The angle between two vectors \(a=\hat i-\hat k\) and \(b=\hat i-\hat j+\hat k\) is:
1. \(\cos^{-1}\frac13\)
2. \(\cos^{-1}\frac{-1}3\)
3. \(\sin^{-1}\frac{-1}3\)
4. \(90^\circ\)
A tangential force acting on the top of a sphere of mass \(m\) kept on a rough horizontal plane as shown in the figure.
If the sphere rolls without slipping, then the acceleration with which the centre of the sphere moves is:
1. \(\frac{10~F}{7~M}\)
2. \(\frac{F}{2~M}\)
3. \(\frac{3~F}{7~M}\)
4. \(\frac{7~F}{2~M}\)
The density of a rod having length \(l\) varies as \(\rho=c+dx,\) where \(x\) is the distance from the left end. The distance from origin to the centre of mass is:
1. \(\frac{3cl+2Dl^2}{3(2c+Dl)}\)
2. \(\frac{3cl+4Dl^2}{3(2c+Dl)}\)
3. \(\frac{2cl+3Dl^2}{3(2c+1)}\)
4. \(\frac{cl+3Dl^2}{3(2c+Dl)}\)
1. 0.1 m
2. 10 cm
3. 1 cm
4. 0.01 cm
A block slides down on an incline of angle 30° with an acceleration \(\frac g4.\) Find the kinetic friction coefficient.
1. \(\frac{1}{2\sqrt2}\)
2. \(0.6\)
3. \(\frac{1}{2\sqrt3}\)
4. \(\frac{1}{\sqrt2}\)
Two long straight wires, each carrying an electric current of 5 A, are kept parallel to each other at a separation of 2.5 cm. Find the magnitude of the magnetic force experiment by 10 cm of a wire.
1. 4.0 × 10-4 N
2. 3.5 × 10-6 N
3. 2.0 × 10-5 N
4. 2.0 × 10-9 N
A wire of resistance 10 Q is bent to form a complete circle. Find its resistance between two diametrically opposite points.
1. \(5~\Omega\)
2. \(2.5~\Omega\)
3. \(1.25~\Omega\)
4. \(\frac{10}{3}~\Omega\)
1. 2.1 x 10-3 \(\Omega\)
2. 1.3 x 10-4 \(\Omega\)
3. 3.2 x 10-4 \(\Omega\)
4. 4.6 x 10-2 \(\Omega\)
1. 50 N
2. 26 N
3. 29 N
4. 45.9 N
3. \( 600 \mathrm{~J}\)
4. \( 900 \mathrm{~J} \)
A uniform ring of mass \(m\) and radius a is placed directly above a uniform sphere of mass m and of equal to radius. The centre of the ring is at a distance \(\sqrt3a\) from the centre of the sphere. The gravitational force (F) exerted by the sphere on the ring is:
1. \(\frac{3G~Mm}{8a^2}\)
2. \(\frac{2G~Mm}{3a^2}\)
3. \(\frac{7G~Mm}{\sqrt2a^2}\)
4. \(\frac{3G~Mm}{a^2}\)
A projectile is fired with a velocity \(u\) at angle \(\theta\) with the ground surface. During the motion at any time, it is making an angle \(\alpha\) with the ground surface. The speed of the particle at this time will be:
1. \(u\cos\theta~\sec\alpha\)
2. \(u\cos\theta.\tan\alpha\)
3. \(u^2\cos^2\theta.\sin\alpha\)
4. \(u\sin\theta.\sin\alpha\)
A horizontal tube of length \(l\) dosed at both ends contains an ideal gas of molecular weight \(M.\) The tube is rotated at a constant angular velocity \(\omega\) about a vertical axis passing through an end. Assuming the temperature to be uniform and constant. If \(P_1\) and \(P_2\) denote the pressure at the free and the fixed end respectively, then choose the correct relation.
1. \(\frac{P_2}{P_1}=e^{\frac{M\omega^2l^2}{2RT}}\)
2. \(\frac{P_1}{P_2}=e^{\frac{M\omega^2}{RT}}\)
3. \(\frac{P_1}{P_2}=e^{\frac{\omega lM}{3RT}}\)
4. \(\frac{P_2}{P_1}=e^{\frac{M^2\omega^2l^2}{3RT}}\)
The parts of two concentric circular arcs joined by two radial lines and carries current \(i.\) The arcs subtend an angle \(\theta\) at the centre of the circle the magnetic field at the centre \(O,\) is:
1. \(\frac{\mu_{_0}i(b-a)\theta}{4\pi ab}\)
2. \(\frac{\mu_{_0}i(b-a)}{4\pi ab}\)
3. \(\frac{\mu_{_0}i(b-a)\theta}{\pi ab}\)
4. \(\frac{\mu_{_0}i(a-b)}{2\pi ab}\)
1. 0.125 A
2. 1.67 A
3. 0.13 A
4. 0.67A
1. 4.5 x 106 A
2. 3.2 x 10-5 A
3. 9.8 x 10-6 A
4. 6.7 x 10-4 A
1. 27 MV
2. 18 MV
3. 20 MV
4. 23 MV
1. 1.0 m\(\Omega\)
2. 2.0 m\(\Omega\)
3. 3.0 m\(\Omega\)
4. None of these
A particle is subjected to two simple harmonic motions along the X-axis while the other is along a line making an angle of 45° with the X-axis. The two motions are given by \(x = x_0\) sin \(\omega t\) and \(s = s_0\) sin \(\omega t\). The amplitude of the resultant motion is:
1. \(x_0+s_0+2x_0s_0\)
2. \(\sqrt{x^2_0+s^2_0}\)
3. \(\sqrt{x^2_0+s^2_0+2x_0s_0}\)
4. \(x^2_0=s^2_0+\sqrt2x_0s_0~^{1/2}\)
What is the change in the volume of \(1.0~\mathrm{L}\) kerosene when it is subjected to an extra pressure of \(2.0 \times 10^5 \mathrm{~Nm}^{-2}\) from the following data?
(The density of kerosene \(=800~\mathrm{kgm^3}\) and the speed of sound in kerosene \(=1330~\mathrm{ms^{-1}}\))
1. \(
0.97 \mathrm{~cm}^{-3}
\)
2. \( 0.66 \mathrm{~cm}^{-3} \)
3. \(
0.15 \mathrm{~cm}^{-3}
\)
4. \(0.59 \mathrm{~cm}^{-3}\)
Water level is maintained in a cylindrical vessel up to a fixed height \(H.\) The vessel is kept on a horizontal plane. At what height above the bottom should a hole be made in the vessel, so that the water stream coming out of the hole strikes the horizontal plane of the greatest distance from the vessel?
1. \(h=\frac{H}{2}\)
2. \(h=\frac{3H}{2}\)
3. \(h=\frac{2H}{3}\)
4. \(h=\frac{3}{4}H\)
The figure shows a spring + block + pulley system which is light. The time period of mass would be:
1. \(2\pi\sqrt{\frac{k}{m}}\)
2. \(\frac{1}{2\pi}\sqrt{\frac{k}{m}}\)
3. \(2\pi\sqrt{\frac{m}{k}}\)
4. None of these
A pendant having a bob of mass \(m\) is hanging in a ship sailing along the equator from east to west. When the strip is stationary with respect to water, the tension in the string is \(T_0.\) The difference between \(T_0\) and earth attraction on the bob, is:
1. \(\frac{mg+m\omega^2R}{2}\)
2. \(\frac{m\omega^2R}{3}\)
3. \(\frac{m\omega^2R}{2}\)
4. \(\frac{m\omega^2}R\)
A solid sphere is set into motion on a rough horizontal surface with a linear speed \(v\) in the forward direction and an angular speed \(\frac{v}{R}\) in the anticlockwise direction as shown in the figure. The linear speed of the sphere when it stops rotating is:
1. \(\frac{3v}{5}\)
2. \(\frac{2v}{5}\)
3. \(3v\)
4. \(\frac{6v}{5}\)
Two blocks of masses \(m_1\) and \(m_2\) are connected by a spring of spring constant \(k.\) The block of mass \(m_2\) is given a sharp impulse so that it acquires a velocity \(v_0\) towards the right. What is the maximum elongation that the spring will suffer?
1. \(\left[\frac{\mathrm{m}_1 \mathrm{~m}_2}{\mathrm{~m}_1+\mathrm{m}_2}\right]^{\frac{1}{2}} \mathrm{v}_0\)
2. \(\left[\frac{\mathrm{m}_1+\mathrm{m}_2}{\mathrm{~m}_1-\mathrm{m}_2}\right] \mathrm{v}_0\)
3. \(\left[\frac{\mathrm{m}_1+\mathrm{m}_2}{\mathrm{~m}_1-\mathrm{m}_2}\right]^{\frac{1}{2}} \mathrm{v}_0\)
4. \(\left[\frac{2 \mathrm{~m}_1+\mathrm{m}_2}{\mathrm{~m}_1 \mathrm{~m}_2}\right]^{\frac{1}{2}} \mathrm{v}_0\)
A ball of mass \(m\) hits the floor with a speed \(v\) making an angle of incidence \(e\) with the normal. The coefficient of restitution is \(e.\) The speed of the reflected ball and the angle of reflection of the ball will be:
1. \(v'=v,~\theta=\theta'\)
2. \(v'=\frac v2,~\theta=2\theta'\)
3. \(v'=2v,~\theta=2\theta'\)
4. \(v'=\frac{3v}{2},~\theta=\frac{2\theta'}3\)
A particle slides on the surface of a fixed smooth sphere starting from the topmost point. The angle rotated by the radius through the particle, when it leaves contact with the sphere, is:
1. \(\theta=cos^{-1}\Big(\frac13\Big)\)
2. \(\theta=cos^{-1}\Big(\frac23\Big)\)
3. \(\theta=tan^{-1}\Big(\frac13\Big)\)
4. \(\theta=sin^{-1}\Big(\frac43\Big)\)
What is the radius of curvature of the parabola traced out by the projectile in the previous problem at a point where the particle velocity makes an angle \(\frac{\theta}{2}\) with the horizontal?
1. \(r=\frac{v^2\cos^2\theta}{g\cos^2\theta}\)
2. \(r=\frac{2v\sin\theta}{g\tan\theta}\)
3. \(r=\frac{v\cos\theta}{g\sin^2\frac{\theta}{2}}\)
4. \(r=\frac{3v\cos\theta}{g\cot\theta}\)
1. 15 ° with 15 N force
2. 53 ° with 15 N force
3. 45 ° with 15 N force
4. 75 ° with 15 N force
1. 30 cm
2. zero
3. 20 cm
4. 25 cm
1. 150 N
2. >160 N
3. 165N
4. 150<T160N
A square loop is made by a uniform conductor wire as shown in the figure,
The net magnetic field at the centre of the loop if the side length of the square is a:
1. \(\frac{\mu_{_0}i}{2a}\)
2. zero
3. \(\frac{\mu_{_0}i^2}{a^2}\)
4. None of these
The electron of an H-atom is revolving around the nucleus in circular orbit having radius \(\frac{h^2}{4\pi me^2}\) with \(\Big(\frac{2\pi e^2}{h}\Big).\) The current produced due to the motion of the electron is:
1. \(\frac{2\pi m^2e^2}{3h^2}\)
2. zero
3. \(\frac{2\pi^2me}{h^2}\)
4. \(\frac{4\pi^2me^5}{h^3}\)
Two small balls, each carrying a charge \(q\) are suspended by equal insulator strings of length 1 m from the hook of a stand. This arrangement is carried in a satellite in space. The tension in each string will be:
1. \(\frac{1}{4\pi \varepsilon_0}\frac{q}{I^2}\)
2. \(\frac{1}{4\pi\varepsilon_0}\frac{q^2}{4I^2}\)
3. \(\frac{1}{4\pi\varepsilon_0}\frac{q^2}{I^2}\)
4. \(\frac{1}{(4\pi~\varepsilon_0)}\frac{q}{I}\)
A vessel of depth \(t\) is half filled with a liquid having a refractive index \(n_1\) and the other half is filled with water having a refractive index \(n_2.\) The apparent depth of the vessel as viewed from the top is:
1. \(\frac{2t(n_1+n_2)}{n_1n_2}\)
2. \(\frac{tn_1n_2}{(n_1+n_2)}\)
3. \(\frac{t(n_1+n_2)}{2n_1n_2}\)
4. \(\frac{n_1n_2}{(n_1+n_2)t}\)
1. | velocity of incident beam |
2. | frequency of incident beam |
3. | intensity of incident beam |
4. | work function for cathode material |
1. 0.86
2. 0.91
3. 0.80
4. 0.99
1. 4 days
2. 3.4 days
3. 3.9 days
4. None of the above
The de-Broglie wavelength of electrons falling on the target in an X-ray tube is 'A. The cut-off wavelength of the emitted X-ray is:
1.
2.
3.
4.
If M0 is the mass of an oxygen isotope 8O17, MP and Mn are the masses of a proton and a neutron, respectively, the nuclear binding energy of the isotope is:
1.
2.
3.
4.
A nucleus disintegrates into two nuclear parts which have their velocities in the ratio \(2:1\). The ratio of their nuclear size will be:
1. \(
2^{1 / 3}: 1
\)
2. \(
1: 3^{1 / 2}
\)
3. \( 3^{1 / 2}: 1
\)
4. \( 1: 2^{1 / 3}\)
A rod Ab of length 1 is moving with ends remaining in contact with frictionless wall and floor. If at the instant, shown the velocity of end B is 2 m/s towards the negative direction of x. The speed of end A will be:
1.
2.
3.
4.
1. Rotational effect of the earth about its axis
2. Vibrations of cesium atom
3. Orbital motion of the earth around the sun
4. Oscillation of quartz crystal
A slab consists of portions of different materials of the same thickness and having the conductivities K1 and K2. The equivalent thermal conductivity of the slab is:
1.
2.
3.
4.
Two rigid boxes containing different ideal gases are placed on the table. Box \(A\) contains one mole of nitrogen at temperature \(T_0\), while box \(B\) contains \(1\) mole of helium at temperature \(\frac{7T_0}{3}\). The boxes are then put into thermal contact with each other and heat flows between them until the gases reach a common final temperature (ignore the heat capacity of boxes) then the final temperature of gases, \(T_f\) in terms of \(T_0\) is:
1. \(
\frac{2 \mathrm{~T}_0}{5}
\)
2. \( \frac{3 \mathrm{~T}_0}{7}
\)
3. \( \frac{5 \mathrm{~T}_0}{3}
\)
4. \( \frac{9 \mathrm{~T}_0}{7}\)
1. 3000 C
2. 2000 C
3. 5000 C
4. 4000 C
1. 2470 \(\Omega\)
2. 2320 \(\Omega\)
3. 2180 \(\Omega\)
4. 2210 \(\Omega\)
A thin bar magnet of length \(2L\) is bent at the mid-point so that the angle between them is \(60^\circ\). The new length of the magnet is:
1. \(
\frac{\mathrm{L}}{2 \sqrt{3}}
\)
2. \( \frac{\sqrt{3} \mathrm{~L}}{2}
\)
3. \(\mathrm{~L}
\)
4. \(\frac{2 \mathrm{~L}}{3}\)
1. 0.7 V
2. 1.2 V
3. 0.8 V
4. 0.9 V
Given that the reduced temperature, the reduced pressure, the reduced volume, Thus, it can be said that the reduced equation of state may be given as:
1.
2.
3.
4.
The suitable reaction steps to carry out the following transformation is:
1.
2.
3.
4.
1. SO3
2. Colloidal sulphur
3. Gaseous sulphur
4. Solid Sulphur
1. 8.57 L
2. 2.14L
3. 1.28 L
4. 7.51 L
1. Potassium salt has preservative action
2. Potassium metabisulphite prevents oxidation
3. Potassium metabisulphite is not influenced by acid
4. Sulphur dioxide and sulphurous acid formed kill bacteria and germs
1. 319.4 m and X-rays
2. 319.4 m and radio wave
3. 219.3 m and microwave
4. 219.3 m and radio wave
Which of the following soap/detergent is least, reduce space biodegradable?
1.
2.
3.
4.
Buna-N, a synthetic rubber is copolymer of:
1.
2.
3.
4.
1. 28.5 kJ
2. 17.1 kJ
3. 45.7 kJ
4. 1 .7 kJ
1. -1
2. 0
3. > 1
4. < 1
1. K+ < Ca2+ < Mg2+ < Be2+
2. Be2+ < K2+ < Ca2+ < Mg2+
3. Mg2+ < Be2+ < K+ < Ca2+
4. Ca2+ < Mg2+ <Be+ < K+
1. 4.32
2. 3.34
3. 9.46
4. 5.97
1. 500 K
2. 400 K
3. 600 K
4. 200 K
1. 64%
2. 36%
3. 100%
4. 50%
1. 0.0105 equivalent of H2C2O4. 2H2O<0.625g of Fe<0.006g atom of Ag<6.0×1021 atoms of Zn
2. 0.625 g of Fe < 0.0105 equivalent of H2C2O4 2H2O<6.0×1021 atoms of Zn<0.006g atoms of Ag
3. 0.625 g of Fe<6.0×1021 atoms of Zn<0.006 g atoms of Ag<0.0105 equivalent of H2C2O4.2H2O
4. 0.0105 equivalent of H2C2O4. 2H2O < 0.006 g atoms of Ag<6.0×1021 atoms of Zn<0.625 g of Fe
1. I > II > IV > III
2. IV > III > II > I
3. II > III > IV > I
4. III> IV> II> I
If for a given substance, melting point is T8 and freezing point is TA then correct variation of entropy by graph between entropy changes:
1.
2.
3.
4.
When a mixture of 1-hexanol and hexanoic acid in diethyl ether is shaken with an aqueous NaHC03solution, then which of the following is right distribution?
1. a
2. b
3. c
4. d
1. 3528 K
2. 463 K
3. 73 K
4. 144 K
The major product P will be
1.
2.
3.
4.
1. 4.68 x 10-3
2. 5.2x 10-17
3. 0.31 X 10-2
4. 3.1 X 10-2
What is product of the following sequence of reactions?
1.
2.
3.
4.
For the following equilibrium (omitting charges)
I. M+Cl MCl, Keq =
II. MCl + Cl MC1, Keq =
III. MCl2 + Cl MCl3, Keq =
IV. M + 3Cl MC1, Keq =K
Then relationship between k,, , is
1.
2.
3.
4. All of the above
R-CH2-CH2-OH can be converted into
RCH2CH2COOH by the following sequence of steps:
1.
2.
3.
4.
1. 1, 3, 4, 5
2. 3, 2, 1, 4
3. 1, 5, 3, 7
4. 4, 3, 2, 1
The product P of the given reaction is
1.
2.
3.
4.
1. 24.5
2. 49
3. 125
4. 250
1. d-form
2. l-from
3. meso-form
4. racemic mixture
1. Four Fe2+ and two O2-
2. Four Fe2+ and four O2–
3. Two Fe2+and four O2–
4. Two Fe2+ and two O2-
1. o-bromotoluene
2. m-bromotoluene
3. p-bromotoluene
4. 3-bromo-2, 2, 6- trichlorotoluene
1. ABAB ............. and ACBACB...........
2. ABCABC ......... and ABAB............
3. Both have ABCABC.............. Arrangement
4. Both have ABAB ............. arrangement
0.001 mole of was passed through a cation exchanger and the acid coming out of it required 20mL of 0.1 M NaOH for neutralization. Thus, the complex is
1.
2.
3.
4. None of the above
1. Se8
2. Se6
3. Se4
4. Se2
In the complexes, , and more stability is shown by
1.
2.
3.
4.
For an ideal binary liquid solution with px0>py0 which relation between Xx (mole fraction of X in liquid phase) and Yx (mole fraction of X in vapour phase) is correct, Xy and Yy are mole fraction of Y in liquid and vapour phase respectively
1.
2.
3.
4. cannot be correlated
Point out the incorrect reaction from the following.
1.
2.
3.
4.
X, Y and Z respectively are
1.
2.
3.
4.
1. Pb, Cu, Ag
2. Pb, Ag, Cu
3. Cu, Ag, Pb
4. Cu, Pb, Ag
Choose the correct alkyne and reagents for the preparation
1.
2.
3.
4.
1. 18x 10-5 mol-1 L-1
2. 1.78x 10-5 mol L-1
3. 3.72x 10- 4 mol L-1
4. 2.37x 10-4 mol L-1
1. 128g
2. 41.75g
3. 31.60g
4. 62.34g
Which of the following represents the correct order of decreasing number of S =0 bonds?
1.
2.
3.
4.
A hypothetical reaction,
X2 + Y22XY follow the following mechanism
X+Y2XY+Y…… slow
X+YXY……. Fast
The order of the overall reaction is
1. 2
2. 3/2
3. 1
4. 0
1. I, II
2. II, III
3. I, II, III
4. III, IV
The variation of concentration of the product P with time in the reaction, AP is shown in following graph.
The graph between and time will be of the type
1.
2.
3.
4.
1. Below 710 °C, C is better reducing agent than CO
2. Below 710 °C, CO is better reducing agent than C
3. Below 710 °C, CO is an oxidizing agent
4. Below 710 °C, C02 is a reducing agent
Which of the following represents physical adsorption?
1.
2.
3.
4.
1. 50 ml of 0.1 M FeS04
2. 20 ml of 0.1 MFeS04
3. 40 ml of 0.1 M FeS04
4. 30 ml of 0.1 MFeS04
1. Ba2+, 1 .0
2. Ba2+, 2.0
3. Cl-, 1 .0
4. Cl-, 2.0
1. Hydrogen > Deuterium > Tritium;(Melting point /K)
2. Hydrogen < Deuterium < Tritium;(Boiling point/K)
3. Hydrogen< Deuterium< Tritium; (density /gl- 1)
4. Hydrogen > Deuterium > Tritium;(%relative abundance)
1. is low is nutrients
2. is high in nutrients
3. Has a high temperature
4. Has excess amount of organic matter
1. A blue colour is obtained in ether because of formation of Cr05
2. A blue colour is obtained in ether because of formation of Cr03
3. A blue colour is obtained in ether because of formation of Cr2 (SO4) a
4. Chromyl chloride is formed
1. 3.2 ppm
2. 7.2 ppm
3. 6.4 ppm
4. 4.6 ppm
The chemical formulae of X, Y and Z are
1. a
2. b
3. c
4. d
1. P > Q > S > R
2. P > R > Q > S
3. Q > R > S > R
4. S > R > Q > P
1. Sodium thiosulphate
2. Sodium bisulphite
3. Sodium sulphite
4. Sodium sulphide
1. 348, 167, 180
2. 348, 180, 167
3. 167, 180, 348
4. 180, 167, 348
1. Total stereoisomers = 4
2. Number of chiral carbons= 1
3. Number of optical isomers= 2
4. Number of meso compounds= 2
1. 3, 3, 2
2. 3, 2, 2
3. 4, 3, 1
4. 4, 3, 2
1. Ramapithecus
2. Homo habilis
3. Australopithecus
4. Homo sapiens neanderthalensis
1. Stomach
2. duodenum
3. Jejunum
4. ileum
1. Additional requirement of 02 for the invader germs
2. High temperature of the body
3. Mental worry of a patient
4. Loss of appetite
1. Reptiles
2. Birds
3. Amphibians
4. Mammals
Which of the following is not correctly matched?
1. Trichomonas vaginalis - Leishmaniasis
2. Glossina palpalis- Sleeping sickness
3. Aedes aegypti- Yellow fever
4. Culex pipiens- Filariasis
1. Olfactory receptors
2. Baroreceptors
3. Chemoreceptors
4. Phonoreceptors
1. dyspnea
2. anthracosis
3. Atelectasis
4. cyanosis
1. Bone moulding
2. Elongation of bone
3. Bone formation
4. Formation of Haversian canal
1. Biceps
2. Gluteus maximus
3. Stapedius
4. masseter
1. Brain
2. spinal nerve
3. Cranial nerves
4. All of these
1. Ear
2. eye
3. Nose
4. throat
1. 40 decibels
2. 50 decibels
3. 60 decibels
4. none of these
1. Ectoderm
2. mesoderm
3. Endoderm
4. None of the above
1. Same as in spermatid
2. Same as in spermatogonium
3. Help of that in spermatogonium
4. Same as in secondary spermatocyte
1. Decidua basalis
2. Decidua umbilicus
3. Decidua capsularis
4. Decidua functionalis
1. Injectible contraceptive
2. Intra uterine device
3. Implant
4. Oral contraceptive
1. Adenine
2. Guanine
3. 5-bromouracil
4. 5-methyl cytosine
1. Permian
2. Jurassic
3. Cambrian
4. Ordovician
1. Guanine
2. uracil
3. Thymine
4. cytosine
1. 5 -TATAAT-3'
2. 5'-TAATAT-3'
3. 5'-A AT A AT-3'
4. 5'-A TAT T A-3'
1. 3 billion base pairs and 30,000 genes
2. 12 million base pairs and 6000 genes
3. 4.7 million base pairs and 4000 genes
4. 97 million base pairs and 18,000 genes
1. 3 billion years ago
2. 10 billion years ago
3. 4.6 billion years ago
4. 20 billion years ago
1. Clostridium botulinum
2. Xanthomonas campestris
3. Pseudomonas
4. Clostridium perfringens
Who received Nobel Prize in 1951 for the development of vaccine for yellow fever?
1. Max Theiler
2. Ronald Ross
3. Max Delbruck
4. Francis Peyton Rous
1. Liver
2. spleen
3. Vagina
4. prostate gland
1. Cytotoxic T-cells
2. Killer T-cells
3. Suppressor T-cells
4. Helper T-cells
1. AIDS
2. haemophilia
3. Allergy
4. Myasthenia gravis
1. Thyroxine
2. FSH
3. Insulin
4. All of these
1. Haustra
2. Histones
3. Haptens
4. None of these
1. More acidity in the blood
2. Less acidity in the blood
3. More basicity in the blood
4. Less basicity in the blood
1. Carica papaya
2. Triticum aestivum
3. Ziziphus mauritiana
4. Nelumbo nucifera
1. bast fibre from secondary xylem
2. bast fibre from primary xylem
3. bast fibre from secondary phloem
4. bast fibre from primary phloem
1. Fe, S
2. N, S
3. Mg, S
4. Mg, N
1. I and IV
2. I and II
3. I, II and IV
4. All of these
1. I and II, but not III
2. II and III, but not I
3. I and III, but not II
4. All of these
1. A-2 B-3 C-1
2. A-3 B-2 C-1
3. A-1 B-3 C-2
4. A-3 B-1 C-2
1. I is false, but II is true
2. II is false, but I is true
3. Both I and II are true
4. Both I and II are false
1. It leads to greater genetic diversity
2. Seed dispersal is more efficient and wide spread
3. Seed set is not dependent on pollinators
4. Each visit of a pollinator results in transfer of hundreds of pollen grains
1. karyokinesis is not followed by cytokinesis
2. karyokinesis is followed by cytokinesis
3. Formation of liquid endosperm is not dependent upon karyokinesis and cytokinesis
4. None of the above
1. While proteins can flip flop, liquids can not
2. Neither lipids, nor proteins can flip flop
3. Both lipids and proteins can flip flop
4. While lipids can flip-flop at times, proteins can not
1. 80% and 20%
2. 60% and 40%
3. 50% and 50%
4. 40% and 60%
Column I |
Column II |
A. Glycogen |
1. Hormone |
1. A-3 B-2 C-4 D-1
2. A-4 B-2 C-1 D-3
3. A-2 B-4 C-3 D-1
4. A-4 B-3 C-1 D-2
1. 9 : 1
2. 1: 3.
3. 3: 1
4. 50: 50
1. Frameshift mutation
2. Transcription
3. Transition
4. Transversion
1. Metaphase-I of mitosis
2. Metaphase-I Of meiosis
3. Metaphase-II of meiosis
4. Any phase of the cell division
1. Prophase-1, prophase-II
2. Metaphase-I, anaphase-II
3. Anaphase-I, anaphase-II
4. AnaphaseI1, telophase-II
1. In the lytic cycle, the bacterial host replicates viral DNA, passing it on to daughter cells during binary fission
2. In the lysogenic cycle, the bacterial host replicates viral DNA, passing it onto daughter cells during binary fission
3. In the lytic cycle, viral DNA is integrated into the host genome
4. In the lysogenic cycle, the host bacterial cell burst, releasing phases
1. Eugenic
2. Exogenote
3. Endogenote
4. Dysgenic
1. DNAase
2. Protease
3. Lipase
4. Amylase
Thermococcus, Methanococcus and Methanobacterium are groups of
1. Bacteria containing a cytoskeleton and all membrane bound organelles
2. Archaebacteria with peptidoglycan in their cell wall
3. Archaebacteria that consists of protein homologous to eukaryotic core histones
4. Most advanced type of bacteria
Match the following Column I with Column II.
Column I |
Column II |
A. Complementary ratio |
1. 9 : 7 |
1. A-4 B-1 C-2 D-3
2. A-1 B-2 C-3 D-4
3. A-4 B-1 C-2 D-3
4. A-1 B-3 C-2 D-4
1. Rough ER Secretory vesicle Ribosome Golgi apparatus
2. Ribosome Rough ER Golgi apparatus Secretory vesicle
3. Secretory vesicle Golgi apparatus - Ribosomes Rough ER
4. Rough ER Ribosomes Secretory vesicles Golgi apparatus
1. Paramecium
2. Chlamydomonas
3. Chlorella
4. Euglena
1. Proteins are separated by molecular weight
2. SDS is a detergent which gives charge to protein
3. Large protein moves more slowly through the gel
4. SDS is used to maintain the 3-dimensional structure of protein
1. Spontaneous
2. Non-spontaneous
3. At equilibrium
4. Endothermic
1. Species
2. Tribe
3. Genus
4. Sub-genus
1. I and II
2. I and II
3. Only III
4. All of these
1. Be present in non-cancerous cells
2. Cause signal cell death
3. Regulate the cell cycle
4. Both 1 and 3
1. G1-1 S-3 G2-5 M-9
2. G1-9 S-1 G2-3 M-5
3. G1-9 S-5 G2-3 M-1
4. G1-3 S-5 G2-9 M-1
Match the following Column I with Column II
Column I |
Column II |
A. Carcinogen |
1. Cancerous tumour |
2. A-3 B-1 C-4 D-2
3. A-2 B-3 C-1 D-4
4. A-4 B-1 C-3 D-2