Solved papers for NEET Physics Nuclear Physics And Radioactivity NEET PYQ-Nuclear Physics

1) Half-lives of two radioactive substances A and B are respectively 20 min and 40 min. Initially the samples of A and B have equal number of nuclei. After 80 min the ratio of remaining number of A and B nuclei is: [AIPMT 1998]

A)

1 : 16

B)

4 : 1

C)

1 : 4

D)

1 : 1

View Answer

2) Atomic weight of boron is 10.81 and it has two isotopes \[_{5}^{10}B\] and \[_{5}^{11}B\]. Then, the ratio of atoms of \[_{5}^{10}B\] and \[_{5}^{11}B\] in nature, would be: [AIPMT 1998]

A)

19 : 81

B)

10 : 11

C)

15 : 16

D)

81 : 19

View Answer

3) A nucleus \[_{n}{{X}^{m}}\] emits one \[\alpha \] and two \[\beta \] particles The resulting nucleus is : [AIPMT 1998]

A)

\[_{n}{{X}^{m-4}}\]

B)

\[_{n-2}{{Y}^{m-4}}\]

C)

\[_{n-4}{{Z}^{m-4}}\]

D)

none of these

View Answer

4)

Complete the equation for the following fission process: [AIPMT 1998]

\[_{92}{{U}^{235}}+{{\,}_{0}}{{n}^{1}}\,\xrightarrow[{}]{{}}{{\,}_{38}}S{{r}^{90}}+.......\]

A)

\[_{54}X{{e}^{143}}+\,3{{\,}_{0}}{{n}^{1}}\]

B)

\[_{54}X{{e}^{145}}\]

C)

\[_{57}X{{e}^{142}}\]

D)

\[_{54}X{{e}^{142}}+{{\,}_{0}}{{n}^{1}}\]

View Answer

5) Alpha particles are: [AIPMT 1999]

A)

2 free protons

B)

helium atoms

C)

singly ionised helium atoms

D)

doubly ionised helium atoms

View Answer

6) In one a and 2 \[\beta -\]emissions: [AIPMT 1999]

A)

mass number reduces by 2

B)

mass number reduces by 6

C)

atomic number reduces by 2

D)

atomic number remains unchanged

View Answer

7) Nuclear fission can be explained by: [AIPMT 2000]

A)

proton-proton cycle

B)

liquid drop model of nucleus

C)

independent of nuclear particle model

D)

None of these

View Answer

8) The relationship between disintegration constant \[(\lambda )\] and half-life \[(T)\] will be: [AIPMT 2000]

A)

\[\lambda =\frac{{{\log }_{10}}2}{T}\]

B)

\[\lambda =\frac{{{\log }_{e}}2}{T}\]

C)

\[\lambda =\frac{T}{{{\log }_{e}}2}\]

D)

\[\lambda =\frac{{{\log }_{2}}e}{T}\]

View Answer

9) The half-life of a radioactive material is 3 h. If the initial amount is 300 g, then after 18 h, it will remain: [AIPMT 2000]

A)

4.68 g

B)

46.8 g

C)

9.375 g

D)

93.75 g

View Answer

10)

A nuclear decay is expressed as [AIPMT 2000]

\[_{6}{{C}^{11}}\to {{\,}_{5}}{{B}^{11}}+\,{{\beta }^{+}}+X\]

Then the unknown particle X is:

A)

neutron

B)

antineutrino

C)

proton

D)

neutrino

View Answer

11) Which of the following is positively charge? [AIPMT 2001]

A)

\[\alpha -\]particle

B)

\[\beta -\]particle

C)

\[\gamma -\]rays

D)

X-rays

View Answer

12) \[{{m}_{p}}\] and \[{{m}_{n}}\] are masses of proton and neutron respectively. An element of mass M has Z protons and N neutrons then: [AIPMT 2001]

A)

\[M>Z{{m}_{p}}+N{{m}_{n}}\]

B)

\[M=Z{{m}_{p}}+N{{m}_{n}}\]

C)

\[M<Z{{m}_{p}}+N{{m}_{n}}\]

D)

M may be greater than, less than or equal to \[Z{{m}_{p}}+N{{m}_{n}},\] depending on nature of element

View Answer

13) In nuclear fission process, energy is released because: [AIPMT 2001]

A)

mass of products is more than mass of nucleus

B)

total binding energy of products formed due to nuclear fission is more than the parent fissionable material

C)

total binding energy of products formed due to nuclear fission is less than parent fissionable material

D)

mass of some particles is converted into energy

View Answer

14) Half-life period of a radioactive substance is 6h. After 24 h activity is \[0.01\,\mu C,\] what was the initial activity? [AIPMT 2001]

A)

\[0.04\,\mu C\]

B)

\[0.08\,\mu C\]

C)

\[0.24\,\mu C\]

D)

\[0.16\,\mu C\]

View Answer

15) Half-life of a radioactive substance is 12.5 h and its mass is 256 g. After what time, the amount of remaining substance is 1g? [AIPMT 2001]

A)

75 h

B)

100 h

C)

125 h

D)

150 h

View Answer

16) In compound \[X(n,\,\,\alpha )\to \,{{\,}_{3}}L{{I}^{7}},\] the element X is: [AIPMT 2001]

A)

\[_{2}H{{e}^{4}}\]

B)

\[_{5}{{B}^{10}}\]

C)

\[_{5}{{B}^{9}}\]

D)

\[_{4}B{{e}^{11}}\]

View Answer

17) A sample of radioactive elements contains \[4\times {{10}^{10}}\] active nuclei. If half-life of element is 10 days, then the number of decayed nuclei after 30 days is: [AIPMT 2002]

A)

\[0.5\times {{10}^{10}}\]

B)

\[2\times {{10}^{10}}\]

C)

\[3.5\times {{10}^{10}}\]

D)

\[1\times {{10}^{10}}\]

View Answer

18) Which of the following are suitable for the fusion process? [AIPMT 2002]

A)

Light nuclei

B)

Heavy nuclei

C)

Elements lying in the middle of periodic table

D)

Elements lying in the middle of binding energy curve

View Answer

19) When a deuterium is bombarded on \[_{8}{{O}^{16}}\] nucleus, an \[\alpha -\]particle is emitted then the product nucleus is: [AIPMT 2002]

A)

\[_{7}{{N}^{13}}\]

B)

\[_{5}{{B}^{10}}\]

C)

\[_{4}B{{e}^{9}}\]

D)

\[_{7}{{N}^{14}}\]

View Answer

20) The volume occupied by an atom is greater than the volume of the nucleus by factor of about: [AIPMT 2003]

A)

\[{{10}^{10}}\]

B)

\[{{10}^{15}}\]

C)

\[{{10}^{1}}\]

D)

\[{{10}^{5}}\]

View Answer

21) The mass of proton is \[1.0073\text{ }u\] and that of neutron is \[1.0087\text{ }u\] (\[u=\]atomic mass unit) The binding energy of \[_{2}H{{e}^{4}}\] is: [AIPMT 2003]

A)

\[28.4\text{ }MeV\]

B)

\[0.061\text{ }u\]

C)

\[0.0305\text{ }J\]

D)

\[0.0305\text{ }erg\]

View Answer

22) A nuclear reaction given by: [AIPMT 2003] \[_{Z}{{X}^{A}}{{\to }_{Z+1}}{{Y}^{A}}{{+}_{-1}}{{e}^{0}}+\overline{v}\] represents:

A)

fusion

B)

fission

C)

\[\beta -\]decay

D)

\[\gamma -\]decay

View Answer

23) A sample of radioactive element has a mass of \[10\text{ }g\] at an instant \[t=0\]. The approximate mass of this element in the sample after two mean lives is: [AIPMT 2003]

A)

3.70 g

B)

6.30 g

C)

1.35 g

D)

2.50 g

View Answer

24) Solar energy is mainly caused due to: [AIPMT 2003]

A)

fusion of protons during synthesis of heavier elements

B)

gravitational contraction

C)

burning of hydrogen in the oxygen

D)

fission of uranium present in the sun

View Answer

25) If in a nuclear fusion process, the masses of the fusing nuclei be m1and m2 and the mass of the resultant nucleus be \[{{m}_{3}},\] then [AIPMT (S) 2004]

A)

\[{{m}_{3}}={{m}_{1}}+{{m}_{2}}\]

B)

\[{{m}_{3}}=|{{m}_{1}}-{{m}_{2}}|\]

C)

\[{{m}_{3}}<({{m}_{1}}+{{m}_{2}})\]

D)

\[{{m}_{3}}>({{m}_{1}}+{{m}_{2}})\]

View Answer

26) The half-life of radium is about 1600 years. Of 100 g of radium existing now, 25 g will remain unchanged after: [AIPMT (S) 2004]

A)

4800 year

B)

6400 year

C)

2400 year

D)

3200 year

View Answer

27) \[{{M}_{p}}\] denotes the mass of a proton and \[{{M}_{n}}\] that of a neutron. A given nucleus, of binding energy B, contains Z protons and N neutrons. [AIPMT (S) 2004] The mass \[M(N,\text{ }Z)\] of the nucleus is given by :

A)

\[M\left( N,\text{ }Z \right)=N{{M}_{n}}+Z{{M}_{p}}-B{{e}^{2}}\]

B)

\[M\left( N,Z \right)=N{{M}_{n}}+Z{{M}_{p}}+B/{{c}^{2}}\]

C)

\[M\left( N,\text{ }Z \right)=N{{M}_{n}}+Z{{M}_{p}}-B/{{c}^{2}}\]

D)

\[M\left( N,\text{ }Z \right)=N{{M}_{n}}+Z{{M}_{p}}+B/{{c}^{2}}\]

View Answer

28) In the reaction \[_{1}^{2}H+\,_{1}^{3}H\,\to \,_{2}^{4}He+\,_{0}^{1}n,\] if the binding energies of \[_{1}^{2}H\,,\,_{2}^{3}H\] and \[_{2}^{4}He\] are respectively a, b and c (in MeV), then the energy (in MeV) released in-this reaction is: [AIPMT (S) 2005]

A)

\[c+a-b\]

B)

\[c-a-b\]

C)

\[a+b+c\]

D)

\[a+b-c\]

View Answer

29) Fission of nuclei is possible because the binding energy per nucleon in them: [AIPMT (S) 2005]

A)

increases with mass number at high mass numbers

B)

decreases with mass number at high mass numbers

C)

increases with mass number at low mass numbers

D)

decreases with mass number at low mass numbers

View Answer

30) In any fission process the ratio \[\frac{\text{mass}\,\text{of}\,\text{fission}\,\text{products}}{\text{mass}\,\text{of}\,\text{parent}\,\text{nucleus}}\,\] is: [AIPMT (S) 2005]

A)

less than 1

B)

greater than 1

C)

equal to 1

D)

depends on the mass of parent nucleus

View Answer

31) The binding energy of deuteron is 2.2 MeV and that of \[_{2}^{4}He\] is 28 MeV. If two deuterons are fused to form one \[_{2}^{4}He\] then the energy released is: [AIPMT (S) 2006]

A)

25.8 MeV

B)

23.6 MeV

C)

19.2 MeV

D)

30.2 MeV

View Answer

32) In a radioactive material die activity at time \[{{t}_{1}}\] is \[{{R}_{1}}\] and at a later time \[{{t}_{2}},\] it is \[{{R}_{2}}\]. If the dacay constant of the material is \[\lambda ,\] then : [AIPMT (S) 2006]

A)

\[{{R}_{1}}={{R}_{2}}\,{{e}^{-\lambda ({{t}_{1}}-{{t}_{2}})}}\]

B)

\[{{R}_{1}}={{R}_{2}}\,{{e}^{\lambda ({{t}_{1}}-{{t}_{2}})}}\]

C)

\[{{R}_{1}}={{R}_{2}}\,({{t}_{2}}/{{t}_{1}})\]

D)

\[{{R}_{1}}={{R}_{2}}\]7

View Answer

33) The radius of germanium (Ge) nuclide is measured to be twice the radius of \[_{4}^{9}Be\]. The number of nucleons in Ge are: [AIPMT (S) 2006]

A)

73

B)

74

C)

75

D)

72

View Answer

34) In radioactive decay process, the negatively charged emitted \[\beta -\]particles are: [AIPMT (S) 2007]

A)

the electrons present inside the nucleus

B)

the electrons produced as a result of the decay of neutrons inside the nucleus

C)

the electrons produced as a result of collisions between atoms

D)

the electrons orbiting around the nucleus

View Answer

35) A nucleus \[_{Z}^{A}X\] has mass represented by \[M(A,\text{ }Z).\] If \[{{M}_{p}}\] and \[{{M}_{n}}\] denote the mass of proton and neutron respectively and BE the binding energy (in MeV), then: [AIPMT (S) 2007]

A)

\[BE=[M(A,\,Z)-Z{{M}_{p}}-(A-Z){{M}_{n}}]\text{ }{{c}^{2}}\]

B)

\[BE=[Z{{M}_{p}}+(A-Z)\,{{M}_{n}}-M(A,\,Z)]{{c}^{2}}\]

C)

\[BE=[Z{{M}_{p}}+A{{M}_{n}}-M(A,\,\,Z)]{{c}^{2}}\]

D)

\[BE=M(A,\,Z)-Z{{M}_{p}}-(A-Z)\,{{M}_{n}}\]

View Answer

36) If the nucleus \[_{13}^{27}Al\] has a nuclear radius of about 3.6 fm, then \[_{52}^{125}Te\] would have its radius approximately as: [AIPMT (S) 2007]

A)

6.0 fm

B)

9.6 fm

C)

12.0 fm

D)

4.8 fm

View Answer

37) Two radioactive substances A and B have decay constants \[5\,\lambda ,\] and \[\lambda \] respectively. At \[t=0\] they have the same number of nuclei. The ratio of number of nuclei of A to those of B will be \[{{\left( \frac{1}{e} \right)}^{2}}\] after a time interval: [AIPMT (S) 2007]

A)

\[\frac{1}{4\lambda }\]

B)

\[4\,\lambda \]

C)

\[2\,\lambda \]

D)

\[\frac{1}{2\lambda }\]

View Answer

38) Two radioactive materials \[{{X}_{1}}\] and \[{{X}_{2}}\] have decay constants \[5\lambda \] and \[\lambda \] respectively. If initially they have the same number of nuclei, then the ratio of the number of nuclei of \[{{X}_{1}}\] to that of \[{{X}_{2}}\] will be \[\frac{1}{e}\] after a time [AIPMPT (S) 2008]

A)

\[\lambda \]

B)

\[\frac{1}{2}\lambda \]

C)

\[\frac{1}{4\lambda }\]

D)

\[\frac{e}{\lambda }\]

View Answer

39) If \[M(A,\text{ }Z),\] \[{{M}_{p}}\] and M, denote the masses of the nucleus \[_{Z}^{A}X,\]proton and neutron respectively in units of \[u(1u=931.5MeV/{{c}^{2}})\] and BE represents its binding energy in M [AIPMPT (S) 2008]

A)

\[M(A,Z)=Z{{M}_{p}}+(A-Z){{M}_{n}}-BE/{{c}^{2}}\]

B)

\[M(A,Z)=Z{{M}_{p}}+(A-Z){{M}_{n}}+BE\]

C)

\[M(A,Z)=Z{{M}_{p}}+(A-Z){{M}_{n}}-BE\]

D)

\[M(A,Z)=Z{{M}_{p}}+(A-Z){{M}_{n}}-BE/{{c}^{2}}\]

View Answer

40) Two nuclei have their mass numbers in the ratio of 1 : 3. The ratio of their, nuclear densities would be [AIPMPT (S) 2008]

A)

1 : 3

B)

3 : 1

C)

\[{{(3)}^{1/3}}:1\]

D)

1 : 1

View Answer

41) In the nuclear decay given below\[_{Z}^{A}Z\xrightarrow{{}}\,_{Z+1}^{4}Y\xrightarrow{{}}\,_{Z-1}^{A-4}B*\xrightarrow{{}}\,_{Z-1}^{A-4}B,\]the particles emitted in the sequence are [AIPMT (S) 2009]

A)

\[\beta ,\,\,\alpha ,\,\,\gamma \]

B)

\[\gamma ,\,\,\beta ,\,\,\alpha \]

C)

\[\beta ,\,\,\gamma ,\,\,\alpha \]

D)

\[\alpha ,\,\,\beta ,\,\,\gamma \]

View Answer

42) The number of beta particles emitted by a radioactive substance is twice the number of alpha particles emitted by it. The resulting daughter is an [AIPMT (S) 2009]

A)

isobar of parent

B)

isomer of parent

C)

isotone of parent

D)

isotope of parent

View Answer

43) The mass of a \[_{\text{3}}^{\text{7}}Li\] nucleus is 0.042 u less than the sum of the masses of all its nucleons. The binding energy per nucleon of \[_{\text{3}}^{\text{7}}Li\] nucleus is nearly [AIPMT (S) 2010]

A)

46 MeV

B)

5.6 MeV

C)

3.9 MeV

D)

23 MeV

View Answer

44) The activity of a radioactive sample is measured as \[{{N}_{0}}\] counts per minute at \[t=0\] and \[{{N}_{0}}/e\] counts per minute at \[t=5\] min. The time (in minute) at which the activity reduces to half its value is [AIPMT (S) 2010]

A)

\[\text{lo}{{\text{g}}_{\text{e}}}\text{2/5}\]

B)

\[\frac{5}{{{\log }_{e}}2}\]

C)

\[5{{\log }_{10}}2\]

D)

\[5{{\log }_{e}}2\]

View Answer

45) The decay constant of a radio isotope is \[\lambda \]. If \[{{A}_{1}}\] and \[{{A}_{2}}\] are its activities at times \[{{t}_{1}}\] and \[{{t}_{2}}\] respectively, the number of nuclei which have decayed during the time \[({{t}_{1}}-{{t}_{2}})\] [AIPMT (M) 2010]

A)

\[{{A}_{1}}{{t}_{1}}-{{A}_{2}}{{t}_{2}}\]

B)

\[{{A}_{1}}-{{A}_{2}}\]

C)

\[\frac{({{A}_{1}}-{{A}_{2}})}{\lambda }\]

D)

\[\lambda ({{A}_{1}}-{{A}_{2}})\]

View Answer

46) The binding energy per nucleon in deuterium and helium nuclei are 1.1 MeV and 7.0 MeV, respectively. When two deuterium nuclei fuse to form a helium nucleus the energy released in the fusion is [AIPMT (M) 2010]

A)

23.6 MeV

B)

2.2 MeV

C)

28.0 MeV

D)

30.2 MeV

View Answer

47) Two radioactive nuclei P and Q, in a given sample decay into a stable nucleous R. At time \[t=0,\] number of P species are \[4\,{{N}_{0}}\] and that of Q are \[{{N}_{0}}\] Half-life of P (for conversion to K) is 1 min where as that of Q is 2 min. 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 [AIPMT (M) 2011]

A)

\[3{{N}_{0}}\]

B)

\[\frac{9{{N}_{0}}}{2}\]

C)

\[\frac{5{{N}_{0}}}{2}\]

D)

\[2{{N}_{0}}\]

View Answer

48) A radioactive nucleus of mass M emits a photon of frequency v and the nucleus recoils. The recoil energy will be [AIPMT (S) 2011]

A)

x\[{{h}^{2}}{{v}^{2}}/2M{{c}^{2}}\]

B)

zero

C)

\[hv\]

D)

\[M{{c}^{2}}-hv\]

View Answer

49) The power obtained in a reactor using \[{{U}^{235}}\] disintegration is 1000 kW. The mass decay of \[{{U}^{235}}\] per hour is [AIPMT (S) 2011]

A)

\[20\mu g\]

B)

\[40\mu g\]

C)

\[1\,\mu g\]

D)

\[10\,\mu g\]

View Answer

50) The half-life of a radioactive isotope X is 50 yr. It decays to another element Y which is stable. The two elements X and Y were found to be in the ratio of 1 : 15 in a sample of a given rock. The age of the rock was estimated to be [AIPMT (S) 2011]

A)

200 yr

B)

250 yr

C)

100 yr

D)

150 yr

View Answer

51) Fusion reaction takes place at high temperature because [AIPMT (S) 2011]

A)

atoms get ionised at high temperature

B)

kinetic energy is high enough to overcome the coulomb repulsion between nuclei

C)

molecules break up at high temperature

D)

nuclei break up at high temperature

View Answer

52) A nucleus \[_{n}^{m}X\] emits one a-particle and two \[\beta -\]particles. The resulting nucleus is [AIPMT (S) 2011]

A)

\[_{n}^{m-6}Z\]

B)

\[_{n}^{m-4}X\]

C)

\[_{n-2}^{m-4}Y\]

D)

\[_{n-4}^{m-6}Z\]

View Answer

53) The half-life of a radioactive nucleus is 50 days. The time interval \[({{t}_{2}}-{{t}_{1}})\] between the time t2 when \[\frac{2}{3}\] of it has decayed and the time \[{{t}_{1}}\] when \[\frac{1}{3}\] of it had decayed is [AIPMT (M) 2012]

A)

30 days

B)

50 days

C)

60 days

D)

15 days

View Answer

54) If the nuclear radius of \[^{27}Al\] is 3.6 Fermi, the approximate nuclear radius of \[^{64}Cu\] in Fermi is [AIPMT (S) 2012]

A)

2.4

B)

1.2

C)

4.8

D)

3.6

View Answer

55) A mixture consists of two radioactive materials \[{{A}_{1}}\] and \[{{A}_{2}}\] with half-lives of 20s and 10s respectively. Initially the mixture has 40 g of \[{{A}_{1}}\] and 160 g of \[{{A}_{2}}\]. The amount of the two in the mixture will become equal after [AIPMT (S) 2012]

A)

60 s

B)

80 s

C)

20 s

D)

40 s

View Answer

56) The half-life of a radioactive isotope X is 20 yr. It decays to another element Y which is stable. The two elements X and Y were found to be in the ratio 1 : 7 in a sample of a given rock. The age of the rock is estimated to be [NEET 2013]

A)

40 yr

B)

60 yr

C)

80 yr

D)

100 yr

View Answer

57) A certain mass of hydrogen is changed to helium by the process of fusion. The mass defect in fusion reaction is 0.02866 u. The energy liberated per u is (given \[1\text{ }u=931\text{ }MeV\]) [NEET 2013]

A)

2.67 MeV

B)

26.7 MeV

C)

6.675 MeV

D)

13.35 MeV

View Answer

58) The binding energy per nucleon of \[_{3}^{7}Li\] and \[_{2}^{4}He\] nuclei are 5.60 MeV and 7.06 MeV, respectively. In the nuclear reaction\[_{3}^{7}Li+_{1}^{1}H\to _{2}^{4}He\]\[+_{2}^{4}He+Q,\] the value of energy Q released is [NEET 2014]

A)

19.6 MeV

B)

- 2.4 MeV

C)

8.4 MeV

D)

17.3 MeV

View Answer

59) A radio isotope X with a half-life \[1.4\times {{10}^{9}}\,\,yr\] decays of Y which is stable. A sample of the rock from a cave was found to contain X and Y in the ratio 1 : 7. The age of the rock is [NEET 2014]

A)

\[1.96\times {{10}^{9}}\,yr\]

B)

\[3.92\times {{10}^{9}}\,yr\]

C)

\[4.20\times {{10}^{9}}yr\]

D)

\[8.40\times {{10}^{9}}\,yr\]

View Answer

60) If radius of the \[_{13}^{27}Al\] nucleus is taken to be \[{{R}_{Al}},\] then the radius of \[_{53}^{125}Te\] nucleus is nearly [NEET 2015]

A)

\[{{\left( \frac{53}{13} \right)}^{\frac{1}{3}}}{{R}_{Al}}\]

B)

\[\frac{5}{3}{{R}_{Al}}\]

C)

\[\frac{3}{5}{{R}_{Al}}\]

D)

\[{{\left( \frac{13}{53} \right)}^{\frac{1}{3}}}{{R}_{Al}}\]

View Answer

61) Radioactive material \['A'\] has decay constant \['8\lambda '\] and material \['B'\] has decay constant \['\lambda '\]. Initially they have same number of nuclei. After what time, the ratio of number of nuclei of material \['B'\] to that \['A'\] will be \[\frac{1}{e}\]? [NEET-2017]

A)

\[\frac{1}{9\lambda }\]

B)

\[\frac{1}{\lambda }\]

C)

\[\frac{1}{7\lambda }\]

D)

\[\frac{1}{8\lambda }\]

View Answer

62) For a radioactive material, half-life is 10 minutes. If initially there are 600 number of nuclei, the time taken (in minutes) for the disintegration of 450 nuclei is [NEET - 2018]

A)

30

B)

10

C)

20

D)

15

View Answer

63) When a uranium isotope \[_{\,\,\,92}^{235}\bigcup \]is bombarded with a neutron, it generates \[_{36}^{89}Kr\]neutrons and: [NEET 2020]

A)

\[_{40}^{91}Zr\]