2014
NEET
MCQ
AIPMT 2014
Certain quantity of water cools from 70oC to 60oC in the first 5 minutes and to 54oC in the next 5 minutes. The temperature of the surroundings is
A.
45oC
B.
20oC
C.
42oC
D.
10oC
2013
NEET
MCQ
NEET 2013 (Karnataka)
The density of water at 20oC is 998 kg/m3 and at 40oC is 992 kg/m3. The coefficient of volume expansion of water is
A.
3 $ \times $ 10$-$4/oC
B.
2 $ \times $ 10$-$4/oC
C.
6 $ \times $ 10$-$4/oC
D.
10 $ \times $ 10$-$4/oC
2013
NEET
MCQ
NEET 2013 (Karnataka)
Two metal rods 1 and 2 of same lengths have same temperature difference between their ends. Their thermal conductivities are K1 and K2 and cross sectional areas A1 and A2, respectively. If the rate of heat conduction in 1 is four times that in 2, then
A.
K1A1 = 4K2A2
B.
K1A1 = 2K2A2
C.
4K1A1 = K2A2
D.
K1A1 = K2A2
2013
NEET
MCQ
NEET 2013 (Karnataka)
If the ratio of diameters, lengths and Young's modulus of steel and copper wires shown in the figure are p, q and s respectively, then the corresponding ratio of increase in their lengths would be
A.
$\left( {{{5q} \over {7s{p^2}}}} \right)$
B.
$\left( {{{7q} \over {5s{p^2}}}} \right)$
C.
$\left( {{{2q} \over {5sp}}} \right)$
D.
$\left( {{{7q} \over {5sp}}} \right)$
2013
NEET
MCQ
NEET 2013 (Karnataka)
A fluid is in streamline flow across a horizontal pipe of variable area of cross section. For this which of the following statements is correct?
A.
The velocity is maximum at the narrowest part of the pipe and pressure is maximum at the widest part of the pipe.
B.
Velocity and pressure both are maximum at the narrowest part of the pipe.
C.
velocity and pressure both are maximum at the widest part of the pipe.
D.
The velocity is minimum at the narrowest part of the pipe and the pressure is minimum at the widest part of the pipe.
2013
NEET
MCQ
NEET 2013
The molar specific heats of an ideal gas at constant pressure and volume are denoted by Cp and Cv, respectively. If $\gamma $ = ${{{C_p}} \over {{C_v}}}$ and R is the universal gas constant, then Cv is equal to
A.
${{\left( {\gamma - 1} \right)} \over R}$
B.
$\gamma R$
C.
${{1 + \gamma } \over {1 - \gamma }}$
D.
${R \over {\left( {\gamma - 1} \right)}}$
2013
NEET
MCQ
NEET 2013
A piece of iron is heated in a flame. It first becomes dull red then becomes reddish yellow and finally turns to white hot. The correct explanation for the above observation is possible by using
A.
Kirchhoff's Law
B.
Newton's Law of cooling
C.
Stefan's Law
D.
Wien's displacement Law
2013
NEET
MCQ
NEET 2013
The following four wires are made of the same material. Which of these will have the largest extension when the same tension is applied?
A.
length = 200 cm, diameter = 2 mm
B.
length = 300 cm, diameter = 3 mm
C.
length = 50 cm, diameter = 0.5 mm
D.
length = 100 cm, diameter = 1 mm
2013
NEET
MCQ
NEET 2013
The wettability of a surface by a liquid depends primarily on
A.
density
B.
angle of contact between the surface and the liquid
C.
viscosity
D.
surface tension
2012
NEET
MCQ
AIPMT 2012 Mains
A slab of stone of area 0.36 m2 and thickness 0.1 m is exposed on the lower surface to steam at 100oC. A block of ice at 0oC rests on the upper surface of the slab. In one hour 4.8 kg of ice is melted. The thermal conductivity of slab is
(Given latent heat of fusion of ice = 3.36 $ \times $ 105 J kg$-$1)
(Given latent heat of fusion of ice = 3.36 $ \times $ 105 J kg$-$1)
A.
1.24 J/m/s/oC
B.
1.29 J/m/s/oC
C.
2.05 J/m/s/oC
D.
1.02 J/m/s/oC
2012
NEET
MCQ
AIPMT 2012 Prelims
If the radius of a star is R and it acts as a black body, what would be the temperature of the star, in which the rate of energy production is Q?
A.
${Q \over {4\pi {R^2}\sigma }}$
B.
${\left( {{Q \over {4\pi {R^2}\sigma }}} \right)^{ - 1/2}}$
C.
${\left( {{{4\pi {R^2}Q} \over \sigma }} \right)^{1/4}}$
D.
${\left( {{Q \over {4\pi {R^2}\sigma }}} \right)^{1/4}}$
2012
NEET
MCQ
AIPMT 2012 Prelims
Liquid oxygen at 50 K is heated to 300 K at constant pressure of 1 atm. The rate of heating is constant. Which one of the following graphs represents the variation of temperature with time ?
A.
B.
C.
D.
2010
NEET
MCQ
AIPMT 2010 Prelims
The total radiant energy per unit area, normal to the direction of incidence, received at a distance R from the centre of a star of radius r, whose outer surface radiates as a black body at a temperature TK is given by
A.
${{\sigma {r^2}{T^4}} \over {{R^2}}}$
B.
${{\sigma {r^2}{T^4}} \over {4\pi {R^2}}}$
C.
${{\sigma {r^2}{T^4}} \over {{R^4}}}$
D.
${{4\pi \sigma {r^2}{T^4}} \over {{R^2}}}$
2010
NEET
MCQ
AIPMT 2010 Prelims
Assuming the sun to have a spherical outer surface of radius r, radiating like a black body at temperature toC, the power received by a unit surface, (normal to the incident rays) at a distance R from the centre of the sun is
where $\sigma $ is the Stefan's constant.
where $\sigma $ is the Stefan's constant.
A.
${{{r^2}\sigma {{\left( {t + 273} \right)}^4}} \over {4\pi {R^2}}}$
B.
${{16{\pi ^2}{r^2}\sigma {t^4}} \over {{R^2}}}$
C.
${{{r^2}\sigma {{\left( {t + 273} \right)}^4}} \over {{R^2}}}$
D.
${{4\pi {r^2}\sigma {t^4}} \over {{R^2}}}$
2010
NEET
MCQ
AIPMT 2010 Prelims
A cylindrical metallic rod in thermal contact with two reservoirs of heat at its two ends conducts an amount of heat Q in time t. The metallic rod is melted and the material is formed into a rod of half the radius of the original rod. What is the amount of heat conducted by the new rod, when placed in thermal contact with the two reservoirs in time t?
A.
${Q \over 4}$
B.
${Q \over {16}}$
C.
2Q
D.
${Q \over 2}$
2009
NEET
MCQ
AIPMT 2009
The two ends of a rod of length L and a uniform cross-sectional area A are Kept at two temperatures T1 and T2 (T1 > T2). The rate of heat transfer, ${{dQ} \over {dt}}$ through the rod in a steady state is given by :
A.
${{dQ} \over {dt}} = {{k\left( {{T_1} - {T_2}} \right)} \over {LA}}$
B.
${{dQ} \over {dt}} = kLA({T_1} - {T_2})$
C.
${{dQ} \over {dt}} = {{kA\left( {{T_1} - {T_2}} \right)} \over L}$
D.
${{dQ} \over {dt}} = {{kL\left( {{T_1} - {T_2}} \right)} \over A}$
2009
NEET
MCQ
AIPMT 2009
A black body at 227oC radiates heat at the rate of 7 cals/cm2s. At a temperature of 727oC, the rate of heat radiated in the same units will be
A.
50
B.
112
C.
80
D.
60
2008
NEET
MCQ
AIPMT 2008
On a new scale of temperature (which is linear) and called the W scale, the freezing and boiling points of water are 39oW and 239oW respectively. What will be the temperature on the new scale, corresponding to a temperature of 39oC on the Celsius scale ?
A.
200oW
B.
139oW
C.
78oW
D.
117oW
2007
NEET
MCQ
AIPMT 2007
A black body is at 727oC. It emits energy at a rate which is proportional to
A.
(1000)4
B.
(1000)2
C.
(727)4
D.
(727)2
2007
NEET
MCQ
AIPMT 2007
Assuming the sun to have a spherical outer surface of radius r, radiating like a black body at temperature toC, the power received by a unit surface, (normal to the incident rays) at a distance R from the centre of the sun is
where $\sigma $ is the Stefan's constant.
where $\sigma $ is the Stefan's constant.
A.
${{{r^2}\sigma {{\left( {t + 273} \right)}^4}} \over {4\pi {R^2}}}$
B.
${{16{\pi ^2}{r^2}\sigma {t^4}} \over {{R^2}}}$
C.
${{{r^2}\sigma {{\left( {t + 273} \right)}^4}} \over {{R^2}}}$
D.
${{4\pi {r^2}\sigma {t^4}} \over {{R^2}}}$
2006
NEET
MCQ
AIPMT 2006
A black body at 1227oC emits radiations with maximum intensity at a wavelength of 5000 $\mathop A\limits^ \circ $. If the temperature of the body is increased by 1000oC, the maximum intensity will be observed at
A.
3000 $\mathop A\limits^ \circ $
B.
4000$\mathop A\limits^ \circ $
C.
5000$\mathop A\limits^ \circ $
D.
6000$\mathop A\limits^ \circ $
2005
NEET
MCQ
AIPMT 2005
Which of the following rods, (given radius r and length $l$) each made of the same material and whose ends are maintained at the same temperature will conduct most heat ?
A.
r = r0, $l$ = $l$0
B.
r = 2r0, $l$ = $l$0
C.
r = r0, $l$ = 2$l$0
D.
r = 2r0, $l$ = 2$l$0
2004
NEET
MCQ
AIPMT 2004
If $\lambda $m denotes the wavelength at which the radioactive amission from a black body at a temperature TK is maximum, then
A.
${\lambda _m}\, \propto \,{T^4}$
B.
${\lambda _m}$ is independent of T
C.
${\lambda _m}$ $ \propto $ T
D.
${\lambda _m}\, \propto \,{T^{ - 1}}$
2003
NEET
MCQ
AIPMT 2003
Consider a compound slab consisting of two different materials having equal thicknesses and thermal conductivities K and 2K, respectively. The equivalent thermal conductivity of the slab is
A.
${2 \over 3}K$
B.
$\sqrt 2 K$
C.
3 K
D.
${4 \over 3}K$
2002
NEET
MCQ
AIPMT 2002
For a black body at temperature 727oC, its radiating power is 60 watt and temperature of surrounding is 227oC. If temperature of black body is changed to 1227oC then its radiating power will be
A.
304 W
B.
320 W
C.
240 W
D.
120 W
2002
NEET
MCQ
AIPMT 2002
Which of the following is best close to an ideal black body?
A.
black lamp
B.
cavity maintained at constant temperature
C.
platinium black
D.
a lump of charcoal heated to high temperature.
2002
NEET
MCQ
AIPMT 2002
Consider two rods of same length and different specific heats (S1, S2), conductivities (K1, K2) and area of cross-sections (A1, A2) and both having temperatures T1 and T2 at their ends. If rate of loss of heat due to conduction is equal, then
A.
K1A1 = K2A2
B.
${{{K_1}{A_1}} \over {{S_1}}} = {{{K_2}{A_2}} \over {{S_2}}}$
C.
K2A1 = K1A2
D.
${{{K_2}{A_1}} \over {{S_2}}} = {{{K_1}{A_2}} \over {{S_1}}}$
2002
NEET
MCQ
AIPMT 2002
The Wien's displacement law express relation between
A.
wavelength corresponding to maximum energy and temperature
B.
radiation energy and wavelength
C.
temperature and wavelength
D.
colour of light and temperature.
2002
NEET
MCQ
AIPMT 2002
Unit of Stefan's constant is
A.
watt m2 K4
B.
watt m2/K4
C.
watt/m2 K
D.
watt/m2K4
2001
NEET
MCQ
AIPMT 2001
A cylindrical rod having temperature T1 and T2 at its end. The rate of flow of heat Q1 cal/sec. If all the linear dimension are doubled keeping temperature constant, then rate of flow of heat Q2 will be
A.
4Q1
B.
2Q1
C.
${{{Q_1}} \over 4}$
D.
${{{Q_1}} \over 2}$
2000
NEET
MCQ
AIPMT 2000
A black body has maximum wavelength $\lambda $m at 2000 K. Its corresponding wavelength at 3000 K will be
A.
${3 \over 2}{\lambda _m}$
B.
${2 \over 3}{\lambda _m}$
C.
${{16} \over {81}}{\lambda _m}$
D.
${{81} \over {16}}{\lambda _m}$
2019
AIIMS
MCQ
AIIMS 2019
If a small orifice is made at a height of 0.25 m from the ground, the horizontal range of water stream will be
A.
46.5 cm
B.
56.6 cm
C.
76.6 cm
D.
86.6 cm
2019
AIIMS
MCQ
AIIMS 2019
Determine the pressure difference in tube of non-uniform cross sectional area as shown in figure.
$\Delta P=?, d_1=5 \mathrm{~cm}, v_1=4 \mathrm{~m} / \mathrm{s}, d_2=2 \mathrm{~cm}, v_2=?$
A.
304200 Pa
B.
304500 Pa
C.
302500 Pa
D.
303500 Pa
2019
AIIMS
MCQ
AIIMS 2019
In an isothermal process 2 water drops of radius $1 \mathrm{~mm}$ are combined to form a bigger drop. Find the energy change in this process if $T=0.1 \mathrm{~N} / \mathrm{m}$.
A.
$1 \mu \mathrm{J}$
B.
$0.5 \mu \mathrm{J}$
C.
$0.25 \mu \mathrm{J}$
D.
$0.75 \mu \mathrm{J}$
2019
AIIMS
MCQ
AIIMS 2019
Assertion : Water drops take spherical shape when falling freely.
Reason : Water has minimum surface tension among all liquids.
A.
If both assertion and reason are true and reason is the correct explanation of assertion.
B.
If both assertion and reason are true, but reason is not the correct explanation of assertion.
C.
If assertion is true, but reason is false.
D.
If both assertion and reason are false.
2019
AIIMS
MCQ
AIIMS 2019
Assertion : Sometimes insects can walk on water.
Reason : The gravitational force on insect is balanced by force due surface tension.
A.
If both assertion and reason are true and reason is the correct explanation of assertion.
B.
If both assertion and reason are true, but reason is not the correct explanation of assertion.
C.
If assertion is true, but reason is false.
D.
If both assertion and reason are false.
2018
AIIMS
MCQ
AIIMS 2018
Assertion Smaller drop of water resist deformation forces better than the larger drops.
Reason Excess pressure inside drop is inversely proportional to its radius.
A.
Both Assertion and Reason are correct, Reason is the correct explanation of Assertion
B.
Both Assertion and Reason are correct but Reason is not the correct explanation of Assertion
C.
Assertion is correct and Reason is incorrect
D.
Assertion is incorrect and Reason is correct