The laser resonator consists of two
distributed Bragg reflector (DBR) mirrors parallel to the wafer surface with an
active region consisting of one or more
quantum wells for the laser light generation in between. The planar DBR-mirrors consist of layers with alternating high and low refractive indices. Each layer has a thickness of a quarter of the laser wavelength in the material, yielding intensity reflectivities above 99%. High reflectivity mirrors are required in VCSELs to balance the short axial length of the gain region. In common VCSELs the upper and lower mirrors are doped as
p-type and
n-type materials, forming a
diode junction. In more complex structures, the p-type and n-type regions may be embedded between the mirrors, requiring a more complex semiconductor process to make electrical contact to the active region, but eliminating electrical power loss in the DBR structure. In laboratory investigation of VCSELs using new material systems, the active region may be
pumped by an external light source with a shorter
wavelength, usually another laser. This allows a VCSEL to be demonstrated without the additional problem of achieving good electrical performance; however such devices are not practical for most applications. VCSELs for wavelengths from 650 nm to 1300 nm are typically based on gallium arsenide (GaAs) wafers with DBRs formed from GaAs and
aluminium gallium arsenide (Al
xGa(1−
x)As). The GaAs–AlGaAs system is favored for constructing VCSELs because the
lattice constant of the material does not vary strongly as the composition is changed, permitting multiple "lattice-matched"
epitaxial layers to be grown on a GaAs substrate. However, the
refractive index of AlGaAs does vary relatively strongly as the Al fraction is increased, minimizing the number of layers required to form an efficient Bragg mirror compared to other candidate material systems. Furthermore, at high aluminium concentrations, an oxide can be formed from AlGaAs, and this oxide can be used to restrict the current in a VCSEL, enabling very low threshold currents. The main methods of restricting the current in a VCSEL are characterized by two types: ion-implanted VCSELs and oxide VCSELs. In the early 1990s, telecommunications companies tended to favor ion-implanted VCSELs. Ions, (often hydrogen ions, H+), were implanted into the VCSEL structure everywhere except the aperture of the VCSEL, destroying the lattice structure around the aperture, thus inhibiting the current. In the mid to late 1990s, companies moved towards the technology of oxide VCSELs. The current is confined in an oxide VCSEL by oxidizing the material around the aperture of the VCSEL. A high content aluminium layer that is grown within the VCSEL structure is the layer that is oxidized. Oxide VCSELs also often employ the ion implant production step. As a result, in the oxide VCSEL, the current path is confined by the ion implant and the oxide aperture. The initial acceptance of oxide VCSELs was plagued with concern about the apertures "popping off" due to the strain and defects of the oxidation layer. However, after much testing, the reliability of the structure has proven to be robust. As stated in one study by Hewlett Packard on oxide VCSELs, "The stress results show that the activation energy and the wearout lifetime of oxide VCSEL are similar to that of implant VCSEL emitting the same amount of output power." A production concern also plagued the industry when moving the oxide VCSELs from research and development to production mode. The oxidation rate of the oxide layer was highly dependent on the aluminium content. Any slight variation in aluminium would change the oxidation rate sometimes resulting in apertures that were either too big or too small to meet the specification standards. Longer wavelength devices, from 1300 nm to 2000 nm, have been demonstrated with at least the active region made of
indium phosphide. VCSELs at even higher wavelengths are experimental and usually optically pumped. 1310 nm VCSELs are desirable as the dispersion of silica-based
optical fiber is minimal in this wavelength range.
Special forms ; Multiple active region devices (aka bipolar cascade VCSELs) : Allows for differential quantum efficiency values in excess of 100% through carrier recycling ; VCSELs with tunnel junctions : Using a tunnel junction (n+p+), an electrically advantageous n-n+p+-p-i-n configuration can be built that also may beneficially influence other structural elements (e.g. in the form of a
Buried Tunnel Junction (BTJ)). ; Tunable VCSELs with micromechanically movable mirrors (
MEMS) : (either optically or electrically pumped ) ; Wafer-bonded or wafer-fused VCSEL: Combination of semiconductor materials that can be fabricated using different types of substrate wafers ; Monolithically optically pumped VCSELs : Two VCSELs on top of each other. One of them optically pumps the other one. ; VCSEL with longitudinally integrated monitor diode : A photodiode is integrated under the back mirror of the VCSEL. VCSEL with transversally integrated monitor diode: With suitable etching of the VCSEL's wafer, a resonant photodiode can be manufactured that may measure the light intensity of a neighboring VCSEL. ; VCSELs with external cavities (VECSELs) :
VECSELs are optically pumped with conventional laser diodes. This arrangement allows a larger area of the device to be pumped and therefore more power can be extracted – as much as 30 W. The external cavity also allows intracavity techniques such as frequency doubling, single frequency operation and femtosecond pulse modelocking. ;Vertical-cavity semiconductor optical amplifiers:
VCSOAs are optimized as amplifiers as opposed to oscillators. VCSOAs must be operated below threshold and thus require reduced mirror reflectivities for decreased feedback. In order to maximize the signal gain, these devices contain a large number of quantum wells (optically pumped devices have been demonstrated with 21–28 wells) and as a result exhibit single-pass gain values which are significantly larger than that of a typical VCSEL (roughly 5%). These structures operate as narrow linewidth (tens of GHz) amplifiers and may be implemented as amplifying filters. == Characteristics ==