Consider the spectral line resulting from the transition $n=2\to n=1$ in the atoms and ions given below. The shortest wavelength is produced by:

1. hydrogen atom

2. deuterium atom

3. singly ionized helium

4. doubly ionized lithium

 

If the electron in a hydrogen atom were in the energy level with $n=3,$ how much energy in joule would be required to ionize the atom? (Ionization energy of H-atom is 2.18$\times {10}^{-18}J$):

1. 6.54$\times {10}^{-19}$

2. $1.43\times {10}^{-19}$

3. $2.42\times {10}^{-19}$

4. $3.14\times {10}^{-20}$

In a hydrogen atom, the electron is in \(n^\text{th}\) excited state. Knowing that on its way down to the second excited state, the number of different wavelengths that the electron can possibly emit is \(10  .\) What is the value of \(n? \)

1. \(6\)
2. \(7\)
3. \(8\)
4. \(5\)

Consider the following electronic energy level diagram of H-atom: Photons associated with the shortest and longest wavelengths would be emitted from the atom by the transitions labeled-

1. B and C respectively

2. C and A respectively

3.  C and D respectively

4. A and C respectively

The wavelength of the spectral line that corresponds to a transition in a hydrogen atom from n=10 to ground state would be and in which part of the electromagnetic spectrum this line lies?

1. 92.25 nm, ultraviolet

2. 92.25 nm, infrared

3. 86.95 nm, ultraviolet

4. 97.65 nm, ultraviolet

The angular momentum of an electron in the hydrogen atom is 4h/2$\mathrm{\pi }$. Kinetic energy of this electron is:

1. 4.35 eV

2. 1.51 eV

3. 0.85 eV

4. 13.6 eV

In a hydrogen atom, the electron makes a transition from n=2 to n=1. The magnetic field produced by the circulating electron at the nucleus:

1. decreases 16 times

2. increases 4 times

3. decreases 4 times

4. increases 32 times

Angular momentum (L) and radius (r) of a hydrogen atom are related as:

1. Lr = constant

2. $L{r}^2$=constant

3. $L{r}^4$=constant

4. None of these

An electron in the ground state of hydrogen has an angular momentum $L_1$ and an electron in the first excited state of lithium has an angular momentum $L_2$. Then

1. $L_1=L_2$

2. $L_1=4L_2$

3. $L_2=2L_1$

4. $L_1=2L_2$

The voltage applied to an X-ray tube is 18 kV. The maximum mass of photon emitted by the X-ray tube will be: 

1. $2\times {10}^{-13} \mathrm{kg}$

2. $3.2\times {10}^{-36 }\mathrm{kg}$

3. $3.2\times {10}^{-32} \mathrm{kg}$

4. $9.1\times {10}^{31} \mathrm{kg}$