The photon radiated from hydrogen corresponding to the second line of Lyman series is absorbed by a hydrogen-like atom X in the second excited state. As a result the hydrogen-like atom X makes a transition to orbit. Then:
1. X =
2. X = , n = 6
3. X =
4. X = , n = 9
If an electron in an hydrogen atom jumps from an orbit to an orbit with level , the frequency of the emitted radiation is
1.
2. v =
3. v =
4. v =
In an experiment to determine the e/m value for an electron using Thomson's method the electrostatic deflection plates were 0.01 m apart and had a potential difference of 200 volts applied. Then the electric field strength between the plates is
1.
2.
3.
4.
1. | \(4 \lambda_1=2 \lambda_2=2 \lambda_3=\lambda_4\) |
2. | \( \lambda_1=2 \lambda_2=2 \lambda_3=\lambda_4\) |
3. | \( \lambda_1=\lambda_2=4 \lambda_3=9\lambda_4\) |
4. | \( \lambda_1=2\lambda_2=3 \lambda_3=\lambda_4\) |
To explain his theory, Bohr used
1. conservation of linear momentum
2. conservation of angular momentum
3. conservation of quantum frequency
4. conservation of energy
Bragg's law for X-rays is:
1. dsin = 2n
2. 2dsin = n
3. nsin = 2d
4. None of these
The minimum wavelength of X-rays produced by electrons accelerated by a potential difference of V volt is equal to
1.
2.
3.
4.
The graph between the square root of the frequency of a specific line of the characteristic spectrum of X-rays and the atomic number of the target will be:
1.
2.
3.
4.
The wavelength of X-rays for lead isotopes respectively. Then
1.
2.
3.
4.