Title :
High-Performance Directly Modulated 1.3- μm Undoped InAs–InGaAs Quantum-Dot Lasers
Author :
Todaro, M.T. ; Salhi, A. ; Fortunato, L. ; Cingolani, R. ; Passaseo, A. ; De Vittorio, M. ; Della Casa, P. ; Ghiglieno, F. ; Bianco, L.
Author_Institution :
Nat. Nanotechnol. Lab. of CNR, INFM, Lecce
Abstract :
In this letter, we report on experimental results of directly modulated single-transverse mode 1.3-mum InAs-InGaAs quantum-dot (QD) lasers in a wide temperature range. A 3.125-Gb/s data modulation over temperature with an extinction ratio up to 10 dB is reported. Moreover, 10-Gb/s eye patterns at 15 degC and 50 degC and 5-Gb/s modulation in the whole explored temperature range (15 degC-85 degC) are demonstrated. These results were obtained by exploiting heterostructures containing six layers of high modal gain InAs QDs grown without incorporation of p-doping in the active region or tunnelling injection structure implementation. QD lasers exhibited a saturation modal gain as high as 36.3 cm-1, ground state lasing from short cavities down to 400-mum length and a characteristic temperature of about 110 K in a large temperature range between 15 degC and 85 degC
Keywords :
III-V semiconductors; gallium arsenide; ground states; indium compounds; laser cavity resonators; laser modes; optical communication equipment; optical fibre communication; optical modulation; quantum dot lasers; thermo-optical effects; tunnelling; 1.3 mum; 10 Gbit/s; 110 K; 15 to 85 degC; 3.125 Gbit/s; 5 Gbit/s; InAs-InGaAs; data modulation; direct modulation; extinction ratio; ground state lasing; heterostructures; high-performance lasers; optical fiber communication; quantum-dot lasers; saturation modal gain; short laser cavities; single-transverse mode lasers; tunnelling injection structure; undoped InAs-InGaAs lasers; Bandwidth; Land surface temperature; Laser modes; Laser stability; Laser theory; Quantum dot lasers; Quantum dots; Semiconductor lasers; Temperature distribution; Tunneling; In(Ga)As; modulation; quantum dots (QDs); semiconductor lasers;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2006.890045
