Solved papers for JEE Main & Advanced Physics Rotational Motion JEE PYQ-Rotational Motion

JEE PYQ-Rotational Motion Total Questions - 122

1) Two identical particles move towards each other with velocity 2v and v respectively. The velocity of centre of mass is                                                                                                                                       [AIEEE 2002]

A)

  v

B)

                   \[v/3\]

C)

  \[v/2\]

D)

       zero

View Answer
2) Initial angular velocity of a circular disc of mass M is C\[{{\omega }_{\,1}}\]. Then, two small spheres of mass m are attached gently to two diametrically opposite points on the edge of the disc. What is the final angular velocity of the disc?                                                                                                                                             [AIEEE 2002]

A)

  \[\left( \frac{M+m}{M} \right){{\omega }_{1}}\]

B)

       \[\left( \frac{M+m}{m} \right){{\omega }_{1}}\]

C)

  \[\left( \frac{M}{M+4m} \right){{\omega }_{1}}\]

D)

       \[\left( \frac{M}{M+2m} \right){{\omega }_{1}}\]

View Answer
3) A solid sphere, a hollow sphere and a ring are released from top of an inclined plane (frictionless) so that they slide down the plane. Then, maximum acceleration down the plane is for (no rolling)                             [AIEEE 2002]

A)

  solid sphere

B)

       hollow sphere

C)

  ring

D)

       All same

View Answer
4) Moment of inertia of a circular wire of mass M and radius R about its diameter is                    [AIEEE 2002]

A)

  \[M{{R}^{2}}/2\]

B)

                  \[M{{R}^{2}}\]

C)

  \[2M{{R}^{2}}\]

D)

       \[M{{R}^{2}}/4\]

View Answer
5) A particle of mass m moves along line PC with velocity v as shown. What is the angular momentum of the particle about O? [AIEEE 2002]

A)

  mvL

B)

  mvl

C)

  mvr

D)

       0

View Answer
6) A circular disc X of radius R is made from an iron plate of thickness t and another disc Y of radius 4R is made from an iron plate of thickness t/4. Then, the relation between the moment of inertia \[{{I}_{X}}\] and \[{{I}_{Y}}\] is [AIEEE 2003]

A)

              \[{{l}_{Y}}=32\,{{l}_{X}}\]

B)

       \[{{l}_{Y}}=16\,{{l}_{X}}\]

C)

  \[{{l}_{Y}}=\,{{l}_{X}}\]

D)

                   \[{{l}_{Y}}=\,64{{l}_{X}}\]

View Answer
7) A particle performing uniform circular motion has angular momentum L. If its angular frequency is doubled and its kinetic energy halved, then the new angular momentum is                                                [AIEEE 2003]

A)

  \[\frac{L}{4}\]

B)

  2L

C)

  4L

D)

  \[\frac{L}{2}\]

View Answer
8) Let F be the force acting on a particle having position vector r and t be the torque of this force about the origin. Then,              [AIEEE 2003]

A)

  \[r\,.\,\tau =0\] and \[F\,.\,\,\tau \ne 0\]

B)

       \[r\,.\,\,\tau \ne 0\] and \[F\,.\,\,\tau =0\]

C)

  \[r\,.\,\,\tau \ne 0\] and \[F\,.\,\,\tau \ne 0\]

D)

  \[r\,.\,\,\tau =0\] and \[F\,.\,\,\tau =0\]

View Answer
9) A solid sphere is rotating in free space. If the radius of the sphere is increased keeping mass same which one of the following will not be affected?                                                                [AIEEE 2004]

A)

  Moment of inertia

B)

  Angular momentum

C)

  Angular velocity

D)

  Rotational kinetic energy

View Answer
10) One solid sphere A and another hollow sphere B are of same mass and same outer radii. Their moment of inertia about their diameters are respectively\[{{I}_{A}}\]and\[{{I}_{B}}\]such that where\[{{d}_{A}}\]and\[{{d}_{B}}\]are their densities.                                                                                                 [AIEEE 2004]

A)

  \[{{I}_{A}}={{I}_{B}}\]

B)

       \[{{I}_{A}}>{{I}_{B}}\]

C)

  \[{{I}_{A}}<{{I}_{B}}\]

D)

       \[\frac{{{I}_{A}}}{{{I}_{B}}}<\frac{{{d}_{A}}}{{{d}_{B}}}\]

View Answer
11) An annular ring with inner and outer radii\[{{R}_{1}}\]and\[{{R}_{2}}\]is rolling without slipping with a uniform angular speed. The ratio of the forces experienced by the two particles situated on the inner and outer parts of the ring,\[\frac{{{F}_{1}}}{{{F}_{2}}}\]is                                                                           [AIEEE 2005]

A)

                                                                                                                                      \[\frac{{{R}_{2}}}{{{R}_{1}}}\]

B)

       \[{{\left( \frac{{{R}_{1}}}{{{R}_{2}}} \right)}^{2}}\]

C)

  1

D)

       \[\frac{{{R}_{1}}}{{{R}_{2}}}\]

View Answer
12) The moment of inertia of uniform semi-circular disc of mass M and radius r about a line perpendicular to the plane of the disc through the centre is                                                                                   [AIEEE 2005]

A)

  \[\frac{1}{4}M{{r}^{2}}\]

B)

       \[\frac{2}{5}M{{r}^{2}}\]

C)

  \[M{{r}^{2}}\]

D)

       \[\frac{1}{2}M{{r}^{2}}\]

View Answer
13) AT shaped object with dimensions shown in the figure, is lying on a smooth floor. A force F is applied at the point P parallel to AB, such that the object has only the translational motion without rotation. Find the location of P with respect to C.                                                                                                                                                 [AIEEE 2005]

A)

  \[\frac{2}{3}l\]

B)

                 \[\frac{3}{2}l\]

C)

  \[\frac{4}{3}l\]

D)

     \[l\]

View Answer
14) Consider a two particle system with particles having masses\[{{m}_{1}}\]and\[{{m}_{2}}\]. If the first particle is pushed towards the centre of mass through a distance d, by what distance should the second particle be moved, so as to keep the centre of mass at the same position?                                                                               [AIEEE 2006]

A)

  \[\frac{{{m}_{2}}}{{{m}_{1}}}d\]

B)

       \[\frac{{{m}_{1}}}{{{m}_{1}}+{{m}_{2}}}d\]

C)

  \[\frac{{{m}_{1}}}{{{m}_{2}}}d\]

D)

       \[d\]

View Answer
15) Four point masses, each of value m, are placed at the corners of a square ABCD of side 1. The moment of inertia of this system about an axis passing through A and parallel to BD is                                  [AIEEE 2006]

A)

  \[2m{{l}^{2}}\]

B)

       \[\sqrt{3}\,m{{l}^{2}}\]

C)

  \[3\,m{{l}^{2}}\]

D)

       \[\,m{{l}^{2}}\]

View Answer
16) A force of \[-F\hat{k}\] acts on O, the   origin   of   the coordinate system. The torque about the point \[(1,-1)\]is                                                                                                                                                [AIEEE 2006]

A)

  \[F(\hat{i}-\hat{j})\]

B)

       \[-F(\hat{i}+\hat{j})\]

C)

  \[F(\hat{i}+\hat{j})\]

D)

       \[-F(\hat{i}-\hat{j})\]

View Answer
17) A thin circular ring of mass m and radius R is rotating about its axis with a constant angular velocity\[\omega \]. Two objects each of mass M are attached gently to the opposite ends of a diameter of the ring. The ring now rotates with an angular velocity\[\omega '\]is equal to                                                                                  [AIEEE 2006]

A)

  \[\frac{\omega (m+2M)}{m}\]

B)

       \[\frac{\omega (m-2M)}{(m-2M)}\]

C)

  \[\frac{\omega m}{(m+M)}\]

D)

     \[\frac{\omega m}{(m+2M)}\]

View Answer
18)

For the given uniform square lamina ABCD, whose centre is O                                    [AIEEE 2007]

A)

  \[f(x)=\]

B)

       \[{{\log }_{e}}x\]

C)

  \[2{{\log }_{3}}e\]

D)

       \[\frac{1}{2}{{\log }_{e}}3\]

View Answer
19) A circular disc of radius R is removed from a bigger circular disc of radius 2R, such that the circumference of the discs coincide. The centre of mass of the new disc is\[(3,\infty )\]from the centre of the bigger disc. The value of a is [AIEEE 2007]

A)

  \[(-\infty ,-3)\]

B)

       \[x=(2\times {{10}^{-2}})\cos \pi t\]

C)

  \[a=2\times {{10}^{-2}}m=2cm\]

D)

       \[t=0,\]

View Answer
20) A round uniform body of radius R, mass M and moment of inertia\[x=2\text{ }cm\]rolls down (without slipping) an inclined plane making an angle 6 with the horizontal.                                                                   [AIEEE 2007]             Then, its acceleration is

A)

  \[\frac{1}{4}\]

B)

       \[=\frac{T}{4}\]

C)

  \[\omega =\frac{2\pi }{T}=\pi \]

D)

       \[\Rightarrow \]

View Answer
21) Angular momentum of the particle rotating with a central force is constant due to             [AIEEE 2007]

A)

  constant force

B)

  constant linear momentum

C)

  zero torque

D)

  constant torque

View Answer
22) Consider a uniform square plate of side a and mass m. The moment of inertia of this plate about an axis perpendicular to its plane and passing through one of its corners is                                                                    [AIEEE 2008]

A)

  \[\frac{7}{12}m{{a}^{2}}\]

B)

       \[\frac{2}{3}m{{a}^{2}}\]

C)

  \[\frac{5}{6}m{{a}^{2}}\]

D)

       \[\frac{1}{12}m{{a}^{2}}\]

View Answer
23) A thin rod of length L is lying along the x-axis with its ends at \[x=0\] and \[x=L\]. Its linear density (mass/length) varies with x as \[k{{\left( \frac{x}{L} \right)}^{n}}\], where n can be zero or any positive number. If the position \[{{x}_{CM}}\] of the centre of mass of the rod is plotted against n, which of the following graphs best approximates the dependence of \[{{x}_{CM}}\] on n?                            [AIEEE 2008]

A)



B)



C)



D)



View Answer
24) A thin uniform rod of length l and mass m is swinging freely about a horizontal axis passing through its end. Its maximum angular speed is \[\omega \]. Its centre of mass rises to a maximum height of                         [AIEEE 2009]

A)

  \[\frac{1}{3}\frac{{{\ell }^{2}}{{\omega }^{2}}}{g}\]

B)

       \[\frac{1}{6}\frac{\ell \omega }{g}\]

C)

       \[\frac{1}{2}\frac{{{\ell }^{2}}{{\omega }^{2}}}{g}\]

D)

       \[\frac{1}{6}\frac{{{\ell }^{2}}{{\omega }^{2}}}{g}\]

View Answer

25)

A small particle of mass m is projected at an angle\[\theta \]with the x-axis with an initial velocity v0 in the\[x-y\]plane as shown in the figure. At a time \[t<\frac{{{v}_{0}}\sin \theta }{g},\] the angular momentum of the particle is - [AIEEE 2010]

\[\frac{1}{2}mg{{v}_{0}}{{t}^{2}}\cos \theta \hat{i}\]

\[-mg{{v}_{0}}{{t}^{2}}\cos \theta \hat{j}\]

\[mg{{v}_{0}}t\cos \theta \hat{k}\]

\[-\frac{1}{2}mg{{v}_{0}}{{t}^{2}}\cos \theta \hat{k}\]

View Answer

26) A pulley of radius 2 m is rotated about its axis by a force \[F=(20\,t-5{{t}^{2}})\] newton (where t is measured in seconds) applied tangentially. If the moment of inertia of the pulley about its axis of rotation is 10 kg \[{{m}^{2}}\], the number of rotations made by the pulley before its direction of motion if reversed is                                   [AIEEE 2011]

A)

More than 9

B)

  Less than 3

C)

  More than 3 but less than 6

D)

       More than 6 but less than 9

View Answer
27) A thin horizontal circular disc is rotating about a vertical axis passing through its centre. An insect is at rest at a point near the rim of the disc. The insect now moves along a diameter of the disc to reach its other end. During the journey of the insect the angular speed of the disc                                                 [AIEEE 2011]

A)

  First increase and then decrease

B)

  Remains unchanged

C)

  Continuously decreases

D)

  Continuously increases

View Answer
28) A mass m hangs with the help of a string wrapped around a pulley on a frictionless bearing. The pulley has mass m and radius R. Assuming pulley to be a perfect uniform circular disc, the acceleration of the mass m, if the string does not slip on the pulley, is                                                                                                                      [AIEEE 2011]

A)

\[\frac{g}{3}\]

B)

                   \[\frac{3}{2}g\]

C)

  g

D)

                   \[\frac{2}{3}g\]

View Answer
29) A diatomic molecule is made of two masses \[{{m}_{1}}\] and \[{{m}_{2}}\] which are separated by a distance r. If we calculate its rotational energy by applying Bohrs rule of angular momentum quantization, its energy will be given by: (n is an integer)                                                                                                                   [AIEEE 2012]

A)

        \[\frac{{{({{m}_{1}}+{{m}_{2}})}^{2}}{{n}^{2}}{{h}^{2}}}{2m_{1}^{2}m_{2}^{2}{{r}^{2}}}\]

B)

       \[\frac{{{n}^{2}}{{h}^{2}}}{2({{m}_{1}}+{{m}_{2}}){{r}^{2}}}\]

C)

              \[\frac{2{{n}^{2}}{{h}^{2}}}{({{m}_{1}}+{{m}_{2}}){{r}^{2}}}\]

D)

       \[\frac{({{m}_{1}}+{{m}_{2}}){{n}^{2}}{{h}^{2}}}{2{{m}_{1}}{{m}_{2}}{{r}^{2}}}\]

View Answer
30) A circular hole of diameter R is cut from a disc of mass M and radius R, -the circumference of the cut passes through the centre of the disc. The moment of inertia of the remaining portion of the disc about an axis perpendicular to the disc and passing through its centre is [JEE ONLINE 07-05-2012]

A)

  \[\left( \frac{15}{32} \right)M{{R}^{2}}\]

B)

       \[\left( \frac{1}{8} \right)M{{R}^{2}}\]

C)

  \[\left( \frac{3}{8} \right)M{{R}^{2}}\]

D)

       \[\left( \frac{13}{32} \right)M{{R}^{2}}\]

View Answer

31) A solid sphere having mass m and radius r rolls down an inclined plane. Then its kinetic energy is [JEE ONLINE 07-05-2012]

\[\frac{5}{7}\]rotational and \[\frac{2}{7}\]translational

\[\frac{2}{7}\]rotational and \[\frac{5}{7}\]translational

\[\frac{2}{5}\]rotational and \[\frac{3}{5}\]translational

\[\frac{1}{2}\]rotational and \[\frac{1}{2}\]translational

View Answer

32)

A solid sphere is rolling on a surface as shown in figure, with a translational velocity \[v\,m\,{{s}^{-1}}.\] If it is to climb the inclined surface continuing to roll without slipping, then minimum velocity for this to happen is

[JEE ONLINE 12-05-2012]

\[\sqrt{2gh}\]

\[\sqrt{\frac{7}{5}gh}\]

\[\sqrt{\frac{7}{2}gh}\]

\[\sqrt{\frac{10}{7}gh}\]

View Answer

33)

This question has Statement land Statement 2. [JEE ONLINE 12-05-2012]

Of the four choices given after the Statements, choose the one that best describes the two Statements.

Statement 1: When moment of inertia/of a body rotating about an axis with angular speed \[\omega \]increases, its angular momentum L is unchanged but the kinetic energy K increases if there is no torque applied on it.

Statement 2: \[L=I\omega ,\] kinetic energy of rotation \[=\frac{1}{2}I{{\omega }^{2}}\]

Statement 1 is true, Statement 2 is true, Statement 2 is not the correct explanation of Statement 1.

Statement 1 is false, Statement 2 is true.

Statement 1 is true, Statement 2 is true. Statement 2 is correct explanation of the Statement 1.

Statement 1 is true, Statement 2 is false.

View Answer

34) A stone of mass m, tied to the end of a string, is whirled around in a circle on a horizontal frictionless table. The length of the string is reduced gradually keeping the angular momentum of the stone about the centre of the circle constant. Then, the tension in the string is given by \[T=A{{r}^{n}},\]where A is a constant, r is the instantaneous radius of the circle. The value of n is equal to [JEE ONLINE 26-05-2012]

- 1

- 2

- 4

- 3

View Answer

35) A thick-walled hollow sphere has outside radius \[{{R}_{0}}.\]It rolls down an incline without slipping and its speed at the bottom is \[{{v}_{0}}.\] Now the incline is waxed, so that it is practically frictionless and the sphere is observed to slide down (without any rolling). Its speed at the bottom is observed to be \[5{{v}_{0}}/4.\]The radius of gyration of the hollow sphere about an axis through its centre is [JEE ONLINE 26-05-2012]

\[3{{R}_{0}}/2\]

\[3{{R}_{0}}/4\]

\[9{{R}_{0}}/16\]

\[3{{R}_{0}}\]

View Answer

36) A hoop of radius r and mass m rotating with an angular velocity ω0 is placed on a rough horizontal surface. The initial velocity of the centre of the hoop is zero. What will be the velocity of the centre of the hoop when it ceases to slip? [JEE MAIN 2013]

\[\frac{r{{\omega }_{0}}}{4}\]

\[\frac{r{{\omega }_{0}}}{3}\]

\[\frac{r{{\omega }_{0}}}{2}\]

\[r{{\omega }_{0}}\]

View Answer

37) A bullet of mass 10 g and speed 500 m/s is fired into a door and gets embedded exactly at the centre of the door. The door is 1.0 m wide and weighs 12 Kg. It is hinged at one end and rotates about a vertical axis practically without friction. The angular speed of the door just ager the bullet embeds into it will be: [JEE ONLINE 09-04-2013]

6.25 rad/sec

0.625 rad/sec

3.35 rad/sec

0.335 rad/sec

View Answer

38) A tennis ball (treated as hollow spherical shell) starting from O rolls down a hill. At point A the ball becomes air borne leaving at an angle of \[{{30}^{0}}\] with the horizontal. The ball strikes the ground at B. What is the value of the distance AB? (Moment of inertia of spherical shell of mass m and radius R about its diameter \[=\frac{2}{3}{{\operatorname{mR}}^{2}})\] [JEE ONLINE 22-04-2013]

1.87 m

2.08 m

1.57 m

1.77 m

View Answer

39) A particle of mass 2 kg is moving such hat at time t, its position, in meter, is given by \[\overset{\to }{\mathop{\operatorname{r}}}\,(\operatorname{t})=5\hat{i}-2{{\operatorname{t}}^{2}}\hat{j}.\] The angular momentum of the particle at \[\operatorname{t}=2s\] about the origin in kg \[{{\operatorname{m}}^{-2}}\]\[{{\operatorname{s}}^{-2}}\] is: [JEE ONLINE 23-04-2013]

\[-80\hat{k}\]

\[\left( 10\hat{i}-16\hat{j} \right)\]

\[-40\hat{k}\]

\[40\hat{k}\]

View Answer

40) A boy of mass 20 kg is standing on a 80 kg free to move long cart. There is negligible friction between cart and ground. Initially, the boy is standing 25 m from a wall. If he walks 10 m on the cart toward the wall, then the final distance of the boy from the wall will be: [JEE ONLINE 23-04-2013]

15 m

12.5 m

15.5 m

17 m

View Answer

41) A 70 Kg man leaps vertically into the air from a crouching position. To take the leap the man pushes the pushes the ground with a constant force F to raise himself. The center of gravity rises by 0.5 m before he leaps. After the leap the c.g. rises by another 1 m. The maximum power delivered by the muscles is: (Take g = 10 \[\text{m}{{\text{s}}^{\text{2}}}\]). [JEE ONLINE 23-04-2013]

\[\text{6}\text{.26}\times \text{1}{{\text{0}}^{\text{3}}}\] Watts at the start

\[\text{6}\text{.26}\times \text{1}{{\text{0}}^{\text{3}}}\] Watts at take off

\[\text{6}\text{.26}\times \text{1}{{\text{0}}^{\text{4}}}\] Watts at the start

\[\text{6}\text{.26}\times \text{1}{{\text{0}}^{\text{4}}}\] Watts at take off

View Answer

42) A ring of mass M and radius R is rotating about its axis with angular velocity \[\omega \]. Two identical bodies each of mass m are now gently attached at the two ends of a diameter of the ring. Because of this, the kinetic energy loss will be: [JEE ONLINE 25-04-2013]

\[\frac{\operatorname{m}(\operatorname{M}+2m)}{\operatorname{M}}{{\omega }^{2}}{{R}^{2}}\]

\[\frac{\operatorname{Mm}}{(\operatorname{M}+m)}{{\omega }^{2}}{{R}^{2}}\]

\[\frac{\operatorname{Mm}}{(\operatorname{M}+2m)}{{\omega }^{2}}{{R}^{2}}\]

\[\frac{\left(\operatorname{M}+m \right)\operatorname{M}}{(\operatorname{M}+2m)}{{\omega }^{2}}{{R}^{2}}\]

View Answer

43) A bob of mass m attached to an inextensible string of length l is suspended from a vertical support. The bob rotates in a horizontal circle with an angular speed \[\omega \]rad/s about the vertical. About the point of suspension: [JEE MAIN 2014]

\[\left( \frac{7}{12}m,\frac{\sqrt{3}}{8}m \right)\]

\[\left( \frac{\sqrt{3}}{4}m,\frac{5}{12}m \right)\]

\[\left( \frac{7}{12}m,\frac{\sqrt{3}}{4}m \right)\]

\[\left( \frac{\sqrt{3}}{8}m,\frac{7}{12}m \right)\]

View Answer

108) The radius of gyration of a uniform rod of length l, about an axis passing through a point \[\frac{l}{\text{4}}\] away from the centre of the rod, and perpendicular to it, is: [JEE MAIN Held on 07-01-2020 Morning]

\[\sqrt{\frac{\text{7}}{\text{48}}}l\]

\[\frac{\text{1}}{\text{8}}l\]

\[\frac{1}{4}l\]

\[\sqrt{\frac{\text{3}}{\text{8}}}l\]

View Answer

109)

As shown in the figure, a bob of mass m is tied by a massless string whose other end portion is wound on a fly wheel (disc) of radius r and mass m. When released from rest the bob starts falling vertically. When it has covered a distance of h, the angular speed of the wheel will be:

[JEE MAIN Held on 07-01-2020 Morning]

\[r\sqrt{\frac{3}{2gh}}\]

\[r\sqrt{\frac{3}{4gh}}\]

\[\frac{1}{r}\sqrt{\frac{4gh}{3}}\]

\[\frac{1}{r}\sqrt{\frac{2gh}{3}}\]

View Answer

110)

Three point particles of masses 1.0 kg, 1.5 kg and 2.5 kg are placed at three corners of a right angle triangle of sides 4.0 cm, 3.0 cm and 5.0 cm as shown in the figure. The center of mass of system is at a point

[JEE MAIN Held on 07-01-2020 Morning]

1.5 cm right and 1.2 cm above 1 kg mass

2.0 cm right and 0.9 cm above 1 kg mass

0.9 cm right and 2.0 cm above 1 kg mass

0.6 cm right and 2.0 cm above 1 kg mass

View Answer

111) Mass per unit area of a circular disc of radius a depends on the distance r from its centre as\[\sigma \,(r)=A+Br\]. The moment of inertia of the disc about the axis, perpendicular to the plane and passing through its centre is: [JEE MAIN Held on 07-01-2020 Evening]

\[2\pi {{a}^{4}}\,\left( \frac{A}{4}+\frac{B}{5} \right)\]

\[\pi {{a}^{4}}\,\left( \frac{A}{4}+\frac{aB}{5} \right)\]

\[2\pi {{a}^{4}}\,\left( \frac{A}{4}+\frac{aB}{5} \right)\]

\[2\pi {{a}^{4}}\,\left( \frac{aA}{4}+\frac{B}{5} \right)\]

View Answer

112) An elevator in a building can carry a maximum of 10 persons, with the average mass of each person being 68 kg. The mass of the elevator itself is 920 kg and it moves with a constant speed of 3 m/s. The frictional force opposing the motion is 6000 N. If the elevator is moving up with its full capacity, the power delivered by the motor to the elevator \[(g=10\text{ }m/{{s}^{2}})\]must be at least [JEE MAIN Held on 07-01-2020 Evening]

56300 W

66000 W

48000 W

62360 W

View Answer

113)

Consider a uniform cubical box of side a on a rough floor that is to be moved by applying minimum possible force F at a point b above its centre of mass (see figure). If the coefficient of friction is\[\mu =0.4,\] the maximum possible value of \[100\times \frac{b}{a}\] for box not to topple before moving is _________. [JEE MAIN Held on 07-01-2020 Evening]

View Answer

114)

The coordinates of centre of mass of a uniform Flag shaped lamina (thin flat plate) of mass 4 kg. (The coordinates of the same are shown in figure) are [JEE MAIN Held On 08-01-2020 Morning]

\[\left( 0.75\text{ }m,\text{ }1.75\text{ }m \right)\]

\[\left( 1.25\text{ }m,\text{ }1.50\text{ }m \right)\]

\[\left( 1\text{ }m,\text{ }1.75\text{ }m \right)\]

\[\left( 0.75\text{ }m,\text{ }0.75\text{ }m \right)\]

View Answer

115) Consider a uniform rod of mass M = 4 m and length l pivoted about its centre. A mass moving with velocity v making angle\[\theta =\frac{\pi }{4}\]to the rods long axis collides with one end of the rod and sticks to it. The angular speed of the rod-mass system just after the collision is [JEE MAIN Held On 08-01-2020 Morning]

\[\frac{4}{7}\frac{V}{l}\]

\[\frac{3}{7}\frac{V}{l}\]

\[\frac{3}{7\sqrt{2}}\frac{V}{l}\]

\[\frac{3\sqrt{2}}{7}\frac{V}{l}\]

View Answer

116) A uniform sphere of mass 500 g rolls without slipping on a plane horizontal surface with its centre moving at a speed of 5.00 cm/s. Its kinetic energy is [JEE MAIN Held on 08-01-2020 Evening]

\[6.25\times {{10}^{4}}J\]

\[1.13\times {{10}^{3}}J\]

\[8.75\times {{10}^{\,4}}\text{ }J\]

\[8.75\times {{10}^{3}}\text{ }J\]

View Answer

117) A particle of mass m is dropped from a height h above the ground. At the same time another particle of the same mass is thrown vertically upwards from the ground with a speed of\[\sqrt{2gh}\]. If they collide head-on completely inelastically, the time taken for the combined mass to reach the ground, in units of \[\sqrt{\frac{h}{g}}\] is [JEE MAIN Held on 08-01-2020 Evening]

\[\sqrt{\frac{1}{2}}\]

\[\sqrt{\frac{3}{4}}\]

\[\frac{1}{2}\]

\[\sqrt{\frac{3}{2}}\]

View Answer

118)

As shown in fig. when a spherical cavity (centred at O) of radius 1 is cut out of a uniform sphere of radius R (centred at C), the centre of mass of remaining (shaded) part of sphere is at G, i.e. on the surface of the cavity. R can be determined by the equation [JEE MAIN Held on 08-01-2020 Evening]

\[\left( {{R}^{2}}\text{+}R+1 \right)\left( 2R \right)=1\]

View Answer

119)

Three solid spheres each of mass m and diameter d are stuck together such that the lines connecting the centres form an equilateral triangle of side of length d. The ratio

of moment of inertia

of the system about an axis passing the centroid and about center of any of the spheres

and perpendicular to the plane of the triangle is:

[JEE MAIN Held on 09-01-2020 Morning]

View Answer

120)

One end of a straight uniform 1 m long bar is pivoted on horizontal table. It is released from rest when it makes an angle

from the horizontal (see figure). Its angular speed when it hits the table is given as

, where n is an integer. The value of n is ______ [JEE MAIN Held on 09-01-2020 Morning]

View Answer

121) A rod of length L has non-uniform linear mass density given by

, where a and b are constants and

. The value of x for the centre of mass of the rod is at [JEE MAIN Held on 09-01-2020 Evening]

View Answer

122)

A uniformly thick wheel with moment of inertia I and radius R is free to rotate about its centre of mass (see fig.), A massless string is warapped over its rim and two blocks of masses