Electrostatics (Practice questions)

1. A negatively charged ebonite rod attracts a suspended ball of straw. Can we infer that the ball is positively charged? [No]

2. Can two similarly charged balls attract each other? [Yes]

3. How can you charged a metal sphere negatively without touching it? [Induction]

4. If two objects repel one another, you know both carry either a positive charge or negative charge. How would you determine whether these charges are positive or negative? [Repulsion Test]

5. Does motion of the body affect its charge? [No]

6. What is the dimensional formula for $ \epsilon_0 $? [$M^{-1}L^{-3}T^3A^2$]

7. Two small balls having equal positive charge q coulomb are suspended by two insulating string of equal length l meter from a hook fixed to a stand. The whole setup is taken in a satellite into space where there is no gravity. What is the angle between the two strings and the tension in each string? [$180^0$]

8. Two point charges of + 2μ C and + 6 μ C  repel each other with a force of 12 N. If each is given an additional charge of -4μ C, what will be the new force? [$-4N$]

9. Two point charges of 10^-8‑C and -10^-8 C are placed 0.1 m apart. Calculate electric field intensity at A, B, and C shown in figure. [$E_A = 7.2 \times 10^4 N/C $ along AQ, $E_B = 3.2 \times 10^4 N/C $ along PB, $E_C =9 \times 10^3 N/C $ parallel to PQ]

10. When does a charged circular loop behave at a point charge? [When the point is very very far away ]

11. How does a free electron at rest move in an electric field? [Opposite to Electric Field]

12. What does (q₁ + q ₂) = 0 signify? [Dipole]

13. Two-point charges of +16 μ C and -9 μ C are placed 8 cm apart in the air. Determine the position of the point at which the resultant electric field is zero. [24 cm to the right of -9$\mu C$]

14. Four particles, each having a charge q are placed on the four corners A, B, C, D of a regular pentagon ABCD. The distance of each corner from the center is a. Find the electric field at the center of the pentagon. [$\frac{q}{4\pi \epsilon_0 a^2}$ along OE]

15. Two charges of -4 μ C and + 4 μ C are placed at the points A (1, 0, 4) and B (2, -1, 5) located in an electric field E = 0.20 $\hat{i}$ V/cm. Calculate the torque acting on the dipole. [$1.131 \times 10^{-4} N-m $]

16. Can we produce high voltage on the human body without getting a  shock? [Yes]

17. Do electron tend to go to region of high potential or low potential? [High Potential]

18. In a certain 0.1 m³ of space, electric potential is found to be 5 V throughout. What is the electric field in this region? [$E = 0$]

19. Write an expression for potential the energy of two charges  q₁ and q₂ at r₁ and r₂ in a uniform electric field E. [$P.E. = q_1V(\vec{r_1})+q_2V(\vec{r_2})+ \frac{q_1q_2}{4\pi \epsilon_0 |\vec{r_1}-\vec{r_2}|}$]

20. Two point charges 4 μ C and -2 μ C are separated by a distance of 1 m in air. Calculate at what point on the line joining the two charges in the electric potential zero? [$\frac{2}{3}m $ from $4\mu C$ ]

21. An electric field of  20 N/C exists along the X-axis in space. Calculate the potential difference (V_B – V_A) where the coordinates of A and B are given by (i) A (0, 0); B (4m, 2 m) (ii) A (4 m, 2m); B (6 m, 5 m). [$-80V,-40V$]

22. If the potential in the region of space around the point (-1 m, 2m, 3m) is given by V = (10 x² + 5 y² – 3 z²), calculate the three component of electric field at this point. [$E_x=20Vm^{-1},E_y=-20Vm^{-1},E_z=18Vm^{-1}$]

23. The electric field in a certain region of space is $(5\hat{i} + 4\hat{j} -4 \hat{k})$ x 10⁵ N/C. calculate electric flux due to this field over an area of $ (2\hat{i} – \hat{j})$ x 10^-2 m². [$6 \times 10^3 NC^{-1}m^2$]

24. A point charge q moves from a point P to the point S along the path PQRS in a uniform electric field E along the positive direction of the x-axis. Calculate work done in this process, when co-ordinate of P, Q, R,S are (a, b, 0), (2a 0, 0), (a, -b , 0) and (0, 0, 0) respectively. [$-qEa$]

25. Find the capacitance of the combination shown in figure between A and B. [$1\mu F$]

26. A network of four 10 μ F capacitors is connected to a 500 V supply, as shown in figure. Determine the (a) equivalent capacitance of the network and (b) charge on each capacitor. [$C=13.3\mu F, Q_1=Q_2=Q_3=1.7 \times 10^{-3}C, Q_4=5\times 10^{-3}C$ ]

27. Find equivalent capacity between A & B, as shown in figure [$1\mu F$]

28. In figure, find equivalent capacity between A and B. [$5\mu F$]

29. A slab of material of dielectric constant K has the same area as the plates of a parallel plate capacitor but has a thickness (3/4)d, where d is the separation of the plates. How is the capacitance changed when the slab is interested between the plates. [$C=\frac{4K}{3+K}C_0$]

30. Two spheres of radii R and 2 R are charged so that both of these have the same surface charge density. The spheres are located away from each other and are connected by a thin conducting wire. Find the new charge density on the two spheres. [$\sigma_1' = \frac{5}{3}\sigma,\sigma_2' = \frac{5}{6}\sigma$]

31. A spherical shell of radius b with charge Q is expended to radius a. Find the work done by the electric force in the process? [$W = \frac{Q^2}{8\pi \epsilon_0}[\frac{1}{a}-\frac{1}{b}]$]

32. Sketch a graph to show how charge Q is given a capacitor of capacity C varies with the potential difference V. [ Figure ] 

33. The space between the plate of a parallel plate capacitor is filled consecutively with two dielectric layers of thickness d₁ and d₂ having relative permittivities $\epsilon_1$ and $\epsilon_2$ respectively. If a is area of each plate, what is the capacity of a capacitor? [$C = \frac{\epsilon_0 A}{\frac{d_1}{\epsilon_1}+\frac{d_2}{\epsilon_2}}$]

34. The equivalent capacitance of the combination between A and B in the given figure is 4 μ F. pageno.1/160 (i) Calculate the capacitance of capacitor C. (ii) Calculate charge on each capacitor if 12 V battery is connected between A and B. (iii) Calculater potential drop across each capacitor. [$5\mu F, 48\mu C, 2.4V,9.6V$]

35. Calculate the capacitance of the capacitor C in the figure. The equivalent capacitance of the combination between P and Q is 30 μ F. [$60\mu F$]

36. A combination of four identical capacitors is shown in figure . If resultant capacitance of the combination between the point A and D is 1 μ F. Calculate capacitance of each capacitor. [$4 \mu F$]

37. A parallel plate capacitor is filled with a dielectric as shown in figure. What is its capacitance? [$\frac{2\epsilon_0 AK_1K_2}{d(K_1+K_2)}$]

38. Three capacitors of capacitances 2 μ F, 3 μ F and 6 μ F are connected in series with a 12 V battery. All the connecting wires are disconnected. The three positive plates are connected together and the three negative plates are connected together. Find the charges on the three capacitors after the reconnection. [$\frac{72}{11}\mu C,\frac{108}{11}\mu C,\frac{216}{11}\mu C$]

38. Calculate the charges which will flow in sections 1 and 2 in figure, when key K is pressed. [$EC_1,\frac{EC_1C_2}{(C_1+C_2)}$]

39. In the circuit shown in figure, the emf of each battery is E = 12 volt and the capacitance are C₁ = 2.0 μ F and C₂ = 3.0 μ F. Find the charges which flow along the paths 1, 2, 3 when key K is pressed. [$24\mu C,-36\mu C,12\mu C$] 

40. Calculate the equivalent capacitance between the point A and B in the combination shown in figure [$13.44 \mu C$]

41. If C₁ = 3 pF and C₂ = 2 Pf, calculate the equivalent capacitance of the network shown in figure between points A and B. [$1pF$]

42. Find the equivalent capacitance of the combination of capacitors between the points A and B as shown in figure. Also, calculate the total charge that flows in the circuit, when a 100 V battery is connected between the points A and B. [$C = 20\mu F, Q=2\times 10^{-3}C$]

43. A capacitor is made of a flat plate of area A and a second plate having a stair-like structure as shown in figure The width of each stair is a and the height is b. Find the capacitance of the assembly. [$C = \frac{\epsilon_0 A(3d^2+6bd+2b^2)}{3d(b+d)(d+2b)}$]

44. Find out the potential difference across the plates of 1 μ F capacitor in figure. [$3.82 V$]

45. Find the capacitance of three parallel plates, each of area A m² and separated by d₁ and d₂ meter. The in-between spaces are filled with dielectrics of relative permittivity $\epsilon_1$ and $\epsilon_2$. The permittivity of free space in $\epsilon_0$. [$C = \frac{\epsilon_1 \epsilon_2 \epsilon_0 A}{\epsilon_1d_2 + \epsilon_2 d_1}$]

46. An uncharged capacitor is connected to a battery. Show that half the energy supplied by the battery is lost as heat while charging the capacitor. 

47. Obtain the formula for the electric field due to a long thin wire of uniform linear charge density λ without using Gauss’s law. [$E = \frac{\lambda}{2\pi \epsilon_0 r}$]

48. A particle of mass m and charge (-q) enters the region between the two charged plates initially moving along x-axis with speed v_x,  the length of plate is l and a uniform electric field E is maintained between the plates. Show that the vertical deflection of the particle at the far edge of the plate is \[\frac{qEL^2}{(2 m v_x^2)}\].Compare this motion with the motion of a projectile in a gravitational field. 

49. A spherical conducting shell of inner radius r₁ and outer radius r₂ has a charge Q. (a)  A charge q is placed at the center of the shell. What is the surface charge density on the inner and outer surfaces of the shell? (b)  Is the electric field intensity inside a cavity (with no charge) zero, even if the shell is not spherical, but has any irregular shape? Explain.[(i) $\sigma_1 = -\frac{q}{4\pi r_1^2},\sigma_2 = \frac{Q+q}{4\pi r_2^2}$, (ii) $Yes$]

50. Two charges q and -3q are placed fixed on x-axis separated by distance ‘d’. Where should a third charge 2q be placed such that it will not experience any force? [$x = \frac{(1+\sqrt{3})d}{2}$ from 2q]

51. In 1959, Lyttleton and Bondi suggested that the expansion of the universe could be explained if matter carried a net charge. Suppose that the universe is made up of hydrogen atoms with a number density N, which is maintained a constant. Let the charge on the proton be: e_p = -(1 +y) e where e is the electronic charge. (a)    Find the critical value of y such that expansion may start. (b)    Show that the velocity of expansion is proportional to the distance from the centre. [(a) $\approx 10^{-18}$]

52. Consider a sphere of radius R with charge density distributed as $ \rho (r) = kr $ for r< R,  =0 for r> R. (a)    Find the electric field at all points r. (b)  Suppose the total charge on the sphere is 2e, where e is the electron charge. Where can two proton be embedded such that the force on each of them is zero. Assume that the introduction of the proton does not alter the negative charge distribution. [(a) For r<R, $E = \frac{kr^2}{4\epsilon_0}$, For r>R, $E = \frac{kR^4}{4\epsilon_0 r^2}$ (b) $r = \frac{R}{8^{1/4}}$ from center of sphere]

53. Two fixed, identical conducting plates ($ \alpha $ and $\beta $), each of surface area S are charged to -Q and q, respectively, where Q > q > 0. A third identical plate $ \gamma $, free to move is located on the other side of the plate with charge q at a distance d as shown in figure. Third plate is released and collides with the plate $\beta $. Assume the collision is elastic and the time of collision is sufficient to redistributed charge amongst $\beta $ and $\gamma $. (a)    Find the electric field acting on the plate $\gamma $ before collision. (b)   Find the charges on $\gamma $ and $\beta $ after the collision. (c)  Find the velocity of the plates $\gamma $ after the collision and at a distance d from the plate $\beta $. [(a) $E = \frac{q-Q}{2\epsilon_0 S}$, (b) $q_{\beta} = (Q+\frac{q}{2}),q_{\gamma} = \frac{q}{2}$, (c) $(Q-\frac{q}{2})\sqrt{\frac{d}{m\epsilon_0 S}}$]

54. There is another useful system of units, besides the SI/mks A system, called the cgs (centimeter-gram-second). In this system, Coloumb’s law is given by \[F = \frac{Qq}{r^2} \hat{r}\]where the distance r is measured in cm (= 10^-2m), F in dynes (= 10^-5 N ) and the charges in electrostatic units (es units), where 1 es unit of charge = $ \frac{1}{[3]} $ x 10^-9 C. The number [3] actually arises from the speed of light in vacuum which is now taken to be exactly given by c = 2.99792458 x 10⁸ m/s.An approximate value of c then is c =[3] x 10⁸   m/s. Show that the coulomb law in cgs  unit yield 1 esu of charge = 1 (dyne)^1/2 cm. Obtain the  dimensions  of units of charge in terms of mass M, lengh L and time T. Show that it is given in terms of fractional powers of M and L. Write 1 esu of charge = xC, where x is a dimenionless number. Show that this gives \[\frac{1}{4\pi \epsilon_0} = \frac{10^{-9}}{x^2} N.m^2/C^2\]    

55. Two charges -q each are fixed separated by distance 2d. A third charge q of mass m placed at the mid-point is displaced slightly by x (x << d) perpendicular to the line joining the two fixed charges as shown in figure. Show that q will perform simple harmonic oscillation of time period. \[T= [\frac{8\pi^3 \epsilon_0 md^3}{q^2}]^{1/2}\]

56. Total charge -Q is uniformly spread along length of a ring of radius R. A small test charge +q of mass m is kept at the centre of the ring and is given a gentle push along the axis of the ring. Show that the particle executes a simple harmonic oscillation. Obtain its time period. [(b) $T = 2\pi \sqrt{\frac{4\pi \epsilon_0 mR^3}{Qq}}$]

57. Prove that a closed equipotential surface with no charge within itself must enclose an equipotential volume.

58. Calculate potential energy of a point charge -q placed along the axis due to a charge +Q uniformly distributed along a ring of radius R. Sketch P.E. as a function of axial distance z from the centre of the ring. Looking at graph, can you see what would happen if -q is displaced slightly from the centre of the ring (along the axis)? [$U = \frac{-qQ}{4\pi \epsilon_0\sqrt{R^2+z^2}}$]

59. Find the equation of the equipotential for an infinite cylinder of radius r₀, carrying charge of linear density $ \lambda $. [$r=r_0e^{-2\pi \epsilon_0[V(r)-V(r_0)]/\lambda}$]

60. Two point charges of magnitude + q and -q are placed at (- d/2, 0, 0) and (d/2, 0, 0), respectively. Find the equation of the equipotential surface where the potential is zero. [$x=0$]

61. A parallel plate capacitor is filled by a dielectric whose relative permittivity varies with the applied voltage (u) as $ \epsilon  =\alpha U $ where $\alpha $ = 2 V^-1. A similar capacitor with no dielectric is charged to U₀ = 78 V. It is then connected to the uncharged capacitor with the dielectric. Find the final voltage on the capacitors. [$6V$]

62. A capacitor is made of two circular plates of radius R each, separated by a distance d <<R. The capacitor is connected to a constant voltage. A thin conducting disc of radius r << R and thickness t << r is placed at the centre of the bottom plate. Find the minimum voltage required to lift the disc if the mass of the disc is m. [$V = \sqrt{\frac{mbd^2}{\pi \epsilon_0 r^2}}$]

63. In a circuit shown in figure, initially K₁ is closed and K₂ is open. What are the charges on each capacitor. Then K₁ was opened and K₂ are closed (order is important ). What will be the charge on each capacitor now?[ C = 9$\mu $F].  

64. Calculate potential on the axis of a disc of radius R due to a charge Q uniformly distributed on its surface. [$V = \frac{2Q}{4\pi \epsilon_0 R^2}[\sqrt{R^2+z^2}-z]$]

65. Two charges q₁ and q₂ are placed at (0, 0, d) and (0, 0, -d) respectively. Find locus of points where the potential a zero. [$x^2+y^2+z^2+[\frac{(q_1/q_2)^2+1}{(q_1/q_2)^2-1}](2zd)+d^2 = 0$]

66. Two charges -q each are separated by distance 2d. A third charge +q is kept at mid point O. Find potential energy of +q as a function of small distance x from O due to -q charges. Sketch P.E. v/s x and convince yourself that the charge at O is in an unstable equilibrium.

67. Two point masses, m each carrying charge -q and +q are attached to the ends of a massless rigid non conducting rod of length l. The arrangement is placed in a uniform electric field E such that a rod makes a small angle  = 5⁰ with the field direction. Show that the minimum time needed by the rod to align itself along the field (after it is set free)is \[T =\frac{\pi}{2}\sqrt{\frac{ml}{2qE}}\] 

68. Plate A of a parallel plate air filled capacitor is connected to a spring having force constant k and plate B is fixed. They are held on a frictionless tabletop as shown in figure. If a charge +q is placed on plate A and a charge -q on plate B, how much does the spring expand? [$\frac{q^2}{2\epsilon_0 Ak}$]

69. Find the capacitance of the infinite ladder between points X and Y, as shown in figure [$2\mu F$]

70. Two identical charged sphere are suspended in air by strings of equal length and make an angle of 30⁰ with each other. When suspended in a liquid of density 0.8 g/cc., the angle remain the same. What is the dielectric constant of the liquid? Take density of the material of the sphere = 1.6 g/c.c. [$K=2$]

71. A thin fixed ring of radius 1 m has a positive charge of 10^-5 C uniformly distributed over it. A particle of mass 0.9 gram and having a negative charge of 10^-6 C is placed on the axis at a distance of 1 cm from the centre of the ring. Show that the motion of the negatively charged particle is approximately SHM. Calculate the time period of oscillation. [$T=0.628 s$]

72. Find the potential difference between the left and right plate of each capacitor in the circuit shown in  figure.  [$V_1 = \frac{(E_2-E_1)C_2}{C_1+C_2},V_2 = \frac{(E_2-E_1)C_1}{C_1+C_2}$]