Preface. Photograph of Participants. Introduction. Part I: Light emitting diodes. High efficiency silicon light emitting diodes; M.A. Green, et al. Dislocation-based silicon light emitting devices; M.A. Lourenço, et al. Efficient electroluminescence in alloyed silicon diodes; O.B. Gusev, et al. Light emitting devices based on silicon nanocrystals; A. Irrera, et al. Optical and electrical characteristics of LEDs fabricated from Si-nanocrystals embedded in SiO2; B. Garrido, et al. Electroluminescence in Si/SiO2 Layers; L. Heikkilö, et al. Reverse biased porous silicon light emitting diodes; S. Lazarouk. Strong blue light emission from ion implanted Si/SiO2 structures; W. Skorupa, et al. Si/Ge nanostructures for LED; G.E. Cirlin, et al. Part II: Silicon nanocrystals. Optical spectroscopy of single silicon quantum dots; J. Valenta, et al. Luminescence from Si/SiO2 nanostructures; Y. Kanemitsu. Electronic and dielectric properties of porous silicon; D. Kovalev, J. Diener. Silicon technology used for size-controlled silicon nanocrystals; M. Zacharias, et al. Structural and optical properties of silicon nanocrystals embedded in Silicon Oxide films; M. Miu, et al. Part III: Optical gain in silicon nanocrystals. Stimulated emission in silicon nanocrystals; L. Dal Negro, et al. Lasing effects in ultrasmall silicon nanoparticles; M.H. Nayfeh. On fast optical gain in silicon nanostructures; L. Khriachtchev, M. Räsänen. Experimental observation of optical amplification in silicon nanocrystals; M. Ivanda, et al. Optical amplification in nanocrystalline silicon superlattices; P.M. Fauchet, Jinhao Ruan.Optical gain from silicon nanocrystals: a critical perspective; A. Polman, R.G. Elliman. Optical gain measurements with variable stripe length technique; J. Valenta, et al. Part IV: Theory of silicon nanocrystals. Theory of silicon nanocrystals; C. Delerue, et al. Gain theory and models in silicon nanostructures; S. Ossicini, et al. Part V: Silicon/Germanium quantum dots and quantum cascade structures. Si-Ge quantum dot laser: What can we learn from III-V experience? N.N. Ledentsov. Promising SiGe superlattice and quantum well laser candidates; G. Sun, et al. Optical properties of arrays of Ge/Si quantum dots in electric field; A.V. Dvurechenskii, A.I. Yakimov. MBE of Si-Ge heterostructures with Ge nanocrystals; P.P. Pchelyakov, et al. Strain compensated Si/SiGe quantum cascade emitters grown on SiGe pseudosubstrates; L. Diehl, et al. Part VI: Terahertz silicon laser. Terahertz silicon laser: Intracenter optical pumping; S.G. Pavlov, et al. Silicon lasers based on shallow donor centers: Theoretical background and experimental results; V.N. Shastin, et al. Resonant states in modulation doped SiGe Heterostructures as a source of THz lasing; A.A. Prokofiev, et al. THz lasing of strained p-Ge and Si/Ge structures; M.S. Kagan. Terahertz emission from Silicon-Germanium quantum cascade; R.W Kelsall, et al. Part VII: Optical gain in Er doped Si nanocrystals. Towards an Er-doped Si nanocrystal sensitized waveguide laser: The thin line between gain and loss; P.G. Kik, A. Polman. Optical gain using nanocrystal sensitized Erbium; Jung H. Shin, et al. Excitation mechanism of Er photoluminescence in bulk Si and SiO2 with nanocryst

Lorenzo Pavesi is Professor of experimental physics at the university of Trento (Italy). Born the 21st of november 1961, he received his master degree in physics in 1985 at the university of trento and the phd in physics in 1990 at the ecole polytechnique federale of lausanne (switzerland). in 1990 he became assistant professor, an associate professor in 1999 and full professor in 2002 at the university of trento. He organized several international conferences, workshops and schools and is a frequent invited speaker. He manages several research projects, both national and european.