kcðlmÞ¼
hc
Eg¼
1 : 240
EgðeVÞð 5 : 4 ÞThe cutoff wavelength is about 1.06μm for Si and 1.6μm for Ge. For longer
wavelengths the photon energy is not sufficient to excite an electron from the
valence to the conduction band in these two materials. Thus other semiconductor
alloys have been developed for long wavelength operation.
Example 5.3Consider a GaAs photodiode that has a bandgap energy of
1.43 eV at 300 K. What is the cutoff wavelength of this device?Solution: From Eq. (5.2) the long-wavelength cutoff iskc¼
hc
Eg¼
ðÞ 6 : 625 10 ^34 JsðÞ 3 108 m=s
ð 1 :43 eVÞðÞ 1 : 6 10 ^19 J=eV¼869 nmThis GaAs photodiode will not respond to photons that have a wavelength
greater than 869 nm.At the lower-wavelength end, the photon response cuts off as a result of the very
large values ofαsat the shorter wavelengths. In this case, the photons are absorbed
very close to the photodetector surface, where the recombination time of the
0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8
Wavelength (μm)Light absorption coefficient (cm-1)102101103104Fig. 5.3 Optical absorption 105
coefficient as a function of
wavelength of several
different photodetector
materials
5.1 ThepinPhotodetector 123