How Do Red and Blue Laser Photon Emissions Compare at Equal Power?

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The discussion centers on comparing the rates of photon emission from red and blue lasers with equal power, specifically a red laser at 650 nm and a blue laser at 450 nm. The key equation involves the relationship between power, photon energy, and frequency, leading to the conclusion that red photons, having lower energy, require a higher emission rate to match the same power output. A participant initially miscalculated the ratio of photon emissions, arriving at an incorrect value of 0.6925 instead of the correct 1.44. The confusion stemmed from incorrect substitution of values, which was clarified by focusing on the wavelengths and their reciprocals. Ultimately, the correct approach confirmed that the red laser emits more photons than the blue laser due to the differences in photon energy.
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[SOLVED] I'm doing something wrong...

1. A red laser with a wavelength of 650 nm and a blue laser with a wavelength of 450 nn emit laser beams with the same light power. How do their rates of photon emission compare? Answer this by computing R_{red} / R_{blue}
2. P = Rhf = dNhf / dt = dE_{light} / dt
R = dN / dt
E_{light} = Nhf, where N is the number of photons
f = c / \lambda
h = 6.624E-32 Js
3. I have the f_{red} = 4.62 x 10^{14} s
and f_{blue} = 6.67 x 10^{14} s , it says their Powers are the same, so I go ahead and went and equaled:

P_{red} to P_{blue}, which is:P_{red}h_{red}f_{red} = P_{blue}h_{blue}f_{blue}

but I am tired and can't see the relevance, because when I multiplied times h [in Js] and then I divide like explained, I get .6925, and the ANSWER is 1.44.

Help? Please?
 
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Since red photons carry less energy per photon, there will need to be more of them. You just got your answer upside-down.

Just use your equation for E = Nhf, and be sure to take the ratio in the correct direction.
 
elephantorz said:
1. A red laser with a wavelength of 650 nm and a blue laser with a wavelength of 450 nn emit laser beams with the same light power. How do their rates of photon emission compare? Answer this by computing R_{red} / R_{blue}



2. P = Rhf = dNhf / dt = dE_{light} / dt
R = dN / dt
E_{light} = Nhf, where N is the number of photons
f = c / \lambda
h = 6.624E-32 Js



3. I have the f_{red} = 4.62 x 10^{14} s
and f_{blue} = 6.67 x 10^{14} s , it says their Powers are the same, so I go ahead and went and equaled:

P_{red} to P_{blue}, which is:


P_{red}h_{red}f_{red} = P_{blue}h_{blue}f_{blue}

but I am tired and can't see the relevance, because when I multiplied times h [in Js] and then I divide like explained, I get .6925, and the ANSWER is 1.44.

Help? Please?
Yes the answer is 1.44.

You got confused because you plugged in your number way too soon. Consider this:

Only the wavelengths are important. Obviously "R" here is used as "N," th number of photons per second? Well, P=P, you got that, and P=(Rhf)/t and f =c/ lamda.

Just substitute, see what cancel out, and use what you are left with.
 
I double checked the math, looks good.
 
Ok...that was...really weird, I guess I somehow reversed wavelengths? I simply did the reciprocal and it worked, thanks all!
 
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