http://iitscholars.com http://iitvidya.com http://iitscholar.com PHYSICS 1. 2. Two particles, each of mass m carrying charge Q, are separated by some distance. If they are in equilibrium under mutual gravitational and electrostatic forces then Q/m (in C/kg) is of the order of (A) 10–5 (B) 10–10 –15 (C) 10 (D) 10–20 R The value of R for which 20 % of the main current passes through galvanometer of resistance 80 is ( m a in c u r r e n t) (A) 10 (B) 20 G I (C) 30 (D) 40 3. Charge Q is divided into two parts which are then kept some distance apart. The force between them will be maximum if eth two parts are (A) Q/2 each (B) Q/4 and 3Q/4 (C) Q/3 and 2Q/3 (D) e and (Q – e), where e = electronic charge 4. If switch S is closed at t = 0 then the time at which power supplied by battery is equal to rate of energy storage in capacitor is (A) t = 0 (B) t = 4RC (C) t = 5RC (D) It never happens (except t ) because resistor always consume energy 5. 6. 7. R C S A point charge Q is moved along a circular path around another fixed point charge. The work done is zero (A) only if Q returns to its starting point (B) only if the two charges have the same magnitude (C) only if the two charges have the same magnitude and opposite signs (D) in all cases 4 6 A Potential difference between point A and B is (A) 122 volt 4 (B) 60 volt A B 3 3 (C) 100 volt (D) none of these Which of the following is not true for a region with a uniform electric field ? (A) it can have free charges (B) it may have uniformly distributed charge (C) it may contain dipoles (D) none of the above http://iitscholars.com http://iitvidya.com http://iitscholar.com http://iitscholars.com http://iitvidya.com http://iitscholar.com 8. 9. 10. 1 B 6V Potential of point B is (A) 6 volt (C) 4 volt (B) 5 volt (D) 3 volt 3 2 A positive point charge, which is free to move, is placed inside a hollow conducting sphere with negative charge, away from its centre. It will (A) move towards the centre (B) move towards the nearer wall of the conductor (C) remain stationary (D) oscillate between the centre and the nearer wall C2 Charge on the capacitor having capacitance C2 in steady state is R (A) Zero (B) (C1 + C2)V R (C) C2V (D) C1V C1 V 11. A spherical conductor A or radius r is placed concentrically inside a conducting shell B of radius R (R > r). A charge Q is given to A, and then A is joined to B by a metal wire. The charge flowing from A to B will be R r (A) Q (B) Q Rr Rr (C) Q (D) zero 12. The capacitor shown in the figure is in steady state. The energy stored in the capacitor is R IR 2 2 (A) CI R (C) 4CI2R2 R C (B) 2CI2R2 (D) None of the above 13. A simple pendulum of time period T is suspended above a large horizontal metal sheet with uniformly distributed positive charge. If the bob is given some negative charge, its time period of oscillation will be (A) > T (B) < T (C) T (D) proportional to its amplitude 14. Figure shows a portion of circuit the potential of point D is. (A) – 5 V (B) 5 V (C) – 10 V (D) 10 V 10V 1 4 1 10V 1 10V http://iitscholars.com http://iitvidya.com http://iitscholar.com 2 6A D http://iitscholars.com http://iitvidya.com http://iitscholar.com 15. 16. C In the circuit shown, the equivalent capacitance between the points A and B is (A) C/5 (B) C/3 (C) C/2 (D) C C C A In the figure shown, if Galvanometer shows no deflection then the value of x is (A) 4 (B) 3 (C) 2 (D) 8 C B C 2 4 4 G 8 x 17. In a parallel–plate capacitor, the region between the plates is filled by a dielectric slab. The capacitor is connected to a cell and the slab is taken out (A) some charge is drawn from the cell (B) some charge is returned to the cell (C) the potential difference across the capacitor is reduced (D) no work is done by an external agent in taking the slab out 18. When the switch is closed, the initial current through the 1 resistor is (A) 12 A (B) 4 A 10 (C) 3 A (D) A 7 1 6 12 V 3 S 19. The drift velocity of electrons in a metallic conductor carrying in current is usually of the order of (A) 1 cm/s (B) 10 m/s (C) 104 m/s (D) 108 m/s 20. For what value of R, power developed across 6 resistor is equal to the power developed across 24 resistor? (A) 12 (B) 6 (C) 24 (D) 8 R i i 6 24 21. The resistance of a metallic conductor increases with temperature due to (A) change in carrier density (B) change in dimensions of the conductor (C) increase in the number of collisions among the carriers (D) increase in the rate of collisions between the carriers and the vibrating atoms of the conductor 22. A parallel combination of two resistors of 1 each, is connected in series with a 1.5 resistor, and two uncharged capacitances of 1.5F and 3F , also in series. The combination is connected to a 10 V battery. The initial current flowing in the circuit is (assume that the capacitors are initially uncharged) (A) 5 A (B) 0 A (C) 0.3 A (D) 0.4 A. http://iitscholars.com http://iitvidya.com http://iitscholar.com http://iitscholars.com http://iitvidya.com http://iitscholar.com 23. 2V A source of internal resistance 4 is connected in a circuit as shown in the figure: The maximum energy that can be dissipated in R occurs when (A) R 1 (B) R 7 (C) R 12 7 4 R (D) R 0 . 3 24. A piece of copper and another of germanium are cooled from room temperature to 80 K. The resistance of (A) each of them increases (B) each of them decreases (C) copper increases and that of germanium decreases (D) copper decreases and that of germanium increases 25. A cell of emf 2V is connected across a resistance 5 . The potential difference between the terminals of the cell is found to be 1.25 V. The internal resistance is 15 8 10 (C) 3 (A) 26. (B) 3 (D) none of these. The net resistance between point P and Q in shown in the figure is R (A) (B) 2 3R (C) (D) 5 R the circuit R R Q P 2R 5 R 3 R 27. Current flows through a metallic conductor whose area of cross–section increases in the direction of the current. If we move in this direction, (A) the current will change (B) the carrier density will change (C) the drift velocity will increase (D) the drift velocity will decrease 28. The current passing through 4 resistance is zero. Then the emf E is (A) 8V (B) 12V (C) 6V (D) none of these 12V 2 E 29. A cell of internal resistance r drives a current through an external resistance R. The power delivered by the cell to the external resistance is maximum when (A) R = r (B) R >> r (C) R << r (D) R = 2r 30. In a potentiometer experiment, two cells connected in series get balanced at 9 cm length on the wire. Now the connections of terminals of the cell of lower emf are reversed then the balancing length is obtained at 3 cm. The ratio of emf’s of two cells will be (A) 1 : 3 (B) 2 : 1 (C) 1 : 4 (D) 4 : 1. 31. In the given figure R1 > R2. We will get a better ammeter if (A) only K1 is closed (B) only K2 is closed (C) both K1 and K2 is closed (D) both K1 and K2 are open http://iitscholars.com http://iitvidya.com http://iitscholar.com G K 1 R 1 K 2 R 2 http://iitscholars.com http://iitvidya.com http://iitscholar.com 32. 33. 34. When a 500 W electric bulb and a 500 W heater operate at their rated voltages, the filament of the bulb reaches a much higher temperature than the filament of the heater. The most important reason for this is that (A) their resistances are not equal (B) they are made of different materials (C) their dimensions are very different (D) they radiate different powers at different temperatures A galvanometer may be converted into ammeter or voltmeter. In which of the following cases the resistance of the device will be the largest ? (Assume maximum range of galvanometer = 1 mA) (A) an ammeter of range 10 A (B) a voltmeter of range 5 V (C) an ammeter of range 5 A (D) a voltmeter of range 10 V. A capacitor of capacitance C is charged by an ideal battery of emf V. Then, heat generated during the charging of capacitor is, (A) zero (B) CV2 CV 2 1 (C) CV 2 (D) . 4 2 C V 35. All charge on a conductor must reside only on its outer surface. This statement is true (A) in all cases (B) for spherical conductors only (both solid and hollow) (C) for hollow spherical conductor only (D) for conductors which do not have nay sharp points or corners 36. A point charge Q is placed outside a hollow spherical conductor of radius R, at a distance r (r > R) from its centre C. The field at C due to the induced charges on the conductor is Q (A) zero (B) k (r R) 2 Q Q (C) k 2 , directed towards Q (D) k 2 , directed away from Q r r 37. A spherical equipotential surface is not possible (A) for a point charge (B) for a dipole (C) inside a uniformly charge sphere (D) inside a spherical capacitor 38. In an isolated parallel–plate capacitor of capacitance C, the four surface have charges Q1, Q2, Q3 and Q4, as shown. The potential difference between the plates is Q Q 2 Q3 Q 4 Q Q3 (A) 1 (B) 2 2C 2C Q 2 Q3 Q1 Q 4 (C) (D) 2C 2C 39. In the arrangement shown, all plates have equal area. The amount of spacing between plates is mentioned. Find the equivalent capacitance A of the system between A and B if C 0 L 5 C 7 1 (C) C 7 (A) (B) 3 C 7 2L L L L 2L (D) None of these http://iitscholars.com http://iitvidya.com http://iitscholar.com Q1 Q3 Q2 Q4 A B http://iitscholars.com http://iitvidya.com http://iitscholar.com 40. 41. Potential within a hypothetical charged sphere varies with the distance of a point from centre as V a.r where a is a vector of constant magnitude parallel to r and r is position vector of point under consideration taking centre of sphere as origin. Then the total charge stored within a sphere of radius R is. (A) R2 0a (B) 2R2 0a (C) 3R2 0a (D) 4R2 0a y-axis What is the direction of electric field at point O as shown in figure ? + + – –– (A) positive x-axis (B) negative x-axis + –– + – + (C) positive y-axis (D) negative y-axis O – – x-axis + + ++ + – – –– – – 42. In a parallel plate capacitor of plate area A, plate separation d and charge Q, the force of attraction between the plates is F, then 1 (A) F Q2 (B) F 2 A 1 (C) F d (D) F d 43. An arrangement of three metallic conductors is shown. What is the magnitude of charge appearing on the left face of the conductor B? (A has a total charge Q1 and C has a total charge Q2) (A) zero (B) Q1 Q Q1 (C) Q2 (D) 2 2 Q1 Q2 B A C 44. Uniform electric field lines pass inward through the flat surface of a hemisphere of radius r , making angle of 60º with the normal to the plane of the surface. The strength of the field is E0 . There is no charge anywhere. The net outward flux through the curved surface is . Then (A) E0 r 2 cos60º (B) E0 r 2 sin 60º (C) 0 (D) E0 r 2 cos2 60º . 45. A, B, C, D are identical, parallel, conducting plates arranged as shown, with equal separations between consecutive plates. A and D are connected to a cell. If B is now connected to C, which of the following will occur ? (A) only that some charge will flow through the cell. (B) only that some charge will flow from B to C. (C) only that there will be no electric field between B and C. (D) more than one of the above. A 46. A B C D E A particle of charge q and mass m is projected from a large distance towards another identical charged particle at rest with velocity v0. The distance of closest approach will be q2 q2 (A) (B) 20 mv02 0 mv02 (C) 2q 2 0 mv02 (D) q2 40 mv02 http://iitscholars.com http://iitvidya.com http://iitscholar.com http://iitscholars.com http://iitvidya.com http://iitscholar.com 47. 48. A point of charged q is placed at a distance 2r from the centre O of a conducting uncharged sphere of radius r. Potential of O +q induced charges at point P(lying in a line joining the point charge P 2r and centre of sphere) is Kq Kq (A) (B) 2r 3r Kq (C) (D) None of these 6r Four charges of 6C, 2C, 12C and 4C are placed at the circumference of a circle. The circle is in x-y plane and its centre at its origin. Locus of the points where electric potential is zero is (A) x = y, z = 0 (B) x = 0 = z (C) x = 0 = y (D) x = z, y = z 49. A large metallic plate is given a charge Q. Area of one face of the plate is A. Electric field at a point near the metallic plate is Q Q (A) (B) Aε 0 2Aε 0 Q (C) (D) None of the above 4Aε 0 50. In the circuit shown below, the galvanometer G will show zero deflection (A) in all cases (B) only if S is open (C) only if S is closed (D) none of the above 6 4 + 4 6 G S CHEMISTRY 51. The general molecular formula, which represents the homologous series of alkanols is : (A) CnH2n+1O (B) CnH2n+2O (C) CnH2nO2 (D) CnH2nO 52. Reaction of t-butyl bromide with sodium methoxide produces : (A) isobutane (B) isobutylene (C) sodium t-butoxide (D) t-butyl methyl ether 53. The best reagent to convert pent-3-en-2-ol into pent-3-en-2-one is : (A) acidic KMnO4 (B) alkaline K2Cr2O7 (C) Chromium anhydride in glacial acetic acid (D) pyridinium chlorochromate 54. Ethylene oxide when, treated with Grignard reagent yields : (A) cyclopropyl alcohol (B) primary alcohol (C) secondary alcohol (D) tertiary alcohol 55. Reaction of http://iitscholars.com http://iitvidya.com http://iitscholar.com http://iitscholars.com http://iitvidya.com http://iitscholar.com H2C CH2 O with RMgX followed with hydrolysis produces : (A) RCHOHR (B) RCH2CH2OH (C) RCHOHCH3 (D) RCH = CHOH 56. The major organic product in the reaction, CH3 O CH CH3 2 HI Product is : (A) CH3O C (CH3)2 (B) CH3I + (CH3)2CHOH | I (C) CH3OH + (CH3)2CHI (D) ICH2OCH(CH3)2 57. HBr reacts with CH2 = CH – OCH3 under anhydrous conditions at room temperature to give (A) CH3CHO and CH3Br (B) BrCH2CHO and CH3OH (C) BrCH2 – CH2 – OCH3 (D) H3C – CHBr – OCH3 58. An industrial method of preparation of methanol is : (A) catalytic reduction of carbon monoxide in presence of ZnO – Cr2O3 (B) by reacting methane with steam at 900°C with a nickel catalyst (C) by reacting formaldehyde with lithium aluminium hydride (D) by reacting formaldehyde with aqueous sodium hydroxide solution 59. Which will not form a yellow precipitate on heating with an alkaline solution of iodine? (A) CH3CHOHCH3 (B) CH3CH2CHOHCH3 (C) CH3OH (D) CH3CH2OH 60. 1-phenyl ethanol can be prepared from banzaldehyde by the action of : (A) CH3Br (B) CH3Br and AlBr3 (C) CH3I, Mg and HOH (D) C2H5I and Mg 61. HBr reacts fastest with : (A) 2-methylpropan-2-ol (C) propan-2-ol (B) propan-1-ol (D) 2-methylpropan-1-ol 62. Dehydration of alcohols to alkene by heating with conc. H2SO4 the initiation step is . . . . . followed with . . . . . mechanism, (A) elimination of water, free radical (B) formation of an ester, free radical (C) protonation of alcohol, carbocation (D) protonation of alcohol, carbanion 63. A carbonyl compound reacts with hydrogen cyanide to form cyanohydrin which on hydrolysis form a racemic mixture of -hydroxy acid. The carbonyl compound is : (A) diethyl ketone (B) formaldehyde (C) acetaldehyde (D) acetone 64. The increasing order of the rate of HCN addition to compounds A – D is : (i) HCHO (ii) CH3COCH3 (iii)PhCOCH3 (iv) PhCOPh (A) (i) < (ii) < (iii) < (iv) (B) (iv) < (ii) < (iii) < (i) (C) (iv) < (iii) < (ii) < (i) (D) (iii) < (iv) < (ii) < (i) 65. Nucleophilic addition reaction will be most favoured in : (A) CH3CH2CHO (B) CH3CHO (C) CH3 CH2 CH2COCH3 (D) (CH3)2C = O http://iitscholars.com http://iitvidya.com http://iitscholar.com http://iitscholars.com http://iitvidya.com http://iitscholar.com 66. Which one of the following aldehydes will not form an aldol when treated with dil. NaOH? (A) CH3CHO (B) CH3CH2CHO (C) (CH3)3CCHO (D) C6H5CH2CHO 67. Ketones can be obtained in one step by : (A) hydrolysis of ester (C) reaction of acid halide with alcohols 68. 69. 70. (B) oxidation of primary alcohols (D) oxidation of secondary alcohol CH3 2 C CHCOCH3 can be oxidized to CH3 2 C CHCOOH by : (A) Cu at 300°C (C) chromic acid (B) KMnO4 (D) NaOI Acetaldehyde reacts with : (A) only nucleophiles (C) only electrophiles (B) both electrophiles and nucleophiles (D) only free radicals CH3COCH3 can be obtained by : (A) heating acetaldehyde with methanol (C) oxidation of isopropyl alcohol (B) oxidation of propyl alcohol (D) reduction of propionic acid 71. The reagent which can be used to distinguish acetophenone from benzophenone is : (A) 2, 4-dinitrophenyl hydrazine (B) aqueous NaHSO3 (C) benedict’s solution (D) I2 and Na2CO3 72. Pd/H CH3COCl X. Here X is : BaSO 2 4 (A) acetaldehyde (C) acetone (B) propionaldehyde (D) acetic anhydride 73. Which of the following compounds will undergo self aldol condensation in presence of cold dilute alkali? (A) C6H5CHO (B) CH2 = CH – CHO (C) CH3CH2CHO (D) none of these 74. Which can be oxidized to the corresponding carbonyl compound? (A) Propan-2-ol (B) Ortho-nitro-phenol (C) Phenol (D) 2-methylpropan-2-ol 75. Which can be reduced to corresponding hydrocarbon by Zn / HCl? (A) Butan-2-one (B) Acetic acid (C) Acetamide (D) Ethyl acetate 76. Which of the following will react with acetone to give a product containing C=N– (A) C6H5NH2 (B) (CH3)3N (C) C6H5NHC6H5 (D) C6H5NHNH2 77. 78. dil.NaOH how many distinct products (saturated) are In the reaction HO – CH2 – CHO possible ? (A) 1 (B) 2 (C) 3 (D) 4 In which of the following substrates, rate of Benzoin condensation will be maximum? http://iitscholars.com http://iitvidya.com http://iitscholar.com http://iitscholars.com http://iitvidya.com http://iitscholar.com 79. (a) (A) O2N (C) (c) HO (B) (b) CHO H3C CHO (D) NH2 CHO CHO Mg/Hg 2CH3 C CH3 Product. Product in the reaction is || H O CH3 CH3 | | (B) CH3 C O C CH3 (A) H3C C C CH3 | | OH OH (C) CH3 CH CH CH3 | || || O O (D) none of these | OH OH 80. What is A in the following reaction? O Cl O t BuOK A t BuOH O H5 C 2 O O H3C O (A) (B) C 2 H5 C 2H5 O O (C) O O 81. OH (D) C 2 H5 O CH3 is the final product obtained when one of the following is reacted with base. O O O (A) (B) H3C H3C CH3 O (C) O CH3 O O (D) H3C H3C CH3 82. O CH3 End product of the following sequence of reactions is CH3MgBr CO2 /H3O HgSO4 /H2SO4 Ag2O CH CH O (A) O H3C OH O (B) HO O OH http://iitscholars.com http://iitvidya.com http://iitscholar.com http://iitscholars.com http://iitvidya.com http://iitscholar.com O (C) O H3C (D) H O 83. O OH H / Pt 2 —CH=CH—CHO A NaBH 4 B A and B are: (A) —CH CH CHO, 2 2 —CH=CH—CH2OH (B) —CH2CH2CH2CHOH, (C) —CH=CH—CH2OH in both cases (D) —CH2CH2CH2OH in both cases —CH=CH—CH2OH 84. Dipole moment of CH3CH2CH3(I), CH3CH2OH (II) and CH3CH2F(III) is in order (A) I II III (B) I II III (C) I III II (D) III I II 85. The strongest acid among the following aromatic compounds is (A) p-chlorophenol (B) p-nitrophenol (C) m-nitrophenol (D) o-nitrophenol 86. The boiling points of isomeric alcohols follow the order (A) primary secondary tertiary (B) tertiary secondary primary (C) secondary tertiary primary (D) does not follow any order 87. Phenol can be distinguished from alcohol with (A) Tollens reagent (B) Schiff's base (C) Neutral FeCl3 (D) HCl 88. Which compound is formed when CH3OH reacts with CH3 – Mg - X (A) Acetone (B) Alcohol (C) Methane (D) Ethane 89. Methyl alcohol can be distinguished from ethyl alcohol using (A) Fehling solution (B) Schiff’s reagent (C) Sodium hydroxide and iodine (D) Phthalein fusion test 90. The reagent which easily reacts with ethanol and propanol is (A) Fehling solution (B) Grignard reagent (C) Schiff’s reagent (D) Tollen’s reagent 91. An aromatic amine (A) was treated with alcoholic potash and another compound (Y) when foul smelling gas was formed with formula C6H5NC. Y was formed by reacting a compound (Z) with Cl2 in the presence of slaked lime. The compound (Z) is (A) C6H5NH2 (B) C2H5OH (C) CH3OCH3 (D) CHCl3 http://iitscholars.com http://iitvidya.com http://iitscholar.com http://iitscholars.com http://iitvidya.com http://iitscholar.com 92. The reaction of C2H5OH with H2SO4 does not yield (A) Ethylene (B) Diethyl ether (C) Acetylene (D) Ethyl hydrogen sulphate 93. Which of the following are isomers (A) Methyl alcohol and dimethyl ether (C) Acetone and acetaldehyde (B) Ethyl alcohol and dimethyl ether (D) Propionic acid and propanone 94. An alcohol on oxidation is found to give CH3COOH and CH3CH2COOH. The structure of the alcohol is (A) CH3CH2CH2OH (B) (CH3)2C(OH)CH2CH3 (C) CH3CH2CHOHCH3 (D) CH3CH(OH)CH2CH2CH3 95. Dehydration of cyclopentyl carbinol with conc. H2SO4 forms (A) Cyclopentene (B) Cyclohexene (C) Cyclohexane (D) None of these 96. Phenol does not react with NaHCO3 because (A) phenol is a weaker acid than carbonic acid (B) phenol is a stronger acid than carbonic acid (C) phenol is as strong as carbonic acid (D) phenol is insoluble in water. 97. The acidic character of 1°, 2°, 3° alcohols, H2O and RCCH is in the order (A) H2O 1° 2° 3° RCCH (B) RCCH 3° 2° 1° H2O (C) 1° 2° 3° H2O RCCH (D) 3° 2° 1° H2O RCCH 98. The major product P in the following reaction is H (CH3 )3 COH C2 H5OH P (A) (CH3)3COC(CH3)3 (C) C2H5OC2H5 (B) (CH3)3COC2H5 (D) (CH3)2C = CH2 OD 99. D i) CO2 NaOH [ ] P. ii)D Here P is OH (A) D O OD (C) 100. OD OD (B) OD D O OH D O (D) Reaction not possible The product (B) in the following sequence of reaction is: C6 H5CO3H HCl A B CH2 http://iitscholars.com http://iitvidya.com http://iitscholar.com http://iitscholars.com http://iitvidya.com http://iitscholar.com OH O (A) (B) Cl O Cl (C) (D) OH OH MATHEMATICS 101. x 3 x 1 dx If = Ax3 + Bx2 + Cx – ln (x + 1) + k then A + B + C is equal to 1 6 2 (C) 3 2 6 5 (D) 6 (A) 102. x 2f (x 3 ) dx is equal to f (x 3 ) I (A) f (x 3 ) c 3 2x f (x 3 ) (D) 2 f (x 3 ) c (2x 3) is equal to x 1 (A) 2ex x 1 + C ex (C) + C x 1 e x 1 104. (B) 2 f (x 3 ) dx 3 (C) 103. (B) The value of dx x1/3 1 (A) (9/40) (8.22/3 - 9) (C) (9/40) (8.21/3 - 9) 3 (B) ex x 1 + C (D) none of these is equal to 0 (B) (40/9) (8.22/3 - 9) (D) none of these 4 105. {x 0.4}dx equals ({x} is a fractional part of x) 1 (A) 1.3 (C) 1.5 106. (B) 6.3 (D) 7.5 1 log(x 1 x 2 ) 1 x log(x 1 x 2 ) (A) 0 (C) 2f(x) (f (x) f (x)) dx is equal to (B) 2 1 log(x 1 x 2 ) x log(x 1 x 2 ) (D) none of these 0 (f (x) f (x))dx http://iitscholars.com http://iitvidya.com http://iitscholar.com http://iitscholars.com http://iitvidya.com http://iitscholar.com 1 107. | x x 2 | dx | x 2 3x 2 |dx 2 0 1 1 (A) 2 1 (C) 4 108. 109. 1 3 1 (D) 8 (B) tan–1 . tanx d equals (A) tan–1. secx + c 1 (C) tanx { tan–1 – log (1 + 2)} + c 2 x 2 dx is equal to (1 x 4 ) / 4 (1 x 4 )1/ 4 c x (1 x 4 )3 / 4 c (C) x (A) 110. 111. (B) (1 x 4 )1/ 4 c x (D) none of these 2x 1 e tan x 1 x2 2 dx is equal to 1 (A) e x tan 1 x C 1 x2 1 (C) e x cot 1 x C 1 x2 x The value of the x 2 11 5 2 10 C x 2 x 11 11 6 (C) x 110 C 7 x dx 1 x3 x x (A) 112. (B) tan–1.. log(secx) + c 1 (D) tan {x tan–1 x – log (1 + x2)} + c 2 8 1 (B) e x tan 1 x C 1 x2 2 (D) e x tan 1 x C 1 x2 1 2 x 9 10 dx is 11 5 x 110 C 6 10 11 2 (D) x 2 x 11 C 5 (B) dx (A) 1 1 x3 1 log c 3 1 x3 1 (B) 1 1 x2 1 log c 3 1 x 2 1 (C) 1 1 log c 3 1 x3 (D) 1 log 1 x 3 c 3 1 113. If e x sin x k 0 (for some , R), 0, then the value of k can belong to 2 0 5 (A) , 3 12 (B) , 3 2 http://iitscholars.com http://iitvidya.com http://iitscholar.com http://iitscholars.com http://iitvidya.com http://iitscholar.com (D) , 2 3 (C) , 4 6 114. The value of x cot x cosec x x cot x 2 dx is equal to (A) 1 C x tan x 1 (B) 1 C x sin x cos x (C) 1 C x cot x (D) 1 C x sin x cos x 115. Area bounded by the curve y = (x – 1) (x – 2) (x – 3) and x-axis lying between the ordinate x = 0 and x = 3 is equal to 9 11 (A) (B) 4 4 11 (C) (D) none of these 2 116. The area bounded by the curve y = 2x – x2 and the straight line y = – x is 9 43 (A) (B) 2 6 35 (C) (D) none of these 6 117. The area of the region bounded by the curve y = ordinates x = /6 and x = /3 is; (A) /4 (C) /8 1 1 (tan x) Area enclosed by the curve y = x3 and y = x1/3 is (A) 1 sq. unit (B) 2 sq. unit (C) there is no area enclosed (D) none of these 119. | ln x | dx equals (0 < x < 1) 1 120. | x x (B) x |lnx| – x + c (D) x + x |lnx| + c 2 2 | dx | x 2 3x 2 |dx 0 121. and the x-axis between the (B) /2 (D) none of these 118. (A) x (|lnx| – (x – 1)) + c (C) x (|lnx| + (x – 1)) + c 2 1 (A) 1 2 (B) 1 3 (C) 1 4 (D) 1 8 The value of x cot x cosec x x cot x 2 dx is equal to http://iitscholars.com http://iitvidya.com http://iitscholar.com http://iitscholars.com http://iitvidya.com http://iitscholar.com 1 C x tan x 1 1 C (C) x cot x (A) 1 C x sin x cos x 1 C (D) x sin x cos x (B) 122. The area bounded by the curve y = 2x – x2 and the straight line y = – x is 9 43 (A) (B) 2 6 35 (C) (D) none of these 6 123. The area of the region bounded by the curve y = ordinates x = /6 and x = /3 is; (A) /4 (C) /8 124. x c y x (C) x 2 y 2 2In c y 126. (B) xy 2In x c y (D) none of these The degree and order of differential equation of family of circle touching a parabola y2 = 4x (R) at its vertex is (A) degree = 2, order = 1 (B) degree = 1, order = 2 (C) degree = 1, order = 0 (D) none of these Let y A Bx e3x is a solution of the differential equation then (m, n) is (A) (-6, 9) (C) (9, 6) 127. (B) /12 (D) none of these The solution of the differential equation 1 x 2 y2 y dx x 2 y2 1 x dy 0 is (A) xy In 125. 1 and the x-axis between the 1 (tan x)1/2 d2 y dy m ny 0, m n I, 2 dx dx (B) (-6, 8) (D) (-9-, -6) The area bounded by the parabola y = x2 – 7x + 10 and x-axis equals 1 (A) 5/2 sq. units (B) sq. units 6 5 9 (C) sq. units (D) sq. units 6 2 2 128. 129. dy dy A solutions of the differential equation (e x e x ) 1 0 are given by dx dx –x (A) y + e = C (B) y – e–x = C x (C) y + e = C (D) none of these 2 1 2 1 1 cos ec101 x dx is x x http://iitscholars.com http://iitvidya.com http://iitscholar.com http://iitscholars.com http://iitvidya.com http://iitscholar.com (A) 1 (C) 2 130. 131. 132. / 2 (B) 3 (D) 0 2cos x 1 2x (A) 1 (C) 3 / 2 3 dx is (B) 2 (D) 0 sin 6x dx is sin x (A) 0 (C) 4 (B) 6 (D) 3 The area bounded by y = 3x and y = x2 (A) 5/2 (C) 3 (B) 7/2 (D) 9/2 0 133. The area bounded by x = 4 – y2 and the y-axis (A) 16/3 (B) 4/3 (C) 4/3 (D) 8/3 134. The area in square units of the region bounded by the curve x2 = 4y the line x = 2 and the xaxis is (A) 1 (B) 5/3 (C) 2/3 (D) 7/6 135. The area bounded by y = x3, y = x2 and x = 1, x = 2 (A) 13/12 (B) 17/12 (C) 5/12 (D) none of these 136. 137. d2 y The order and degree of 2 dx (A) (2, 2) (C) 1,2 2/3 43 dy 2 The order and degree of 1 dx (A) (1, 2) (C) (3, 4) 3/2 dy 0 dx (B) (3, 2) (D) (3, 4) d3 y K 3 is dx (B) (3, 2) (D) (2, 2) /4 138. In In = tan n d, then I8 + I6 equals 0 (A) 1/4 (C) 1/6 /2 139. 0 (B) 1/5 (D) 1/7 2sin x dx is 2sin x 2cos x (A) 2 (C) /4 (B) (D) /2 http://iitscholars.com http://iitvidya.com http://iitscholar.com http://iitscholars.com http://iitvidya.com http://iitscholar.com 140. The area common to the parabola y = 2x2 and y = x2 + 4 is (A) 2/3 sq. units (B) 3/2 sq. units (C) 32/3 sq. units (D) 3/32 sq. units 141. The area bounded by y = 1 + 8/x2 and the ordinates x = 2 and x = 4 is (A) 2 (B) 4 (C) log 2 (D) log 4 2/3 142. 143. 144. d3 y d2 y dy The degree of the differential equation 3 4 3 2 5 = 0 is dx dx dx (A) 1 (B) 2 (C) 3 (D) none of these The solutions of (x + y + 1) dy = dx is (A) x + y + 2 = Cey (C) log (x + y + 2) = Cy The solution of the equation dy/dx = (A) y siny = x2 logx + x2/2 + c (C) ycosy = x2 log x + x2/2 + c 145. 146. (B) x + y + 4 = C logy (D) log (x + y + 2) = C - y x(2log x 1) is sin y y cos y (B) y cosy = x2 (logx + 1) + c (D) y siny = x2 log x + c dy = y (logy - logx + 1) then the solution of the equation is dx y x (A) log cy (B) log cy x y x (C) log cx (D) none of these y If x dy The solution of the equation log = ax + by is dx by ax e e e by eax (A) (B) c c b a b a e by eax c (C) (D) none of these a b 3 147. The solution of y dx - x dy + 3x2 y2 e x dx = 0 is 3 3 x x (A) e x C (B) e x = 0 y y 3 x (C) e x = C (D) none of these y 148. Solution of differential equation dy - sinx siny dx = 0 is (A) ecosx. tan y/2 = c (B) ecosx . tany = c (C) cosx. tany = c (D) cosx. siny = c 149. The order of the differential equation whose solution is y = acosx + bsinx + Ce-x is (A) 3 (B) 2 (C) 1 (D) none of these http://iitscholars.com http://iitvidya.com http://iitscholar.com http://iitscholars.com http://iitvidya.com http://iitscholar.com 5 150. If f(x) denotes the greatest integer less than or equal to x, then the value of | x 3 | dx 1 (A) 1 (C) 4 (B) 2 (D) 8 ANSWERS PHYSICS 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50. 58. 59. 60. 61. 62. 63. 64. 65. 66. 67. 68. 69. 70. 71. 72. 73. 74. 75. 76. 77. 78. 79. 80. 81. 82. 83. 84. 85. 86. 87. 88. 89. 90. 91. 92. 93. 94. 95. 96. 97. 98. 99. 100. (B) (B) (A) (D) (D) (A) (D) (B) (C) (A) (C) (B) (B) (A) (D) (D) (B) (B) (A) (C) (D) (A) (B) (D) (B) (B) (D) (B) (A) (B) (C) (C) (D) (C) (A) (C) (B) (C) (B) (D) (A) (A) (D) (A) (D) (B) (C) (C) (A) (C) MATHEMATICS CHEMISTRY 51. 52. 53. 54. 55. 56. 57. (B) (B) (D) (B) (B) (B) (D) (A) (C) (C) (A) (C) (C) (C) (B) (C) (D) (D) (B) (C) (D) (A) (C) (A) (A) (C) (D) (D) (A) (C) (A) (B) (B) (A) (B) (A) (C) (C) (C) (B) (B) (C) (B) (D) (D) (A) (A) (B) (C) (C) 101. 102. 103. 104. 105. 106. 107. 108. 109. 110. 111. 112. 113. 114. 115. 116. (D) (C) (A) (A) (C) (A) (B) (C) (A) (A) (A) (A) (C) (B) (B) (A) http://iitscholars.com http://iitvidya.com http://iitscholar.com 117. 118. 119. 120. 121. 122. 123. 124. 125. 126. 127. 128 129. 130. 131. 132. 133. 134. 135. 136. 137. 138. 139. 140. 141. 142. 143. 144. 145. 146. 147. 148. 149. 150. (D) (A) (D) (B) (B) (A) (B) (C) (D) (A) (D) (A) (D) (B) (A) (D) (B) (C) (B) (A) (B) (D) (C) (C) (B) (B) (A) (D) (D) (B) (A) (A) (A) (B) is
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