Answer: [tex]1.593*10^{17} photons[/tex] released if the laser is used 0.056 s during the surgery
Explanation:
First, you have to calculate the energy of each photon according to Einstein's theoty, given by:
[tex]E =\frac{hc}{\lambda}[/tex]
Where [tex]\lambda[/tex] is the wavelength, [tex]h[/tex] is the Planck's constant and [tex]h[/tex] is the speed of light
[tex]h = 6.626*10^{-34} \frac{m^{2} kg }{s}[/tex] -> Planck's constant
[tex]c = 3*10^{8} \frac{m}{s}[/tex] -> Speed of light
So, replacing in the equation:
[tex]E =\frac{ 6.626*10^{-34} \frac{m^{2} kg }{s}*3*10^{8} \frac{m}{s}}{514*10^-9 m}[/tex]
Then, the energy of each released photon by the laser is:
[tex]E = 3.867*10^{-19} \frac{J}{photons}[/tex]
After, you do the inverse of the energy per phothon and as a result, you will have the number of photons in a Joule of energy:
[tex]\frac{1}{3.867*10^{-19}} = 2.586*10^{18} \frac{photons}{J}[/tex]
The power of the laser is 1.1 W, or 1.1 J/s, that means that you can calculate how many photons the laser realease every second:
[tex]2.586*10^{18}\frac{photons}{J} * 1.1 \frac{J}{s} = 2.844*10^{18} \frac{photons}{s}[/tex]
And by doing a simple rule of three, if [tex]2.844*10^{18} photons[/tex] are released every second, then in 0.056 s:
[tex]0.056 s*2.844*10^{18} \frac{photons}{s} = 1.593*10^{17} photons[/tex] are released during the surgery
