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 Page 1


JEE Solved Example on Dual Nature of Matter and 
Radiation 
JEE Mains 
Q1: What is the de-Broglie wavelength of the ?? -particle accelerated through a potential difference 
?? 
(A) 
?? .??????
v ?? Å 
(B) 
???? .????
v ?? Å 
(C) 
?? .??????
v ?? ?? 
(D) 
?? .??????
v ?? ?? 
Ans: (C) 1 =
h
v 2????
=
h
v2?? 2
?? 2
?? 
On putting ?? ?? = 2
'
1.6
'
10
-19
C 
?? a
= 4 m
p
= 4
'
1.67 · 10
-27
 kg p 1 =
0.101
v ?? A 
Q2: The de-Broglie wavelength of a particle moving with a velocity ?? . ???? · ????
?? ?? /?? is equal to the 
wavelength of photon. The ratio of kinetic energy of the particle to the energy of the photon is 
(velocity of light is ?? . ????
?? ?? /?? ) 
(A) ?? /?? 
(B) ?? /?? 
(C) ?? /?? 
(D) ?? /?? 
Ans: (B) ?? partice 
=
1
2
?? ?? 2
 also 1 =
h
????
 
b ?? partice 
=
1
2
Rh
?? ?
¨
F
?
× ?? 2
=
?? h
21
 
b K
pholon 
=
hc
1
 
K
partide 
K
protoon 
=
V
2C
=
2.25 · 10
8
2
'
3
'
10
8
=
3
8
 
Q3: The kinetic energy of electron and proton is ????
-????
 ?? . Then the relation between their de -
Broglie wavelengths is 
(A) ?? ?? < ?? ? 
(B) ?? ?? > ?? ? 
(C) ?? ?? = ?? ? 
(D) ?? ?? = ???? 
Ans: (A) By using 1 =
h
v 2mE
 E = 10
-32
 J 3/4 Constant for both particles. Hence 1?? 1
v ?? Since ?? ?? >
?? ?? so 1
?? < 1
?? . 
 
Page 2


JEE Solved Example on Dual Nature of Matter and 
Radiation 
JEE Mains 
Q1: What is the de-Broglie wavelength of the ?? -particle accelerated through a potential difference 
?? 
(A) 
?? .??????
v ?? Å 
(B) 
???? .????
v ?? Å 
(C) 
?? .??????
v ?? ?? 
(D) 
?? .??????
v ?? ?? 
Ans: (C) 1 =
h
v 2????
=
h
v2?? 2
?? 2
?? 
On putting ?? ?? = 2
'
1.6
'
10
-19
C 
?? a
= 4 m
p
= 4
'
1.67 · 10
-27
 kg p 1 =
0.101
v ?? A 
Q2: The de-Broglie wavelength of a particle moving with a velocity ?? . ???? · ????
?? ?? /?? is equal to the 
wavelength of photon. The ratio of kinetic energy of the particle to the energy of the photon is 
(velocity of light is ?? . ????
?? ?? /?? ) 
(A) ?? /?? 
(B) ?? /?? 
(C) ?? /?? 
(D) ?? /?? 
Ans: (B) ?? partice 
=
1
2
?? ?? 2
 also 1 =
h
????
 
b ?? partice 
=
1
2
Rh
?? ?
¨
F
?
× ?? 2
=
?? h
21
 
b K
pholon 
=
hc
1
 
K
partide 
K
protoon 
=
V
2C
=
2.25 · 10
8
2
'
3
'
10
8
=
3
8
 
Q3: The kinetic energy of electron and proton is ????
-????
 ?? . Then the relation between their de -
Broglie wavelengths is 
(A) ?? ?? < ?? ? 
(B) ?? ?? > ?? ? 
(C) ?? ?? = ?? ? 
(D) ?? ?? = ???? 
Ans: (A) By using 1 =
h
v 2mE
 E = 10
-32
 J 3/4 Constant for both particles. Hence 1?? 1
v ?? Since ?? ?? >
?? ?? so 1
?? < 1
?? . 
 
Q4: The de-Broglie wavelength of a particle accelerated with 150 volt potential is ????
-????
 ?? . If it is 
accelerated by 600 volts p.d., its wavelength will be 
(A) ?? . ???? Å 
(B) ?? . ?? Å 
(C) ?? . ?? Å 
(D) ?? Å 
Ans: (B) By using 1?? 1
v ?? P 
1
1
1
2
= v
?? 2
?? 1
 
b 
10
-10
1
2
= v
600
150
= 2 b  1
2
= 0.5Å 
Q5: When the momentum of a proton is changed by an amount ?? ?? , the corresponding change in 
the de-Broglie wavelength is found to be ?? . ???? %. Then, the original momentum of the proton was 
(A) ?? ?? 
(B) ?????? ?? ?? 
(C) ?????? ?? ?? 
(D) ?? ?? ?? 
Ans: (C) 1?? 1
p
  p  
D?? p
= -
D
1
  p  |
Dp
p
| = |
D
1
| 
b 
?? 0
p
=
0.25
100
=
1
400
  p  p = 400 p
0
. 
Q6: The work function of metal is ?????? . Light of wavelength ???????? Å is incident on this metal 
surface. The velocity of emitted photo -electrons will be 
(A) ???? ?? /?????? 
(B) ?? · ????
?? ?? /?????? 
(C) ?? · ????
?? ?? /?????? 
(D) ?? · ????
?? ?? /?????? 
Ans: (D) ?? = ?? 0
+ ?? max
; ?? =
12375
3000
= 4.125eV 
P K
max 
= E - W
0
= 4.125eV- 1eV= 3.125eV 
P  
1
2
?? ?? max
2
= 3.125· 1.6 · 10
-19
 J 
p  V
max
= v
2·3.125·1.6·10
-19
9.1·10
-31
= 1 · 10
6
 m /s 
 
Q7: The work function of a metallic surface is ?? . ???????? . The photo-electrons are emitted when light 
of wavelength 2000 Å falls on it. The potential difference applied to stop the fastest photo -
electrons is [?? = ?? . ????
'
????
-????
?????????? ] 
(A) 1.2 volts 
(B) 2.24 volts 
(C) 3.6 volts 
(D) 4.8 volts 
Ans: (A) Energy of incident light ?? =
12375
2000
= 6.18eV 
According to relation E = W
0
+ eV
0
 
 p  ?? 0
=
(?? - ?? 0
)
?? =
(6.18eV- 5.01eV )
e
= 1.17 V » 1.2 V 
Page 3


JEE Solved Example on Dual Nature of Matter and 
Radiation 
JEE Mains 
Q1: What is the de-Broglie wavelength of the ?? -particle accelerated through a potential difference 
?? 
(A) 
?? .??????
v ?? Å 
(B) 
???? .????
v ?? Å 
(C) 
?? .??????
v ?? ?? 
(D) 
?? .??????
v ?? ?? 
Ans: (C) 1 =
h
v 2????
=
h
v2?? 2
?? 2
?? 
On putting ?? ?? = 2
'
1.6
'
10
-19
C 
?? a
= 4 m
p
= 4
'
1.67 · 10
-27
 kg p 1 =
0.101
v ?? A 
Q2: The de-Broglie wavelength of a particle moving with a velocity ?? . ???? · ????
?? ?? /?? is equal to the 
wavelength of photon. The ratio of kinetic energy of the particle to the energy of the photon is 
(velocity of light is ?? . ????
?? ?? /?? ) 
(A) ?? /?? 
(B) ?? /?? 
(C) ?? /?? 
(D) ?? /?? 
Ans: (B) ?? partice 
=
1
2
?? ?? 2
 also 1 =
h
????
 
b ?? partice 
=
1
2
Rh
?? ?
¨
F
?
× ?? 2
=
?? h
21
 
b K
pholon 
=
hc
1
 
K
partide 
K
protoon 
=
V
2C
=
2.25 · 10
8
2
'
3
'
10
8
=
3
8
 
Q3: The kinetic energy of electron and proton is ????
-????
 ?? . Then the relation between their de -
Broglie wavelengths is 
(A) ?? ?? < ?? ? 
(B) ?? ?? > ?? ? 
(C) ?? ?? = ?? ? 
(D) ?? ?? = ???? 
Ans: (A) By using 1 =
h
v 2mE
 E = 10
-32
 J 3/4 Constant for both particles. Hence 1?? 1
v ?? Since ?? ?? >
?? ?? so 1
?? < 1
?? . 
 
Q4: The de-Broglie wavelength of a particle accelerated with 150 volt potential is ????
-????
 ?? . If it is 
accelerated by 600 volts p.d., its wavelength will be 
(A) ?? . ???? Å 
(B) ?? . ?? Å 
(C) ?? . ?? Å 
(D) ?? Å 
Ans: (B) By using 1?? 1
v ?? P 
1
1
1
2
= v
?? 2
?? 1
 
b 
10
-10
1
2
= v
600
150
= 2 b  1
2
= 0.5Å 
Q5: When the momentum of a proton is changed by an amount ?? ?? , the corresponding change in 
the de-Broglie wavelength is found to be ?? . ???? %. Then, the original momentum of the proton was 
(A) ?? ?? 
(B) ?????? ?? ?? 
(C) ?????? ?? ?? 
(D) ?? ?? ?? 
Ans: (C) 1?? 1
p
  p  
D?? p
= -
D
1
  p  |
Dp
p
| = |
D
1
| 
b 
?? 0
p
=
0.25
100
=
1
400
  p  p = 400 p
0
. 
Q6: The work function of metal is ?????? . Light of wavelength ???????? Å is incident on this metal 
surface. The velocity of emitted photo -electrons will be 
(A) ???? ?? /?????? 
(B) ?? · ????
?? ?? /?????? 
(C) ?? · ????
?? ?? /?????? 
(D) ?? · ????
?? ?? /?????? 
Ans: (D) ?? = ?? 0
+ ?? max
; ?? =
12375
3000
= 4.125eV 
P K
max 
= E - W
0
= 4.125eV- 1eV= 3.125eV 
P  
1
2
?? ?? max
2
= 3.125· 1.6 · 10
-19
 J 
p  V
max
= v
2·3.125·1.6·10
-19
9.1·10
-31
= 1 · 10
6
 m /s 
 
Q7: The work function of a metallic surface is ?? . ???????? . The photo-electrons are emitted when light 
of wavelength 2000 Å falls on it. The potential difference applied to stop the fastest photo -
electrons is [?? = ?? . ????
'
????
-????
?????????? ] 
(A) 1.2 volts 
(B) 2.24 volts 
(C) 3.6 volts 
(D) 4.8 volts 
Ans: (A) Energy of incident light ?? =
12375
2000
= 6.18eV 
According to relation E = W
0
+ eV
0
 
 p  ?? 0
=
(?? - ?? 0
)
?? =
(6.18eV- 5.01eV )
e
= 1.17 V » 1.2 V 
Q8: A particle of mass ?? at rest decays into two particles of masses ?? ?? and ?? ?? , having non-zero 
velocities. The ratio of the de -Broglie wavelengths of the particles, ?? ?? /?? ?? is 
(A) ?? ?? /?? ?? 
(B) ?? ?? /?? ?? 
(C) 1.0 
(D) 
v
?? ?? /
v
?? ?? 
Ans: (C) By law of conservation of momentum 
0 = ?? 1
?? ?
1
+ ?? 2
?? ?
2
  b  ?? 1
?? ?
1
= -?? 2
?? ?
2
 
-ve sign indicates that both the particles are moving in opposite direction. Now de -Broglie 
wavelengths 
1
1
=
h
?? 1
?? 1
  and  1
2
=
h
?? 2
?? 2
; 
1
1
1
2
=
?? 2
?? 2
?? 1
?? 1
= 1 
Q9: When photon of energy ?? . ???????? strike the surface of a metal ?? , the ejected photoelectrons 
have maximum kinetic energy ?? ?? ???? and de-Broglie wavelength ?? ?? . The maximum kinetic energy 
of photoelectrons liberated from another metal B by photon of energy ?? . ???????? is ?? ?? =
(?? ?? - ?? . ???? )???? . If the de-Broglie wavelength of these photoelectrons is ?? ?? = ????
?? , then 
(A) The work function of ?? is ?? . ???????? 
(B) The work function of ?? is ?? . ???????? 
(C) ?? ?? = ?? . ???????? 
(D) ?? ?? = ?? . ???????? 
Ans: (A, B, C) K
max
= E - W
0
 
?? ?? = 4.25 - (?? 0
)
?? ?? ?? = (?? ?? - 1.5) = 4.70 - (?? 0
)
?? 
Equation (i) and (ii) gives (W
0
)
B
= (W
0
)
A
= 1.95eV 
De Broglie wavelength 1 =
h
v 2mK
, 1?? 1
v ?? 
p 
1
?? 1
?? = v
?? ?? ?? ?? p 2 = v
?? ?? ?? ?? -1.5
 p  ?? ?? = 2eV 
From equation (i) and (ii) 
W
A
= 2.25eV and W
B
= 4.20eV 
Q10: In a photoemissive cell with executing wavelength ?? , the fastest electron has speed ?? . If the 
exciting wavelength is changed to ?? ?? /?? , the speed of the fastest emitted electron will be 
(A) ?? (?? /?? )
?? /?? 
(B) ?? (?? /?? )
?? /?? 
(C) Less than ?? (?? /?? )
?? /?? 
(D) Greater than ?? (?? /?? )
?? /?? 
Ans:  
Page 4


JEE Solved Example on Dual Nature of Matter and 
Radiation 
JEE Mains 
Q1: What is the de-Broglie wavelength of the ?? -particle accelerated through a potential difference 
?? 
(A) 
?? .??????
v ?? Å 
(B) 
???? .????
v ?? Å 
(C) 
?? .??????
v ?? ?? 
(D) 
?? .??????
v ?? ?? 
Ans: (C) 1 =
h
v 2????
=
h
v2?? 2
?? 2
?? 
On putting ?? ?? = 2
'
1.6
'
10
-19
C 
?? a
= 4 m
p
= 4
'
1.67 · 10
-27
 kg p 1 =
0.101
v ?? A 
Q2: The de-Broglie wavelength of a particle moving with a velocity ?? . ???? · ????
?? ?? /?? is equal to the 
wavelength of photon. The ratio of kinetic energy of the particle to the energy of the photon is 
(velocity of light is ?? . ????
?? ?? /?? ) 
(A) ?? /?? 
(B) ?? /?? 
(C) ?? /?? 
(D) ?? /?? 
Ans: (B) ?? partice 
=
1
2
?? ?? 2
 also 1 =
h
????
 
b ?? partice 
=
1
2
Rh
?? ?
¨
F
?
× ?? 2
=
?? h
21
 
b K
pholon 
=
hc
1
 
K
partide 
K
protoon 
=
V
2C
=
2.25 · 10
8
2
'
3
'
10
8
=
3
8
 
Q3: The kinetic energy of electron and proton is ????
-????
 ?? . Then the relation between their de -
Broglie wavelengths is 
(A) ?? ?? < ?? ? 
(B) ?? ?? > ?? ? 
(C) ?? ?? = ?? ? 
(D) ?? ?? = ???? 
Ans: (A) By using 1 =
h
v 2mE
 E = 10
-32
 J 3/4 Constant for both particles. Hence 1?? 1
v ?? Since ?? ?? >
?? ?? so 1
?? < 1
?? . 
 
Q4: The de-Broglie wavelength of a particle accelerated with 150 volt potential is ????
-????
 ?? . If it is 
accelerated by 600 volts p.d., its wavelength will be 
(A) ?? . ???? Å 
(B) ?? . ?? Å 
(C) ?? . ?? Å 
(D) ?? Å 
Ans: (B) By using 1?? 1
v ?? P 
1
1
1
2
= v
?? 2
?? 1
 
b 
10
-10
1
2
= v
600
150
= 2 b  1
2
= 0.5Å 
Q5: When the momentum of a proton is changed by an amount ?? ?? , the corresponding change in 
the de-Broglie wavelength is found to be ?? . ???? %. Then, the original momentum of the proton was 
(A) ?? ?? 
(B) ?????? ?? ?? 
(C) ?????? ?? ?? 
(D) ?? ?? ?? 
Ans: (C) 1?? 1
p
  p  
D?? p
= -
D
1
  p  |
Dp
p
| = |
D
1
| 
b 
?? 0
p
=
0.25
100
=
1
400
  p  p = 400 p
0
. 
Q6: The work function of metal is ?????? . Light of wavelength ???????? Å is incident on this metal 
surface. The velocity of emitted photo -electrons will be 
(A) ???? ?? /?????? 
(B) ?? · ????
?? ?? /?????? 
(C) ?? · ????
?? ?? /?????? 
(D) ?? · ????
?? ?? /?????? 
Ans: (D) ?? = ?? 0
+ ?? max
; ?? =
12375
3000
= 4.125eV 
P K
max 
= E - W
0
= 4.125eV- 1eV= 3.125eV 
P  
1
2
?? ?? max
2
= 3.125· 1.6 · 10
-19
 J 
p  V
max
= v
2·3.125·1.6·10
-19
9.1·10
-31
= 1 · 10
6
 m /s 
 
Q7: The work function of a metallic surface is ?? . ???????? . The photo-electrons are emitted when light 
of wavelength 2000 Å falls on it. The potential difference applied to stop the fastest photo -
electrons is [?? = ?? . ????
'
????
-????
?????????? ] 
(A) 1.2 volts 
(B) 2.24 volts 
(C) 3.6 volts 
(D) 4.8 volts 
Ans: (A) Energy of incident light ?? =
12375
2000
= 6.18eV 
According to relation E = W
0
+ eV
0
 
 p  ?? 0
=
(?? - ?? 0
)
?? =
(6.18eV- 5.01eV )
e
= 1.17 V » 1.2 V 
Q8: A particle of mass ?? at rest decays into two particles of masses ?? ?? and ?? ?? , having non-zero 
velocities. The ratio of the de -Broglie wavelengths of the particles, ?? ?? /?? ?? is 
(A) ?? ?? /?? ?? 
(B) ?? ?? /?? ?? 
(C) 1.0 
(D) 
v
?? ?? /
v
?? ?? 
Ans: (C) By law of conservation of momentum 
0 = ?? 1
?? ?
1
+ ?? 2
?? ?
2
  b  ?? 1
?? ?
1
= -?? 2
?? ?
2
 
-ve sign indicates that both the particles are moving in opposite direction. Now de -Broglie 
wavelengths 
1
1
=
h
?? 1
?? 1
  and  1
2
=
h
?? 2
?? 2
; 
1
1
1
2
=
?? 2
?? 2
?? 1
?? 1
= 1 
Q9: When photon of energy ?? . ???????? strike the surface of a metal ?? , the ejected photoelectrons 
have maximum kinetic energy ?? ?? ???? and de-Broglie wavelength ?? ?? . The maximum kinetic energy 
of photoelectrons liberated from another metal B by photon of energy ?? . ???????? is ?? ?? =
(?? ?? - ?? . ???? )???? . If the de-Broglie wavelength of these photoelectrons is ?? ?? = ????
?? , then 
(A) The work function of ?? is ?? . ???????? 
(B) The work function of ?? is ?? . ???????? 
(C) ?? ?? = ?? . ???????? 
(D) ?? ?? = ?? . ???????? 
Ans: (A, B, C) K
max
= E - W
0
 
?? ?? = 4.25 - (?? 0
)
?? ?? ?? = (?? ?? - 1.5) = 4.70 - (?? 0
)
?? 
Equation (i) and (ii) gives (W
0
)
B
= (W
0
)
A
= 1.95eV 
De Broglie wavelength 1 =
h
v 2mK
, 1?? 1
v ?? 
p 
1
?? 1
?? = v
?? ?? ?? ?? p 2 = v
?? ?? ?? ?? -1.5
 p  ?? ?? = 2eV 
From equation (i) and (ii) 
W
A
= 2.25eV and W
B
= 4.20eV 
Q10: In a photoemissive cell with executing wavelength ?? , the fastest electron has speed ?? . If the 
exciting wavelength is changed to ?? ?? /?? , the speed of the fastest emitted electron will be 
(A) ?? (?? /?? )
?? /?? 
(B) ?? (?? /?? )
?? /?? 
(C) Less than ?? (?? /?? )
?? /?? 
(D) Greater than ?? (?? /?? )
?? /?? 
Ans:  
 (D) hv - W
0
=
1
2
?? ?? max
2
?
h?? ?? -
h?? ?? 0
=
1
2
?? ?? max
2
 ? h?? (
?? 0
- ?? ?? ?? 0
) =
1
2
?? ?? max
2
? ?? max
= v
2h?? ?? (
?? 0
- ?? ?? ?? 0
)
 
(D) h?? - ?? 0
=
1
2
?? ?? max
2
?
h?? ?? -
h?? ?? 0
=
1
2
?? ?? max
2
 
When wavelength is ?? and velocity is ?? , then 
?? = v
2hc
m
(
?? 0
- ?? ?? ?? 0
) 
When wavelength is 
3?? 4
 and velocity is ?? '
 then 
?? '
= v
2?? h
?? [
?? 0
- 3?? /4
(3?? /4) × ?? 0
] 
Divide equation (ii) by (i), we get 
?? '
?? =
v
?? 0
- (3?? /4)]
3
4
?? ?? 0
×
?? ?? 0
?? 0
- ?? ?? '
= ?? (
4
3
)
4/2
v
[?? 0
- (3?? /4)]
?? 0
- ?? i.e. ?? '
> ?? (
4
3
)
1/2
 
Q11: Photoelectric emission is observed from a metallic surface for frequencies ?? ?? and ?? ?? of the 
incident light rays (?? ?? > ?? ?? ). If the maximum values of kinetic energy of the photoelectrons 
emitted in the two cases are in the ratio of 1 : ?? , then the threshold frequency of the metallic 
surface is 
(A) 
?? ?? -?? ?? ?? -?? 
(B) 
?? ?? ?? -?? ?? ?? -?? 
(C) 
?? ?? ?? -?? ?? ?? -?? 
(D) 
?? ?? -?? ?? ?? 
Ans: (B) By using h?? - h?? 0
= ?? max
 
? h(v
1
- v
0
) = k
1
 
And h(?? 2
- ?? 0
) = ?? 2
 
?
?? 1
-?? 0
?? 2
-?? 0
=
?? 1
?? 2
=
1
?? , 
Hence ?? 0
=
?? ?? 1
-?? 2
?? -1
. 
An X-ray tube is operating at 50kV and 20 mA . The target material of the tube has a mass of 1.0 kg 
and specific heat 495 J kg
-10
C
-1
. One percent of the supplied electric power is converted into X-
Page 5


JEE Solved Example on Dual Nature of Matter and 
Radiation 
JEE Mains 
Q1: What is the de-Broglie wavelength of the ?? -particle accelerated through a potential difference 
?? 
(A) 
?? .??????
v ?? Å 
(B) 
???? .????
v ?? Å 
(C) 
?? .??????
v ?? ?? 
(D) 
?? .??????
v ?? ?? 
Ans: (C) 1 =
h
v 2????
=
h
v2?? 2
?? 2
?? 
On putting ?? ?? = 2
'
1.6
'
10
-19
C 
?? a
= 4 m
p
= 4
'
1.67 · 10
-27
 kg p 1 =
0.101
v ?? A 
Q2: The de-Broglie wavelength of a particle moving with a velocity ?? . ???? · ????
?? ?? /?? is equal to the 
wavelength of photon. The ratio of kinetic energy of the particle to the energy of the photon is 
(velocity of light is ?? . ????
?? ?? /?? ) 
(A) ?? /?? 
(B) ?? /?? 
(C) ?? /?? 
(D) ?? /?? 
Ans: (B) ?? partice 
=
1
2
?? ?? 2
 also 1 =
h
????
 
b ?? partice 
=
1
2
Rh
?? ?
¨
F
?
× ?? 2
=
?? h
21
 
b K
pholon 
=
hc
1
 
K
partide 
K
protoon 
=
V
2C
=
2.25 · 10
8
2
'
3
'
10
8
=
3
8
 
Q3: The kinetic energy of electron and proton is ????
-????
 ?? . Then the relation between their de -
Broglie wavelengths is 
(A) ?? ?? < ?? ? 
(B) ?? ?? > ?? ? 
(C) ?? ?? = ?? ? 
(D) ?? ?? = ???? 
Ans: (A) By using 1 =
h
v 2mE
 E = 10
-32
 J 3/4 Constant for both particles. Hence 1?? 1
v ?? Since ?? ?? >
?? ?? so 1
?? < 1
?? . 
 
Q4: The de-Broglie wavelength of a particle accelerated with 150 volt potential is ????
-????
 ?? . If it is 
accelerated by 600 volts p.d., its wavelength will be 
(A) ?? . ???? Å 
(B) ?? . ?? Å 
(C) ?? . ?? Å 
(D) ?? Å 
Ans: (B) By using 1?? 1
v ?? P 
1
1
1
2
= v
?? 2
?? 1
 
b 
10
-10
1
2
= v
600
150
= 2 b  1
2
= 0.5Å 
Q5: When the momentum of a proton is changed by an amount ?? ?? , the corresponding change in 
the de-Broglie wavelength is found to be ?? . ???? %. Then, the original momentum of the proton was 
(A) ?? ?? 
(B) ?????? ?? ?? 
(C) ?????? ?? ?? 
(D) ?? ?? ?? 
Ans: (C) 1?? 1
p
  p  
D?? p
= -
D
1
  p  |
Dp
p
| = |
D
1
| 
b 
?? 0
p
=
0.25
100
=
1
400
  p  p = 400 p
0
. 
Q6: The work function of metal is ?????? . Light of wavelength ???????? Å is incident on this metal 
surface. The velocity of emitted photo -electrons will be 
(A) ???? ?? /?????? 
(B) ?? · ????
?? ?? /?????? 
(C) ?? · ????
?? ?? /?????? 
(D) ?? · ????
?? ?? /?????? 
Ans: (D) ?? = ?? 0
+ ?? max
; ?? =
12375
3000
= 4.125eV 
P K
max 
= E - W
0
= 4.125eV- 1eV= 3.125eV 
P  
1
2
?? ?? max
2
= 3.125· 1.6 · 10
-19
 J 
p  V
max
= v
2·3.125·1.6·10
-19
9.1·10
-31
= 1 · 10
6
 m /s 
 
Q7: The work function of a metallic surface is ?? . ???????? . The photo-electrons are emitted when light 
of wavelength 2000 Å falls on it. The potential difference applied to stop the fastest photo -
electrons is [?? = ?? . ????
'
????
-????
?????????? ] 
(A) 1.2 volts 
(B) 2.24 volts 
(C) 3.6 volts 
(D) 4.8 volts 
Ans: (A) Energy of incident light ?? =
12375
2000
= 6.18eV 
According to relation E = W
0
+ eV
0
 
 p  ?? 0
=
(?? - ?? 0
)
?? =
(6.18eV- 5.01eV )
e
= 1.17 V » 1.2 V 
Q8: A particle of mass ?? at rest decays into two particles of masses ?? ?? and ?? ?? , having non-zero 
velocities. The ratio of the de -Broglie wavelengths of the particles, ?? ?? /?? ?? is 
(A) ?? ?? /?? ?? 
(B) ?? ?? /?? ?? 
(C) 1.0 
(D) 
v
?? ?? /
v
?? ?? 
Ans: (C) By law of conservation of momentum 
0 = ?? 1
?? ?
1
+ ?? 2
?? ?
2
  b  ?? 1
?? ?
1
= -?? 2
?? ?
2
 
-ve sign indicates that both the particles are moving in opposite direction. Now de -Broglie 
wavelengths 
1
1
=
h
?? 1
?? 1
  and  1
2
=
h
?? 2
?? 2
; 
1
1
1
2
=
?? 2
?? 2
?? 1
?? 1
= 1 
Q9: When photon of energy ?? . ???????? strike the surface of a metal ?? , the ejected photoelectrons 
have maximum kinetic energy ?? ?? ???? and de-Broglie wavelength ?? ?? . The maximum kinetic energy 
of photoelectrons liberated from another metal B by photon of energy ?? . ???????? is ?? ?? =
(?? ?? - ?? . ???? )???? . If the de-Broglie wavelength of these photoelectrons is ?? ?? = ????
?? , then 
(A) The work function of ?? is ?? . ???????? 
(B) The work function of ?? is ?? . ???????? 
(C) ?? ?? = ?? . ???????? 
(D) ?? ?? = ?? . ???????? 
Ans: (A, B, C) K
max
= E - W
0
 
?? ?? = 4.25 - (?? 0
)
?? ?? ?? = (?? ?? - 1.5) = 4.70 - (?? 0
)
?? 
Equation (i) and (ii) gives (W
0
)
B
= (W
0
)
A
= 1.95eV 
De Broglie wavelength 1 =
h
v 2mK
, 1?? 1
v ?? 
p 
1
?? 1
?? = v
?? ?? ?? ?? p 2 = v
?? ?? ?? ?? -1.5
 p  ?? ?? = 2eV 
From equation (i) and (ii) 
W
A
= 2.25eV and W
B
= 4.20eV 
Q10: In a photoemissive cell with executing wavelength ?? , the fastest electron has speed ?? . If the 
exciting wavelength is changed to ?? ?? /?? , the speed of the fastest emitted electron will be 
(A) ?? (?? /?? )
?? /?? 
(B) ?? (?? /?? )
?? /?? 
(C) Less than ?? (?? /?? )
?? /?? 
(D) Greater than ?? (?? /?? )
?? /?? 
Ans:  
 (D) hv - W
0
=
1
2
?? ?? max
2
?
h?? ?? -
h?? ?? 0
=
1
2
?? ?? max
2
 ? h?? (
?? 0
- ?? ?? ?? 0
) =
1
2
?? ?? max
2
? ?? max
= v
2h?? ?? (
?? 0
- ?? ?? ?? 0
)
 
(D) h?? - ?? 0
=
1
2
?? ?? max
2
?
h?? ?? -
h?? ?? 0
=
1
2
?? ?? max
2
 
When wavelength is ?? and velocity is ?? , then 
?? = v
2hc
m
(
?? 0
- ?? ?? ?? 0
) 
When wavelength is 
3?? 4
 and velocity is ?? '
 then 
?? '
= v
2?? h
?? [
?? 0
- 3?? /4
(3?? /4) × ?? 0
] 
Divide equation (ii) by (i), we get 
?? '
?? =
v
?? 0
- (3?? /4)]
3
4
?? ?? 0
×
?? ?? 0
?? 0
- ?? ?? '
= ?? (
4
3
)
4/2
v
[?? 0
- (3?? /4)]
?? 0
- ?? i.e. ?? '
> ?? (
4
3
)
1/2
 
Q11: Photoelectric emission is observed from a metallic surface for frequencies ?? ?? and ?? ?? of the 
incident light rays (?? ?? > ?? ?? ). If the maximum values of kinetic energy of the photoelectrons 
emitted in the two cases are in the ratio of 1 : ?? , then the threshold frequency of the metallic 
surface is 
(A) 
?? ?? -?? ?? ?? -?? 
(B) 
?? ?? ?? -?? ?? ?? -?? 
(C) 
?? ?? ?? -?? ?? ?? -?? 
(D) 
?? ?? -?? ?? ?? 
Ans: (B) By using h?? - h?? 0
= ?? max
 
? h(v
1
- v
0
) = k
1
 
And h(?? 2
- ?? 0
) = ?? 2
 
?
?? 1
-?? 0
?? 2
-?? 0
=
?? 1
?? 2
=
1
?? , 
Hence ?? 0
=
?? ?? 1
-?? 2
?? -1
. 
An X-ray tube is operating at 50kV and 20 mA . The target material of the tube has a mass of 1.0 kg 
and specific heat 495 J kg
-10
C
-1
. One percent of the supplied electric power is converted into X-
Q12: rays and the entire remaining energy goes into heating the target. Then 
(A) A suitable target material must have a high melting temperature 
(B) A suitable target material must have low thermal conductivity 
(C) The average rate of rise of temperature of target would be ?? 
°
?? /?? 
(D) The minimum wavelength of the X-rays emitted is about ?? . ???? · ????
-????
 ?? 
Ans:  (A, C, D)P = VI = 50 · 10
3
· 20 · 10
-3
= 1000 W 
Power converted into heat 3/4990 W 
msDT= 990 b  DT = 2
°
C/sec 
Now 
h?? 1
min 
= ????  p  1
min 
=
h?? eV
= 0.248· 10
-10
 m 
Q13: Electrons with energy ?????????? are incident on the tungsten target of an X-ray tube. K shell 
electrons of tungsten have ionization energy ???? . ???????? . X-rays emitted by the tube contain only 
(A) A continuous X -ray spectrum (Bremsstrahlung) with a minimum wavelength of ~ ?? . ?????? Å. 
(B) A continuous X -ray spectrum (Bremsstrahlung) with all wavelengths. 
(C) The characteristic X -rays spectrum of tungsten. 
(D) A continuous X -ray spectrum (Bremsstrahlung) with a minimum wavelength of ~ ?? . ?????? Å and 
the characteristic X -ray spectrum of tungsten. 
Ans: (D) Minimum wavelength of continuous X -ray spectrum is given by 1
min
( in Å) =
12375
?? (???? )
=
12375
80
'
10
3
»0.155 
Q14: The ?? -ray wavelength of ?? ?? line of platinum (?? = ???? ) is 1.30 Å. The X-ray wavelength of ?? ?? 
line of Molybdenum (?? = ???? ) is 
(A) ?? . ???? Å 
(B) ?? . ???? Å 
(C) ?? . ???? Å 
(D) ?? . ???? Å 
Ans:  The wavelength of ?? ?? line is given by 
1
?? = ?? (?? - 7.4)
2
(
1
2
2
-
1
3
2
) ? ?? ?
1
(?? - 7.4)
2
 ?
?? 1
?? 2
=
(?? 2
- 7.4)
2
(?? 1
- 7.4)
2
?
1.30
?? 2
=
(4.2 - 7.4)
2
(78 - 7.4)
2
? ?? 2
= 5.41Å
 
Q15: The ratio of de -Broglie wavelengths of molecules of hydrogen and helium which are at 
temperature ????
°
?? and ??????
°
?? respectively is 
(A) 
?? ?? 
(B) v
?? ?? 
 (C) v
?? ?? 
(D) 1 
Ans: (C) de-Broglie wavelength ?? =
h
mv?? ms
, rms velocity of a gas particle at the given temperature (T) 
is given as
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FAQs on Solved Example: Dual Nature of Matter and Radiation - Physics for JEE Main & Advanced

1. What is the dual nature of matter and radiation?
Ans. The dual nature of matter and radiation refers to the concept that particles such as electrons exhibit both wave-like and particle-like properties. This duality was established by experiments like the double-slit experiment.
2. How does the dual nature of matter and radiation impact our understanding of the universe?
Ans. The dual nature of matter and radiation has revolutionized our understanding of the universe by showing that classical physics principles are insufficient at the atomic and subatomic levels. It has led to the development of quantum mechanics, which is crucial for modern physics.
3. Can you provide an example of an experiment that demonstrates the dual nature of matter and radiation?
Ans. One famous experiment that demonstrates the dual nature of matter and radiation is the double-slit experiment. In this experiment, when electrons are fired through two slits onto a screen, they create an interference pattern similar to that of waves, indicating their wave-like nature.
4. How do scientists reconcile the wave-particle duality of matter and radiation?
Ans. Scientists reconcile the wave-particle duality of matter and radiation by using the principles of quantum mechanics. They understand that particles like electrons can exhibit wave-like behavior under certain conditions and particle-like behavior under others, depending on how they are observed or measured.
5. What are the practical applications of understanding the dual nature of matter and radiation?
Ans. Understanding the dual nature of matter and radiation has led to the development of technologies like electron microscopes, which can image structures at the atomic level. It also plays a crucial role in fields like quantum computing and particle physics research.
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