Consider atoms `H, He^(+), Li^(++)` in their ground states. If `L_(1), L_(2)` and `L_(3)` are magnitude of angular momentum of their electrons about the nucleus respectively then:

Consider atoms H, He^(+), Li^(++) in their ground states. Suppose E_(1), E_(2) and E_(3) are minimum energies required so that the atoms H He^(+), Li^(++) can achieve their first excited states respectively, then

The angular momentum (L) of an electron in a Bohr orbit is gives as:

The angular momentum (L) of an electron moving in a stable orbit around nucleus is

Assertion: In the duration electron jumps from fist excited state to ground state in a stationary isolated hydrogen atom, angular momentum of the electron about the nucleus is conserved. Reason: As the electron jumps from first excited state to ground state, in a hydrogen atom, the electrostatic force on electron is always directed twoards the nucleus.

A Hydrogen atom and Li^(++) ion are both in the second excited state. If L_(H) and L_(Li) are their respective angular momenta, and E_(H) and E_(Li) their respective energies, then:

Consider a satellite orbiting the earth as shown in the figure below. Let L_(a) and L_(p) represent the angular momentum of the satellite about the earth when at aphelion and perihelion respectively. Consider the following relations (i) L_(a)=L_(p) (ii) L_(a)=-L_(p) (iii) r_(a)xxL_(a) =r_(p)xxL_(p) Which of the above relation(s) is/are true ?

If E_n and L_n denote the total energy and the angular momentum of an electron in the nth orbit of Bohr atom, then

A hydrogen atom and a Li^(2+) ion ae both in the second excited state . If l_H and l_(li) are their respective angular momentum in an orbit and E_H and E_(Li) are their respective enrgies, then :

A hydrogen atom and a Li^(2+) ion are both in the second excited state. If l_H and l_(Li) are their respective electronic angular momenta, and E_H and E_(Li) their respective energies, then (a) l_H gt l_(Li) and |E_H| gt |E_(Li)| (b) l_H = l_(Li) and |E_H| lt |E_(Li)| (C ) l_H = l_(Li) and |E_H| gt |E_(Li)| (d) l_H lt l_(Li) and |E_H| lt|E_(Li)|

A spherical body of radius R rolls on a horizontal surface with linear velociltly v . Let L_(1) and L_(2) be the magnitudes of angular momenta of the body about centre of mass and point of contact P . Then: