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JEE Main 2020 September 5 Question Paper Shift 2 | JEE Main & Advanced Previous Year Papers PDF Download

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 Page 1


1. A ring is hung on a nail. It can oscillate, without slipping or sliding (i) in its plane with a time period
T
1
 and, (ii) back and forth in a direction perpendicular to its plane, with a period T
2
. The ratio 
1
2
T
T
will be:
(1) 
3
2
(2) 
2
3
(3) 
2
3
(4) 
2
3
SOl. 3
T
1
 = 
?
?
2 2
(mR mR )
2
mgR
T
1
 = 2 ? 
2R
g
T
2
 = 2 ? 
cm
I
mgL
T
2 
= 2 ? 
2
3mR /2
mgR
 = 
3R
2
2g
?
COM
x
Back and forth
1
2
T
T
 =  
4 2
3
3
?
2. The correct match between the entries in column I and column II are:
I         II
     Radiation Wavelength
(a) Microwave (i)   100 m
(b) Gamma rays (ii)  10
–15
 m
(c)  A.M. radio waves (iii) 10
–10
 m
(d) X-rays (iv)  10
–3
 m
(1) (a) - (ii), (b)-(i), (c)-(iv), (d)-(iii) (2) (a)-(iii), (b)-(ii), (c)-(i), (d)-(iv)
(3) (a)-(iv), (b)-(ii), (c)-(i), (d)-(iii) (4) (a)-(i),(b)-(iii), (c)-(iv), (d)-(ii)
Sol. 3
By theory
3. In an experiment to verify Stokes law, a small spherical ball of radius r and density ? falls under
gravity through a distance h in air before entering a tank of water. If the terminal velocity of the
ball inside water is same as its velocity just before entering the water surface, then the value of h
is proportional to : (ignore viscosity of air)
(1) r
4
(2) r (3) r
3
(4) r
2
Page 2


1. A ring is hung on a nail. It can oscillate, without slipping or sliding (i) in its plane with a time period
T
1
 and, (ii) back and forth in a direction perpendicular to its plane, with a period T
2
. The ratio 
1
2
T
T
will be:
(1) 
3
2
(2) 
2
3
(3) 
2
3
(4) 
2
3
SOl. 3
T
1
 = 
?
?
2 2
(mR mR )
2
mgR
T
1
 = 2 ? 
2R
g
T
2
 = 2 ? 
cm
I
mgL
T
2 
= 2 ? 
2
3mR /2
mgR
 = 
3R
2
2g
?
COM
x
Back and forth
1
2
T
T
 =  
4 2
3
3
?
2. The correct match between the entries in column I and column II are:
I         II
     Radiation Wavelength
(a) Microwave (i)   100 m
(b) Gamma rays (ii)  10
–15
 m
(c)  A.M. radio waves (iii) 10
–10
 m
(d) X-rays (iv)  10
–3
 m
(1) (a) - (ii), (b)-(i), (c)-(iv), (d)-(iii) (2) (a)-(iii), (b)-(ii), (c)-(i), (d)-(iv)
(3) (a)-(iv), (b)-(ii), (c)-(i), (d)-(iii) (4) (a)-(i),(b)-(iii), (c)-(iv), (d)-(ii)
Sol. 3
By theory
3. In an experiment to verify Stokes law, a small spherical ball of radius r and density ? falls under
gravity through a distance h in air before entering a tank of water. If the terminal velocity of the
ball inside water is same as its velocity just before entering the water surface, then the value of h
is proportional to : (ignore viscosity of air)
(1) r
4
(2) r (3) r
3
(4) r
2
Sol. 1
V
T
 = 2gh
2
9
 r
2
 
? ? ? ? ?
?
b l
g
 = 2gh
r
2
 ? 
h
 ? r
4
 ? ?h
h ? r
4
4. Ten charges are placed on the circumference of a circle of radius R with constant angular separation
between successive charges. Alternate charges 1, 3, 5, 7, 9 have charge (+q) each, while 2, 4, 6,
8, 10 have charge (–q) each. The potential V and the electric field E at the centre of the circle are
respectively: (Take V= 0 at infinity)
(1) V = 0; E = 0 (2) 2
0 0
10q 10q
V ;E
4 R 4 R
? ?
? ? ? ?
(3) 2
0
10q
V 0;E
4 R
? ?
? ?
(4) 
0
10q
V ;E 0
4 R
? ?
? ?
Sol. 1
v
net
 = 5 
kq
R
? ?
? ?
? ?
 + 
5k( q)
R
? ? ?
? ?
? ?
v
net
 = 0 [Q
net
 = 0]
E
net
 = 0 by symmetry
Page 3


1. A ring is hung on a nail. It can oscillate, without slipping or sliding (i) in its plane with a time period
T
1
 and, (ii) back and forth in a direction perpendicular to its plane, with a period T
2
. The ratio 
1
2
T
T
will be:
(1) 
3
2
(2) 
2
3
(3) 
2
3
(4) 
2
3
SOl. 3
T
1
 = 
?
?
2 2
(mR mR )
2
mgR
T
1
 = 2 ? 
2R
g
T
2
 = 2 ? 
cm
I
mgL
T
2 
= 2 ? 
2
3mR /2
mgR
 = 
3R
2
2g
?
COM
x
Back and forth
1
2
T
T
 =  
4 2
3
3
?
2. The correct match between the entries in column I and column II are:
I         II
     Radiation Wavelength
(a) Microwave (i)   100 m
(b) Gamma rays (ii)  10
–15
 m
(c)  A.M. radio waves (iii) 10
–10
 m
(d) X-rays (iv)  10
–3
 m
(1) (a) - (ii), (b)-(i), (c)-(iv), (d)-(iii) (2) (a)-(iii), (b)-(ii), (c)-(i), (d)-(iv)
(3) (a)-(iv), (b)-(ii), (c)-(i), (d)-(iii) (4) (a)-(i),(b)-(iii), (c)-(iv), (d)-(ii)
Sol. 3
By theory
3. In an experiment to verify Stokes law, a small spherical ball of radius r and density ? falls under
gravity through a distance h in air before entering a tank of water. If the terminal velocity of the
ball inside water is same as its velocity just before entering the water surface, then the value of h
is proportional to : (ignore viscosity of air)
(1) r
4
(2) r (3) r
3
(4) r
2
Sol. 1
V
T
 = 2gh
2
9
 r
2
 
? ? ? ? ?
?
b l
g
 = 2gh
r
2
 ? 
h
 ? r
4
 ? ?h
h ? r
4
4. Ten charges are placed on the circumference of a circle of radius R with constant angular separation
between successive charges. Alternate charges 1, 3, 5, 7, 9 have charge (+q) each, while 2, 4, 6,
8, 10 have charge (–q) each. The potential V and the electric field E at the centre of the circle are
respectively: (Take V= 0 at infinity)
(1) V = 0; E = 0 (2) 2
0 0
10q 10q
V ;E
4 R 4 R
? ?
? ? ? ?
(3) 2
0
10q
V 0;E
4 R
? ?
? ?
(4) 
0
10q
V ;E 0
4 R
? ?
? ?
Sol. 1
v
net
 = 5 
kq
R
? ?
? ?
? ?
 + 
5k( q)
R
? ? ?
? ?
? ?
v
net
 = 0 [Q
net
 = 0]
E
net
 = 0 by symmetry
5. A spaceship in space sweeps stationary interplanetary dust. As a result, its mass increases at a
rate 
? ? dM t
dt
= bv
2
 (t), where v(t) is its instantaneous velocity. The instantaneous acceleration of
the satellite is :
(1) –bv
3
(t) (2) 
3
bv
–
M(t)
(3) 
3
2bv
–
M(t)
(4) 
3
bv
–
2M(t)
Sol. 2
dM(t)
dt
 = -bv
2
in free space
no external force
so there in only thrust force on rocket
f
in
 = 
dM
dt
 (V
rel
)
Ma = 
v
) t (
bv
2
?
?
?
?
?
?
?
? ?
a = 
3
bv
M(t)
?
6. Two different wires having lengths L
1
 and L
2
, and respective temperature coefficient of linear
expansion ?
1
 and ?
2
, are joined end-to-end. Then the effective temperature coefficient of linear
expansion is:
(1) 
2
1 1 2 2
1
L L
L L
? ? ?
?
(2) 
1 2
2 ? ?
(3) 
? ?
1
2
1 2
2
1 2
2 1
L L
4
L L
? ?
? ? ?
?
(4) 
1 2
2
? ? ?
Sol. 1
L'
1
 = L
1
 (1 + ?
1
?T)
L'
2
 = L
2
 (1 + ?
2
?T)
L'+L
2
'
 
= L
1
 + L
2
 + L
1
?
1
?T + L
2
?
2
?T
= (L
1
 + L
2
) 
1 1 2 2
1 2
L L
1 T
L L
? ? ? ? ? ? ?
? ?
? ? ? ?
?
? ? ? ? ? ?
= (L
1
 + L
2
) [1 + ?
eq
?T)
So, ?
eq
 = 
1 1 2 2
1 2
L L
L L
? ? ?
?
Page 4


1. A ring is hung on a nail. It can oscillate, without slipping or sliding (i) in its plane with a time period
T
1
 and, (ii) back and forth in a direction perpendicular to its plane, with a period T
2
. The ratio 
1
2
T
T
will be:
(1) 
3
2
(2) 
2
3
(3) 
2
3
(4) 
2
3
SOl. 3
T
1
 = 
?
?
2 2
(mR mR )
2
mgR
T
1
 = 2 ? 
2R
g
T
2
 = 2 ? 
cm
I
mgL
T
2 
= 2 ? 
2
3mR /2
mgR
 = 
3R
2
2g
?
COM
x
Back and forth
1
2
T
T
 =  
4 2
3
3
?
2. The correct match between the entries in column I and column II are:
I         II
     Radiation Wavelength
(a) Microwave (i)   100 m
(b) Gamma rays (ii)  10
–15
 m
(c)  A.M. radio waves (iii) 10
–10
 m
(d) X-rays (iv)  10
–3
 m
(1) (a) - (ii), (b)-(i), (c)-(iv), (d)-(iii) (2) (a)-(iii), (b)-(ii), (c)-(i), (d)-(iv)
(3) (a)-(iv), (b)-(ii), (c)-(i), (d)-(iii) (4) (a)-(i),(b)-(iii), (c)-(iv), (d)-(ii)
Sol. 3
By theory
3. In an experiment to verify Stokes law, a small spherical ball of radius r and density ? falls under
gravity through a distance h in air before entering a tank of water. If the terminal velocity of the
ball inside water is same as its velocity just before entering the water surface, then the value of h
is proportional to : (ignore viscosity of air)
(1) r
4
(2) r (3) r
3
(4) r
2
Sol. 1
V
T
 = 2gh
2
9
 r
2
 
? ? ? ? ?
?
b l
g
 = 2gh
r
2
 ? 
h
 ? r
4
 ? ?h
h ? r
4
4. Ten charges are placed on the circumference of a circle of radius R with constant angular separation
between successive charges. Alternate charges 1, 3, 5, 7, 9 have charge (+q) each, while 2, 4, 6,
8, 10 have charge (–q) each. The potential V and the electric field E at the centre of the circle are
respectively: (Take V= 0 at infinity)
(1) V = 0; E = 0 (2) 2
0 0
10q 10q
V ;E
4 R 4 R
? ?
? ? ? ?
(3) 2
0
10q
V 0;E
4 R
? ?
? ?
(4) 
0
10q
V ;E 0
4 R
? ?
? ?
Sol. 1
v
net
 = 5 
kq
R
? ?
? ?
? ?
 + 
5k( q)
R
? ? ?
? ?
? ?
v
net
 = 0 [Q
net
 = 0]
E
net
 = 0 by symmetry
5. A spaceship in space sweeps stationary interplanetary dust. As a result, its mass increases at a
rate 
? ? dM t
dt
= bv
2
 (t), where v(t) is its instantaneous velocity. The instantaneous acceleration of
the satellite is :
(1) –bv
3
(t) (2) 
3
bv
–
M(t)
(3) 
3
2bv
–
M(t)
(4) 
3
bv
–
2M(t)
Sol. 2
dM(t)
dt
 = -bv
2
in free space
no external force
so there in only thrust force on rocket
f
in
 = 
dM
dt
 (V
rel
)
Ma = 
v
) t (
bv
2
?
?
?
?
?
?
?
? ?
a = 
3
bv
M(t)
?
6. Two different wires having lengths L
1
 and L
2
, and respective temperature coefficient of linear
expansion ?
1
 and ?
2
, are joined end-to-end. Then the effective temperature coefficient of linear
expansion is:
(1) 
2
1 1 2 2
1
L L
L L
? ? ?
?
(2) 
1 2
2 ? ?
(3) 
? ?
1
2
1 2
2
1 2
2 1
L L
4
L L
? ?
? ? ?
?
(4) 
1 2
2
? ? ?
Sol. 1
L'
1
 = L
1
 (1 + ?
1
?T)
L'
2
 = L
2
 (1 + ?
2
?T)
L'+L
2
'
 
= L
1
 + L
2
 + L
1
?
1
?T + L
2
?
2
?T
= (L
1
 + L
2
) 
1 1 2 2
1 2
L L
1 T
L L
? ? ? ? ? ? ?
? ?
? ? ? ?
?
? ? ? ? ? ?
= (L
1
 + L
2
) [1 + ?
eq
?T)
So, ?
eq
 = 
1 1 2 2
1 2
L L
L L
? ? ?
?
7. In the circuit, given in the figure currents in different branches and value of one resistor are shown.
Then potential at point B with respect to the point A is:
2A
F
B
2V
C
1V
A
1A
E
D
2
(1) +2 V (2) –2 V (3) +1 V (4) –1 V
Sol. 3
Let V
A
 = 0
V
B
 – V
A
 = 1 – 0
= 1 volt
8. The velocity (v) and time (t) graph of a body in a straight line motion is shown in the figure. The
point S is at 4.333 seconds. The total distance covered by the body in 6 s is:
–2
0
2
4
1 2 3 4 5 6
A B
S D
C
t (in s)
v (m/s)
(1) 
37
m
3
(2) 
49
m
4
(3) 12 m (4) 11 m
Sol. 1
Page 5


1. A ring is hung on a nail. It can oscillate, without slipping or sliding (i) in its plane with a time period
T
1
 and, (ii) back and forth in a direction perpendicular to its plane, with a period T
2
. The ratio 
1
2
T
T
will be:
(1) 
3
2
(2) 
2
3
(3) 
2
3
(4) 
2
3
SOl. 3
T
1
 = 
?
?
2 2
(mR mR )
2
mgR
T
1
 = 2 ? 
2R
g
T
2
 = 2 ? 
cm
I
mgL
T
2 
= 2 ? 
2
3mR /2
mgR
 = 
3R
2
2g
?
COM
x
Back and forth
1
2
T
T
 =  
4 2
3
3
?
2. The correct match between the entries in column I and column II are:
I         II
     Radiation Wavelength
(a) Microwave (i)   100 m
(b) Gamma rays (ii)  10
–15
 m
(c)  A.M. radio waves (iii) 10
–10
 m
(d) X-rays (iv)  10
–3
 m
(1) (a) - (ii), (b)-(i), (c)-(iv), (d)-(iii) (2) (a)-(iii), (b)-(ii), (c)-(i), (d)-(iv)
(3) (a)-(iv), (b)-(ii), (c)-(i), (d)-(iii) (4) (a)-(i),(b)-(iii), (c)-(iv), (d)-(ii)
Sol. 3
By theory
3. In an experiment to verify Stokes law, a small spherical ball of radius r and density ? falls under
gravity through a distance h in air before entering a tank of water. If the terminal velocity of the
ball inside water is same as its velocity just before entering the water surface, then the value of h
is proportional to : (ignore viscosity of air)
(1) r
4
(2) r (3) r
3
(4) r
2
Sol. 1
V
T
 = 2gh
2
9
 r
2
 
? ? ? ? ?
?
b l
g
 = 2gh
r
2
 ? 
h
 ? r
4
 ? ?h
h ? r
4
4. Ten charges are placed on the circumference of a circle of radius R with constant angular separation
between successive charges. Alternate charges 1, 3, 5, 7, 9 have charge (+q) each, while 2, 4, 6,
8, 10 have charge (–q) each. The potential V and the electric field E at the centre of the circle are
respectively: (Take V= 0 at infinity)
(1) V = 0; E = 0 (2) 2
0 0
10q 10q
V ;E
4 R 4 R
? ?
? ? ? ?
(3) 2
0
10q
V 0;E
4 R
? ?
? ?
(4) 
0
10q
V ;E 0
4 R
? ?
? ?
Sol. 1
v
net
 = 5 
kq
R
? ?
? ?
? ?
 + 
5k( q)
R
? ? ?
? ?
? ?
v
net
 = 0 [Q
net
 = 0]
E
net
 = 0 by symmetry
5. A spaceship in space sweeps stationary interplanetary dust. As a result, its mass increases at a
rate 
? ? dM t
dt
= bv
2
 (t), where v(t) is its instantaneous velocity. The instantaneous acceleration of
the satellite is :
(1) –bv
3
(t) (2) 
3
bv
–
M(t)
(3) 
3
2bv
–
M(t)
(4) 
3
bv
–
2M(t)
Sol. 2
dM(t)
dt
 = -bv
2
in free space
no external force
so there in only thrust force on rocket
f
in
 = 
dM
dt
 (V
rel
)
Ma = 
v
) t (
bv
2
?
?
?
?
?
?
?
? ?
a = 
3
bv
M(t)
?
6. Two different wires having lengths L
1
 and L
2
, and respective temperature coefficient of linear
expansion ?
1
 and ?
2
, are joined end-to-end. Then the effective temperature coefficient of linear
expansion is:
(1) 
2
1 1 2 2
1
L L
L L
? ? ?
?
(2) 
1 2
2 ? ?
(3) 
? ?
1
2
1 2
2
1 2
2 1
L L
4
L L
? ?
? ? ?
?
(4) 
1 2
2
? ? ?
Sol. 1
L'
1
 = L
1
 (1 + ?
1
?T)
L'
2
 = L
2
 (1 + ?
2
?T)
L'+L
2
'
 
= L
1
 + L
2
 + L
1
?
1
?T + L
2
?
2
?T
= (L
1
 + L
2
) 
1 1 2 2
1 2
L L
1 T
L L
? ? ? ? ? ? ?
? ?
? ? ? ?
?
? ? ? ? ? ?
= (L
1
 + L
2
) [1 + ?
eq
?T)
So, ?
eq
 = 
1 1 2 2
1 2
L L
L L
? ? ?
?
7. In the circuit, given in the figure currents in different branches and value of one resistor are shown.
Then potential at point B with respect to the point A is:
2A
F
B
2V
C
1V
A
1A
E
D
2
(1) +2 V (2) –2 V (3) +1 V (4) –1 V
Sol. 3
Let V
A
 = 0
V
B
 – V
A
 = 1 – 0
= 1 volt
8. The velocity (v) and time (t) graph of a body in a straight line motion is shown in the figure. The
point S is at 4.333 seconds. The total distance covered by the body in 6 s is:
–2
0
2
4
1 2 3 4 5 6
A B
S D
C
t (in s)
v (m/s)
(1) 
37
m
3
(2) 
49
m
4
(3) 12 m (4) 11 m
Sol. 1
distance = area under graph
= 
1
2
 (4) 
13
1
3
? ?
?
? ?
? ?
 + 
1 13
6 2
2 3
? ? ? ?
? ?
? ? ? ?
? ? ? ?
= 2 × 
16
3
 + 
5
3
= 
32
3
 + 
5
3
 = 
37
3
 m
9. An infinitely long straight wire carrying current I, one side opened rectangular loop and a conductor
C with a sliding connector are located in the same plane, as shown in the figure. The connector has
length l and resistance R. It slides to the right with a velocity v. The resistance of the conductor
and the self inductance of the loop are negligible. The induced current in the loop, as a function of
separation r, between the connector and the straight wire is:
v
l R
C
r
I
one side opened long
conducting wire loop
(1) 
0
Ivl
2 Rr
?
?
(2) 
0
Ivl
Rr
?
?
(3) 
0
2 Ivl
Rr
?
?
(4) 
0
Ivl
4 Rr
?
?
Sol. 1
B = 
0
I
2 r
? ? ?
? ?
?
? ?
induced emf
e = Bvl
l
v
r
I = 
0
I
2 r
?
?
 V .l
= 
?
?
0
Ivl
2 r
induced current i = 
e
R
 = 
?
?
0
Ivl
2 rR
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FAQs on JEE Main 2020 September 5 Question Paper Shift 2 - JEE Main & Advanced Previous Year Papers

1. What are some important dates related to JEE Main 2020 September exam?
Ans. Some important dates related to JEE Main 2020 September exam are: - Exam dates: 1st to 6th September 2020 - Release of answer key: After the exam - Declaration of result: By the end of September 2020
2. How can I download the JEE Main 2020 September 5 question paper shift 2?
Ans. You can download the JEE Main 2020 September 5 question paper shift 2 from the official website of NTA (National Testing Agency) once it is released.
3. What is the exam pattern for JEE Main 2020 September exam?
Ans. The JEE Main 2020 September exam consists of multiple-choice questions from Physics, Chemistry, and Mathematics. The exam duration is 3 hours, and there is a negative marking for incorrect answers.
4. How can I prepare effectively for JEE Main 2020 September exam?
Ans. To prepare effectively for the JEE Main 2020 September exam, make sure to follow a study schedule, solve previous year question papers, take online mock tests, and focus on understanding the concepts thoroughly.
5. Are there any changes in the syllabus for JEE Main 2020 September exam?
Ans. No, there are no changes in the syllabus for JEE Main 2020 September exam. The syllabus remains the same as the previous exams.
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