DSpace Communauté:http://archives.univ-biskra.dz/handle/123456789/21662026-04-19T16:28:21Z2026-04-19T16:28:21ZDeep traps and temperature effects on the capacitance of p-type Si-doped GaAs Schottky diodes on (2 1 1) and (3 1 1) oriented GaAs substratesR. BoumarafN. SengougaR.H. MariAf. MeftahM. AzizDler JameelNoor Al SaqriD. TaylorM. Heninihttp://archives.univ-biskra.dz/handle/123456789/73652019-05-06T11:50:23Z2016-03-03T00:00:00ZTitre: Deep traps and temperature effects on the capacitance of p-type Si-doped GaAs Schottky diodes on (2 1 1) and (3 1 1) oriented GaAs substrates
Auteur(s): R. Boumaraf; N. Sengouga; R.H. Mari; Af. Meftah; M. Aziz; Dler Jameel; Noor Al Saqri; D. Taylor; M. Henini
Résumé: The SILVACO-TCAD numerical simulator is used to explain the
effect of different types of deep levels on the temperature depen-
dence of the capacitance of p-type Si-doped GaAs Schottky diodes
grown on high index GaAs substrates, namely (3 1 1)A and (2 1 1)A
oriented GaAs substrates. For the (3 1 1)A diodes, the measured
capacitance–temperature characteristics at different reverse biases
show a large peak while the (2 1 1)A devices display a much smaller
one. This peak is related to the presence of different types of deep
levels in the two structures. These deep levels are characterized by
the Deep Level Transient Spectroscopy (DLTS) technique. In the
(3 1 1)A structure only majority deep levels (hole deep levels) were
observed while both majority and minority deep levels were pres-
ent in the (2 1 1)A diodes. The simulation software, which calcu-
lates the capacitance–voltage and the capacitance–temperature
characteristics in the absence and presence of different types of
deep levels, agrees well with the experimentally observed behavior
of the capacitance–temperature properties. A further evidence to
confirm that deep levels are responsible for the observed phenom-
enon is provided by a simulation of the capacitance–temperature
characteristics as a function of the ac-signal frequency.2016-03-03T00:00:00ZModeling the effect of defects on the performance of an n-CdO/p-Si solar cellS. ChalaN. SengougaF. Yakuphanogluhttp://archives.univ-biskra.dz/handle/123456789/73642019-05-06T11:54:04Z2016-03-03T00:00:00ZTitre: Modeling the effect of defects on the performance of an n-CdO/p-Si solar cell
Auteur(s): S. Chala; N. Sengouga; F. Yakuphanoglu
Résumé: The interest in the study of Cadmium oxide (CdO) for photonic applications has
increased significantly because of its promising electrical and optical properties. Real
solar cells based on an n-CdO/p-Si heterostructures show poor photovoltaic
performance, however. In this work numerical simulation is used to elucidate this poor
performance by considering two cases. CdO is firstly considered as a perfect crystalline
semiconductor. The second case models CdO as a semiconductor with continuous
distribution of defects states in its band gap, similar to an amorphous semiconductor,
made of two tail bands (a donor-like and an acceptor-like) and two Gaussian
distribution deep level bands (an acceptor-like and a donor-like). Evidently the first
case produced results far from reality. In the second case, however, and by adjusting
the constituents of the band gap states the open circuit voltage (VOC) and the short
circuit current (JSC) were almost perfectly reproduced but not the fill factor (FF) and the
conversion efficiency (η). The p-type doping of Silicon adjustment has lead to a better
reproduction of the two latter parameters.2016-03-03T00:00:00ZOptimization of Optical Gain in Inx Ga1-xSb/GaSb unstrained quantum well structuresSaid DehimiAissat AbdelkaderDjamel HaddadLakhdar Dehimihttp://archives.univ-biskra.dz/handle/123456789/73632019-05-06T11:57:08Z2016-03-03T00:00:00ZTitre: Optimization of Optical Gain in Inx Ga1-xSb/GaSb unstrained quantum well structures
Auteur(s): Said Dehimi; Aissat Abdelkader; Djamel Haddad; Lakhdar Dehimi
Résumé: n this paper we study the effects of In concentration, temperature, quantum well width and carrier density on optical gain for
GaSb/InxGa1-xSb/GaSb untrained quantum well structures. This system was chosen as it is useful in infrared emission, finally, we
introduce the optimum structure of quantum well to obtain the maximum optical gain, at room temperature and infrared emission
particularly 2.3 (μm), for the use this structure in application of spectroscopic analysis of the gases specially CH4. This structure
can be used for light absorption to increase the solar cell efficiency a based on a quantum well and multi-junction.2016-03-03T00:00:00ZSMALL-SIGNAL TIME-DOMAIN PHYSICAL/ELECTRICAL FET MODELING APPROACHN.A. AbdeslamS. AsadiN. SengougaM.C.E. Yagoubhttp://archives.univ-biskra.dz/handle/123456789/73622019-05-06T11:54:01Z2016-03-03T00:00:00ZTitre: SMALL-SIGNAL TIME-DOMAIN PHYSICAL/ELECTRICAL FET MODELING APPROACH
Auteur(s): N.A. Abdeslam; S. Asadi; N. Sengouga; M.C.E. Yagoub
Résumé: In this paper, a reliable small-signal time-domain FET
modeling approach is proposed. Based on physical/electrical
parameters, the proposed model can efficiently characterize
high-frequency transistors.2016-03-03T00:00:00Z