JEE Advanced 2026 Paper 1 Online

MCQ (More than One Correct Answer)

-1

Consider a hydrogen atom with $v_k, r_k,$ and $K_k$ denoting the velocity, orbital radius and kinetic energy of the electron in the $k^{{th}}$ orbit, respectively. The electron undergoes a transition from the $n^{{th}}$ orbit, emitting radiation corresponding to the Lyman series. Considering $h$ to be the Planck’s constant and $ ho_0$ the permittivity of the free space, the correct statement(s) is/are:

Magnitude of change in kinetic energy of electron can be expressed as $\frac{h}{4\pi}\left|\frac{nv_n}{r_n} - \frac{v_1}{r_1}\right|$.

Magnitude of change in de Broglie wavelength of the electron can be expressed as $\frac{e^2}{4\epsilon_0}\left|\frac{1}{K_n} - \frac{1}{K_1}\right|$.

Frequency of the radiation emitted can be expressed as $\frac{e^2}{8\pi\epsilon_0 h}\left(\frac{1}{r_1} - \frac{1}{r_n}\right)$.

Magnitude of change in total energy of the electron can be expressed as $\frac{h}{2\pi}\left|\frac{v_1}{r_1} - \frac{nv_n}{r_n}\right|$.

JEE Advanced 2024 Paper 1 Online

MCQ (More than One Correct Answer)

-2

A particle of mass $m$ is moving in a circular orbit under the influence of the central force $F(r)=-k r$, corresponding to the potential energy $V(r)=k r^2 / 2$, where $k$ is a positive force constant and $r$ is the radial distance from the origin. According to the Bohr's quantization rule, the angular momentum of the particle is given by $L=n \hbar$, where $\hbar=h /(2 \pi), h$ is the Planck's constant, and $n$ a positive integer. If $v$ and $E$ are the speed and total energy of the particle, respectively, then which of the following expression(s) is(are) correct?

$r^2=n \hbar \sqrt{\frac{1}{m k}}$

$v^2=n \hbar \sqrt{\frac{k}{m^3}}$

$\frac{L}{m r^2}=\sqrt{\frac{k}{m}}$

$E=\frac{n \hbar}{2} \sqrt{\frac{k}{m}}$

JEE Advanced 2022 Paper 1 Online

MCQ (More than One Correct Answer)

-2

The binding energy of nucleons in a nucleus can be affected by the pairwise Coulomb repulsion. Assume that all nucleons are uniformly distributed inside the nucleus. Let the binding energy of a proton be $E_{b}^{p}$ and the binding energy of a neutron be $E_{b}^{n}$ in the nucleus.

Which of the following statement(s) is(are) correct?

$E_{b}^{p}-E_{b}^{n}$ is proportional to $Z(Z-1)$ where $Z$ is the atomic number of the nucleus.

$E_{b}^{p}-E_{b}^{n}$ is proportional to $A^{-\frac{1}{3}}$ where $A$ is the mass number of the nucleus.

$E_{b}^{p}-E_{b}^{n}$ is positive.

$E_{b}^{p}$ increases if the nucleus undergoes a beta decay emitting a positron.

JEE Advanced 2021 Paper 2 Online

MCQ (More than One Correct Answer)

-2

A heavy nucleus N, at rest, undergoes fission N $$\to$$ P + Q, where P and Q are two lighter nuclei. Let $$\delta$$ = M_N $$-$$ M_P $$-$$ M_Q, where M_P, M_Q and M_N are the masses of P, Q and N, respectively. E_P and E_Q are the kinetic energies of P and Q, respectively. The speeds of P and Q are v_P and v_Q, respectively. If c is the speed of light, which of the following statement(s) is(are) correct?

$${E_P} + {E_Q} = {c^2}\delta $$

$${E_P} = \left( {{{{M_P}} \over {{M_P} + {M_Q}}}} \right){c^2}\delta $$

$${{{v_P}} \over {{v_Q}}} = {{{M_Q}} \over {{M_P}}}$$

The magnitude of momentum for P as well Q is $$c\sqrt {2\mu \delta } $$, where $$\mu = {{{M_P}{M_Q}} \over {({M_P} + {M_Q})}}$$

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