Question #15e99

1 Answer
Jul 18, 2016

The IR photon.

Explanation:

The energy of a photon is directly proportional to its frequency as described by the Planck - Einstein relation

#color(blue)(|bar(ul(color(white)(a/a)E = h * nu color(white)(a/a)|)))#

Here

#E# - the energy of the photon
#h# - Planck's constant, equal to #6.626 * 10^(-34)"J s"#
#nu# - the frequency of the photon

For two photons of frequency #nu_1# and #nu_2#, you can say that

#E_1 = h * nu_1" "# and #" "E_2 = h * nu_2#

If you were to divide these two equations, you would find

#E_1/E_2 = (color(red)(cancel(color(black)(h))) * nu_1)/(color(red)(cancel(color(black)(h))) * nu_2)#

Rearrange to get

#E_2 = nu_2/nu_1 * E_1#

If #nu_2>nu_1#, i.e. if the first photon has a higher frequency than the second photon, then #E_2 > E_1#, meaning that it's also more energetic.

If #nu_2 < nu_1#, i.e. if the first photon has a lower frequency than the second photon, then #E_2 < E_1#, meaning that it's also less energetic.

Now, take a a look at the EM Spectrum.

http://www.visionlearning.com/blog/2014/04/10/frequency-fingerprints/

Notice that infrared frequency measures at about #10^12"Hz"# and microwave frequency measures at about #10^9"Hz"#.

Since a photon of IR radiation has a higher frequency than a photon of microwave radiation, it follows that it will also be more energetic.

In fact, you can say that you have

#E_"IR" = (10^12 color(red)(cancel(color(black)("Hz"))))/(10^9color(red)(cancel(color(black)("Hz")))) * E_"microwave"#

#E_ "IR"= 10^3 * E_"microwave"#

Therefore, a photon of frequency #10^12 "Hz"# is about #10^3# times more energetic than a photon of frequency #10^9"Hz"#.