The photodiode (PD) is a variation on the familiar silicon photocell used in solar power conversion.  But the photodiode is constructed and operated for optimum sensitivity and accuracy, while the solar cell is optimized to generate maximum electrical power.

The photodiode is an ordinary diode in which the diode junction is exposed to light.  Photons with sufficient energy generate free electron-hole pairs in the diode junction, or "depletion layer".  The free electrons travel through the N-layer and the holes move through the P-layer, thus generating a backward photocurrent.

Link: A simple model of a photodiode

In either mode of operation, the photocurrent I is proportional to the power P of the light illuminating the photodiode.

I = K_PD P,

where K_PD is the responsivity of the photodiode.  K_PD depends on the diode construction, the wavelength of the light, and on the temperature.  The photodiode is a quantum device.  Almost every incident photon generates an electron-hole charge pair.

We therefore have I = e N Q, where Q is the quantum efficiency and e is the magnitude of the electron's charge.  Q is less than or equal to 100 %.  The optical power is equal to the number of photons per second, N, times the energy per photon,  E = hc/λ.

P = N E = Nhc/λ

The PD responsivity therefore is given by K_PD = Qeλ/(hc).  The responsivity of a typical Hamamatsu model S2386 silicon photodiode is shown on the right.  The value of the responsivity is K_PD = 0.43 A/W at 632.8 nm wavelength.  The quantum efficiency at 632.8 nm is Q = K_PDE /e = 84 % .

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A photon absorbed by the photocathode can liberate a free electrons into the vacuum tube, via the photoelectric effect.  The quantum efficiency Q of a PMT is usually 25% or less, so not every photon liberates an electron.  Since the photocathode is biased with a large negative voltage, HV = 500–2000 V, the electron is accelerated toward a second electrode called a "dynode." 

The electron gains speed and therefore kinetic energy while traveling toward the first dynode. It strikes the first dynode hard enough to generate about 10 new free electrons, which are accelerated to the second dynode, where each of these electrons generates 10 more electrons, and so on.  The final electrode, the anode, collects the electrons and delivers them to an external circuit for measurement.  In a nine-dynode PMT the ten-fold multiplication by each dynode delivers one billion electrons to the external circuit for each photon detected. 

The voltage divider network shown in the figure on the right carries a steady current (–HV/R_tot) which supplies the electrons for multiplication at each dynode.  The desired signal is the current generated at the anode,

I = NQeG

where N is the number of photons hitting the photocathode per second, Q is the cathode quantum efficiency and G is the photomultiplier gain, which is 10⁹ in the example above.

The minimum detectable light level is much lower for the PMT than for the PD.  The output anode current of the PMT an be measured directly with a pico-ammeter, or it can be determined by measuring the voltage across a load resistor connected from the anode to ground.

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