Electron beam used in an electron microscope, when accelerated by a voltage of , has a de-Broglie wavelength of . If the voltage is increased to , then the de-Broglie wavelength associated with the electron beam would be:
- A
- B
- C
- D
Electron beam used in an electron microscope, when accelerated by a voltage of , has a de-Broglie wavelength of . If the voltage is increased to , then the de-Broglie wavelength associated with the electron beam would be:
Correct answer:D
Standard Method
Given: An electron beam has de-Broglie wavelength at accelerating voltage .
Find: The new de-Broglie wavelength when the accelerating voltage becomes .
For an electron accelerated through a potential difference , the de-Broglie wavelength is
where is Planck's constant, is the mass of the electron, and is the electronic charge.
Hence,
If at , the wavelength is , then at ,
So,
Therefore, the de-Broglie wavelength becomes . The correct option is D.
Note: The solution marks option C, but its working concludes , which matches option D in the given options.
Direct Proportionality Trick
Given: The voltage is doubled from to .
Find: How the de-Broglie wavelength changes.
Since
doubling makes the wavelength smaller by a factor of .
So the new wavelength is
Therefore, the correct option is D.
Assuming wavelength is inversely proportional to voltage instead of to its square root. This is wrong because , so the dependence is on . Use square-root scaling, not linear scaling.
Choosing because the voltage doubles. This is incorrect because doubling the accelerating voltage does not halve the wavelength directly. Instead, divide the wavelength by .
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