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1.INTRODUCTIONAn example for the schematic design of a VECSEL [1,2] is shown in Fig. 1. The main building block is the quantum-well (QW) gain material on top of the high-reflectivity Bragg mirror (DBR). Together, these constitute the ‘active mirror’ or VECSEL chip. The cavity with an extension in the centimeter range is completed by a high-reflectivity external mirror, which is also used for the out-coupling of the laser emission. The VECSEL chip is mounted on a heat sink which typically consists of a diamond heat spreader on top of a copper block. The QWs are optically pumped using commercially available high-power pump sources. Figure 1 shows a simple generic VECSEL layout. Besides the depicted linear cavity arrangement, also more elaborate geometries with so-called V-cavities or even more complicated structures are in practical use. A wide variety of semiconductor materials can be used as the VECSEL gain medium allowing for lasing at many desirable wave lengths [2]. To further extend this range, one uses intracavity frequency up-conversion with suitable nonlinear crystals. Since VECSELs are optically pumped, one can realize close to circular beam profiles. Furthermore, the emission intensity scales with the pumped area such that high-power performance is possible. The wide range of envisioned VECSEL applications includes large-area projection, displays in automobiles, laser television, welding, micromachining, nonlinear microscopy, laser-induced breakdown spectroscopy, underwater photonics, and the realization of powerful THz emitters. 2.MICROSCOPIC APPROACHIn many ways, the VECSEL can be considered a physicist’s dream system since virtually all aspects can be well-controlled experimentally and – at least in principle – computed theoretically. It all starts from the carrier generation via optical absorption of the pump beam in energetically high states well above the band gap. These carriers then relax into energetically lower states via carrier-carrier and carrier-phonon scattering. Both processes lead to the redistribution of the carrier populations into Fermi-Dirac functions. Since the Coulomb scattering conserves the total electronic energy, it leads to the establishment of a carrier specific electronic temperature. Through the phonon coupling, the electron-hole system loses energy to the lattice which leads to carrier cooling and lattice heating. All of these processes happen within the QWs and barriers. However, the heat is subsequently also transferred into the surrounding material, into the Bragg mirror, and from there into the heat sink. These heat-spreading effects are governed by classical drift and diffusion processes. For too strong pumping, or if the pump energy is too close to the band gap, the filling of the carrier states leads to absorption bleaching, which renders the pumping inefficient. The degree of this Pauli blocking depends on the interplay between the generation of carriers and their subsequent relaxation into the unpumped, energetically lower states. The relaxed carriers then contribute to the QW gain, which directly depends on the detailed carrier distribution functions. Carriers are removed from the system via the desired stimulated recombination, by the unwanted but intrinsically unavoidable spontaneous emission, and by nonradiative (defect, Auger and intersubband) recombination processes. In order to treat all these effects correctly, one systematically has to account for the carrier Coulomb and phonon-scattering processes as well as their interactions with the light fields, i.e., the pump beam and the generated laser emission. We treat the optically excited semiconductors as fully quantum-mechanical many-body systems whose properties are governed by the Coulomb interaction and coupling between charge carriers, photons, and phonons [3,4]. Hence, the total Hamiltonian contains the band structure part H0, the light-matter interaction Hlm, the Coulomb-interaction HCoul among the charge carriers, as well as the coupling to phonons, Since the system of electronic excitations has overwhelmingly many degrees of freedom, an attempt to solve the Schrödinger equation for the many-body wave function is not feasible with current computational resources. Therefore, we choose the alternative, quantum-dynamic approach based on the Heisenberg equations of motion. Evaluating the commutators with the total Hamiltonian H, we derive the equations of motion for the relevant operator combinations. Focusing on the electronic excitations governing the response of the QW gain medium in the VECSEL systems, we need to compute the carrier distributions and the optically induced polarization (induced dipole density) whose expectation value enters Maxwell’s wave equation as a source. With this input, we can then evaluate the electromagnetic field of the full system and determine, e.g., absorption and gain properties. The microscopic polarization and its complex conjugate are the off-diagonal elements of the reduced single-particle density matrix. The diagonal elements are the electron and hole state-occupation probabilities, i.e., the carrier distribution functions. The dynamic equations for these single-particle quantities couple to two-particle correlations (doublets) due to the interaction parts of the Hamiltonian. Since the equations for the doublets involve three-particle quantities (triplets) which then couple to quadruplets etc., we encounter the infinite equation hierarchy, which is characteristic for quantum-mechanical many-body problems. Schematically, the equation of motion for the expectation value <N> of an N-particle operator has the form Here, F[<N>] describes the mean-field (Hartree-Fock) contributions, whereas the many-body interactions lead to a coupling to <N+1>-particle correlations, symbolically denoted by the functional I[<N+1>]. The generic structure of the dynamic equation for <N> is typical of a many-body system with single-particle contributions and pairwise particle interactions. The ever-rising hierarchy couples the N-particle expectation values to the N+1-particle correlations. Since we want to treat all the correlations of a given order systematically with the same level of accuracy, we decompose all expectation values into singlets, correlated doublets, correlated triplets and higher order correlations. As symbolically shown in Fig. 2, we identify the correlated parts (shaded areas in Fig. 2) as the full expectation values minus their lower-order factorizable ingredients. This approach is based on the idea that any given <N>-particle quantity can be expressed in terms of a consistent factorization (see Fig. 2) into:
In many ways, the different clusters can be considered as moments and cumulants (e.g., variance and kurtosis) of quantum-statistical distributions. Since the relatively high electron-hole-pair density in a VECSEL induces strong screening, dephasing, and particle scattering effects, we expect higher-order correlations to be of reduced significance. We therefore truncate the equation hierarchy with the help of the cluster-expansion method. As relevant singlet contributions, we treat the electron and hole occupation probabilities and the optical polarization. Doublets include exciton populations, photon-assisted polarizations etc. This correlated-cluster expansion and truncation procedure allows us to account for all the important physical properties of our system and to avoid all the notorious problems that typically arise in ad-hoc approximations. In contrast to such unsystematic treatments, our approach assures the consistent evaluation of all the contributions at the same correlation level. In particular, we fully include the intrinsic balancing effects such as the compensation of the excitation-induced excitonic blue shift by the red shift of the band gap or the cancellations between diagonal and off-diagonal contributions in the microscopic dephasing analysis. The cluster truncation casts the equation hierarchy into a closed form [4]. However, due to the very large number of quantum states in the semiconductor system, one still has to deal with extended sets of integro-differential equations. After the integral discretization, we are left with huge numbers (often many hundreds of millions) of coupled ordinary differential equations (ODEs). The efficient choice of the discretization scheme and the numerical treatment of the ODEs constitute significant challenges in their own right. The successful numerical implementation requires advanced computation strategies and dedicated high-performance hardware. 3.QUANTUM DESIGN OF VECSELSFor the design and optimization of real VECSELs [5], we have to implement a full multiband approach in order to account for the quantum confinement and strain effects in the QWs. Using the appropriate band structure theory, we will compute the relevant single-particle dispersions in H0 of Eq. (1) for the particular heterostructure system under investigation. In most cases, we will apply the multiband k·p approach with optimized parameters obtained from detailed theory-experiment comparisons or from an analysis of density-functional calculations. We use the k·p wave functions to evaluate the interband dipole and Coulomb matrix elements in Hlm and HCoul of Eq. (1), respectively. In order to account for the dielectric environment, we will adopt our filter function scheme to relate the emission from a free-standing QW to the full microcavity output. Typically, one uses around 10 QWs as the resonantly periodic VECSEL gain medium. The precise number is a compromise between the pump power needed to achieve inversion (i.e., the laser threshold) and the gain provided by the QWs. Since the laser light propagates perpendicular to these wells, there is not much round-trip amplification. Hence, one has to make sure that the available gain is optimally utilized, i.e., the spectral gain maximum and the cavity mode have to be very well aligned under lasing conditions. In this context, the thermal problems need particular consideration. Heat is generated via the so-called quantum defect caused by the excess energy pumped into the system when generating carriers at frequencies well above the lasing frequency. Those carriers have to relax into lower states via carrier scattering and phonon emission before they can contribute to the lasing. Furthermore, the nonradiative carrier loss processes significantly increase the thermal carrier energy. Part of this heat is removed by providing a proper heat sink. To account for this effect, we complement our microscopic equations with classical drift-diffusion models for the heat transfer from the optically pumped active region to the lattice and the heat sink. In comparison to most standard semiconductor-laser models, the main improvements of our microscopic approach are:
Due to the complex interplay of the heat generation and dissipation processes, it is a priori not known, at which effective temperature the system will operate, if it works at all. To make matters worse, the temperature of the carrier plasma, i.e., the electronic temperature, and the temperatures of the host lattice and of the heat sink are generally all different and depend on the operating conditions. Since semiconductor gain/absorption, radiative and nonradiative losses as well as cavity resonance all change with temperature, one directly sees the strength of our approach, which self-consistently evaluates all of these properties together with the thermal analysis. 4.NONEQUILIBRIUM ASPECTS IN VECSEL MODELINGUnder many conditions, it is not sufficient to approximate the carriers in VECSELs by a quasi-equilibrium system, instead so-called nonequilibrium effects become important. One nonequilibrium situation is realized under high-power laser-operation conditions, where the stimulated carrier recombination strongly depletes those states that are resonant with the laser emission wavelength. The state-selective rapid interband transitions lead to kinetic hole-burning, i.e. nonequilibrium deviations of the actual carrier distribution from quasi-equilibrium Fermi-Dirac distributions even in steady-state operation. The depth and extend of these kinetic holes is ultimately determined by the balance between the stimulated carrier removal and the replenishing of the carrier populations via carrier-carrier and carrier-phonon scattering. Other important aspects are the overall carrier pumping (optical or though current injection) and the heat balance. The pumping adds carriers in energetically higher states from where they have to loose energy before they contribute to the lasing. As discussed above, this energy loss leads to carrier and lattice heating, requiring sophisticated thermal balancing to maintain stationary high-power operation. Another important nonequilibrium situation concerns the ultra-short pulse generation in VECSELs. To determine the ultimate limit for the shortest possible pulse duration in a semiconductor medium has intrigued and challenged physicists for many decades. The available gain bandwidth of semiconductor heterostructures suggests that it should be possible to generate ultrashort optical pulses in the regime of few femtoseconds or less. However, state-of-the-art experimental verifications so far are hardly able to go much below the regime of 100s of fs. For the microscopic modelling of the VECSEL nonequilibrium effects, we use the semiconductor Bloch equations (SBE), i.e. the coupled equations of motion for the carrier occupation probabilities of the different band states and the optically induced interband polarizations between those states [3,4]. To obtain some basic insights into the significance of nonequilibrium features, we are numerically integrate the SBE for a situation typical for mode locked pulsed operation. The quantum wells are inverted and the distributions are in thermal equilibrium. Then the system is hit by a short, intense light pulse with a central frequency corresponding to the energy of maximum quantum well gain. This pulse depletes the carrier inversion due to stimulated emission leading to a so-called spectral hole in the distributions. If the pulse is strong enough, it will eventually lead to a distribution in the well for which the system becomes transparent. In an ideal system with equal electron and hole masses, a single frequency pulse and no carrier re-distributions due to scattering, the remainder of the pulse would pass through the well without further modifications of the system. However, as can be seen in Figure 3, in a realistic situation the pulse causes further changes in the distributions due to changes from absorptive-to gain-behavior in a Rabi-flopping manner. Without carrier re-distributions due to electron-electron and electron-hole scattering, the distributions become static once the pulse has passed the system. Eventually, the lost carriers will be re-filled by the pump light and subsequent carrier relaxation from the barriers to the wells (barrier-pumping is assumed here). However, this happens on a rather slow timescale of typically ten(s) of picoseconds. Taking into account the carrier scatterings explicitly reveals a far more complex dynamic. As mentioned, the pump-injection of carriers happens on a picosecond-timescale. This involves carrier transitions between different subbands which is slow due to the rather large required energy transfer. However, Coulomb scattering within each subband takes place on a much faster timescale of only ten(s) of femtoseconds. This leads to significant modifications already during the presence of the light-pulse. Carriers from higher and lower momentum states re-fill the spectral hole at the lasing frequency during and after the pulse. Eventually, this leads to a hot equilibrium distribution that is cooled down on a slower timescale by phonon scatterings. The intra-subband scattering also allows for the pulse to deplete more carriers due to stimulated emission than would be possible otherwise (se Fig. 4). This means that the amplification of the pulse is also much stronger than one would assume otherwise. The scattering re-fills the states near the center frequency of the pulse while the pulse is still there and the pulse can stimulate these additional carriers to recombine. Since the intraband scattering time is on the scale of tens of femtoseconds, this effect becomes more pronounced the longer the pulse is. In our case, for a 15fs pulse it only enhances the total amount of carriers lost to stimulated emission by a few tens of percent. For a 100fs pulse it almost doubles the amount. This simulation clearly demonstrates the underlying microscopic complexity of a typical laser situation. The microscopic scatterings dramatically alter the distribution functions already during the presence of a femtosecond pulse. This will modify the amplification of the pulse – its overall amplification as well as its spectral dependence. In turn, this will lead alter the phase changes experienced in the quantum well medium. Overall, these processes have to be taken into account seriously if one attempts to model mode locked VECSELs or tries to determine optimal solutions like, the shortest possible pulse, the shortest possible pulse repetition or the strongest possible pulses. Acknowledgements:This work is supported by AFOSR (grant FA9550-10-1-0064) and by the German Science Foundation (DFG: GRK1782). ReferencesM. Kuznetsov,
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