Which photon has the higher frequency?

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In the discussion, a hydrogen atom transitions from n=3 to n=2 and then from n=2 to n=1, producing two photons. The energy of these transitions is determined by the principal quantum number "n," where lower values indicate more tightly bound states. The energy difference between states is not constant but inversely proportional to the square of "n," leading to greater energy release when moving to lower states. The energy released as light corresponds to the negative change in energy of the electron, confirming that the photon emitted during the n=2 to n=1 transition has a higher frequency than that from n=3 to n=2. Understanding these energy transitions is crucial for grasping the relationship between quantum states and photon frequencies.
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Chemistry is not my strong subject...

A hydrogen atom undergoes a transition from the state n=3 to n=2 and then another transition from n=2 to n=1. Two photons are created due to these processes. Which photon has the higher frequency?

AND What is meant by 'n = #' ?
 
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Check out this thread, keeping in mind that E=h\nu. The principal quantum number, "n", is a property of a quantum mechanical state with certain energy. States with different "n" have different energies.
 
I didn't understand the discussion on that site very well. The course I'm in is a physics course and they threw in some chemistry, however, we don't have a textbook, so my resource is mainly the internet...

States with different 'n' values have different energies, but do the energies from n = 1, 2, 3 differ by a constant value [i.e. 1, 3, 5] or not?
 
smokie said:
States with different 'n' values have different energies, but do the energies from n = 1, 2, 3 differ by a constant value [i.e. 1, 3, 5] or not?

Actually, the energy of a state is proportional to the square of the inverse of the principal quantum number, "n". So, if we choose units in which the energy of the n=1 state is -1 (the total energy of a bound state is always negative), then the n=2,3, and 4 states will have energies of -1/4, -1/9, and -1/16, respectively. An energy greater than 0 will mean that the electron is no longer bound to the nucleus.
 
ok got that...so then obviously an electron moving from energy state -1/9 to -1/4, it would give off more energy than one moving from -1/4 to -1, correct?
 
smokie said:
ok got that...so then obviously an electron moving from energy state -1/9 to -1/4, it would give off more energy than one moving from -1/4 to -1, correct?

You might want to try that subtraction again. :wink:
 
Well I can see what I did wrong but doesn't an electron moving to a state 'closer' to the nucleus give off energy?
 
smokie said:
Well I can see what I did wrong but doesn't an electron moving to a state 'closer' to the nucleus give off energy?

If by "closer" you mean more tightly bound to the nucleus, then yes. The most tightly bound state is n=1.
 
Yes, what I mean is that the electrons are more tightly bound to the nucleus. So, how should I do my subtraction? I should do -1/4 - -1/9 ? <-- Negative number would be required for energy released... ?
 
Last edited:
  • #10
smokie said:
Yes, what I mean is that the electrons are more tightly bound to the nucleus. So, how should I do my subtraction? I should do -1/4 - -1/9 ? <-- Negative number would be required for energy released... ?

When it moves from state n=3 to n=2, does the electron's energy increase or decrease (based on what I already said)? If energy is conserved, what does this mean for the photon that's emitted?
 
  • #11
When moving from state n = 3 to n = 2, the electron's energy decreases... it loses some of the energy to the escaping photon...that's what I'm understanding..
 
  • #12
smokie said:
When moving from state n = 3 to n = 2, the electron's energy decreases... that's what I'm understanding..

That's right. So, to conserve energy, the atom must emit a photon of light!
 
  • #13
Exactly, soo, but then isn't my subtraction correct?

The only thing I'm seeing wrong with my subtraction is that for 'energy' I should have a negative answer...
 
  • #14
In our units, the energy change from n=3 to n=2 is (-1/9)-(-1/4)=5/36. This is the energy that's released as light. It's the change in energy of the electron that's negative: (-1/4)-(-1/9)=-5/36.
 
  • #15
Ahh, I see what you mean. E2 - E1 = energy released as light, while E1 - E2 = change in energy of the electron.
 
  • #16
That would mean that more energy is released from n = 2 to n = 1, than is from n = 3 to n = 2, would it not?
 

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