356504 The ratio of ionization energy of Bohr's hydrogen atom and Bohr's hydrogen like Lithium atom is

356505 A small particle of mass \(m\) moves in such a way that its potential energy \(U=\dfrac{1}{2} m \omega^{2} r^{2}\), where \(\omega\) is constant and \(r\) is the distance of the particle from origin. Assuming Bohr's quantization of momentum and circular orbit, the radius of \(n^{\text {th }}\) orbit will be proportional to

356506 The angular momentum of an electron in the \({2^{nd}}\) excited state of Helium ion \((H{e^ + })\) is

356507 A hydrogen-like atom of atomic number \({Z}\) is in an excited state of quantum number \({2 n}\). It can emit a maximum energy photon of 204 \(eV\) . If it makes a transition to quantum state \({n}\), a photon of energy 40.8 \(eV\) is emitted. Find the minimum energy that can be emitted by this atom during de-excitation. Ground state energy of hydrogen atom is \(-\)13.6 \(eV\) .

356504 The ratio of ionization energy of Bohr's hydrogen atom and Bohr's hydrogen like Lithium atom is

356505 A small particle of mass \(m\) moves in such a way that its potential energy \(U=\dfrac{1}{2} m \omega^{2} r^{2}\), where \(\omega\) is constant and \(r\) is the distance of the particle from origin. Assuming Bohr's quantization of momentum and circular orbit, the radius of \(n^{\text {th }}\) orbit will be proportional to

356506 The angular momentum of an electron in the \({2^{nd}}\) excited state of Helium ion \((H{e^ + })\) is

356507 A hydrogen-like atom of atomic number \({Z}\) is in an excited state of quantum number \({2 n}\). It can emit a maximum energy photon of 204 \(eV\) . If it makes a transition to quantum state \({n}\), a photon of energy 40.8 \(eV\) is emitted. Find the minimum energy that can be emitted by this atom during de-excitation. Ground state energy of hydrogen atom is \(-\)13.6 \(eV\) .

356504 The ratio of ionization energy of Bohr's hydrogen atom and Bohr's hydrogen like Lithium atom is

356505 A small particle of mass \(m\) moves in such a way that its potential energy \(U=\dfrac{1}{2} m \omega^{2} r^{2}\), where \(\omega\) is constant and \(r\) is the distance of the particle from origin. Assuming Bohr's quantization of momentum and circular orbit, the radius of \(n^{\text {th }}\) orbit will be proportional to

356506 The angular momentum of an electron in the \({2^{nd}}\) excited state of Helium ion \((H{e^ + })\) is

356507 A hydrogen-like atom of atomic number \({Z}\) is in an excited state of quantum number \({2 n}\). It can emit a maximum energy photon of 204 \(eV\) . If it makes a transition to quantum state \({n}\), a photon of energy 40.8 \(eV\) is emitted. Find the minimum energy that can be emitted by this atom during de-excitation. Ground state energy of hydrogen atom is \(-\)13.6 \(eV\) .

356504 The ratio of ionization energy of Bohr's hydrogen atom and Bohr's hydrogen like Lithium atom is

356505 A small particle of mass \(m\) moves in such a way that its potential energy \(U=\dfrac{1}{2} m \omega^{2} r^{2}\), where \(\omega\) is constant and \(r\) is the distance of the particle from origin. Assuming Bohr's quantization of momentum and circular orbit, the radius of \(n^{\text {th }}\) orbit will be proportional to

356506 The angular momentum of an electron in the \({2^{nd}}\) excited state of Helium ion \((H{e^ + })\) is

356507 A hydrogen-like atom of atomic number \({Z}\) is in an excited state of quantum number \({2 n}\). It can emit a maximum energy photon of 204 \(eV\) . If it makes a transition to quantum state \({n}\), a photon of energy 40.8 \(eV\) is emitted. Find the minimum energy that can be emitted by this atom during de-excitation. Ground state energy of hydrogen atom is \(-\)13.6 \(eV\) .