MCQ Questions for Class 12 Medical Physics Nuclei Quiz 13

Binding energy of deuterium is 2.23 MeV, then its mass defect in a.m.u. is:
The value of energy for $$_1H^2, _2He^4, _{26}Fe^{56}, _{92}U^{235}$$.

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-0.0024
0%
-0.0012
0%
0.0012
0%
0.0024

The binding energy of $$\alpha$$-particle $$\begin{array} { l } { 4 } \\ { 2 } \end{array}He$$ is $$7.047$$ $$MeV$$ per nucleon and the binding energy of deutron $$\begin{array} { l } { 2} \\ { 1 } \end{array}H$$ is $$1.112$$ $$MeV$$ per nucleon. Then in the fusion reaction $$_ { 1 } ^ { 2 } H + _ { 1 } ^ { 2 } H \rightarrow _ { 2 } ^ { 4 } H e + Q$$, the energy $$Q$$ released is

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$$23.74 \mathrm { MeV }$$
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$$32.82 \mathrm { MeV }$$
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$$11.9 MeV$$
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$$4.94 \mathrm { MeV }$$

Two radioactive nuclei P and Q in a given sample decay into a stable nucleus R. At time t = 0, number of P species are $$4 N_o$$ and that of Q are $$N_o$$. Half-life of P (for conversion to R) is 1 minute where as that of Q is 2 minutes. Initially there are no nuclei of R present in the sample. When number of nuclei of P and Q are equal, the number of nuclei of
R present in the sample would be :-

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$$\dfrac{9 N_o}{2}$$
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$$\dfrac{ 7N_o}{2}$$
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$$\dfrac{N_o}{4}$$
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$$\dfrac{9 N_o}{4}$$

A nucleus of atomic mass M emits a gamma ray photon of frequency v. then

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Kinetic energy acquired by nucleus $$= \frac { h ^ { 2 } v ^ { 2 } } { 2 M c ^ { 2 } }$$
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Loss in the internal energy of the nucleus $$h v \left( 1 + \frac { h v } { 2 M c ^ { 2 } } \right)$$
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Momentum of nucleus is equal and opposite to $$\gamma$$ ray photon
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Loss in internal energy of nucleus is hv

The above is a plot of binding energy per nucleon $$E _ { b }$$ , against the nuclear mass $$\mathrm { M } ; \mathrm { A } , \mathrm { B } , \mathrm { C } , \mathrm { D } , \mathrm { E } , \mathrm { F }$$ correspond to different nuclei. Consider four reactions:
where $$\varepsilon$$ is the energy released? In which reactions is $$\varepsilon$$ positive?

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$$A + B \rightarrow C + \varepsilon$$
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$$\mathrm { C } \rightarrow \mathrm { A } + \mathrm { B } + \varepsilon$$
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$$D + E \rightarrow F + \varepsilon$$
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$$\mathrm { F } \rightarrow \mathrm { D } + \mathrm { E } + \varepsilon$$

In a hydrogen atom, the binding energy of the electron in the nth state is $$E _ { n }$$ , then the frequency of revoulation the electron in the nth orbit is

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$$2 \mathrm { E } _ { \mathrm { n } } / \mathrm { nh }$$
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$$2 \mathrm { E } _ { \mathrm { n } } \mathrm { n }$$
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$$\mathrm { E } _ { \mathrm { n } } / \mathrm { nh }$$
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$$\mathrm { E } _ { \mathrm { n } } \mathrm { n } / \mathrm { h }$$

The binding energy per nucleon for $$O^{16}$$ and $$O^{17}$$ are respectively 7.99 MeV and 7.95 MeV. The energy required to remove one neutron from the nucleus of $$O^{17}$$ expressed in MeV is

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7.31
0%
4.23
0%
7.13
0%
15.94

If radius of the $$_{ 13 }^{ 27 }{ Al }$$ nucleus is estimated to be $$3.6$$ fermi, then the radius of $$^{ 125 }{ Te }$$ nucleus be nearly

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$$6$$ fermi
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$$8$$ fermi
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$$4$$ fermi
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$$5$$ fermi

If the nucleus is seen as a cubical box of length $$10^{-14}\ m$$, then compute the minimum energy of a nucleon confined to the nucleus. Mass of nucleon=$$1.6\times 10^{-27}\ Kg$$

0%
$$10\ MeV$$
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$$10\ KeV$$
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$$6\ MeV$$
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$$6\ KeV$$

Ratio of binding energy of a satellite revolving few metre above the earth's surface and same satellite rest on earth is

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1 : 2
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2 : 1
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1 : 4
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1 : 1

Calculate the binding energy per nucleon of $$_ { 17 } ^ { 35 } \mathrm { C } \ell$$ nucleus. Given that mass of $$_ { 17 } ^ { 35 } \mathrm { C } \ell$$ nucleus $$= 34.98000 \mathrm { u } ,$$ mass of proton $$= 1.007825 \mathrm { u } ,$$ mass of neutron $$= 1.008665 \mathrm { u }$$ and 1$$\mathrm { u }$$ is equivalent to 931$$\mathrm { Mev. }$$

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6.2$$\mathrm { Mev }$$
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7.2$$\mathrm { Mev }$$
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4.2$$\mathrm { Mev }$$
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8.2$$\mathrm { Mev }$$

Which of the following elements is non- radioactive?

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plutonium
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Zirconium
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Thorium
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Uranium

An X-ray pulse of wavelength $$4.9 A^{o}$$ is sent through a section of Wilson cloud chamber containing a supersaturated gas, and tracks of photoelectron ejected from the gaseous atoms are observed. Two groups of tracks of lengths $$1.40 cm$$ and $$2.02 cm$$ are noted. If the range energy relation for cloud chamber is given by $$R = aE$$ with $$ \alpha = \frac { 1 \mathrm { cm } } { k e V }$$. Obtain the binding energies of the two levels from which electrons are emitted. Given $$ h = 6.63 \times 10 ^ { - 34 } \mathrm { J } - \mathrm { s } , \mathrm { e } = 1.6 \times 10 ^ { - 19 } \mathrm { J } $$

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$$\phi_{1} = 1.14 KeV$$ $$\phi_{2}=0.52 KeV$$
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$$\phi_{1} = 1.14 KeV$$ $$\phi_{2}=0.75 KeV$$
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$$\phi_{1} = 0.52 KeV$$ $$\phi_{2}=0.75 KeV$$
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$$\phi_{1} = 1.14 KeV$$ $$\phi_{2}=0.52 KeV$$

The binding energy of deutron is $$2.23MeV$$. What should be its mass defect in the units of $$amu$$ or $$u$$ ?

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$$0.0012$$
0%
$$0.0024$$
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$$0.0242$$
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$$0.2422$$

A radioactive element $$X$$ converts into another stable element $$Y .$$ Half-life of $$X$$ is 2$$h$$ . Initially,only $$X$$ is present. After time $$t$$ , the ratio of atoms of $$X$$ and $$Y$$ is found to be $$1 : 4 .$$ Then $$t$$ inhours is

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$$2$$
0%
$$4$$
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between $$4$$ and $$6$$
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$$6$$

In an $$\alpha$$-decay the Kinetic energy of $$\alpha$$ particle is 48 MeV and Q-value of the reaction is 50 MeV. The mass number of the mother nucleus is : (Assume that daughter nucleus is in ground state)

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96
0%
100
0%
104
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none of these

From the following equations pick out the possible nuclear fusion reactions

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$$_{ 6 }{ C }^{ 13 }+_{ 1 }{ H }^{ 1 }\rightarrow _{ 6 }{ C }^{ 14 }+1.3\quad MeV$$
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$$_{ 6 }{ C }^{ 12 }+_{ 1 }{ H }^{ 1 }\rightarrow _{ 7 }{ C }^{ 14 }+2\quad MeV$$
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$$_{ 7}{ C }^{ 14 }+_{ 1 }{ H }^{ 1 }\rightarrow _{ 8 }{ C }^{ 15 }+7.3\quad MeV$$
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$$_{ 92 }{ U }^{ 235 }+_{ 0 }{ n }^{ 1 }\rightarrow _{ 54 }{ X }^{ 140 }+36{ Sr }^{ 94 }+_{ 0 }{ n }^{ 1 }+_{ 0 }{ n }^{ 1 }+y+200\quad MeV$$

$${{\text{Bi}}^{{\text{210}}}}$$ has half life of 5 days. The time taken for $$\dfrac{7}{8}$$th of a sample to decay is___ days

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15
0%
3.4
0%
10
0%
20

The binding energy per nucleon for a deuterium is 1.115 MeV. Mass deflect for this nucleus is about -

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2.23 u
0%
0.0024
0%
0.027 u
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0.0012 u

Atomic weight of boron is 10.81 and it has two isotopses $$ _5B^{10} and _5B^{11} $$ . then the ratio of $$ _5B^{10} : _5B^{11} $$ in nature would be

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15 : 16
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10: 11
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19 : 81
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81 ; 19

The binding energy per nucleon for a $$_6{C^{12}}$$ the nucleus is

( nuclear mass of $$_6{C^{12}}$$ =12.00000 a.m.u.

Mass of hydrogen nucleus = 1.007825 a.m.u.

Mass of neutron =1.00 8665 a.m.u)

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2.675 MeV
0%
7.675 MeV
0%
0 MeV
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3.675 MeV

Let $${ m }_{ p }$$ be the mass of a proton, $${ m }_{ n }$$ the mas of a neutron, $${ M }_{ 1 }$$ the mass of a $$^{20}_{10}Ne$$ nucleus and $${ M }_{ 2 }$$ the mass of a $$^{ 40 }_{ 20 }Ca$$ nucleus. Then

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$${ M }_{ 2 }>2{ M_1 }$$
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$${ M }_{ 2 }<2{ M_{ 1 } }$$
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$${ M }_{ 2 }=2{ M }_{ 1 }$$
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$${ M }_{ 1 }>10\left( { m }_{ n }+{ m }_{ p } \right) $$

For $${\text{N = }}{{\text{N}}_0}{e^{ - kt}}and\,{t_2} > {t_1},$$ the number of nuclei disintegrating between $${t_1}\,and\,{t_2}$$ is..............

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$${{\text{N}}_0}[{e^{ - \lambda t_1}} - {e^{ - \lambda t_2}}]$$
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$${{\text{N}}_0}[{e^{ - \lambda t_2}} - {e^{ - \lambda t_1}}]$$
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$${{\text{N}}_0}[{e^{\lambda t_2}} - {e^{\lambda t_1}}]$$
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none of the above.

How much energy is released when $$1$$ amu of mass is annihilated?

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$$931.5\,MeV$$
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$$1.49 \times {10^{ - 3}}J$$
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$$4.138 \times {10^{ - 17}}\,kWh$$
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All of these

If $$M(A,Z)$$, $$ M_p$$ and $$M_n $$ denote the masses of the nucleus $$^A_ZX , $$ proton and neutron respectively in units of $$u$$ $$( 1u = 931.5 MeV /C^2 )$$ and BE represents its bonding energy in $$MeV$$, then

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$$ M(A, Z) = ZM_p + (A-Z)M_n + BE/C^2 $$
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$$ M(A, Z) = ZM_p + (A-Z)M_n - BE/C^2 $$
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$$ M(A, Z) = ZM_p + (A-Z)M_n + BE $$
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$$ M(A, Z) = ZM_p + (A-Z)M_n - BE $$

If the mass of proton = $$1.008 amu$$ and mass of neutron = $$1.009 a.m.u.$$, then binding energy per nucleon for $$_{4}Be^{9}$$ (mass = $$9.012amu$$) would be:-

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$$0.065 MeV$$
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$$60.44MeV$$
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$$67.2MeV$$
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$$6.72MeV$$

The mass of proton is $$1.0073 u$$ and that of neutron is $$1.0087 u$$ ($${ u } =$$ atomic mass unit). The binding energy of $$_ { 2 } H e ^ { 4 }$$ is (Given, mass of helium nucleus $$= 4.0015{ u }$$ )

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$$28.4{ MeV }$$
0%
$$62.4{ MeV }$$
0%
$$42.4{ MeV }$$
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$$10.2{ MeV }$$

The decay constant of the end product if a radioactive series is

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zero
0%
infinite
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finite ( non zero)
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depends on the end product

Free $$ ^{238}U $$ nuclei kept in a train emit alpha particles. When the train is stationary and a uranium nucleus decays, a passenger measures that the separation between the alpha particle and the recoiling nucleus becomes x in time t after the decay. If a decay takes place when the train is moving at a uniform speed v, the distance between the alpha particle and the recoiling nucleus at a time t after the decay, as measured by the passenger will be

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x + vt
0%
x- vt
0%
x
0%
depends on the direction of the train.

If ionization potential of Hydrogen atom is 13.6 V then what is ionization potential of He atom ?

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27.6 V
0%
13.6 V
0%
54.2 V
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None of these

Using the following data mass of hydrogen atom$$=1.00783u$$ mass of neutron $$1.00867u$$ mass of nitrogen atom $$(_{ 7 }N^{14})$$=$$14.00307u$$. The calculated value of the binding energy of the nucleus of the nitrogen atom $$(_{ 7 }N^{ \ 14\ })$$ is close

0%
$$56MeV$$
0%
$$98MeV$$
0%
$$104MeV$$
0%
$$112MeV$$

Which element is the end product of each natural radioactive series?

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Sn
0%
Bi
0%
Pb
0%
C

Choose the element which is not radioactive.

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Cm
0%
No
0%
Mo
0%
Md

Nd (Z = 60) is a member of group -3 in the periodic table. An isotope of it is $$\beta$$ -active. The daughter nuclei will be a member of:

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Group - 3
0%
Group - 4
0%
Group - 1
0%
Group - 2

Radioactivity was discovered by

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Henry Becquerel
0%
Rutherford
0%
J. J. Thomson
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Madam Curie

Tritium undergoes radioactive decay giving:

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$$\alpha$$ - particles
0%
$$\beta$$ - particles
0%
Neutrons
0%
None of these

The phenomenon of radioactivity arises from the

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Binary fission
0%
Nuclear fusion
0%
Stable nuclei
0%
Decay of unstable nuclei

If radium and chlorine combine to from radium chloride the compound is:

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No longer radioactive
0%
Twice as radioactive as radium
0%
Half as radioactive as radium
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As radioactive as radium

Which of the following statements about the radioactivity of an element is incorrect?

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It is a nuclear property
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It does not involve any rearrangement of electrons
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Its rate is affected by change in temperature and/or pressure
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It remains unaffected by the presence of other element or elements chemically combined with it

When a sample of solid lithium is placed in a flask of hydrogen gas then following reaction happened
$$_1^1H+_3Li^7 \rightarrow He^4+_2He^4$$
This statement is

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True
0%
False
0%
May be true at a particular presure
0%
None of these

Radioactivity is affected by:

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temperature
0%
pressure
0%
electric and magnetic field
0%
none of these

One or more answers is/are correct.
In electron capture (radioactive process)

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a neutron is formed
0%
a proton is consumed
0%
$$\gamma$$-ray emission takes place
0%
X-ray emission takes place

CBSE Questions for Class 12 Medical Physics Nuclei Quiz 13 - MCQExams.com

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Practice Class 12 Medical Physics Quiz Questions and Answers

CBSE Questions for Class 12 Medical Physics Nuclei Quiz 13 - MCQExams.com

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Practice Class 12 Medical Physics Quiz Questions and Answers

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