In the following, column I lists some physical quantities and the column II gives approximate energy values associated with those. Choose appropriate values of energies as per the choices given below Column I Column II i Energy of thermal neutrons a 3 eV ii Binding energy per nucleon b 10 keV iii Energy of X-rays c 8 MeV iv Photoelectric threshold of a meta d 0 . 025 eV e 1 eV f 0 . 8 eV

i → d , i i → c , i i i → b , i v → a

i → f , i i → c , i i i → e , i v → a

i → c , i i → e , i i i → f , i v → b

i → d , i i → c , i i i → f , i v → e

EASY

Earn 100

The anti-particle of electron is known as

33.33% studentsanswered this correctly

Important Questions on Nuclear Physics

MEDIUM

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

A nucleus

X

emits a

β

-particle to produce a nucleus

Y

. If their atomic masses are

M_{x}

and

M_{y}

respectively, then the maximum energy of the

β

-particle emitted is (where,

m_{e}

is the mass of an electron and

c

is the velocity of light)

HARD

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

The electrostatic energy of

Z

protons uniformly distributed throughout a spherical nucleus of radius

R

is given by,

E = \frac{3}{5} \frac{Z (Z - 1) e^{2}}{4 π ε_{0} R}

. The measured masses of the neutron,

{}_{1}^{1}H, {}_{7}^{15}N and {}_{8}^{15}O

are

1.008665 u

1.007825 u, 15.000109 u and 15.003065 u

respectively. Given that the radii of both the

{}_{7}^{15}N and {}_{8}^{15}O

nuclei are same,

1 u = 931.5 MeV c^{- 2}

(

c

is the speed of light) and

\frac{e^{2}}{(4 π ϵ_{0})} = 1.44 MeV fm

. Assuming that the difference between the binding energies of

{}_{7}^{15}N a n d {}_{8}^{15}O

is purely due to the electrostatic energy, the radius of either of the nuclei is

(1 fm = 10^{- 15} m)

EASY

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

If the binding energy of

N^{14}

7.5 MeV

per nucleon and that of

N^{15}

7.7 MeV

per nucleon, then the energy required to remove a neutron from

N^{15}

EASY

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

The binding energy of a nucleus is equivalent to

MEDIUM

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

Find the Binding energy per nucleon for

{}_{50}^{120}{Sn}

. Mass of proton

m_{p} = 1.00783 u

, mass of neutron

m_{n} = 1.00867 u

and mass of tin nucleus

m_{Sn} = 119.902199 u

. (take

1 u = 931 MeV

)

EASY

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

In a certain mass spectrometer, an ion beam passes through a velocity filter consisting of mutually perpendicular fields E and B. The beam then enters a region of another magnetic field

B^{'}

, perpendicular to the beam. The radius of curvature of the resulting ion beam is proportional to

EASY

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

What is the binding energy of ${}_{14}^{29}S i$ whose atomic mass is $28.976495 u$

Mass of proton $= 1.007276 u$

Mass of neutron $= 1.008664 u$

(Neglect the electron mass) (Assume $1 u = 931.5 MeV$ )

MEDIUM

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

A nucleus with mass number

240

breaks into two fragments each of mass number

120,

the binding energy per nucleon of unfragmented nuclei is

7.6 MeV

while that of fragments is

8.5 MeV

. The total gain in the binding energy in the process is :

HARD

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

Consider the nuclear fission,

{Ne}^{20} \to 2 {He}^{4} + C^{12}

. Given that the binding energy/nucleon of

{Ne}^{20}, {He}^{4}

and

C^{12}

are

8.03 MeV, 7.86 MeV

, respectively. Identify the correct statement:

EASY

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

You are given that Mass of

{}_{3}^{7}{Li} = 7.0160 u,

Mass of

{}_{2}^{4}{He} = 4.0026 u

and Mass of

{}_{1}^{1}{He} = 1.0079 u

. When

20 g

{}_{3}^{7}{Li}

is converted into

_{2}^{4} He

by proton capture, the energy liberated, (in

kWh

), is: [Mass of nucleon

= 1 GeV / c^{2}

]

MEDIUM

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

The ratio of the binding energies of three nuclei is

1 : 4 : 9

. If the ratio of their nuclear radii is

1 : 2 : 3

, the nuclei in the decreasing order of the stability can be arranged as

EASY

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

The binding energy per nucleon of

{}_{5} B^{10}

8.0 MeV

and that of

{}_{5} B^{11}

7.5 MeV .

The Energy required to remove a neutron from

{}_{5} B^{11}

is (mass of electron and proton are

9.11 \times 10^{- 31} kg

and

1.67 \times 10^{- 27} kg

)

EASY

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

The binding energy per nucleon of

{{}_{8}C}^{12} = 12.0038 amu

, mass of neutron

= 1.00898 amu

and mass of proton

= 1.007599 amu

EASY

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

The mass-defect in a nuclear fusion reaction is

0.3

per cent. The amount of energy released in one

kg

of fusion reaction is

MEDIUM

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

From the given data, the amount of energy required to break the nucleus of aluminium ${}_{13}^{27}{Al}$ is __________ $x \times 10^{- 3} J$ .

Mass of neutron $= 1.00866 u$
Mass of proton $= 1.00726 u$
Mass of Aluminium nucleus $= 27.18846 u$
(Assume $1 u$ corresponds to $x J$ of energy)
(Round off to the nearest integer)

EASY

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

In the following, column I lists some physical quantities and the column II gives approximate energy values associated with those. Choose appropriate values of energies as per the choices given below

	Column I		Column II
$(i)$	Energy of thermal neutrons	$a$	$3 eV$
$(ii)$	Binding energy per nucleon	$b$	$10 keV$
$(iii)$	Energy of X-rays	$c$	$8 MeV$
$(iv)$	Photoelectric threshold of a meta	$d$	$0.025 eV$
		$e$	$1 eV$
		$f$	$0.8 eV$

EASY

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

Which of the following statement is correct?

EASY

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

The energy required to break one bond in DNA is

10^{- 20} J

. This value in

eV

is nearly

EASY

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

If the binding energy of the electron in a hydrogen atom is

13.6 eV

, the energy required to remove the electron from the first excited state of

{Li}^{+ +}

is :

MEDIUM

Physics>Modern Physics>Nuclear Physics>Mass Defect and Binding Energy

Two deuterons undergo nuclear fusion to form a Helium nucleus. The energy released in this process is (given binding energy per nucleon for deuteron

= 1.1 MeV

and for helium

= 7.0 MeV

)

The anti-particle of electron is known as

Important Questions on Nuclear Physics

Learn and Prepare for any exam you want !