Verification of Multiple Mechanism Model for the Photoluminescence of Oxidized Porous Silicon and Nanosilicon Particle Embedded in Silicon Oxide

dc.contributor.advisorGhoshal, Sib Krishna (PhD)
dc.contributor.authorTilahun, Wondwosen
dc.date.accessioned2018-07-09T08:55:08Z
dc.date.accessioned2023-11-09T11:25:06Z
dc.date.available2018-07-09T08:55:08Z
dc.date.available2023-11-09T11:25:06Z
dc.date.issued2007-07
dc.description.abstractThe purpose of this thesis is to give a coherent explanation of the most debatable issue of highly efficient photoluminescence (PL) in the visible range found in oxidized porous Silicon (p-Si). In order to describe the PL mechanism, we considered three competitive processes, process (A) where in both photoexcitation and photoemission occur in the NSP, (B), in which photexcitation occurs in the NSP and photemission occurs in luminescence centers (LCs), in the Si-oxide layer surrounding the NSP, and (C) in which both photoexcitation and photoemission occur in the LCs. We used the first two processes to explain the optical process by the quantum confinement (QC) and quantum confinement luminescence center (QCLC) models. For the nanoscale Si/SiO2 systems, the radiative recombination rates of processes A and B are compared qualitatively. Process that plays the major role in the PL is determined by the capture cross-section, the luminescence efficiency, and the density of the LCs and size of the NSPs, all of which are dependent on the oxidation degree of the p-Si sample. For a nanoscale Si/Si-oxide system with the LC having certain capture cross-section and luminescence efficiency, it is found that the higher the LC density and the larger the size of the NSPs, the more beneficial for the QCLCM process to surpass the QCM process and vise versa. For certain LC parameters, there is a critical most probable size of the NSPs. In case when the most probable size of the NSPs is larger than the critical one, the QCLCM process dominates the PL on the other hand if the most probable size of the NSPs is smaller than the critical one, the QCM process dominates the PL. Furthermore, if the most probable size is close to the critical one both processes should be taken in to account. In general, for a p-Si sample free from oxidation, the QCM process dominates and the model is important to describe the PL. For most oxidized p-Si, the QCLCM process dominates and the model is useful to describe the PL and when the NSPs in oxidized p-Si samples have very small density or very large size, the process that both photexcitation and photoemission occur in the LCs in the silicon-oxide layer dominating. Hence, the importance of more than one type of mechanism models to describe the PL from oxidized p-Si and NSP embedded in Si-oxide is verifieden_US
dc.identifier.urihttp://10.90.10.223:4000/handle/123456789/7307
dc.language.isoenen_US
dc.publisherAddis Ababa Universityen_US
dc.subjectMechanism Model for the Photoluminescenceen_US
dc.titleVerification of Multiple Mechanism Model for the Photoluminescence of Oxidized Porous Silicon and Nanosilicon Particle Embedded in Silicon Oxideen_US
dc.typeThesisen_US

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