Quantised Energy Levels - Bohr model

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SUMMARY

The discussion centers on the quantized energy levels of atoms, specifically within the context of the Bohr model, using Mercury as an example. It is established that an electron requires a photon with an energy of 4.9 eV to transition from the ground state to the first excited state. The inquiry explores whether firing an electron with the same energy would achieve the same result. The response highlights the mechanics of fluorescent lights, where electrons collide with gas atoms, causing excitation and subsequent light emission, while suggesting that the incident electron would likely be repulsed after the interaction.

PREREQUISITES
  • Understanding of quantized energy levels in atomic physics
  • Familiarity with the Bohr model of the atom
  • Knowledge of photon-electron interactions
  • Basic principles of thermionic emission and gas excitation
NEXT STEPS
  • Research the Franck-Hertz experiment and its implications for atomic theory
  • Study the mechanics of electron collisions in gas discharge tubes
  • Explore the principles of fluorescence and phosphorescence in materials
  • Investigate the behavior of electrons in electric fields and their interactions with atoms
USEFUL FOR

Students and professionals in physics, particularly those focused on atomic and quantum mechanics, as well as engineers and scientists working with gas discharge technologies and fluorescence applications.

VooDoo
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Hi Guys,

Because of the absorption and emmision spectrum we know that atoms have quantised engergy levels. For example for an electron to jump from ground state to the first excited state in a Mecury atom, a photon with the exact energy of 4.9eV is required.

Now my question is what would happen if instead of a photon we fired an electron with 4.9eV of energy? Would the electron in the Mecury atom still jump to the first excited state? If so what happens to the incident electron?
 
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VooDoo said:
Hi Guys,
Because of the absorption and emmision spectrum we know that atoms have quantised engergy levels. For example for an electron to jump from ground state to the first excited state in a Mecury atom, a photon with the exact energy of 4.9eV is required.
Now my question is what would happen if instead of a photon we fired an electron with 4.9eV of energy? Would the electron in the Mecury atom still jump to the first excited state? If so what happens to the incident electron?

Well, how do you think your fluorescent lights work? There's a thermionic cathode that emits electrons. These electrons are attracted to a positive anode, but in between, there's a gas (usually an inert gas). The electrons collide with the gas atoms, causing them to be excited and then decays with the emission of light. That's the light you see in neon lamps, etc.

The electrons that did the colliding lost most of their energy, but get re-accelerated towards the anode, and the process gets repeated.

Zz.
 
Bohr postulates have been confirmed in Franck-Hertz experiment (see web) and that is exactly your case .

(but I don't know what happens to incident electron with kinetic energy exactly 4,9eV but I guess repulsed)
 

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