Title :
Feasibility of laser action at 1550 nm by direct gap type I GeC/GeSiSn heterojunctions
Author :
Mukhopadhyay, Bratati ; Sen, Gopa ; Basu, P.K.
Author_Institution :
Inst. of Radio Phys. & Electron., Univ. of Calcutta, Kolkata, India
Abstract :
Application of tensile strain in Ge lowers the G valley below the L valleys but the direct gap is reduced from the value in unstrained Ge. We considered Ge1-qCq (C <4%) active layers with Ge1-x-ySixSny as the barrier and estimated the range of compositions in the active and barrier layers to yield direct gap (~0.8 eV) type I alignment by using model solid theory. We have chosen a composition to give the critical thickness as high as possible and estimated its absorption coefficients by using theoretical expressions. The linear gain spectra and transparency carrier density for the chosen heterostructure are then estimated. The threshold current density for an optimized structure may be approximately 300 A/cm2.
Keywords :
absorption coefficients; buffer layers; current density; energy gap; germanium compounds; piezo-optical effects; self-induced transparency; semiconductor heterojunctions; semiconductor lasers; semiconductor materials; silicon compounds; solid theory; GeC-GeSiSn; absorption coefficient; barrier layers; direct gap type I heterojunctions; heterostructure; lasing action; layer thickness; linear gain spectra; model solid theory; tensile strain; threshold current density; transparency carrier density; wavelength 1550 nm; Absorption; Charge carrier density; Heterojunctions; Laser theory; Photonic band gap; Silicon alloys; Solid lasers; Solid modeling; Tensile strain; Threshold current; Group IV Photonics; Laser; Strained GeC alloy;
Conference_Titel :
Computers and Devices for Communication, 2009. CODEC 2009. 4th International Conference on
Conference_Location :
Kolkata
Print_ISBN :
978-1-4244-5073-2
