356547
If the wavelength of first transition of the Balmer series is displaced by \(\Delta \lambda = 0.2\)\( \mathop A^{~~\circ} \), then the velocity of the excited hydrogen atoms is found to be \({N} \times 10^{3} {~m} / {s}\). When their radiations are observed at an angle \(\theta=60^{\circ}\) to their motion, then the value of \({N}\) is
[Take \({R}=10^{7} {~m}^{-1}\) ]
356547
If the wavelength of first transition of the Balmer series is displaced by \(\Delta \lambda = 0.2\)\( \mathop A^{~~\circ} \), then the velocity of the excited hydrogen atoms is found to be \({N} \times 10^{3} {~m} / {s}\). When their radiations are observed at an angle \(\theta=60^{\circ}\) to their motion, then the value of \({N}\) is
[Take \({R}=10^{7} {~m}^{-1}\) ]
356547
If the wavelength of first transition of the Balmer series is displaced by \(\Delta \lambda = 0.2\)\( \mathop A^{~~\circ} \), then the velocity of the excited hydrogen atoms is found to be \({N} \times 10^{3} {~m} / {s}\). When their radiations are observed at an angle \(\theta=60^{\circ}\) to their motion, then the value of \({N}\) is
[Take \({R}=10^{7} {~m}^{-1}\) ]
356547
If the wavelength of first transition of the Balmer series is displaced by \(\Delta \lambda = 0.2\)\( \mathop A^{~~\circ} \), then the velocity of the excited hydrogen atoms is found to be \({N} \times 10^{3} {~m} / {s}\). When their radiations are observed at an angle \(\theta=60^{\circ}\) to their motion, then the value of \({N}\) is
[Take \({R}=10^{7} {~m}^{-1}\) ]