A 100 W sodium lamp is radiating light of wavelength `5890A`, uniformly in all directions, a. At what rate, photons are emitted from the lamp? b. At what distance from the lamp, the average flux is 1 photon(`cm^2-s)^-1?` c. What are the photon flux and photon density at 2m from the lamp?

A 100 W sodium lamp is radiating light of wavelength `5890A`, uniforml

1.	A 100 W sodium lamp is radiating light of wavelength `5890A`, uniformly in all directions, a. At what rate, photons are emitted from the lamp? b. At what distance from the lamp, the average flux is 1 photon(`cm^2-s)^-1?` c. What are the photon flux and photon density at 2m from the lamp?
Answer» The energy of photon is given by `E=hupsilon=(hc)/(lamda)=(1990xx10^(-28)J)/(lamda)` `=(1990xx10^(-28))/(5890A)=3376xx10^(-22)J` ..(i) Given that the lamp is emitting energy at the rate of `100Js^(-1)` (power=100 W). Hence, number of photons N emitted is given by `N=(100)/(3376xx10^(-22))cong3xx10^(20)` photons `s^(-1)` ..(ii) b. We regard the lamp as a point source. Therefore, at a distance r from the lamp, the light energy is uniformly distributed over the surface of sphere of radius r. So, N photons are crossing area `4pir^2` of spherical surface per second. So, flux at a distance r is given by `n=(N)/(4pir^2)` or `r=sqrt(((N)/(4pi)))` or `r=sqrt(((3xx10^(20))/4xx3.14))cm=488860km` ...(iii) So, at this distance, on the average one photon will cross through `1 cm^(2)` area normal to tradial direction. c. Photon flux at `t=2m` `n=sqrt(((3xx10^(20))/(4xx3.14)))cm=5.9xx10^(14)` photons `cm^(-2)` Average density of photons at `r=2m `is given by `rho=(3xx10^(20))/(4xx3.14xx(200)^(2)xx(3xx10^(10)))` `=2xx10^(4)` photons `cm^(-2)`

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A 100 W sodium lamp is radiating light of wavelength `5890A`, uniformly in all directions, a. At what rate, photons are emitted from the lamp? b. At what distance from the lamp, the average flux is 1 photon(`cm^2-s)^-1?` c. What are the photon flux and photon density at 2m from the lamp?

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