Pulsing a diode laser with very long pulses and very low repetition rates

In summary, the conversation discusses the difference between average pulsed power and CW power for high power laser diodes, and how the needed optical peak power depends on the amount of cooling time between pulses. It also mentions the importance of heat sinking in determining the performance of a diode laser.
  • #1
r_daniel
2
0
Greetings,

I am an electronic engineer doing some research on high power laser diodes.

The problem I try to solve needs ~2300W of optical peak power coming from a high power laser diode.

The pulses must be with very long (30ms) at very low repetition rates (2Hz).
So,the duty cycle is DC = 0.06.


The calculations I do with the above parameters yield an average power
Pav= Ppeak x DC = 2300 x 0.06 = 138W.


Now the confusing part:

I have been told that the "average optical power" is not equal with the "optical power in CW mode" for very long pulses and very low repetition rates.

Hence, I can not use a laser diode which has 140W optical power in CW mode to get the needed ~2300W peak power.

Is that true ? Why ?

Are there any formulas that I can use to do the calculations for very long pulses to drive a laser diode ?
Any suggested books to read would be greate help..


Best Regards
chris
 
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  • #2
The reason that average pulsed power and CW power aren't necessarily the same is that when you first turn on a laser, you get better performance out of it for a brief time. Assuming that current injection happens quickly, the population inversion is larger than the threshold value for a brief time (as the photon density hasn't yet had time to build up), and the device is also at a lower temperature than when it has been on for a long time. So, if you imagine pulsing a laser as a series of turning a laser on, turning it off again, and letting it cool off before turning it on again, then it should be clear that average pulsed power is higher than CW power.

But at the long timescales we're talking about (especially for diode lasers), any electronic effects will be washed out, and the only factor that matters is heating. What matters is whether your laser has time to cool off between pulses, and ultimately, that depends on how well heat sunk it is.
 
  • #3
Thanks for the answer..

So, the needed optical peak power will depend on, if the diode has the time to be cooled enough between the pulses..
 

1. How do you define "long pulses" and "low repetition rates" in relation to diode laser pulsing?

"Long pulses" typically refer to pulses that are longer than 1 millisecond, while "low repetition rates" refer to pulses that are spaced more than 10 milliseconds apart. These terms may vary based on the specific application and laser setup.

2. What are the advantages of using long pulses and low repetition rates in diode laser pulsing?

Long pulses and low repetition rates allow for higher peak power and energy output, which can be beneficial for certain applications such as material processing and medical treatments. They also reduce the thermal load on the laser, increasing its reliability and lifespan.

3. What are the potential drawbacks of using long pulses and low repetition rates in diode laser pulsing?

One potential drawback is that the longer pulses and lower repetition rates can result in a lower average power output, which may not be suitable for some applications. Additionally, the longer pulse duration can increase the risk of thermal damage to the target material.

4. How do you select the appropriate pulse duration and repetition rate for a specific application?

The optimal pulse duration and repetition rate will depend on the specific application and desired outcome. It is important to consider factors such as the target material, required precision and speed, and potential thermal effects. Consulting with a laser expert and conducting thorough testing can help determine the best parameters for a given application.

5. Are there any safety considerations to keep in mind when using long pulses and low repetition rates in diode laser pulsing?

Yes, it is important to follow appropriate laser safety protocols and wear appropriate protective gear. The longer pulse duration can increase the risk of eye damage, so it is important to use proper eye protection. Additionally, the higher peak power and energy output may require additional precautions to prevent potential hazards.

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