Understanding Atom-Photon Interaction: How Long Will an Electron Hold Energy?

In summary, when an atom absorbs a photon, it can jump up to a higher energy level depending on the energy of the photon. The length of time the electron holds this energy is determined by the excitation lifetime of the molecule. The photon is essentially making up the difference between the ground and excited states of the atom/molecule system. For Neon specifically, it may take in a photon and jump to the third energy level, but this can also depend on the energy of the photon.
  • #1
QuarkCharmer
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I am told that when an atom absorbs a photon, it jumps up an energy level, these are discrete levels of energy etc etc. What determines how long the electron will hold this energy, and what exactly is the photon (wave) doing to up it's energy level. For ease of explanation, let's assume Neon (1s^2 2s^2 2p^6) takes in a photon particle/wave. Is it now at the third energy level? How does this effect it's electron configuration?

I'm having a difficult time finding the answer to this question. Thanks
 
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  • #2
you might google 'selection rules'
 
  • #3
QuarkCharmer said:
let's assume Neon (1s^2 2s^2 2p^6) takes in a photon particle/wave. Is it now at the third energy level?

It depends on the energy of the photon. In order for the atom to absorb the photon, the photon's energy has to match one of the possible upward transitions. It might kick an electron from n=2 to n=3 or from n=2 to n=4 or from n=1 to n=3, etc. Or it might do nothing at all because its energy doesn't match any transition.
 
  • #4
QuarkCharmer said:
I am told that when an atom absorbs a photon, it jumps up an energy level, these are discrete levels of energy etc etc. What determines how long the electron will hold this energy, and what exactly is the photon (wave) doing to up it's energy level. For ease of explanation, let's assume Neon (1s^2 2s^2 2p^6) takes in a photon particle/wave. Is it now at the third energy level? How does this effect it's electron configuration?

I'm having a difficult time finding the answer to this question. Thanks

The excitation lifetime of an isolated molecule is one thing:
http://en.wikipedia.org/wiki/Fluorescence#Lifetime
and can depend on the number and type of states that it's allowed to relax to,
but it can also become de-excited by other non-radiative processes.

As to your other question, I have no direct experience with quantized light fields, so this may be an oversimplified idea, but in terms of what the photon is "doing", you can think of any excited state wave function as describing a atom/molecule + photon system, and what it's "doing" is making up the difference between the ground and excited states. I guess that doesn't really explain "what it's doing" but just "how to think about it". Hope that was at all helpful.
 

1. What is the concept of electron energy and how does it interact with photons?

The concept of electron energy refers to the energy levels of an electron in an atom. When an electron absorbs a photon, it moves to a higher energy level. Conversely, when an electron releases a photon, it moves to a lower energy level. This interaction between electrons and photons is essential for understanding the behavior of atoms and the properties of light.

2. How long can an electron hold onto absorbed energy?

The amount of time an electron can hold onto absorbed energy varies depending on the specific atom and its energy levels. Generally, the lifetime of an excited electron is very short, on the order of nanoseconds or even femtoseconds. This means that the electron quickly releases the absorbed energy in the form of a photon and returns to its ground state.

3. What factors affect the duration of an electron's energy storage?

Several factors can affect the duration of an electron's energy storage. These include the energy level of the electron, the energy of the absorbed photon, and the presence of other atoms and molecules in the surrounding environment. Additionally, the properties of the material or medium in which the electron is located can also influence the duration of energy storage.

4. How does the duration of an electron's energy storage impact its behavior?

The duration of an electron's energy storage can impact its behavior in several ways. For example, a longer storage time means that the electron has more time to interact with other particles and potentially cause chemical reactions. Additionally, the duration of energy storage can affect the overall lifetime and stability of an excited state in an atom.

5. What are the practical applications of understanding atom-photon interaction and electron energy storage?

Understanding atom-photon interaction and electron energy storage has many practical applications. This knowledge is essential for developing technologies such as lasers, solar cells, and LED lights. It also plays a crucial role in fields such as quantum computing and spectroscopy, which rely on the interaction between atoms and photons to gather information about the properties of matter.

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