Gain recovery dynamics in active type-II semiconductor heterostructures

Type-II heterostructures as active layers for semiconductor laser devices combine the advantages of a spectrally broad, temperature stable, and efficient gain with the potential for electrical injection pumping. Their intrinsic charge carrier relaxation dynamics limit the maximum achievable repetition rates beyond any constraints of cavity design or heat dissipation. Of particular interest are the initial build up of gain after high-energy injection and the gain recovery dynamics following depletion through a stimulated emission process. The latter simulates the operation condition of a pulsed laser or semiconductor optical amplifier. An optical pump pulse injects hot charge carriers that eventually build up broad spectral gain in a model (Ga,In)As/GaAs/Ga(As,Sb) heterostructure. The surplus energies of the optical pump mimic the electron energies typical for electrical injection. Subsequently, a second laser pulse tuned to the broad spectral gain region depletes the population inversion through stimulated emission. The spectrally resolved nonlinear transmission dynamics reveal gain recovery times as fast as 5 ps. These data define the intrinsic limit for the highest laser repetition rate possible with this material system in the range of 100 GHz. The experimental results are analyzed using a microscopic many-body theory identifying the origins of the broad gain spectrum.

[1]  G. Cerullo,et al.  Ultrafast spectroscopy: state of the art and open challenges. , 2019, Journal of the American Chemical Society.

[2]  S. Koch,et al.  Mode-locking in vertical external-cavity surface-emitting lasers with type-II quantum-well configurations , 2019, Applied Physics Letters.

[3]  U. Keller,et al.  Watt-level 10-gigahertz solid-state laser enabled by self-defocusing nonlinearities in an aperiodically poled crystal , 2017, Nature Communications.

[4]  S. Koch,et al.  Electrical injection type-II (GaIn)As/Ga(AsSb)/(GaIn)As single ‘W’-quantum well laser at 1.2 µm , 2016 .

[5]  M. Koch,et al.  Gain spectroscopy of a type-II VECSEL chip , 2016, 1608.05250.

[6]  Saulius Juodkazis,et al.  Ultrafast laser processing of materials: from science to industry , 2016, Light: Science & Applications.

[7]  M. Koch,et al.  Type-II vertical-external-cavity surface-emitting laser with Watt level output powers at 1.2 μm , 2016 .

[8]  A. Strittmatter,et al.  Fast gain and phase recovery of semiconductor optical amplifiers based on submonolayer quantum dots , 2015 .

[9]  J V Moloney,et al.  Novel type-II material system for laser applications in the near-infrared regime. , 2015, AIP advances.

[10]  Mitchell A Jackson,et al.  Femtosecond laser-assisted cataract surgery. , 2013, Journal of cataract and refractive surgery.

[11]  T. Kippenberg,et al.  Microresonator-Based Optical Frequency Combs , 2011, Science.

[12]  Adrian H. Quarterman,et al.  A passively mode-locked external-cavity semiconductor laser emitting 60-fs pulses , 2009 .

[13]  John T. M. Kennis,et al.  Ultrafast transient absorption spectroscopy: principles and application to photosynthetic systems , 2009, Photosynthesis Research.

[14]  M. Kuntz,et al.  Hybrid mode-locking in a 40 GHz monolithic quantum dot laser , 2009, CLEO/Europe - EQEC 2009 - European Conference on Lasers and Electro-Optics and the European Quantum Electronics Conference.

[15]  Jorg Hader,et al.  Microscopic analysis of mid-infrared type-II "w" diode lasers , 2009 .

[16]  E. Rafailov,et al.  Mode-locked quantum-dot lasers , 2007 .

[17]  M. Laemmlin,et al.  Complete ground state gain recovery after ultrashort double pulses in quantum dot based semiconductor optical amplifier , 2007 .

[18]  Nikolai N. Ledentsov,et al.  Distortion-free optical amplification of 20-80 GHz modelocked laser pulses at 1.3 [micro sign]m using quantum dots , 2006 .

[19]  Jasprit Singh,et al.  Gain dynamics and ultrafast spectral hole burning in In(Ga)As self-organized quantum dots , 2002 .

[20]  T. W. Berg,et al.  Ultrafast gain recovery and modulation limitations in self-assembled quantum-dot devices , 2001, IEEE Photonics Technology Letters.

[21]  Gregory Raybon,et al.  Carrier capture times in 1.5 μm multiple quantum well optical amplifiers , 1992 .

[22]  U. Koren,et al.  Ultrafast gain dynamics in 1.5 μm multiple quantum well optical amplifiers , 1991 .

[23]  Stephan W Koch,et al.  Quantum theory of the optical and electronic properties of semiconductors, fifth edition , 2009 .

[24]  T. Maiman Stimulated Optical Radiation in Ruby , 1960, Nature.