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Temperature-Dependent and Dielectric Relaxation of Porous Silicon Prepared by Electrochemical Etching

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Publicado: 01/09/2016

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Abstract:

In the electronic devices based on porous silicon (PS) is important understand the physical mechanisms governing the electrical behaviour in the PS/c-Si structure. In order to investigate the conduction mechanisms in the PS/p-Si heterojunction, we prepared the PS by electrochemical etching. The temperature dependence of the porous silicon was studied in the range from 240 K to 320 K. On the other hand, the AC electrical measurements were performed from 10 1 to 10 7 Hz in a range of 0,7 to 1,2 V, at room temperature. The calculated activation energies were close to 0,90 eV. The physical mechanisms involved in the Ag/porous silicon contacts and porous silicon/p-Si interface can be obtained from the voltage dependence of the fitting parameters according to electrical model circuits in DC and AC. We found the dielectric behavior of the samples; the relaxation region is presented at high frequency and at low temperatures resulting in a long dielectric relaxation time. The best known metalloid element for semiconductor manufacturing is the chemical element silicon; technologies based on this element are present in our daily lives, but silicon has its limitations. In crystalline form, it is not considered useful as magnetic, biomedical, or optical material. Thereby, this is where development and research for this material are important. Porous silicon has attracted much attention because of its low dimensional semiconductor structure. Since the first work by Koshida et al. [1] there have been published several papers dedicated to the DC and AC electrical characterization of porous silicon layers [2-4]. The electrical properties of these devices are strongly dependent not only on the properties of porous silicon, also on the quality of the metal/PS or PS/Si interfaces [5-7]. AC impedance analysis is a powerful tool and has been widely used to analyze the electrical performance of both metal-semiconductor junctions and p-n junctions [1,5]. The analysis of the frequency-capacitance-voltage characteristics present in an ideal abrupt junction has to be studied to understand the three capacitances effects in the heterojunction PS/c-Si as Low-Frequency Dispersion phenomenon (LFD), depletion capacitance (Cdep) and geometric capacitance (C0) [7]. An important aspect in these structures is the electrical contacts analysis on the PS layer and what is the dependence behavior when the voltage and temperature is variable [4]. Various authors have been reported different mechanism, Schottky junctions due to the metal contact [8], the Ohmic conduction is dominated by the bulk resistance [9] and the power law Space Charge Limit Current (SCLC) [7]. References: [1] N. Koshida, M. Nagasu, K. Echizenia, Y. Kiuchi. “Impedance Spectra of p‐Type Porous Si‐Electrolyte Interfaces”. J. Electrochem. Soc. Vol. 133(11). 1986. pp. 2283-2287. [2] M. Chavarria, F. Fonthal. “Electrical Characterization and Dielectric Relaxation of Au/Porous Silicon Contacts”. K. M. Nair, D. Suvorov, R. W. Schwarts, R. Guo (editors). Advances in Electroceramic Materials: Ceramic Transactions Series. 204. Ed. Wiley. 2009. pp. 113-119. [3] A. Cherif, S. Jomni, R. Hannachi, L. Beji. “Electrical Investigation of the Al/Porous Si/p + -Si Heterojunction. Physica B . Vol. 409. 2013. pp. 10-15. [4] R. S. Dariani. F. Travakoli. “Conductive and Relaxation Time of Porous Silicon Using the Kramers-Kronig Relation”. Physica B . Vol. 456. 2015. pp. 312-320. [5] M. Theodoropoulou, P. K. Karahaliou, C. A. Krontiras, S. N. Georga, N. Xanthopoulos, M. N. Pisanias, C. Tsamis, A. G. Nassiopoulou. “Transient and AC Electrical Transport Under Forward and Reverse Bias Conditions in Aluminum/Porous Silicon/p-cSi Structures”. J. Appl. Phys. Vol. 96(12). 2004. pp. 7637-7642. [6] I. Bazrafkan, R. S. Dariani. “Electrical Behavior of Free-Standing Porous Silicon Layers”. Physica B . Vol. 404. 2009. pp. 1638-1642. [7] M. Chavarria, F. Fonthal. “Electrical Investigation of Porous Silicon/p-Si Heterojunction Prepared by Electrochemical Etching”. ECS J. Solid State Sci. and Tech . Vol. 5(4). 2016. pp. P3172-P3175. [8] M. Gülnahar, T. Karacali, H. Efeoğlu, “Porous Si Based Al Schottky Structures on p + -Si: A Possible Way for Nano Schottky Fabrication”. Electrochimica Acta . Vol. 168. 2015, pp. 41-49. [9] M. E. Azim-Araghi, Z. Bisadi. “Investigation of Morphology, Electrical Behavior (AC and DC) and CO 2 Gas Sensitivity of Porous Silicon Deposited with Nanolayers of Bromo Aluminum Phthalocyanine”. EPJ Appl. Phys. Vol. 58(2). 2012. p. 20302. Figure 1

Tópico:

Silicon Nanostructures and Photoluminescence

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Información de la Fuente:

FuenteMeeting abstracts/Meeting abstracts (Electrochemical Society. CD-ROM)	Cuartil año de publicaciónNo disponible	VolumenMA2016-02
Issue27	Páginas1844 - 1844	pISSNNo disponible
ISSN1091-8213	Perfil OpenAlexhttps://openalex.org/S4210168594

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Uri URL	http://hdl.handle.net/10614/11108	Scholar URL	https://scholar.google.com/scholar?hl=en&as_sdt=0%2C5&q=info%3AXKeFfXQFpsUJ%3Ascholar.google.com&btnG=	Doi URL	https://doi.org/10.1149/ma2016-02/27/1844
Openalex URL	https://openalex.org/W4247360382	Oaipmh URL	https://red.uao.edu.co/server/oai/request?verb=GetRecord&metadataPrefix=dim&identifier=oai:red.uao.edu.co:10614/11108	Dspace URL	https://red.uao.edu.co/handle/10614/11108

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