Which of the alternatives gives the correct match of Column-$I$ with Column-$II$?
Column-$I$ Column-$II$ $a.$ Binding energy per nucleon for ${ }^{56} Fe$ $(i)$ $5.5 \,MeV$ $b.$ Energy of $\alpha$-particle in Geiger-Marsden experiment $(ii)$ $200 \,MeV$ $c.$ Energy of photon of visible light $(iii)$ $8.75 \,MeV$ $d.$ Energy released in fission of a uranium nucleus $(iv)$ $2 \,eV$
| Column-$I$ | Column-$II$ |
| $a.$ Binding energy per nucleon for ${ }^{56} Fe$ | $(i)$ $5.5 \,MeV$ |
| $b.$ Energy of $\alpha$-particle in Geiger-Marsden experiment | $(ii)$ $200 \,MeV$ |
| $c.$ Energy of photon of visible light | $(iii)$ $8.75 \,MeV$ |
| $d.$ Energy released in fission of a uranium nucleus | $(iv)$ $2 \,eV$ |
- A$a(i), b(iii), c(iv), d(ii)$
- B$a(iii), b(i), c(ii), d(iv)$
- C$a(iii), b(i), c(iv), d(ii)$
- D$a(i), b(iv), c(ii), d(iii)$
Explore More
Similar Questions
During the disintegration of a radioactive nucleus of mass number $208$ at rest,two alpha particles each with kinetic energy $E$ are emitted. The total kinetic energy of the emitted alpha particles and the daughter nucleus after the disintegration is
$A$ radioactive nucleus emits an $\alpha$-particle to become a stable nucleus. If the velocity of the $\alpha$-particle is $\upsilon$ and the mass number of the original radioactive nucleus is $A$,what will be the velocity of the daughter nucleus?
Difficult
View SolutionBoth the nucleus and the atom of some element are in their respective first excited states. They get de-excited by emitting photons of wavelengths $\lambda_N$ and $\lambda_A$ respectively. The ratio $\frac{\lambda_N}{\lambda_A}$ is closest to
From the statements given below:
$(A)$ The angular momentum of an electron in $n^{\text{th}}$ orbit is an integral multiple of $\hbar$.
$(B)$ Nuclear forces do not obey inverse square law.
$(C)$ Nuclear forces are spin dependent.
$(D)$ Nuclear forces are central and charge independent.
$(E)$ Stability of nucleus is inversely proportional to the value of packing fraction.
Choose the correct answer from the options given below:
$(A)$ The angular momentum of an electron in $n^{\text{th}}$ orbit is an integral multiple of $\hbar$.
$(B)$ Nuclear forces do not obey inverse square law.
$(C)$ Nuclear forces are spin dependent.
$(D)$ Nuclear forces are central and charge independent.
$(E)$ Stability of nucleus is inversely proportional to the value of packing fraction.
Choose the correct answer from the options given below:
DifficultJEE MAIN 2024
View SolutionMatch List $I$ of the nuclear processes with List $II$ containing parent nucleus and one of the end products of each process and then select the correct answer using the codes given below the lists:
List $I$ List $II$ $P$. Alpha decay $1$. ${ }_{8}^{15} O \rightarrow{ }_{7}^{15} N + \dots$ $Q$. $\beta^{+}$ decay $2$. ${ }_{92}^{238} U \rightarrow{ }_{90}^{234} Th + \dots$ $R$. Fission $3$. ${ }_{83}^{185} Bi \rightarrow{ }_{82}^{184} Pb + \dots$ $S$. Proton emission $4$. ${ }_{94}^{239} Pu \rightarrow{ }_{57}^{140} La + \dots$
Codes: $P \quad Q \quad R \quad S$
| List $I$ | List $II$ |
| $P$. Alpha decay | $1$. ${ }_{8}^{15} O \rightarrow{ }_{7}^{15} N + \dots$ |
| $Q$. $\beta^{+}$ decay | $2$. ${ }_{92}^{238} U \rightarrow{ }_{90}^{234} Th + \dots$ |
| $R$. Fission | $3$. ${ }_{83}^{185} Bi \rightarrow{ }_{82}^{184} Pb + \dots$ |
| $S$. Proton emission | $4$. ${ }_{94}^{239} Pu \rightarrow{ }_{57}^{140} La + \dots$ |
Codes: $P \quad Q \quad R \quad S$
DifficultIIT 2013
View SolutionVedclass Products
For Students
Vedclass Test Series
Mock tests in real JEE/NEET style with performance analysis. 5-day free trial.
Start Free TrialFor Teachers
Exam Paper Generator
Generate Set A/B/C/D exam papers from 7.5L+ questions in 2 minutes. 3 chapters free.
Try FreeFor Institutes
Online Exam Module
Live online exams with unlimited students, 360° analytics & white-label branding.
See Demo