Bansal CLasses Physics Notes for IIT JEE

BANSAL CLASSES TARGET LIT JEE 2007 XI (PQRS) CALORIMETRY & HEAT TRANSFER CONTENT S KEYCONCEPT EXERCISE-I EXERCISE-II EXERCISE-III ANSWER KEY

THERMAL Definition of Heat: EXPANSION Heat is a form of energy which is transfer red between a system and its surroundi ng as a result of temperature difference only. due to increase in temperature. F or temperature change At change in lengt h Al = l0a At Area AA= A^At volume AV = V yAt 0 Thermal Expansion : Expansion 1. Type of thermal expansion Coefficient of expansion (i) Linear (ii) Superficial

(iii) Volume (a) (b) 2. . a = At—>0 / 1 A/t Lim A T 0 P = Lim 1 AA At—A0 At y = At—>o v1 AV Lim At 0 For isotropic solids otj = a = a = olids p = otj + a and y = a, +

a + pansion in X , Y and Z directions. rature volume increases so density 2 3 2 2 3 2 3 0 3 a (let) so P =2a and y = 3a For anisotropic s a Here , a and a are coefficient of linear ex Variation in density : With increase of tempe decreases and vice-versa. H d =(1 + yAt)

Note For solids values of y are generally small so we can write d = d (1-yAt) (u sing bimomial expansion) (0 (ii) y for liquids are in order of 10~ For water de

n sity increases from 0 to 4°C so y is -ve (0 to 4° C) and for 4° C to higher temperat ur e y is +ve. At 4° C density is maximum. 3. Thermal Stress: Arod of length 1 is cla mped between two fixed walls with distance 1 . If temperature is changed by amou nt At then F stress A (area assumed to be constant) 0 0 : so, or A/ strain = I F/A F/ Y = A/// AAI F =YAa A t 0 0 F AaAt (!l Bansal Classes Calorimetry & H eat Transfer [3]

4. If a is not constant (i) (a varies with distance) Let a = ax+b Total expansio n = Jexpansion of length dx i = |(ax + b)dxAt " x 1 (ii) ( a varies with tempear ture) Let a = f (T) T2 0 dx A/ _ j"a/ dT T i Caution: If a is in °C then put Tj an d T in °C. similarly if a is i n K then put Tj and T in K. 2 2 CAL ORIMETR Quantit y of heat transfered and specific heat Y The amount ofheat needed to incerase th e temperature of 1 gmofwaterfrom 14.5°Cto 1 5.5°CatSTP is 1 calorie dQ = mcdT Q = m [ C dT (be careful about unit of temperatu re, use units according to the given units of C) T i Heat transfer in phase change 'h Q = rnL L = latent heat of subs tance in cal/ gm/ °C or in Kcal/ kg/ °C L = 80 cal/ gm for ic e ice L steam = 5 4 0 C a l / g m (A) (i) (ii) Note: 1.

vibration and collision of medium particles. Steady State : In this state heat a bsorption stops and temperature gradient throughout the rod dT becomes constant i.e. — = constant. dx Before steady state : Temp of rod at any point changes If s p ecific heat of any substance is zero, it can be considered always in steady st at e. Let the two ends of rod of length 1 is maintained at temp Tj and T ( Tj > T ) dQ i ~ 2 I Thermal current D 1 = K-XH L T 2 2 T T 1 Conduction : Due to HEAT TRANSFER Ohm's law for Thermal Conduction in Steady State : / Where thermal resi

stance R = K A Th 1 1 2. Differential form of Ohm's Law T-dT dQ dT — =KA— dT dx dT — = temperature gradient dx dx (!lBansal Classes Calorimetry & Heat Transfer [3]

(B) (Q 1. Heat transfer due to movement ofmedium particles. Radiation: Every bod y radiates electromagnetic radiation of all possible wavelength at all temp>0 K. Stefan's Law: Rate of heat emitted by a body at temp T K from per unit area E = GT J/sec/ m d = P = oAT watt Q Radiation power — dl If a body is placed in a surr ounding of temperature T dQ Convection: 4 2 4 s valid only for black body heat f rom general body Emissmty or emmisive power e = ~ Iftemp ofbody falls by dT in t ime dt dT _ _ j4x (dT/dt=rate of cooling) dt ~ m S h e a t f r o m s ^ =cA(T -T ) 4 s 4 Newton's law of cooling Iftemp difference ofbody with surrounding is sma ll i.e. T = T eA then, dT 4mS -a T ( T - T ) dt dT a ( T - T ) so dt rr3/ 2 s Av erage form of Newtons law of cooling If a body cools from T j to T in time 51 T - T _ K T, +T, -T (used generally in objective questions) 5t mS s 2 dt 4. mS (fo r better results use this generally in subjective) At every temperature (>0K) a body radiates energy radiations ofall wavelengths. According to Wein's displacem ent law if the wavelength corresponding to maximum energy is X then X T = b wher e b = is a constant (Wein's constant) T=temperature of body m m Wein's black bod y radiation T3>T2>T, ess (!l Bansal Classes

EXERCISE -1 Q. 1 An aluminium container of mass 100 gm contains 200 gm of ice at - 20°C. Heat is added to the system at the rate of 100 cal/s. Find the temperatur e of the sys tem after 4 minutes (specific heat of ice = 0.5 and L = 80 cal/gm, specific heat of A1 = 0.2 cal/gm/°C) Q. 2 A U-tubefilledwith a liquid ofvolumetric coefficient of 10 /°C lies in a vertical plane. The height of liquid column in th e left vertic al limb is 100 cm. The liquid in the left vertical limb is maintai ned at a tempe rature = 0°C while the liquid in the right limb is maintained at a temperature = 1 00°C. Find the difference in levels in the two limbs. _5 Q.3 A thi n walled metal tank of surface area 5m is filled with water tank and contai ns a n immersion heater dissipating 1 kW. The tank is covered with 4 cm thick lay er of insulation whose thermal conductivity is 0.2 W/m/K. The outer face of the ins ulation is 25°C. Find the temperature of the tank in the steady state 2 Q.4 A glas sflaskcontains some mercury at room temperature. It is found that at diffe rent temperatures the volume of air inside the flask remains the same. If the vo lume of mercury in the flask is 300 cm , thenfindvolume of the flask (given that coe fficient of volume expansion of mercury and coefficient oflinear expansion o f g lass are 1.8 x 10^(°C) and9x 10~ (°C) respectively) 3 _1 6 _1 Q.5 Q.6 Q.7 A clock pe ndulum made of invar has a period of 0.5 sec at 20°C. If the clock is us ed in a c limate where average temperature is 30°C, aporoximately. How much fast or slow wil l the clock run in 10 sec. (a =lxlO /°C) 6 ilwar -6 A pan filled with hot food coo ls from 50.1 °C to 49.9 °C in 5 sec. How long will it take to cool from 40.1 °C to 39. 9°C if room temperature is 30°C? A composite rod made of three rods of equal length and cross-section as shown in the fig. The thermal conductivities of the materia ls of the rods are K/2, 5K and K respectively. The end A and end B are at consta nt temperatures. All heat entering the face A goes out of the end B there being no loss of heat from the sides of the bar. Find th e effective thermal conductiv ity of the bar A I Q.8 Q.9 K/2 I 11 5K 2 6 1 K

1 B An iron bar (Young's modulus = 10 N/m , a = 10" /°C) 1 m long and 10~ m in are a is heated from 0°C to 100°C without being allowed to bend or expand. Find the comp ress ive force developed inside the bar. 3 2 A solid copper cube and sphere, bot h of same mass & emissivity are heated to sam e initial temperature and kept und er identical conditions. What is the ratio of their initial rate of fall of temp erature? Q. 10 A cylindrical rod with one end in a stream chamber and other end in ice ca use melting of 0.1 gm of ice/sec. If the rod is replaced with another rod of hal f the length and double the radius of first and thermal conductivity of second r od is 1/4 that of first, find the rate of ice melting in gm/sec (!l Bansal Classes Calorimetry & Heat Transfer [3]

Q.ll Three aluminium rods of equal length form an equilateral triangle ABC. Taki ng O (mid point of rod BC) as the origin. Find the increase in Y-coordinate per unit change in temperature ofthe centre ofmass of the system. Assume the length of the each rod is 2m, and a = 4 v3 x10" /°C d 6 Q.12 Three conducting rods of sa me material and cross-section are shown in figur e. Temperature of A, D and C ar

e maintained at 20°C, 90°C and 0°C. Find the ratio of l ength BD and BC if there is no heat flow in AB 20°C 90'C 0°C Q. 13 If two rods of layer L and 2 L having coefficie nts of linear expansion a a nd 2a respectively are connected so that total lengt h becomes 3 L, determine the average coefficient of linear expansion of the comp osite rod. Q.14 A volume of 120 ml of drink (half alcohol + half water by mass) originally at a temperature of 25°C is cooled by adding 20 gm ice at 0°C. If all the ice melts, find the final t emperature of the drink, (density of drink = 0.833 gm/cc, specific heat of alcoh ol = 0.6 cal/gm/°C) Q.15 A solid receives heat by ra diation over its surface at th e rate of 4 kW. The heat convection rate from the surface of solid to the surrou nding is 5.2 kW, and heat is generated at a rate of 1.7 kW over the volume of th e solid. The rate of change of the average temp erature of the solid is 0.5 Cs . Find the heat capacity of the solid. o -1 Q.16 The figure shows the face and interface temperature of a composite slab con tain ing offour layers oftwo materials having identical thickness. Under steady s tat

e condition, find the value of temperature 6. 20°C 10°C E -5°C -10°C 2k 2k k = thermal c onductivity Q.17 Two identical calorimeter A and B contain equal quantity of wat

er at 20°C. A 5 gm piece of metal X of specific heat 0.2 cal g (C°) is dropped into A and a 5 gm piece of metal Y into B. The equilibrium temperature in A is 22°C and in B 23°C. Th e initial temperature of both the metals is 40°C. Find the specific h eat of metal Y in cal g" (C°)~ 4 _1 1 l Q.18 Two spheres of same radius R have the ir densities in the ration 8 . 1 and t he ratio of their specific heats are 1 : 4. If by radiation their rates of fall of temperature are same, thenfindthe rati o of their rates of losing heat. Q.19 I n the square frame of side I of metallic rods, the corners A and C are maintaine d at Tj and T respectively. The rate of heat flow from A to Cisa. IfA and D are instead maintained Tj & T respectivleyf ind,findthe total rate ofheat flow. 2 2 Q.20 A hot liquid contained in a contain er of negligible heat capacity loses tem perature at rate 3 K/min, just before i t begins to solidify. The temperature rem ains constant for 30 min, Find the rat io of specific heat capacity of liquid to

specific latent heat of fusion is in Kr (given that rate of losing heat is const ant). 1 (!l Bansal Classes Calorimetry & Heat Transfer [3]

Q. 21 A thermostatted chamber at small height h above earth's surface maintained at 30°C has a clock fitted in it with an uncompensated pendulum. The clock design er correctly designs it for height h, but for temperature of 20°C. Ifthis chamber is taken to earth's surface, the clock in it would click correct time. Find the coefficient oflinear expansion ofmaterial of pendulum, (earth's radius is R) Q. 2 2 The coefficient of volume expansion of mercury is 20 times the coefficient o f linear expansion of glass. Find the volume of mercury that must be poured into a glass vessel ofvolume V so that the volume above mercury may remain constant at all temperature. Q. 23 Two 50 gm ice cubes are dropped into 250 gm ofwater io n a glass. Ifthe water was initially at a temperature of 25°C and the temperature of ice -15°C. Find the final temperature of water, (specific heat ofice = 0.5 cal/ gm /°C and L = 80 cal/gm) Q.24 Water is heated from 10°C to 90°C in a residential hot wat er heater at a rate of 70 litre per minute. Natural gas with a density of 1.

2 kg /m is used in the heater, which has a transfer efficiency of 32%. Find the gas c onsumption rate in cubic meters per hour, (heat combustion for natural gas is 84 00 kcal/kg) 3 Q.25 A metal rod A of 25cm lengths expands by 0.050cm. When its temperature is r aised from 0°C to 100°C. Another rod B of a different metal of length 40cm expands b y 0.040 cm for the same rise in temperature. A third rod C of 50cm length is mad e up of pieces of rods A and B placed end to end expands by 0.03 cm on heating f rom 0°C to 50°C. Find the lengths of each portion of the co mposite rod. Q.26 A subst ance is in the solid form at 0°C. The amount of heat add ed to this substance and i ts temperature are plotted in the following graph. If the relative specific heat capacity of the solid substance is 0.5, find from th e graph (i) the mass of the substance; (ii) the specific latent heat of the melt ing process, and (iii) the specific heat of the substance in the liquid state. Q . 27 One end of copper rod ofuniform cross-section and of length 1.5 meters is i n contact with melting ice and the other end with boiling water. At what point a long its length should a te mperature of200°C be maintained, so that in steady sta te, the mass ofice melting i s equal to that of steam produced in the same inter val oftime? Assume that the w hole system is insulatedfromthe surroundings. Q.28 Two solids spheres are heated to the same temperature and allowed to cool under identical conditions. Compare : (i) initial rates of fall of temperature, and ( ii) initial rates of loss of he at. Assume that all the surfaces have the same e missivity and ratios of their ra dii of, specific heats and densities are respec tively 1 : a, 1 : p, 1 : y. Q.29 A vessel containing 100 gm water at 0°C is suspen ded in the middle of a room. In 1 5 minutes the temperature of the water rises b y 2°C. When an equal amount of ice i s placed in the vessel, it melts in 10 hours. Calculate the specific heat offusi on ofice. Q. 3 0 The maximum in the energy d istribution spectrum of the sun is a t 4753 A and its temperature is 6050K. What will be the temperature of the star whose energy distribution shows a maximum a t 9506 A. (!l Bansal Classes Calorimetry & Heat Transfer [3]

EXERCISE-II Q. 1 A copper calorimeter of mass 100 gm contains 200 gm of a mixtur e of ice and water. Steam at 100°C under normal pressure is passed into the calori meter and th e temperature of the mixture is allowed to rise to 50°C. If the mass of the calori meter and its contents is now 330 gm, what was the ratio of ice an d water in the beginning? Neglect heat losses. Given : Specific heat capacity of copper = 0.42 x 10 J kg K" , Specific heat capacity of water = 4.2 x 10 J kg^Kr , Specific he at of fusion of ice = 3.36 x 10 J kg Latent heat of condensation of steam = 22.5 x 1Q Jkg" 3 _1 x 3 1 5 -1 5 1 Q.2 base and two thin rods each of length l and coefficient of linear expansion a fo r the two pieces, ifthe dista nce between the apex and the midpoint ofthe base re main unchanged as the temper atures /, varied show that 7 2 2 l A n isoscetes triangte is form ed w ith a rod of length l and coefficient of linea r expansion OTJ for the x 2 Q.3 A solid su bstance of mass 10 gm at - 10°C was heated to - 2°C (still in the solid st ate). The heat required was 64 calories. Another 880 calories was required to ra ise the temperature ofthe substance (now in the liquid state) to 1°C, while 900 ca lories was required to raise the temperature from -2°C to 3°C. Calculate the specifi c heat capacities of the substances in the solid and liquid state in calories pe r kil ogram per kelvin. Show that the latent heat of fusion L is related to the m elti ng point temperature t by L = 85400 + 200 t . m m Q.4 (a) (b) Q. 5 Q.6 Q. 7 A st eel drill making 180 rpm is used to drill a hole in a block of steel. The ma ss of the steel block and the drill is 180 gm. If the entire mechanical work is use d up in producing heat and the rate of raise in temperature of the block and the drill is 0.5 °C/s. Find the rate of working of the drill in watts, and the tor qu e required to drive the drill. Specific heat of steel = 0.1 and J = 4.2 J/cal. U se ;P = i o A brass rod of mass m = 4.25 kg and a cross sectional area 5 cm in c reases its length by 0.3 mm upon heatingfrom0°C. What amount ofheat is spent for h eating the rod? The coefficient of linear expansic 1 for brass is 2xl0 /K, its s pecific heat is 0.39 kJ/kg.K and the density of brass is 8.5 x 10 kg/m . A subm arine made of steel weighing 10 g has to take 10 g of water in order to submerge when the temperature of the sea is 10°C. How much less water it will have to take in when the sea is at 15°C? (Coefficient of cubic expansion of sea water = 2 x 10 "V°C, coefficient of linear expansion of steel = 1.2 x 10- /°C) A flow calorimeter i s used to measure the specific heat of a liquid. Heat is added at a known rate t o a stream of the liquid as it passes through the calorimeter at a known rate . T hen a measurement of the resulting temperature difference between the inflow and the outflow points of the liquid stream enables us to compute the specific heat of the liquid. A liquid of density 0.2 g/cm flows through a calorimeter at the rate of 10 cm /s. Heat is added by means of a 250-W electric heating coil, a nd a temperature difference of 25 °C is established in steady-state conditions bet ween

the inflow and the outflow points. Find the specific heat of the liquid. 2 -5 3 3 9 8 5 3 3 (!lBansalClasses Calorimetry & Heat Transfer [3]

Q.8 Toluene liquid of volume 300 cm at 0°C is contained in a beaker an another qua ntit y of toluene of volume 110 cm at 100°C is in another beaker. (The combined vo lume is 410 cm ). Determine the total volume of the mixture ofthe toluene liquid s whe n they are mixed together. Given the coefficient of volume expansion y = 0 .001/C and all forms of heat losses can be ignored. Also find the final temperat ure of the mixture. Q. 9 Ice at -20°C isfilledupto height h = 10 cm in a uniform c ylindr ical vessel. Water at temperature 9°C is filled in another identical vessel upto t he same height h= 10 cm. Now, water from second vessel is poured into fi rst vess el and it is found that level of upper surface falls through Ah = 0. 5 cm when t hermal equilibrium is reached. Neglecting thermal capacity of vessels, change in density of water due to change in temperature and loss of heat due to radiation , calculate initial temperature 0 of water. Given, Density of water, p = 1 gm cm Density of ice, p. =0.9gm/cm Specific heat of water, s = 1 cal/gm °C S pecific hea t of ice, s = 0.5 cal/gm°C Specific latent heat of ice, L = 80 cal/gm Q. 10 A comp osite body consists of two rectangular plates of the same dimension s but differe nt thermal conductivities K and Kg. This body is used to transfer heat between t wo objects maintained at different temperatures. The composite bo dy can be place d such that flow of heat takes place either parallel to the inte rface or perpend icular to it. Calculate the effective thermal conductivities K. and Kj Of the co mposite body for the parallel and perpendicular orientations. Which orientation will have more thermal conductivity? 3 3 3 w -3 3 w ; A Q. 11 Two identical thermally insulated vessels, each containing n mole of an id eal m onatomic gas, are interconnected by a rod of length I and cross-sectional a rea A. Material of the rod has thermal conductivity K and its lateral surface is the rmally insulated. If, at initial moment (t = 0), temperature of gas in two v ess els is T, and T (< T ), neglecting thermal capacity of the rod, calculate dif fe rence between temperature of gas in two vessels as a function of time. 2 } Q. 12 A highly conducting solid cylinder of radius a and length I is surrounded by a co-axial layer of a material having thermal conductivity K and negligible h eat capacity. Temperature of surrounding space (out side the layer) is T , which is higher than temperature of the cylinder. If heat capacity per unit volume of cyl inder material is s and outer radius of the layer is b, calculate time requi red to increase temperature of the cylinder from T to T Assume end faces to be t he rmally insulated. 0 t r Q. 13 A vertical brick duct(tube) is filled with cast ir on. The lower end of the duct is maintained at a temperature T, which is greater than the melting point T of cast iron and the upper end at a temperature T whic h is less than the tempe rature ofthe melting point of cast iron. It is given th at the conductivity of li quid cast iron is equal to k times the conductivity of solid cast iron. Determin e the fraction ofthe duct filled with molten metal. Q .14 Water is filled in a no n-conducting cylindrical vessel of uniform cross-sec tional area. Height of water column is h and temperature is 0°C. Ifthe vessel is e xposed to an atmosphere havi ng constant temperature of- 0°C (< 0°C) at t = 0, calcu late total height h ofthe col umn at time t .Assume thermal conductivity ofice t o be equal to K.Density ofwate r is p and that of ice is p.. Latent heat offusio n ofice isL. m 2 0 ffi (!l Bansal Classes Calorimetry & Heat Transfer [3]

Q.15 A lagged stick of cross section area 1 cm and length 1 m is initially at a

temperature of 0°C. It is then kept between 2 reservoirs of tempeature 100°C and 0°C. Specific heat capacity is 10 J/kg°C and linear mass density is 2 kg/m. Find 100°C o°c (a) temperature gradient along the rod in steady state. (b) total heat absorbed

by the rod to reach steady state. Q.16 A cylindrical block of length 0.4 m an ar ea of cross-section 0.04m is placed coaxially on a thin metal disc ofmass 0.4 k g and ofthe same cross-section. The upper face of the cylinder is maintained at a constant temperature of 400K and the initial temperature of the disc is 300K. I f the thermal conductivity of the material of the cylinder is 10 watt/m-K and th e specific heat of the material of the disc in 600 J/kg-K, how long will it t ake for the temperature of the disc to increase to 350K? Assume, for purposes of ca lculation, the thermal conductivity of the disc to be very high and the syst em t o be thermally insulated except for the upper face of the cylinder. 2 2 Q.1 7 A copper calorimeter of negligible thermal capacity isfilledwith a liquid. The mass of the liquid equals 250 gm. A heating element of negligible thermal ca pa city is immersed in the liquid. It is found that the temperature of the calori m eter and its contents risesfrom25°C to 30°C in 5 minutes when a or rent of 20.5 amp ere is passed through it at potential difference of 5 volts. The liquid is throw n off and the heater is again switched on. It is now found that the temperature ofthe calorimeter alone is constantly maintained at 32°C when the current through the heater is 7A at the potential difference 6 volts. Calculate the specific he a t capacity ofthe liquid. The temperature ofthe surroundings is 25°C. Q.18 A soli d copper sphere cools at the rate of 2.8°C per minute, when its temperature is 127°C . Find the rate at which another solid copper sphere oftwice the radius lose its t emperature at 327°C, ifin both the cases, the room temperature is maintained at 27°C . Q.19 A calorimeter contains 100 cm of a liquid of density 0.88 g/cm in whi ch a re immersed a thermometer and a small heating coil. The effective water equ ivale nt of calorimeter, thermometer and heater may be taken to be 13 gm. Curren t of 2 A is passed through the coil. The potential difference across the coil is 6.3 V and the ultimate steady state temperature is 55°C. The current is increased so th at the temperature rises slightly above 55°C, and then it is switched off. The cal orimeter and the content are found to cool at the rate of 3.6°C/min. (a) F ind the specific heat of the liquid. (b) The room temperature during the experim ent was 10°C. If the room temperature rises to 26°C, find the current required to ke ep the l iquid at 55°C. You may assume that Newton's law is obeyed and the resista nce of th e heater remains constant. 3 3 Q.20 End A of a rod AB of length L = 0. 5 m and of uniform cross-sectional area i s maintained at some constant temperat ure. The heat conductivity of the rod is k = 17 J/s-rn°K. The other end B of this rod is radiating energy into vacuum and th e wavelength with maximum energy dens ity emitted from this end is XQ = 75000 A. If the emissivity of the end B is e = 1, determine the temperature of the end A. Assuming that except the ends, the r od is thermally insulated. Q.21 A wire of l ength 1.0 m and radius 10" m is carr ying a heavy current and is assumed to radia te as a blackbody. At equilibrium t emperature of wire is 900 K while that of the surroundings is 300 K. The resisti vity of the material of the wire at 300 K is n x 10" O-m and its temperature coe fficient of resistance is 7.8 x 10' /°C. Find t he current in the wire, [a = 5.68 x 10" w/m K ]. 3 2 8 3 8 2 4 (!l Bansal Classes Calorimetry & Heat Transfer [3]

Q.22 The temperature distribution of solar radiation is more or less same as tha t of a black body whose maximum emission corresponds to the wavelength 0.483 ja m . Find the rate of change of mass due to radiation. [Radius of Sun = 7.0 x 10 m] 8 Q.23 A black plane surface at a constant high temperature T , is parallel t o ano ther black plane surface at constant lower temperature T . Between the pla tes is vacuum. In order to reduce the heatflowdue to radiation, a heat shield co nsisti ng oftwo thin black plates, thermally isolated from each other, it placed betwee n the warm and the cold surfaces and parallel to these. After some time stationa ry conditions are obtained. By what factor r) is the stationary heatflo wreduced due to the presence of the heat shield? Neglect end effects due to thef initesize of the surfaces. h ; Q.24 The shell of a space station is a blackened sphere in which a temperature T = 500K is maintained due to operation of applian ces of the station. Find the te mperature of the shell if the station is envelop ed by a thin spherical black scr een of nearly the same radius as the radius of the shell. Blackened envelop Q.25 A liquid takes 5 minutes to coolfrom80°C to 50°C. How much time will it take to coolfrom60°C to 30°C ? The temperature of surrounding is 20°C. Use exact method. Q .2 6 Find the temperature of equilibrium of a perfect ly black disc exposed normally to the Sun's ray on the surface of Earth. Imagine that it has a nonconducting b acking so that it can radiate only to hemisphere of space. Assume temperature of surface of Sun = 6200 K, radius of sun = 6.9 * 1 0 m, distance between the Sun a nd the Earth = 1.5 x lo m. Stefan's constant = 5 .7 x i0~ W/m .K . What will be t he temperature ifboth sides of the disc are rad iate? s 11 s 2 4 (!l Bansal Classes Calorimetry & Heat Transfer [3]

Q. 1 Q.2 The temperature of 100 gm of water is to be raised from 24° C to 90° C by a dding ste am to it. Calculate the mass of the steam required for this purpose. [ JEE '96] T wo metal cubes A & B of same size are arranged as shown in figure. Th e extreme e nds of the combination are maintained at the indicated temperatures. The arrange ment is thermally insulated. The coefficients of thermal conductivi ty of A & B a re 300 W/m°C and 200 W/m°C respectively. After steady state is reached the temperatu re T of the interface will be . [JEE' 96] 2 EXERCISE - III o A B Q.3 A double pane window used for insulating a room thermally from outside consi sts of two glass sheets each of area 1 m and thickness 0.01 m separated by a 0.0 5m t hick stagnant air space. In the steady state, the room glass interface and the g lass outdoor interface are at constant temperatures of 27°C and 0°C respective ly. Ca lculate the rate of heat flow through the window pane. Also find the temp erature s of other interfaces. Given thermal conductivities of glass and air as 0.8 and 0.08 W nr'K- respectively. [JEE'97] 1 Q. 4 The apparatus shown in the fi gure consists of four glass columns connected by ho rizontal sections. The heigh t of two central columns B & C are 49 cm each. The t wo outer columns A & D are open to the atmosphere. A & C are maintained at a tem perature of 95° C while the columns B & D are maintained at 5° C. The height of the liquid in A & D measured f rom the base line are 52.8 cm & 51 cm respectively. De termine the coefficient o fthermal expansion ofthe liquid, [JEE '97] A 95° C 95° Q.5 Q.6 Q.7 A spherical black body with a radius of 12 cm radiates 450 W power at 500 K . If the radius were halved and the temperature doubled, the power radiated in watt would be : (A) 22 5 (B) 450 (C) 900 (D) 1800 Earth receives 1400 W/m of solar pow er . If all the solar energy falling on a lens of area 0.2 m is focussed on to a block of ice of mass 280 grams, the time taken to melt the ice will be minutes. (Latent heat of fusion of ice = 3.3 x 10 J/kg) [JEE '97] 2 2 5 A solid body X of heat capacity C is kept in an atmosphere whose temperature is T = 300K. At time t = 0, the tem perature of X is T = 400K. It cools according to Newton's law of cooling. At tim e tj its temperature is found to be 3 5 OK. At t his time t the body X is connec ted to a larger body Y at atmospheric temperature T , through a conducting rod o f length L, cross-sectional area A and thermal co

nductivity K. The heat capacity of Y is so large that any variation in its tempe rature may be neglected. The cross-sectional area A of the connecting rod is sm a ll compared to the surface area of X. Find the temperature of X at time t = 3t [ JEE' 98] A 0 p A r Q.8 A black body is at a temperature of2880 K. The energy ofradiation emitted by thi s obj ect with wavelength between 499 nm and 500 nm i s U between 999 nm and 1000 nm is U and between 1499 nm and 1500nmisU . TheWienc onstantb = 2.88 x 10 nmK. T hen [JEE' 98] (A) Uj = 0 (B)U = 0 (C) Uj > U (D)U >U p 2 3 6 3 2 2 1 (!l Bansal Classes Calorimetry & Heat Transfer [3]

Q.9 A bimetallic strip is formed out oftwo identical strips one ofcopper and the oth er ofbrass. The coefficient of linear expansion ofthe two metals are a and ctg. On heating, the temperature ofthe strip goes up by AT and the strip bends t o for m an arc of radius of curvature R. Then R is: (A) proportional at AT (B) i nverse ly proportional to AT [JEE' 99] (C) proportional to lOg - a | (D) inverse ly prop ortional to |a - a | c c B c Q.10 A block of ice at - 10°C is slowiy heate d and converted to steam at 100°C. Whic h of the following curves represents the p henomenon qualitatively? [JEE (Scr) 20 00] (A) Heat supplied (B) Heat supplied \ (C) Heat supplied (D) Heat supplied Q. 11 The plots of intensity versus wavelen gth for three black bodies at tempera ture T, , T and T, respectively are as sho wn. Thentemperatures are such that [JE E (Scr) 2000] (A)T >T >T (B) T j > T > T (C) T > T > T (C) T. > T > T 2 1 2 3 3 2 2 3 1 2 t Q.12 Three rods made of the s ame material and having the same cross-section have been joined as shown in the figure. Each rod is of the same length. The left and rig ht ends are kept at 0°C a nd 90°C respectively. The temperature of the junction of th e three rods will be [

JEE(Scr)2001 ] o°c(A) 45°C (B) 60°C (C) 30°C (D)20°C ,S0°C "90°C Q. 13 An ideal black body at room temperature is thrown into a furnace. It is ob served that (A) initially it

is the darkest body and at later times the brightes t. (B) it the darkest body at all times (C) it cannot be distinguished at all ti mes. (D) initially it is t he darkest body and at later times it cannot be distin guished. [JEE(Scr)2002] Q . 14 An ice cube of mass 0.1 kg at 0°C is placed in an is olated container which i s at 227°C. The specific heat S of the container varies wi th temperature T accord ing the empirical relations = A + BT, where A= 100 cal/kg -K and B = 2 x 10~ cal /kg-K . If the final temperature of the container is 27°C, d etermine the mass of the container. (Latent heat of fusion for water = 8 x \ o c al/kg. Specific heat of water = 103 cal/kg-K) [JEE' 2001] 2 2 4 Q.15 Two rods one of aluminium of le ngth /, having coefficient of linear expansi on a , and other steel of length l having coefficient of linear expansion a are joined end to end. The expansion in both the a 2 s

[JEE (Scr) 2003] rods is same on variation of temperature. Then the value of , h is . n +/2 ac a0 (D) None of these (A) a + a (B) a s (C) Otc r a s a - a (!l Ba nsal Classes Calorimetry & Heat Transfer [3]

Q.16 2 kg ice at - 20°C is mixed with 5 kg water at 20°C. Thenfinalamount ofwater in the mixture would be; Given specific heat of ice = 0.5cal/g°C, specific heat ofwa ter = 1 cal/g°C, Latent heat of fusion of ice = 80 cal/g. [JEE (Scr) 2003] (A) 6 k g (B) 5 kg (C) 4 kg (D) 2 kg Q.17 If emissivity of bodies X and Y are e and e an d absorptive power are A and Ay then [JEF (Scr) 2003] (A) e > e ; Ay > A (B) e < e ; A < A (C)e >e ;A <A (D) e = e ; Ay = A Q.18 Hot oil is circulated throug h a n insulated container with a wooden lid at the top whose conductivity K = 0. 149 J/(m-°C-sec), thickness t = 5 mm, emissivity = 0.6. Temperature of the top of the lid in steady state is at T =27°C T, = 127°. If the ambient temperature T = 27°C. Calc ulate -=• Hot oil (a) rate ofheat loss per unit area due to radiationfromthe lid. 17 _ [JEE 2003] temperature ofthe oil. (Given a = — 10 ) (b) x y x y x x y x y x y x y x y x x V.a a x 8 Q.19 Three discs A, B, and C having radii 2 m, 4 m a nd 6 m respectively are coat ed with carbon black on their outer surfaces. The w avelengths corresponding to m aximum intensity are 300 nm, 400 nm and 500 nm res pectively. The power radiated by them are QA, QB and QC respectively, (a) Q is m aximum (B) QB is maximum [JEE' 2004 (Scr.)] (C) QC is maximum (D) QA = QB = QC Q .20 Two identical conducting r ods are first connected independently to two vess els, one containing water at 10 0°C and the other containing ice at 0° C. In the sec ond case, the rods are joined en d to end and connected to the same vessels. Let qj and q g/s be the rate of melt ing of ice in the two cases respectively. The ratio q /q is (A) 1/2 (B) 2/1 (C) 4/1 (D) 1/4 [JEE'2004 (Scr.)] Q.21 Liquid oxyg en at 50 K is heated to 300 K at c onstant pressure of 1 atm. The rate of heatin g is constant. Which of the followi ng graphs represents the variation of temper ature with time? a 2 9 T Temp.f Temp.f , Temp.f Temp. (A) [JEE' 2004 (Scr.)] Q.2 2 A cube of coefficient of linear expansion a is floating in a bath containing a liquid of coefficient of volume expansion yt When the tem perature is raised by AT, the depth upto which the cube is submerged in the liqu id remains the same. Find the relation between a and y showing all the steps. [J EE 2004] Q.23 One e nd of a rod of length L and cross-sectional area A is kept in a furnace of tempe rature T The other end of the rod is kept at a temperature T . The thermal condu ctivity ofthe material of the rod is K and emissivity ofthe r od is e. It is giv en that T = T + AT where AT Insulated « T , T being the temperat ure ofthe surroun dings. IfAT oc (Tj - T ), Furance T Rod * L * find the proporti onality constant . Consider that heat is lost only by radiation Insulated at the end where the te mperature ofthe rod is T . [JEE 2004] s s b r 2 2 s s s s f

Time (B) Time (C) Time (D) Time 2 (!l Bansal Classes Calorimetry & Heat Transfer [3]

Q. 24 Three graphs marked as 1,2,3 representing the variation of maximum emissiv e power and wavelength of radiation of the sun, a welding arc and a tungsten fi l ament. Which ofthe following combination is correct (A) 1-bulb, 2 —> welding arc

, 3 —> sun (B) 2-bulb, 3 —» welding arc, 1 -» sun (C) 3-bulb, 1 —» welding arc, 2 —» sun (D) 2 1 -> welding arc, 3 sun [JEE' 2005 (Scr)] Q. 25 In which of the following phe n

omenon heat convection does not take place (A) land and sea breeze (B) boiling o fwater (C) heating ofglass surface due to filament ofthe bulb (D) air around th e furance [JEE' 2005 (Scr)] Q.26 2 litre water at 27°C is heated by a 1 kW heater in an open container. On an average heat is lost to surroundings at the rate 160 J/s. The time required for the temperature to reach 77°C is (A) 8 min 20 sec (B)1 0min (C)7min (D)14min [JEE' 2005 (Scr)] Q.27 A spherical body of area A and emis sivity e = 0.6 is kept insid e a black body. What is the rate at which energy is radiated per second at tempe rature T (A) 0.6 a AT (B)0.4aAT (C)0.8cAT (D)l.OaA T [JEE 2005 (Scr)] Q. 28 1 cal orie is the heat required to increased the temper

ature of 1 gm ofwater by 1 °C fro m (A) 13.5°Cto 14.5°C at 76 mm of Hg (B) 14.5°Cto 15.5°C at760mmofHg (C) 0°C to 1°C at 760 mm of Hg (D) 3°C to 4°C to 760 mm of Hg [JEE* 2005 (Sc r)] 4 4 4 4 (!l Bansal Classes Calorimetry & Heat Transfer [3]

ANSWER KEY Q.i Q.5 Q.9 Q.12 Q.16 Q.20 Q.24 Q.27 Q.I Q.4 Q.7 25.5°C 5 sec slow /6M/ 3 .71. 7/2 5°C 1/90 104.2 10.34 cm Q.2 Q.6 0.1 cm 10 sec EXERCISE -1 Q.3 Q.7 65°C 1 5K/16 Q.ll Q.14 Q.18 Q.22 Q.4 Q.8 2000 cm 10, 000 N 3 Q.10 0.2 Q.13 5 a/3 Q.17 2

7/85 Q.21 h/5R Q.25 10cm, Q.28 ctPy: 4 x 10 m/°C 4°C Q.15 1000 J (C )2:1 Q.19 (4/3)© 3 Y/20 Q.23 0 °C -6 0 1 :a 2 Q.29 80 k cal/kg 1 1 1 -1 Q.30 3025 K Q.3 800 cal kg" K , 1000 cal kg" K 1 : 1.26 (a) 37.8 J/s (Watts), (b) 2.005 N-m Q.5 25 kJ 5000 J/°C kg Q.8 decrease by 0.75 cm ,25°C . K +K 2K K Q.10 K„ > Kj_, K| = K 1 B 3 T A R V A B ; x EXERCISE-II Q.6 Q.9 Q.ll t m m m 9.02 x 10 gm 45°C 5 \n i (T, ~T )e "3 R J 2 2 ( 4KAt N | Q.12 a s. ^log 2 (-) l0geV. 0 ~ 2 J T T Q 1 3 k(T - T ) I k(T -T ) + (T -T ) 1 Q.14 h + 0

Q.17 21000 Jkg^Kr Q.20 T = 423 K a 1 - JBL V / \ 1 \ Pi f L 12k;6t Q.15 (a) 100 °C /m, (b) 1000 J Q.18 9.72°C/min Q.21 36A 0 x Q.16 166.3 sec 9 1 Q.19 (a)0.42 cal/gm°C , (b) 1.6A Q.23 r| = 3 Q.25 10 minutes Q.I Q.4 Q.7 12 gm e Q.22 ~dt = 5.06 x 10 kg/s Q.24 T" = 500 = 600 K Q.26 T = 420 K, T = 353.6 K Q.2 60° C EXERCISE-III Q.3 Q.6 0 41.53 Watt; 26.48 °C;0.55°C 5.5 min Q.14 0.5 kg Q.19 B Q.24 A 2 x 10^ C Q.5 D log 2 ; T = 300 + 50 exp. k= Q.9 B, D Q.10 Q.16 A Q.17 Q.21 C Q. 26 A Q.22 Q.27 Q.8 D Q.15 A Q.20 D Q.25 C (!l Bansal Classes [LC tj A Q.ll B Q.12 B Q.13 D A Q. 18 (a) 595 watt/m , ( b ) T * 4 2 0 K K y,= 2a s Q.23 4eaLTf+K A Q.28 B 2 0 Calo rimetry & Heat Transfer [3]

BA TARGET IIT JEE 2007 XII (ALL) COHTENTS KEYCONCEPTS EXERCISE-1 EXERCISE-II EXE RCISE-III ANSWER KEY

KEY 1. CAPACITANCE O F A N 0 ( CONCEPTS C = 471 e e R in a medium ISOLATED SPHER ICAL CONDUCTOR : C = 47C G „ R in air This sphere is at infinite distance from all the conductors. The Capacitance C = 4T E R exists between the surface of the sp here & earth . 7 Q It consists of tw o concentric spherical shells as shown infi gure.Here capacitance of region betwe en the two shells is C and that outside th e shell is C . We have 471 e ab C = an d C = 471 e b b-a Depending on connection , it may have different combinations of C, and -C . t 2 n 2 Q 2 SPHERICAL CAPACI TOR : 3. PARALLEL PLATE CAPACITOR : If two parallel plates each of area A & sepa rated by a distance d are charged wi th equal & opposite charge Q, then the syst em is called a parallel plate capacit or & its capacitance is given by, ^ S)6 A C = — ; — .in a medium C= with air as medi um r (i) UNIFORM DI-ELECTRIC M E D I U M : This result is only valid when the electricfieldbetween plates of capacitor is c onstant, (ii) M E D I U M PARTLY A I R : C = U d-lt-i r So A When a di-electr ic slab of thickness t & relative permittivity e is l l l l intr oduced between the plates of an air capacitor, then the distance between P3 the plates is effec tively reduced by irrespective ofthe position of BSSSSii® V ^rJ the di-electric sl ab . (iii) COMPOSITE M E D I U M : c= GA I I -rl r2 0 r3

4. CYLINDRICAL CAPACITOR : It consist oftwo co-axial cylinders ofradii a& b, the outer conductor is earthed . The di-electric constant ofthe mediumfilledin the space between the cylinder i s Farad e . The capacitance per unit length is C = 2ne-ne m in r y r (fe^Bansal Classes CAPACITANCE 121

CONCEPT o r VARIATION OF PARAMETERS: 6. e kA , ifeither ofk, A or d varies in th e region between As capacitance ofa para llel plate capacitor isC = the plates, we choose a small dc in between the plate s and for total capacitance of system. dx -, If all dC's are in parallel C = } d C If all dC's are in series 1 e k(x)A (x) 0 T J 0 COMBINATION (i) OF CAPACITORS SERIES : : In this arrangement all the capacitors when uncharged get the same charge Q but the potential difference ac

ross each will differ (if the capacitance are unequal ). 1 — +1 1 1 —+ — + + 1 (ii) CA PACITORS I N rIMHh v, v, v, Q Q Q C| C2 C3 C 3 When one plate of each capacitor

is connected to the positive terminal of the ba ttery & the other plate of each capacitor is connected to the negative terminals of the battery, then the capaci tors are said to be in parallel connection. The capacitors have the same potenti al difference, V but the charge on each one is d ifferent (if the capacitors are unequal). eq. C CAPACITORS I N PARALLEL : I + C 2 + C 3 + +c

s 1 jC3,y 1 Q + v % 1Cj.V c,,v % ENERGY Capacitance C, charge Q & potential diff erence V; then energy stored is 1 U = -1 CV = — QV = 1 Q . This energy is stored i n the electrostatic field set up in the di-electric - — medium between the conduct ing plates of the capacitor . 2 2 STORED IN A CHARGED CAPACITOR : HEAT PRODUCED IN SWITCHING IN CAPACITIVE CIRCUIT Due to charge flow always some amount of heat is produced when a switch is close d in a circuit which can be obtained by ener gy conservation as Heat = Work done by battery - Energy absorbed by capacitor. 9 . 10 When two charged conductors of capacitance C & C at potential V & V respect ively are connected by a conducting wire, the charge flows from higher potential cond uctor to lower potential conductor, until the potential of the two condens ers be comes equal. The common potential (V) after sharing of charges; C,V C V q + V =n etnet charge _ C,j + q capacitance C C+C charges after sharing qj = C,'V & q = C V. In this process energy is lost in the connecting wire C C (V,-V ) as heat. T his loss of energy is U - U = ^ r ^ g s 2 } 2 2 1+ 2 2 SHARING O F CHAR GES : 2 2 t 2 2 2 2 2 initial eal

<§Bansal Classes (i) The energy of a charged conductor resides outside the conduct or in its EF, w here as in a condenser it is stored within the condenser in its EF. (ii) The ene rgy of an uncharged condenser = 0 . (iii) The capacitance of a capacitor depends only on its size & geometry & the di-electric between the cond ucting surface .( i.e. independent ofthe conductor, like, whether it is copper, silver, gold etc) REMEMBER : CAPACITANCE

Q.i A solid conducting sphere ofradius 10 cm is enclosed by a thin metallic shel l of radius 20 cm. A charge Q.2 EXERCISE # I Q.3 Q.4 q = 20pC is given to the i nner sphere. Find the heat generated in the process, t he inner sphere is connec ted to the shell by a conducting wire The capacitor eac h having capacitance C = 2pF are connected with a .CO, battery of emf 30 V as sh own infigure.When the s witch S is closed. Find (a) the amount of chargeflownthro ugh the battery (b) th e heat generated in the circuit (c) the energy supplied by the battery '30V (d) the amount of chargeflownthrough the switch S The plates o f a parallel plate ca pacitor are given charges +4Q and -2Q. The capacitor is the n connected across a n uncharged capacitor of same capacitance asfirstone (= C). Find thefinalpotenti al difference between the plates of thefirstcapacitor. +i, I n the given network if potential difference between p and q is 2V and C = 3C The nfindthe potential difference between a&b. 2 r H M q C, C. c Q.5 Find the equivalent capacitance o f the circuit between point A and B. c 2C 11 11 - C 11 11 2C 4C 11 11 :: C 11 11 4C : 8C 111 ! r 11 II 8C c \ \ \ \ \ Infinite / section/ yQ.6 The two identical parallel plates are given charges as shown infigure.Ifthe plate area of either face of each plate is A and separation between plates is d, thenfindthe amount o fheat liberate after closing the switch. Q. 7 Find heat pro duced in the circuit shown infigureon closing the switch S. +3q +q Q.8 In the following circuit, the resultant capacitance between A and B is 1 pF. Find the value of C. Three capac itors of 2pF, 3pF and 5|iF are independently ch arged with batteries of emf's 5V , 20V and 10V respectively. After disconnectingf romthe voltage sources. These c apacitors are connected as shown infigurewith the ir positive polarity plates ar e connected to A and negative polarity is earthed. Now a battery of 20V and an u ncharged capacitor of4jaF capacitance are connecte d to the junction A as shown with a switch S. When switch is closed,find: (a) th e potential of the junction A. (b) final charges on all four capacitors. Q.9 T

Q.10 Find the charge on the capacitor C = 1 pF in the circuit shown in the figur e. Iph IjxIK C-luF l(iF IpF pF :pnF yUlF::IMF : Q.ll Find the capacitance ofthe system shown in figure. Q.12 Thefigureshows a circuit consisting offour capacit o rs. Find the effective capacitance between X and Y. Q. 13 Five identical capac it or plates, each of area A, are arranged such that adjacent plates are at a di sta nce'd* apart, the plates are connected to a source of emf V as shown infigur e.Th e charge on plate 1 is and that on plate 4 is . Q.14 In the circuit shown i n the figure,intially SW is open. When the switch is closed, the charge passing throug h the switch in the direction to Q.15 In the circuit shown infigure,findt he amou nt ofheat generated when switch s is closed. Q.16 Two parallel plate cap acitors ofcapacitance C and 2C are connected in parallel then following steps ar e perfor med. (i) Abattery of voltage V is connected across points A and B. (ii) A dielec tric slab of relative permittivity k is slowly inserted in capacitor C . (iii) Ba ttery is disconnected. (iv) Dielectric slab is slowly removed from ca pacitor. Fi nd the heat produced in (i) and work done by external agent in step (ii) & (iv). Q.17 The plates of a parallel plate capacitor are separated by a di stance d = 1 cm. Two parallel sided dielectric slabs ofthickness 0.7 cm and 0.3 cmfillthe sp ace between the plates. Ifthe dielectric constants ofthe two slabs are 3 and 5 r espectively and a potential difference of440V is applied across th e plates. Find : (i) the electricfieldintensities in each ofthe slab s. (ii) the ratio of elect ric energies stored in thefirstto that in the second dielectric slab. Q.18 A 10 pF and 20 pF capacitor are connected to a 10 V cell in parallel for some time af ter which the capacitors are disconnectedfromthe cell and recon nected at t = 0 w ith each other, in series, through wires offinite resistance. The +ve plate of t hefirstcapacitor is connected to the -ve plate ofthe second c apacitor. Draw the graph which best describes the charge on the +ve plate ofthe 20 pF capacitor wit h increasing time. List of recommended questions from LE. Ir odov. 3.101, 3.102, 3.103, 3.113, 3.117, 3.121, 3.122, 3.123,3.124, 3.132,3.133, 3.141,3.142, 3.177, 3.184, 3.188. 3.199. 3.200,3.201. 3.203, 3.204. 3.205 121 A E60 V SW 7 k= 1 k=2 k=3 k=4 V- + 2 nF1 3 X 60 V I J (fe^Bansal Classes CAPACITAN CE

EXERCISE # II Q. 1 (a) For the given circuit. Find the potential difference acro ss all the cap acitors, (b) How should 5 capacitors, each of capacities, lpF be connected so as to produce a total capacitance of 3/7 pF. Q.2 6oF, Ih-H^f — I 8(xF —h ' 9|iF +. 25V The gap between the plates of a plane capacitor isfilledwith an isotropic insula tor whose di-electric constant varies in the direction perpendi cular to the plat es according to the law K = K j 1 + sin 71 X — L d where d is th e separation, betw een the plates & K is a constant. The area of the plates is S . Determine the cap acitance of the capacitor. t Q.3 (i) (ii) Q.4 (j) (ii) (iii) Q.5 Five identical conducting plates 1,2,3,4 & 5 arefixedparallel to and equdis tantf romeach other (seefigure).Plates 2 & 5 are connected by a conductor while 1 & 3 are joined by another conductor. The junction of 1 & 3 and the plate 4 are conne cted to a source of constant e.m.f. V . Find; the effective capacity of t he syst em between the terminals ofthe source. the charges on plates 3 & 5. Give n d = di stance between any 2 successive plates & A= area of either face of each plate . 5 0 Apotential difference of300 Vis applied between the plates of a pla ne capacitor spaced 1 cm apart. A plane parallel glass plate with a thickness of 0.5 cm and a plane parallel paraffin plate with a thickness of 0.5 cm are place d in the spac e between the capacitor platesfind: Intensity of electricfieldin e ach layer. The drop ofpotential in each layer. The surface charge density of the charge on cap acitor the plates. Given that: k = 6, k =2 glass paraffin A charg e 200pC is imparted to each of the two identical parallel plate capacitor s conn ected in parallel. At t =0, the plates of both the capacitors are 0.1 m ap art. The plates of first capacitor move towards each other with relative velocit y 0. 001 m/s and plates of second capacitor move apart with the same velocity. Fi nd the current in the circuit at the moment. A parallel plate capacitor has plat es with area A & separation d . A battery charges the plates to a potential diff e rence ofV . The battery is then disconnected & a di-electric slab of constant K & thickness d is introduced. Calculate the positive work done by the system (cap acitor + slab) on the man who introduces the slab. 0 Q.6 Q.7 A capacitor of cap acitance C is charged to a potential V and then isolated. A sm all capacitor C i s then chargedfromC , discharged & charged again, the process b eing repeated n times. The potential ofthe large capacitor has now fallen to V. Find the capacit ance of the small capacitor. If V = 100 volt, V=35volt, find the value ofn for C = 0.2 pF & C = 0.01075 pF . Is it possible to remove charge on

C this way? 0 0 0 0 0 0 Q. 8 When the switch S in thefigureis thrown to the left , the plates of capacitors C, acquire a potential difference V. Initially the ca pacitors C C are uncharged. T hw switchis now thrown to the right. What are thef inalcharges q q & q on the cor responding capacitors. 2 3 p 2 3 .V TLPI Ic T (fe ^Bansal Classes CAPACITANCE 121

Q.9 (1) (ii) (lii) A parallel plate capacitor with air as a dielectric is arrang ed horizontally. Th e lower plate isfixedand the other connected with a vertical spring. The area of each plate is A. In the steady position, the distance betwe en the plates is d . When the capacitor is connected with an electric source wit h the voltage V, a n ew equilibrium appears, with the distance between the plate s as d Mass of the up per plates is m. Find the spring constant K. What is the m aximum voltage for a g iven K in which an equilibrium is possible ? What is the angularfrequencyofthe o scillating system around the equilibrium value dj. (take amplitude of oscillatio n « d ) 0 r { Q.10 An insolated conductor initiallyfreefr omcharge is charged by repeated conta cts with a plate which after each contact has a charge Q due to some mechanism. If q is the charge on the conductor after the first Qq operation, prove that the maximum charge which can be given to the conductor in this way is ~ Q.ll A parallel plate capacitor is filled by a di-ele ctric whose relative permit tivity varies with the applied voltage according to the law = aV, where a = 1 pe r volt. The same (but containing no di-electric) ca pacitor charged to a voltage V = 156 volt is connected in parallel to thefirst"n on-linear" uncharged capacito r. Determine thefinalvoltage V across the capacito rs. f Q.12 A capacitor consists oftwo air spaced concentric cylinders. The outer ofrad ius b isfixed,and the inner is of radius a If breakdown ofair occurs atfi eldstre ngths greater than E^, show that the inner cylinder should have (i) radi us a = b /e ifthe potential of the inner cylinder is to be maximum (ii) radius a = b/Ve i f the energy per unit length of the system is to be maximum. ,.JT 5V-r 46F =n 5V :d=6nf Q. 13 Find the charge flown through the switchfromAto B when it is closed. Q.14 Figure shows three concentric conducting spherical shells with inner and outer s hells earthed and the middle shell is given a charge q. Find t he electrostatic e nergy of the system stored in the region I and II. 6mF Jr~ Q. 15 The capacitors shown infigurehas been charged to a potential difference of V volts, so that it carries a charge CV with both the switches Sj and S remainin g open. Switch Sj is closed at t=0. At t=R,C switch Sj is opened and S is closed . Find the charge on the capacitor at t=2RjC + R^C. 2 2 s, Hi s, Q.16 In the fig ure shown initially switch is open for a long time. Now the switc

h is closed at t = 0. Find the charge on the rightmost capacitor as "yv a functi on oftime given that it was intially unchanged. (fe^Bansal Classes CAPACITANCE 121

Q.17 In the given circuit, the switch is closed in the position 1 at t = 0 and t hen moved , I V to 2 after 250 p,s. Derive an expression for current as a funct i on oftime for J^ov [ t > 0. Also plot the variation of current with time. I X4 0V VL Q.18 Find the charge which flowsfrompoint Ato B, when switch is closed. 5( IF 5NF 5^F 5(.IF 5(IF 2 :500FJ :0.5 NF EXERCISE # III 2 2 120V Q. 1 Two parallel plate capacitors A&B have the same separation d=8.85 x lO^m be tween the plates . The plate areas of A & B are 0.04 m & 0.02 m A B respectively. A slab of di-el ectric constant (relative permittivity) K=9 has dimensions such that it can exac dy 10V fill the space between the plates ofcapacitor B. (i) the di-electric slab is placed inside A as shown in thefigure(i) Ais then charged to a potential dif ference of 110 volt. Calculate the capacitance ofA and the energ y stored in it. (ii) the battery is disconnected & then the di-electric slab is removedfromA. F ind the work done by the external agency in removing the slabfrom A. (iii) the s ame di-electric slab is now placed inside B,fillingit completely. The two capaci tors A& B are then connected as shown in figure (iii). Calculate t he energy sto red in the system. [ JEE '93,7] Q.2 Two square metallic plates of 1 m side are k ept 0.01 m apart, like a parallel plate capacitor, in air in such a way that one oftheir edges is perpendicular, to an oil surface in a tankfilledw ith an insul ating oil. The plates are connected to a battery of e.m.f. 500 volt. The plates are then lowered vertically into the oil at a speed of 0.001 m/s. Ca lculate the current drawn from the battery during the process, [di-electric cons tant of oi l = 11, e = 8.85 x 10" C /N m ] [ JEE '94, 6 ] Q.3 A parallel plate ca pacitor C is connected to a battery & is charged to a potential difference V. An other ca pacitor of capacitance 2C is similarly charged to a potential difference 2V volt . The charging batteiy is now disconnected & the capacitors are connecte d in pa rallel to each other in such a way that the positive terminal of one is c onnect ed to the negative terminal of other. Thefinalenergy ofthe configuration i s: 25 (B) - CV (D) - CV [JEE'95, 1 ] (A) zero (C) — CV 0 12 2 2 2 2 2 2 Q.4 The capacit ance of a parallel plate capacitor with plate area 'A' & separation d is C. The space between the plates isfilledwith two wedges of di-electric const ant Kj & K respectively. Find the capacitance ofthe resulting capacitor. [JEE'96 , 2] 2 Q. 5 © (fe^Bansal Classes Two capacitors A and B with capacities 3 pF and 2 pF are ch arged to a potential difference of 100 V and 180 V respectively. The plates of t he capacitors are con nected as shown in figure with one wire from each 2nF capa citorfree.The upper pl

ate of a is positive and that of B is negative, an 1-. uncharged 2 pF capacitor C with lead wires falls on thefreeends to complete IOOV B 180V the circuit. Calc ulate: thefinalcharges on the three capacitors The amount of electrostatic ener g y stored in the system before and after the completion ofthe circuit. [JEE'97 (c ancelled)] CAPACITANCE 121

Q.6 An electron enters the region between the plates of a parallel plate capacit or a t a point equidistant from eitherplate. The capacitor plates are 2* 10 mapa rt& 1 0 m long. A potential difference of300 volt is kept across the plates. Ass uming that the initial velocity of the electron is parallel to the capacitor pla tes, c alculate the largest value ofthe velocity ofthe electron so that they do notflyo ut ofthe capacitor at the other end. [ JEE '97, 5 ] _2 -1 Q. 7 For the c ircuit shown, which ofthe following statements is true ? (A) with S, cl osed, Vj = 15 V, V = 20 V (B) with S closed, Vj = V = 25 V (C) with & S closed, Vj = V = 0 (D) with Sj & S closed, V = 30 V, V = 20 V 2 3 2 2 2 2 l 2 V, =30V [JEE'99, 2 ] Q.8 Calculate the capacitance of a parallel plate condenser, with plate area A and d istance between plates d, whenfilledwith a medium whose permittivity vari es as; 0<x< | e (x)= e + P x [REE2000, 6] 4 < x < d. S(X)=G + P (d-x) 0 0 Q. 9 T wo identical capacitors, have the same capacitance C. One of them is charged to potential V and the other to V . The negative ends ofthe capacitors are connect ed together. When the positive ends are also connected, the decrease in energy o f the combined system is [ JEE 2002 (Scr), 3 ] t 2 (A) Mvf-vl) (B)Mv,2+v22) (qI c^-vJ 0 0 (D^cfa+vJ 1—m— s/ + c^ " v T Q.10 In the given circuit, the switch S is cl osed at time t = 0. The charge Q on the capacitor at any instant t is given by Q (t) = Q (l-e" *). Find the value o f Q and a in terms of given parameters shown in the circuit. [JEE 2005] 0 Q.ll Given: Rj = ID , R2 = 2Q, Cx = 2pF, C = 4pF T he time constants (in pS) for the circuits I, n, HI are respectively .C, !!—i— R,: K "C2 hi r . - T T-r. k v ,vV ' h-— 2 (A) 18, 8/9, 4 (C) 4, 8/9, 18 (II.)

ANSWER KEY EXERCISE # I Q.l Q.3 Q.7 Q.9 9J 3Q/2C 0 100 Q.2 Q.4 Q.8 (a) 20 pC, (b ) 0.3 mJ, (c) 0.6 mJ. (d) 60 [iC 30 V 32 -MF Q.5 C Q-6 1 qd iZT 2 (a) — volts; (b) 28.56 |iC, 42.84 pC, 71.4 jnC, 22.88 pC Q.10 10 pC 2A e V 25 e„A Q. 13 A G V Q.14 60 (ic,AtoB Q.ll 24 d Q.12 ^ F 0 0 Q.15 150 mJ 4 Q.16 (i) | C V ; (ii) - ~ CV2( K- 1); ^ (K + 2) (K - l ^ V ; 2 2 q(nC), Q. 17 (i) 5 X 10 V/m, 3 x 10 V/m; (ii) 3 5/9 4 Q.18 200 EXERCISE # II HHI Q.l (a) 12 V, 9 V, 3 V, 13 V, 16 V, (b) GSTIK , m T TT ,Q5 = t 7 2 Q.2 C = 2d Q.5 2[iA 5 fe A^ Q.3 (i) 3 v " y ;(ii)Q3=T 0 4 4 IAV„ ,AV Q.4 (i) 1.5 x 10 V/m, 4.5 x 10 V/m, (ii) 75 V, 225 V, (iii) 8 x 10" C/m Q.6 W = \ C V 0 0 2 q.8 q i

-Ci2V(C2+C3) CiC +C C +Cj c 2 2 3 2 0 0 3 c c +c c +c c 1 2 2 3 3 K CCCV 1 2 3 1Q .7 C = C 1 f\v T n V V o \ -1 = 0.01078 |iF,n = 20 1 / n SpAV 2d (d -d!)'v As ^3 2 \3/2 Kdf-e AV 0 2 1/2 MDJ Q.ll 12 volt r 2 Q.13 69 mC Q.14 U, 3kg, lOr 2 wher e q, = ~ ; Uu O CV = 2K(q + ) / 3 5 r Q.15 q = CE 1 — + qi

I(ajnp) Q.17 For t < 250 ps, I = 0.04 e^° amp ; For t > 250 ps, I = - 0.1 i -4000( t-250)xi (r 00t e 0.04 0.015 -o.n 6 a m p ; •t(xIO^s) Q.18 400 ^ - — P EXERCISE # II I Q.l Q.2 Q.5 (i) 0.2 x 10" 9 8 F, 1.2 x lO" J ; (ii) 4.84 x 10" J ; (iii) 1.1 x 10" 5 5 5 J 4.425 x 10~ Ampere QA = 90 Q.3 B q.4 F C K ^ /n K, (Ka-KO K, = 18 M J pC, Q B = 150 pC, Q C = 210

pC, UJ = 4 7 . 4 MJ, U D Q= 0 CVR, Q ' 6 2^9A V48 C & Q.7 Q.10 Q.8 Ri+R2 ^ 2 e0 2 s0 Q.9 R1+R2 anda= Q.ll

QUESTION FOR SHORT ANSWER Q.l The electric strength of air is about 30,000 V/cm. By this we mean that when the electricfieldintensity Q.2 Q.3 Q.4 exceeds this v alue, a spark will jump through the air. We say that "electric bre akdown" has o ccurred. Using this value, estimate the potential difference betwee n two object s where a spark jumps. Atypical situation might be the spark that ju mps between your body and a metal door handle after you have walked on a deep ca rpet or sl id across a plastic car seat in very dry weather. Ifyou grasp the two wires lead ingfromthe two plates of a charged capacitor, you may feel a shock. Th e effect is much greater for a 2-pF capacitor than for a 0.02p,F capacitor, even though b oth are are charged to the same potential difference. Why? <T(+) a(-) T hree inf inite nonconducting sheets, with uniform surface charge densities a, 2a and 3ct are arranged to be parallel like the two sheets in Fig. What is their or der,fro mleft to right, if the electricfieldE produced by the arrangement has mag nitude E = 0 in one region and E = 2a/e in another region? As shown in the figur e plo ts of charge versus potential difference for three parallel plate capacitor s, w hich have the plate areas and separations given in the table. Which of the p lot s goes with which ofthe capacitors? 0 Capacitor 1 2 3 Q.5 Area Separation A d 2A d A 2d t 2 1 t Q.6 Initially, a single capacitance C is wired to a battery. The n capacitance C is a dded in parallel. Are (a) the potential difference across C and (b) the charge q j on C now more than, less than, or the same as previously ? (c) Is the equivalen t capacitance C of Cj and C more than, less than, or equa l to Cj? (d) Is the tot al charge stored on C^ and C , together more than, less than, or equal to the ch arge stored previously on Cj? As shown in thefigurethre e circuits, each consisti ng of a switch and two capacitors, initially charged a s 6q_ indicated. After the switches have been closed, in which 6q_ _ Jq 6q__ C 3 C 2C 2C circuit (ifany) wi ll the charge on the left-hand capacitor 2 C (a) incr ease, (b) decrease and (c) remain the same? 12 2 == := (fe Bansal Classes Cap-mo nster maze. Inthe Figure all the capacitors have a capacitance -- I I h f¥T of 6.0 pF, and all the b atteries have an emf of 10V What is the charge | J_ J ^ on ca pacitor C? (Ifyou canfindthe proper loop through this maze, you T ~ , 4 , 4 4 T , , = I can answer the question with a few seconds of mental calculation.) -r I c 1 H H Q8 An oilfilledcapacitor has been designed to have a capacitance C and t o operate safely at or below a certain maximum potential difference V with out a rcing over. However, the designer did not do a good job and the capacitor o ccas ionally arcs over. What can be done to redesign the capacitor, keeping C and V u nchanged and using the same dielectric? Q.9 One of the plates of a capacitor con nected to battery is earthed. Will the potential diffrence between the plate s c hange if the earthing wire is removed?

ONLY ONE OPTION IS CORRECT. Take approx. 2 minutes for answering each question. Cond. Diele. Q. 1 The distance between plates of a parallel plate capacitor is 5 d. sitively charged plate is at x=0 and negatively charged plate is at 1 o slabs one of conductor and other of a dielectric of equal thickness rted between the plates as shown in figure. Potential versus distance look like: v A) Q.2 w v (B) (C) x=0 x=d x=2d x=3d x=4d x=5d VI (D) A parallel plate capacitor has two layer s of dielectric as shown in figure. This capacitor is connected across a battery . The graph which shows the variation of electricfield(E) and distance (x)fromle ft plate. y y y (A) k=2 k=4 (d,0) (3d,0) (D) (d,0) (3d,0) " 1 (B) (d,0) (3d,0) " (C) (d,0) (3d,0)~ (d,0) (3d,0) Q.3 The distance between the plates of a charged parallel plate capacitor is 5 cm an d electricfieldinside the plates is 200 Vcn r . An uncharged metal bar of width 2 cm is fully immersed into the capacitor. T he length of the metal bar is same as that of plate of capacitor. The voltage ac ross capacitor after the immersion of the bar is (A) zero (B)400V (C)600V (D)100 V Three large plates are arranged as s hown. How much charge will flow through t he key k if it is closed? 5Q 4Q 3Q (D) none (A) (C) ( B ) F 2Q Q.4 2d L Q.5 1 E Five conducting parallel plates having area Aand separation between them d, are Let the po * x=5d. Tw d are inse graph will

placed as shown in the figure. Plate number 2 and 4 are connected wire and betwe en point A and B, a cell of emfE is connected. The charge flown through the cel l is u 3 e AE 2 s AE 4s AE e AE (A) (C) (D) (B) 4 d 3 d 2d 0 0 0 0 5 Q.6 -> If c harge on left plane of the 5 pF capacitor in the circuit segment shown in th e f igure is -20pC, the charge on the right plate of 3 pF capacitor is (A) +8.57 pC (B) -8.57 pC (C)+11.42pC (D)-11.42pC Five identical capacitor plates are arra ng ed such that they make capacitors each of Q.7 2 pF. The plates are connected t o a source of emf 10 V. The charge on plate C is (B) + 40 pC (C) + 60 pC (D) + 8 0pC u (A) + 20 pC |3nF UjiF w |ffH 2(iF (fe Bansal Classes Question Bank on Capa citance [13]

Q.8 A capacitor of capacitance C is charged to a potential difference V from a c ell and then disconnected L + from it. Acharge +Q is now given to its positive plate. The potential difference across the capacitor is now (C)v Q f (D) V - ^ , if V < CV (B) V + (A) V of cap acity 5 pf is (A) 60 pC (C) 30 pC M^lfP^lf. 100 V Q.9 In the circuit shown infigurecharge stored in the capacitor (B) 20 pC (D) zero 2 3 Q.10 A conducting body 1 has some initial charge Q, and its capacitance is C. Th ere are two other conducting bodies, 2 and 3, having capacitances : C = 2C and C -» Q . Bodies 2 and 3 are initially uncharged. O "Body 2 is touched wit h body 1. Then, body 2 is removed from body 1 and touched with body 3, and then removed." This process is repeated N times. Then, the charge on body 1 at the en d must be (A) Q / 3 (B) Q / 3 (C)Q/N (D) None N N _ 1 3 Q.ll Condenser A has a c apacity of 15 pF when it isfilledwith a medium of dielec tric constant 15. Anoth er condenser B has a capacity 1 pF with air between the p lates. Both are charge d separately by a battery C of 100V. After charging, both are connected in paral lel without the battery and the dielectric material being removed. The common po tential now is (A) 4 0 0 V (B) 800V (C) 1200V (D) 1600V Q.12 In the adjoiningfig ure,capacitor (1) and (2) have a capacitance C' each. Wh en the dielectric of di electric consatnt K is inserted between the plates of one ofthe capacitor, the t otal charge flowing through battery is ,c KCE KCE h from B to C from C to B (B) K + l t (A) K + l (K-l)CE (K-l)CE (C) ^ FROM B to C (D) f rom C to B A + 2 ( K + 1) -WUr Q. 13 Two identical capacitors 1 and 2 are connected in series toabatte ryas shown in 1 figure. Capacitor 2 contains a dielectric slab of dielectric con stan t k as shown. Q and Q are the charges stored in the capacitors. Now the die lectr ic slab is removed and the corresponding charges are Q' j and Q' . Then H^ Q^_k +1 k q; = k+i 2 (A) (B) Q _ k + l ( C ) Q ~ 2k (D) 01 2 Qi k Qi t 2 2 2 Q. 14 The area ofthe plates of a parallel plate capacitor is A and the gap betwe e n them is d. The gap is filled with a non-homogeneous dielectric whose dielectr ic constant varies with the distance 'y'fromone plate • as : K = ^sec(7ty/2d), whe re X is a dimensionless constant. The capacitance ofthis capacitor is (A) 7ie ^ A/2d (B)7rs XA/d (C) 27te k A/d (D)none 0 0 0 Q.15 A capacitor stores 60pC char ge when connected across a battery. When the ga p between the plates is filled w ith a dielectric, a charge of 120pC flows throug h the battery. The dielectric c onstant of the material inserted is: i (A) 1 (B) 2 . (C) 3 (D) none (fe Bansal C lasses

Q.16 In the above question, if the initial capacitance ofthe capacitor was 2pF, the amount of heat produced when the dielectric is inserted. £ • (A) 3600pJ (B) 2700 pJ (C) 1800pJ (D)none Q.17 A capacitor of capacitance C is initially charged to a potential difference of V volt. Now it is connected •j to a battery of 2V with o pposite polarity. The ratio of heat generated to the final energy stored in th e capacitor will be (A) 1.75 (B) 2.25 (C) 2.5 (D) 1/2 AQ.18 Three plates A B and C each of area 0.1 m are separated by 0.885 Bmmfromea ch other as shown in the figure. A10 V battery is used to Ccharge the system. Th e energy stored in the s ystem is (A)lpJ (B) 10 pj (C) 10' pJ (D) 10" pJ 2 _1 2 3 hH 10V Q.19 A parallel plate capacitor of capacitance C is connected to a battery and i s charged to a potential difference V. Another capacitor of capacitance 2C is si milarly charge d to a potential difference 2V. The charging battery is now discon nected and th e capacitors are connect in parallel to each other in such a way th at the posit ive terminal of one is connected to the negative terminal of the oth er. Thefina lenergy I ofthe configuration is 2 „ 5 (A)zero (D)-CV ( B ) - CV (C)yCV 2 2 2 Q.20 A 2 pF capacitor is charged to a potential = 10V. Another 4 pF capacitor is cha rged to a potential = 20V. The two capacitors are then connected in a single loo p, with the positive plate of one ; connected with negative plate of the oth er. What heat is evolvecl in the circuit? (A) 300 pj (B) 600 pJ (C) 900 pj (D)45 0p J Q.21 The plates S and T of an uncharged parallel plate capacitor are connect e d across a battery. The battery is then disconnected and the charged plates are now connected in a system as shown in thefigure.The system shown is in equilibr ium. All the strings are insulating and massless. The magnitude of charge on one ofthe capacitor plates is: [Area ofplates=A] -^svtvw 4mgA (A) pmgA (B) 77777777 7777777777ininiii (C)VmgA (D) 2mgA e m 0 Q.22 In the circuit shown, the energy stored in 1 pF capacitor is (A) 40 pJ (B) 64 pJ (D)none (C) 32 pJ 3nF I^ HF Q.23 Four metallic plates arearranged as shown in thefigure.Ifthe distance betwe en each plate then capacitance of the given system between points A and B is (Gi ve n d « A) 2s A I - , _ S pA sA / , I (A) d (B) 3s A 4s o A (C) d (D) n 0n 1 0 (fe B ansal Classes Question Bank on Capacitance [13]

£ Q.24 What is the equivalent capacitance of the system of capacitors between A & B W~6c .A 2. B Q.25 From a supply ofidentical capacitors rated 8 pF, 250 V, the minimum numbe r of capacitors required to form a composite 16 pF, 1000 Vis : (A) 2 (B) 4 (C) 1 6 (D) 32 cP (B) 1.6 C (C)C (D) None £. Q.26 The minimum number ofca pacitors each of3 pF required to make a circuit with an equivalent capacitance 2 .25 pF is (A) 3 (B)4 (C)5 (D)6 0 Q.29 A capacitor of capacitance 1 pF withstands the maximum voltage 6 kV while a capacitor of 2 pF withstands the maximum volta ge 4 kV. What maximum voltage wil l the system of these two capacitor withstands if they are connected in series? £ (A) lOkV (B)12kV (C) 8 kV (D)9kV Q.30 Four ide ntical plates 1,2,3 and 4 are plac ed parallel to each other at equal distance a s shown in the figure. Plates 1 and 4 are joined together and the space between 2 and 3 is filled with a dielectric of dielectric constant k = 2. The capacitanc e of the system between 1 and 3 & 2 and 4 are Cj and C2 C, respectively. The rat io — is : C-2 3 (B)l (A)-: (D) 5 ( C ) £ Q.27 The capacitance (C) for an isolated co nducting sphere of radius (a) is give n by 47ts a. Ifthe sphere is enclosed with an earthed concentric sphere. The rat io ofthe radii of the spheres being n the n the (n-1) Icapacitance of such a sphe re will be increased by a factor n (n-1) (A)n (D) a. n (B) (n-1) (C) n -' Q.28 T wo capacitor having capacitances 8 pF a nd 16 pF have breaking voltages 20 V and 80 V. They are combined in series. The maximum charge they can store individuall y in the combination is (A) 160 pC (B) 200 p,C (C) 1280 p,C (D) none ofthese y Q.31 # In the circuit shown infigure,th e ratio ofcharges on 5pF and 4pF capacitor is: ( A) 4/5 (B)3/5 (C) 3/8 (D) 1/2 3 jiF •JL— 5(iF 4nF 6V

Q.32 In the circuit shown, a potential difference of 60V is applied across AB. T he potential difference between the point M and N is (A) 10 V (B) 15V (C) 20 V ( D) 30 V 60V B I Li r - Cr ^ h r 2d H (fe Bansal Classes Question Bank on Capac itance [13]