              [2008]

• The particle enters Region III only if its velocity $v>\frac{q\ell B}{m}$

   

• The particle enters Region III only if its velocity $v<\frac{q\ell B}{m}$

   

• Path length of the particle in Region II is maximum when velocity $v=\frac{q\ell B}{m}$

   

• Time spent in Region II is same for any velocity $v$ as long as the particle returns to Region I.