Explain the limitations of the Bohr atomic model.
(N/A) $(1)$ The Bohr model is applicable only to hydrogenic atoms. It cannot be extended even to simple two-electron atoms such as helium.
- The analysis of atoms with more than one electron was attempted using the lines of Bohr's model for hydrogenic atoms,but it did not meet with any success.
- The difficulty lies in the fact that each electron interacts not only with the positively charged nucleus but also with all other electrons.
- The formulation of the Bohr model involves the electrical force between the positively charged nucleus and the electron. It does not include the electrical force between electrons,which necessarily appears in multi-electron atoms.
$(2)$ While the Bohr model correctly predicts the frequencies of the light emitted by hydrogenic atoms,it is unable to explain the relative intensities of the frequencies in the spectrum.
- In the emission spectrum of hydrogen,some of the visible frequencies have weak intensity,while others are strong. Why?
- Experimental observations depict that some transitions are more favoured than others.
- The Bohr model is unable to account for these intensity variations.
- This model cannot be applied to complex atoms. For complex atoms,we must use a new theory based on quantum mechanics.
- The analysis of atoms with more than one electron was attempted using the lines of Bohr's model for hydrogenic atoms,but it did not meet with any success.
- The difficulty lies in the fact that each electron interacts not only with the positively charged nucleus but also with all other electrons.
- The formulation of the Bohr model involves the electrical force between the positively charged nucleus and the electron. It does not include the electrical force between electrons,which necessarily appears in multi-electron atoms.
$(2)$ While the Bohr model correctly predicts the frequencies of the light emitted by hydrogenic atoms,it is unable to explain the relative intensities of the frequencies in the spectrum.
- In the emission spectrum of hydrogen,some of the visible frequencies have weak intensity,while others are strong. Why?
- Experimental observations depict that some transitions are more favoured than others.
- The Bohr model is unable to account for these intensity variations.
- This model cannot be applied to complex atoms. For complex atoms,we must use a new theory based on quantum mechanics.
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To which of the following is the angular velocity of the electron in the $n$-th Bohr orbit proportional?
If the force between the electron in the first Bohr orbit and the nucleus (proton) in a hydrogen atom is $F$,then the force between them when the electron is in the second orbit is
Medium
View SolutionWhich of the following statements are true regarding Bohr's model of the hydrogen atom?
$(I)$ Orbiting speed of the electron decreases as it shifts to discrete orbits away from the nucleus.
$(II)$ Radii of allowed orbits of the electron are proportional to the principal quantum number.
$(III)$ Frequency with which the electron orbits around the nucleus in discrete orbits is inversely proportional to the cube of the principal quantum number.
$(IV)$ Binding force with which the electron is bound to the nucleus increases as it shifts to outer orbits.
Select the correct answer using the codes given below.
$(I)$ Orbiting speed of the electron decreases as it shifts to discrete orbits away from the nucleus.
$(II)$ Radii of allowed orbits of the electron are proportional to the principal quantum number.
$(III)$ Frequency with which the electron orbits around the nucleus in discrete orbits is inversely proportional to the cube of the principal quantum number.
$(IV)$ Binding force with which the electron is bound to the nucleus increases as it shifts to outer orbits.
Select the correct answer using the codes given below.
Difficult
View SolutionFor a certain hypothetical one-electron atom,the wavelength (in $\mathring{A}$) for the spectral lines for transition from $n = p$ to $n = 1$ is given by $\lambda = \frac{1500p^2}{p^2 - 1}$ (where $p > 1$). The ionization potential of this element must be .....$V$ (Take $hc = 12420\ eV\cdot\mathring{A}$).
Difficult
View SolutionState the success of the Bohr's atomic model.
Medium
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