Atoms MCQs With Answers – Part 3 (Class 12 Physics)
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Atoms MCQs with Answers – Part 3 (Class 12 Physics)

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211. Bohr’s first postulate about stationary orbits was needed because classical theory predicted that a revolving electron should
ⓐ. radiate energy continuously
ⓑ. absorb all photons at every wavelength
ⓒ. become a neutron
ⓓ. remain stable without any special rule
212. A passage describes an electron in a Bohr atom.
An electron is in one of the allowed circular orbits around the nucleus. It remains in that orbit for some time without changing its energy.
According to Bohr’s postulate, during this time the electron
ⓐ. emits a continuous spectrum
ⓑ. falls gradually into the nucleus
ⓒ. emits no radiation
ⓓ. changes its charge from \(-e\) to \(+e\)
213. A table gives possible descriptions of electron motion in Bohr’s model.
RowDescriptionBohr-model status
PElectron in an allowed orbitNo radiation while it remains there
QElectron changes from one allowed orbit to anotherRadiation may be emitted or absorbed
RElectron in a stationary stateEnergy remains constant
SElectron in every possible circular orbitAll orbits are allowed
The row that conflicts with Bohr’s model is
ⓐ. Row P
ⓑ. Row Q
ⓒ. Row S
ⓓ. Row R
214. The stability of Bohr’s atom depends most directly on the idea that
ⓐ. electrons are not charged particles
ⓑ. the nucleus has no positive charge
ⓒ. atoms contain no moving particles
ⓓ. stationary orbits do not radiate
215. A claim states, “Since Bohr’s electron revolves, it must radiate continuously just as in Rutherford’s model.” The Bohr-model correction is that
ⓐ. the electron stops moving in every allowed orbit
ⓑ. the electron becomes electrically neutral in a stationary orbit
ⓒ. allowed stationary orbits do not radiate
ⓓ. the nucleus disappears during electron revolution
216. In Bohr’s model, radiation is emitted when the electron
ⓐ. drops from a higher to a lower stationary state
ⓑ. remains in the same stationary orbit
ⓒ. moves from a lower energy state to a higher energy state by absorbing energy
ⓓ. stays at rest inside the nucleus
217. The energy of a photon emitted in a Bohr transition depends on
ⓐ. the orbital frequency of the electron alone
ⓑ. the difference between the two allowed energies
ⓒ. the thickness of the gold foil
ⓓ. the number of scintillations on a zinc sulphide screen
218. For an emission transition in Bohr’s model, \(E_i\) is the initial higher energy and \(E_f\) is the final lower energy. The frequency condition is
ⓐ. \(h\nu=E_f-E_i\)
ⓑ. \(h\nu=E_i-E_f\)
ⓒ. \(\nu=h(E_i+E_f)\)
ⓓ. \(h\nu=\frac{E_f}{E_i}\)
219. For absorption in Bohr’s model, the electron moves upward from energy \(E_i\) to energy \(E_f\), where \(E_f\gt E_i\). The absorbed photon must satisfy
ⓐ. \(h\nu=E_i-E_f\)
ⓑ. \(h\nu=0\)
ⓒ. \(h\nu=E_f-E_i\)
ⓓ. \(h\nu=E_iE_f\)
220. A graph description is given below.
Horizontal energy levels are drawn for a Bohr atom. An arrow points downward from a higher level to a lower level.
The arrow represents
ⓐ. absorption of a photon with zero energy
ⓑ. photon emission equal to the level gap
ⓒ. continuous radiation from an unchanged orbit
ⓓ. disappearance of the nucleus
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