An electron of a hydrogen-like atom, having , jumps from energy state to energy state. The energy released in this process, will be:
(Given )
Where = Rydberg constant
= Speed of light in vacuum
= Planck's constant
- A
- B
- C
- D
An electron of a hydrogen-like atom, having , jumps from energy state to energy state. The energy released in this process, will be:
(Given )
Where = Rydberg constant
= Speed of light in vacuum
= Planck's constant
Correct answer:A
Standard Method
Given: A hydrogen-like atom with undergoes a transition from to .
Find: The energy released during the transition and the correct option.
For a hydrogen-like atom, the energy of the electron in the orbit is
So, the emitted energy is
Substituting , , and ,
Therefore, the energy released is .
The solution working gives , which matches Option D. The solution labels the option as A and also says Option 1, which is inconsistent with the calculation. Hence, the defensible correct option from the working is D.
Using the hydrogen atom value directly without multiplying by is incorrect. For hydrogen-like atoms, energy levels scale as . Always include the factor here.
Reversing the order of terms in the energy difference can give a wrong sign. For emitted energy, use with so that the released energy is positive.
Confusing orbit numbers and with their squares leads to wrong fractions. Use and , not and .
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