780 nm Oxide-Confined VCSEL With 13.5 Gb/s Error-Free Data Transmission

“…In addition, the lattice temperature is calculated by solving for the steady-state solution of (11), where e r and e z represent the unit vectors in the radial and the z-direction.…”

“…This equation assumes a local thermal equilibrium between the charge carriers and the lattice solving for a single local temperature T. The air surrounding the samples is assumed to be a good insulator by setting the heat flux to zero and the bottom of the substrate is fixed to the ambient temperature of 300 K. The heat source used in (11) takes into account joule heating, heat generated by recombination, Thomson heat and heat loss by radiation [37]. The radiative heat loss is modeled by the optical generation rate G opt and the energy of the photon, which is calculated using Planck constant h and the photon frequency f. To also include the anisotropic thermal conductivity in the DBR layers, the thermal conductivity κ was modified in the z-direction resulting in a value called κ aniso .…”

“…are triggered by the defects forming in high-stress regions like the mesa sidewall or the edge of the oxide aperture [9,10]. The stress in those regions originates from the wet-oxidation process used to produce the oxide apertures, which is used in various VCSELs emitting in the wavelength range of 780-1150 nm [11][12][13][14]. In this process, an Al x Ga 1−x As layer with a high aluminum concentration x is exposed to a high temperature water vapor between 350 • C and 500 • C [15].…”

Electrical-stress driven oxidation in 940 nm oxide-confined VCSEL

“…In addition, the lattice temperature is calculated by solving for the steady-state solution of (11), where e r and e z represent the unit vectors in the radial and the z-direction.…”

“…This equation assumes a local thermal equilibrium between the charge carriers and the lattice solving for a single local temperature T. The air surrounding the samples is assumed to be a good insulator by setting the heat flux to zero and the bottom of the substrate is fixed to the ambient temperature of 300 K. The heat source used in (11) takes into account joule heating, heat generated by recombination, Thomson heat and heat loss by radiation [37]. The radiative heat loss is modeled by the optical generation rate G opt and the energy of the photon, which is calculated using Planck constant h and the photon frequency f. To also include the anisotropic thermal conductivity in the DBR layers, the thermal conductivity κ was modified in the z-direction resulting in a value called κ aniso .…”

“…are triggered by the defects forming in high-stress regions like the mesa sidewall or the edge of the oxide aperture [9,10]. The stress in those regions originates from the wet-oxidation process used to produce the oxide apertures, which is used in various VCSELs emitting in the wavelength range of 780-1150 nm [11][12][13][14]. In this process, an Al x Ga 1−x As layer with a high aluminum concentration x is exposed to a high temperature water vapor between 350 • C and 500 • C [15].…”

Electrical-stress driven oxidation in 940 nm oxide-confined VCSEL

“…The VCSEL presents a great number of merits such as greater coupling efficiency [17], single-mode operation [18], high speed and lesser threshold [19], reliability [20], enhanced quantum efficiency and optical power [21].The improvements of VCSEL compared to distributed bragg reflector (DBR) and distributed feedback (DFB) laser are little power consumption and low price because of its compactness [22].…”

Effect of Optical Filtering for Error-free Transmission in Optical Networks

Oxide-Confined VCSELs for High-Speed Optical Interconnects