497 research outputs found
Recent Developments In Monolithic Phase-Locked Semiconductor Laser Arrays
Coherent combination of the power of several semiconductor lasers fabricated on the same substrate has been the subject of an intense research effort in recent years, the main motivation being to obtain higher power levels than those available from a single laser in a stable radiation pattern. Best results reported so far include 2.6 Watts cw emitted power and less than 10 far-field angle (in the array plane) in arrays where all the lasers are electrically connected in parallel. A different type of coherent array, where each element has a separate contact, has been recently demonstrated. While requiring the more complex two-level metallization technology, applying a separate contact to each laser provides an additional degree of freedom in the design and the operation of monolithic arrays. The separate contacts can be employed to tailor the near-field and far-field distributions and to compensate for device-to-device nonuniformities. Furthermore, the control of the currents of the array elements allows the performance of a variety of other functions, such as beam scanning, spectral mode control, wavelength tuning and control of the mutual coherence between array elements
Longitudinal-mode control in integrated semiconductor laser phased arrays by phase velocity matching
The spectrum of semiconductor laser arrays with separate contacts is investigated. It is demonstrated that the individual laser currents can be selected such that the array operates in a single longitudinal mode in contrast to the multimode nature of its individual constituents. Moreover, it is possible to tune the lasing frequency by varying the laser currents. Wavelength tuning range of ~50 Ã…, with tuning rate of ~5 Ã…/mA, is demonstrated. It is suggested that these spectral features, characteristic of lasers which are coupled in parallel, result from the strong frequency dependence of their spatial mode pattern near the phase-matching frequency of their coupled waveguides
Controlled fundamental supermode operation of phase-locked arrays of gain-guided diode lasers
Uniform semiconductor laser arrays tend to oscillate in a superposition of their supermodes, thus leading to large beam divergence and spectral spread. Discrimination among the supermodes in phase-locked arrays is discussed theoretically. It is shown that supermode discrimination in gain-guided arrays, in favor of the fundamental supermode, is made possible by the near-field interference patterns which result from the complex optical fields of the gain-guided lasers. A fundamental supermode operation is demonstrated, for the first time, in GaAlAs/GaAs gain-guided laser arrays. This is achieved by control of the current (gain) profile across the array by means of individual laser contacts
Chirped arrays of diode lasers for supermode control
We propose nonuniform structures of phase-locked diode lasers, which make it possible to discriminate efficiently against all the higher order array supermodes (lateral modes). In these nonuniform arrays, the effective mode index in each channel varies across the array. Consequently, the envelopes of the various supermodes, including the highest order one, differ significantly from each other. Thus, by proper tailoring of the gain distribution across the array, one can conveniently select the fundamental supermode. Such fundamental supermode oscillation is essential in order to obtain single lobe, diffraction limited beams and minimal spectral spread from phase-locked laser arrays
Coupling mechanism of gain-guided integrated semiconductor laser arrays
It is shown that a gain-guided laser array couples via propagating fields rather than the evanescent mode coupling typically responsible for directional coupling in passive (directional couplers) and active (laser array) devices. We show that these phase-locked modes exhibit an interference pattern, in the junction plane, which arises from the curvature of the phase fronts of optical fields of the interacting lasers. The experimental results are interpreted with the aid of a simple theoretical model, and the effect of the observed mode pattern on the coupling of gain-guided lasers is discussed
Control of mutual phase locking of monolithically integrated semiconductor lasers
The mutual coherence of two coupled semiconductor lasers is investigated experimentally. It is demonstrated that by varying the gain in the overlap region, the degree of phase coherence can be continuously controlled. The quantitative characterization of the degree of phase coherence by fringe visibility is demonstrated
Excitonic lasing in semiconductor quantum wires
Direct experimental evidences for excitonic lasing is obtained in optically
pumped V-groove quantum wire structures. We demonstrate that laser emission at
a temperature of 10 K arises from a population inversion of localized excitons
within the inhomogenously-broadened luminescence line. At the lasing threshold,
we estimate a maximum exciton density of about 1.8 105cm-1.Comment: 11 pages, 4 figures, submitted to Phys. Rev.
Single contact tailored gain phased array of semiconductor lasers
We demonstrate a single contact tailored gain-guided array in which the gain profile across the array is made strongly asymmetric by varying the width of the contact stripes. A proton isolated array of six (GaAl)As lasers with 5-µm separations and widths varying linearly between 3 and 8 µm had a single lobed far field 2° wide, close to the diffraction limit for a single supermode. Fabrication of this device is simple, and suited to large-scale processing techniques. We also show that in such an asymmetric gain-guided array the fundamental mode is favored over higher order modes, and that higher order modes can have single lobed far-field patterns differing only slightly from that of the fundamental
Non-orthogonal Theory of Polarons and Application to Pyramidal Quantum Dots
We present a general theory for semiconductor polarons in the framework of
the Froehlich interaction between electrons and phonons. The latter is
investigated using non-commuting phonon creation/annihilation operators
associated with a natural set of non-orthogonal modes. This setting proves
effective for mathematical simplification and physical interpretation and
reveals a nested coupling structure of the Froehlich interaction. The theory is
non-perturbative and well adapted for strong electron-phonon coupling, such as
found in quantum dot (QD) structures. For those particular structures we
introduce a minimal model that allows the computation and qualitative
prediction of the spectrum and geometry of polarons. The model uses a generic
non-orthogonal polaron basis, baptized the "natural basis". Accidental and
symmetry-related electronic degeneracies are studied in detail and are shown to
generate unentangled zero-shift polarons, which we consistently eliminate. As a
practical example, these developments are applied to realistic pyramidal GaAs
QDs. The energy spectrum and the 3D-geometry of polarons are computed and
analyzed, and prove that realistic pyramidal QDs clearly fall in the regime of
strong coupling. Further investigation reveals an unexpected substructure of
"weakly coupled strong coupling regimes", a concept originating from overlap
considerations. Using Bennett's entanglement measure, we finally propose a
heuristic quantification of the coupling strength in QDs.Comment: 17 pages, 11 figures, 3 table
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