Calculating how many Joules are required to make a photon

In summary, the double covalent bond of nitrogen (N2) is 15.58eV. This explains why it takes only low amounts of energy to ionize one molecule of nitrogen.
  • #1
reese houseknecht
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1
A double covalent bond of nitrogen (N2) is 15.58eV Now let's go into a example. if i have a laser that is 477nm and i do 1240/477nm then i get 2.6eV per photon.

Now if i do (15.58eV / 2.6eV) it equals ~6 photons.

Now to figure out how many Joules are required for 1 photon I do
(6.626*10^-34S * 3.00*10^17nm/s) / 477nm which equals 4.167e-19 J, and for 6 photons that's 2.5002e-18 J.

Now if i want to get 6 photons in a pulse then I would need 2.5002e-18 J right? Now that is in Joules i need per nanosecond, which is 2.5002e-9 watts. All i want to know is why does it require such low amounts of energy to do this, when all i see is that you need ALOT of watts to ionize. Now as i was typing this i thought that maybe that equation shows how many joules of energy are in each photon, but yet this video
says "Joules required per photon". But if this equation is not right then what equation should i use.

(also this is my first time on this forum so if anything is wrong or I am not in the right place let me know thank you)
 
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  • #2
reese houseknecht said:
... and i do 1240/477nm
Can you explain why you do "1240/477nm"? Where did this come from?

On edit: Can you also explain what exactly you are trying to calculate? Your title suggests that you want to know how to calculate the energy of a photon in Joules. It seems you already know how to do that.
 
  • #3
To be pedantic, the bond in N2 is a triple bond. But leaving that aside:
Do you really only want to ionise one molecule of N2 per pulse? No wonder the power is low. You need high power to produce and maintain a significant concentration of ionised molecules.
 
  • #4
So 1240 is some equation i found online, and it seems to work quite well, so your saying i can ionize an atom with that low energy but i probably won't see anything
 
  • #5
1240 nm is the wavelength of a 1 eV photon.
What are you actually trying to do?
 
  • #6
I think 1240 is h*c and then divided by wavelngth is the ev in each photon, I am trying to understand hiw photoionization works. Right now I am learning about the multiphoton process. I currently don't know why the wnergy required is so low. But i see now that that is to ionize 1 atom and you probably wouldn't see anylight so i need to recalculate to account for 100000s of atons
 
  • #7
Looking at your first post, you seem to be VERY confused.
The energy of a photon is ##E = h \nu## or ##E = hc/\lambda## where ##h## is Planck's constant, ##\nu## is the frequency, ##c## is the speed of light in vacuum and ##\lambda## is the wavelength.
You can easily calculate the energy for any given wavelength.
Atoms are small, so it shouldn't surprise you that it doesn't much of a joule to ionize an atom, since a joule is a macroscopic scale quantity.
 
  • #8
You won't split a nitrogen bond with multiple 2.6 eV photons. It is technically not impossible but you need a ridiculous power density to make the probability of 6 photons interacting at the same time relevant. But if we ignore that:
reese houseknecht said:
Now if i want to get 6 photons in a pulse then I would need 2.5002e-18 J right?
2.5*10-18 J = 15.6 eV. Right.
reese houseknecht said:
Now that is in Joules i need per nanosecond
Where does the nanosecond come from?
 
  • #9
ok i just found out new information, i am using a 150ns pules laser. so i just read that you need ridiculous amounts of watts to be focused because all the photons won't hit the atom at once, now even if i had a peak pulse intensity of 1,666,666,666 watts in each 150ns pulse, what is my probability of ionizing nitrogen in the air. (also I am not trying to split the bond i just need an electron to move to its outer most energy level and fall back in creating light)
 
  • #10
reese houseknecht said:
what is my probability of ionizing nitrogen in the air. (also I am not trying to split the bond i just need an electron to move to its outer most energy level and fall back in creating light)
Do you want to ionize it or do you want to excite it? These are different processes.

Forget processes that involve multiple photons at the same time with your laser. If your energy per photon is not sufficient to directly induce a transition in nitrogen, something you might still get is ionization from heating - the laser heats a small spot in the air enough to make a plasma there.
 
  • #11
I mean excite (photoionize) i know that ionize is removing the electron completely. So your saying screw the whole exact process thing. If i have enough energy to cause great amounts of heat focused on a small area i will see a plasma dot?
 
  • #12
reese houseknecht said:
If i have enough energy to cause great amounts of heat focused on a small area i will see a plasma dot?
Yes.
 
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  • #13
so how many watts do i need, how can i calculate how many i will need to see a plasma dot? also am i targeting specific atoms or just any that are in the air, i say this because if I am putting billions of watts in a pulse 150ns does it really matter what atom is focused upon or will it just make plasme dot no matter what?
 
  • #14
You can't target specific atoms, the focus will always be much larger than the typical distance between atoms (and you can't track individual atoms with your setup anyway). The power will depend on various parameters.

What do you actually want to do?
 
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  • #15
I want to make a plasma dot to be very very vague. But i don't just want someone to tell me what exact laser i need to do it and that's that. I want to understand the process. So i understood photoionization and multiphoton ionization, now i found out that you don't have to be super specific. Just by focusing mass amounts of energy per pulse (watts) to a point and you will make plasma. Judging by my description of what i think happens you can tell i don't know to much about this piece of ionization or if your still ionizing at that point. Also what i want to know if electronvolts still matters in doing this?
 
  • #17
thank you for the post! see we don't want to do femtoseconds, we want to do nanoseconds. it says you can its just more dangerous. we plan on using anywhere from 5mw to 250mw laser at an adjustable frequency of 1hz-1000khz, based on there statistics then this should work. if i find the right values right?
 
  • #18
mW or MW?

200 MW with a suitable focus work as you can see. I'm not sure about lower values.

Even at 1 Hz, a 1 ns pulse at 200 MW leads to an average power of 0.2 W, which is quite a lot. At 1000 kHz you have an average power of 200 kW, which is completely unreasonable.
There is a reason these systems use fs pulses.
 
  • #19
milliwatts not mega
 
  • #20
Im just going to put here what i just emailed a professor so maybe you can help me out, I am a advanced programmer trying to build a project requiring lasers, so you can see my lack of expertise in the area. However, I have been doing a lot of research on how to photoionize air, such as using the eV of N2 in the air (15.58) and then calculating the wavelength i need to ionize that which is 80nm. That is the single photon process and is deadly because of its x-ray requirements. then i found the multiphoton process which was way better in terms of readily available lasers. The problem is i just don't understand it fully. Now i found out that if you focus massive amounts of watts down to a point you can achieve making a "plasma dot".
So i started with a simple equation W/Hz = J per second. so 0.25W/1Hz = 0.25J per second, which is 250mJ per second. I then do mJ/Pulse duration = Watts per pulse. So i then plugged in my values 250mJ/150e-9S = 1,666,666,666 Watts. This number is insanely huge and doesn't make sense why it would be this high. Is my equation right or am i messing something up? Also how many watts do i need to focus down to a point to achieve this "dot of plasma". I look forward to your response.
 
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  • #21
ok tell me if this is right, i can't do mJ / pulse to get Watts because Joules is directly related to Watts, not mJ. so really it should be 0.25J/150e-9 = 250,000,000. still a rediculously high number but maybe more correct then the last statement?
 
  • #22
If you have 250 mW average power delivering one 150 ns pulse every second, your average power during the pulse is about 1.7 MW. I think you forgot to divide by 150 in your previous post.
 

1. How is the energy of a photon calculated?

The energy of a photon can be calculated using the formula E=hf, where E is the energy in Joules, h is Planck's constant (6.626 x 10^-34 Joule seconds), and f is the frequency of the photon in Hertz.

2. What is the relationship between energy and frequency of a photon?

The energy of a photon is directly proportional to its frequency. This means that as the frequency increases, so does the energy of the photon.

3. Can the energy of a photon be negative?

No, the energy of a photon cannot be negative. It is always a positive value.

4. How many Joules are required to make a photon of a specific wavelength?

The number of Joules required to make a photon of a specific wavelength can be calculated using the formula E=hc/λ, where E is the energy in Joules, h is Planck's constant, c is the speed of light (3 x 10^8 meters per second), and λ is the wavelength in meters.

5. Is the energy of a photon affected by its polarization?

No, the energy of a photon is not affected by its polarization. The energy is solely determined by the frequency or wavelength of the photon.

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