K. K. Larbi scite author profile

K. K. Larbi

3Publications

33Citation Statements Received

35Citation Statements Given

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University of Toronto

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Reduction behaviour of rice husk ash for preparation of high purity silicon

Larbi

Barati

McLean

2011

Canadian Metallurgical Quarterly

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The reduction of rice husk ash (RHA) silica for the preparation of high purity silicon was studied using magnesium as the reducing agent. Composite magnesium-RHA pellets with magnesium content varying 0-25 wt-% in excess of stoichiometry requirement were made and heated in the temperature range of 600-900uC under flowing argon. It was found through differential thermal analysis and temperature profile recording that the reaction of RHA silica with magnesium was triggered at y575uC. Quantitative X-ray diffraction analyses of the reduction products showed that both initial magnesium content of the pellets and the reduction dwell temperature had a significant influence on the yield of silicon. In this study, a charge with 5 wt-% magnesium in excess of the stoichiometric amount at a reduction temperature of 900uC gave a maximum silicon yield.On a é tudié la ré duction de la silice de cendre de balle de riz (RHA) dans la pré paration de silicium à haut degré de pureté en utilisant du magné sium comme agent de ré duction. On a fabriqué des boulettes composites de magné sium-RHA avec une teneur en magné sium variant de 0 à 25% en poids en excè s des besoins de la stoechiomé trie et on les a chauffé es dans la gamme de tempé rature de 600 à 900uC sous un flux d'argon. On a trouvé , par analyse thermique diffé rentielle (DTA) et par enregistrement du profil de tempé rature, que la ré action de la silice de RHA avec le magné sium é tait dé clenché e à environ 575uC. Des analyses quantitatives par XRD des produits de ré duction ont montré que tant la teneur initiale en magné sium des boulettes que la tempé rature de maintien de la ré duction avaient une influence importante sur le rendement en silicium. Dans cette é tude, une charge avec 5% en poids d'excè s de magné sium sur la quantité stoechiomé trique à la tempé rature de ré duction de 900uC donnait un rendement maximal de silicium.

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Use of rice husk for emission neutral energy generation and synthesis of solar-grade silicon feedstock

Larbi¹,

Roy

Barati

et al. 2012

Biomass Conv. Bioref.

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How to cite TSpace items Always cite the published version, so the author(s) will receive recognition through services that track citation counts, e.g. Scopus. If you need to cite the page number of the author manuscript from TSpace because you cannot access the published version, then cite the TSpace version in addition to the published version using the permanent URI (handle) found on the record page. This article was made openly accessible by U of T Faculty. Please tell us how this access benefits you. Your story matters.

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Synthesis of Solar‐Grade Silicon from Rice Husk Ash – An Integrated Process

Larbi

Barati

McLean

et al. 2010

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Impurity optimized silicon is needed for the advancement of terrestrial photovoltaic power generation. In this study an approach to synthesis of solar grade silicon using rice husk ash has been pursued. Metallothermic reduction of the purified rice husk ash (RHA) was investigated within the temperature range of 500-950 °C using magnesium in varied amounts. The reduction product was purified by two stage acid leaching sequence. Analysis of the final silicon product by XRD, SEM, and ICP-OES showed crystalline silicon with boron to be less than 3 ppm, corresponding to a reduction by a factor greater than 10 while the phosphorus level was reduced by a factor of over 20 reaching less than 73 ppm. Transition metal impurities and other elements were generally reduced in the processing steps. INTRODUCTIONWorldwide concerns over energy related climate change coupled with spiralling cost and resource-scarcity of fossil based fuels in recent years has provoked interests in renewable and alternate energy technologies. Solar photovoltaic power is one of the main renewable energy alternatives being actively pursued worldwide. Although solar photovoltaic power production is a proven sustainable energy technology especially in the aerospace industry, development of this technology to meet terrestrial energy demands has been largely limited. One of the well known hindrances to widespread use of PV technology is the prohibitively high unit cost of solar PV generated electricity which is partly attributed to cost of substrate material used in fabrication of efficient solar cells. ' Presently, silicon in both monocrystalline and polycrystalline form is the dominant semiconductor material used in the production of most commercially available high efficient solar cells, commanding over 90% of the market share of existing PV technologies. 2 Much of the past and present research efforts to produce low-cost solar grade silicon have focussed on either upgrading metallurgical grade silicon by metallurgical refining processes or modification of the conventional Siemens process to produce silicon with purity in the range of 5-7N which is recognized to be suitable for fabrication of high efficient silicon solar cells 3 Up until now, the possibility of producing solar grade silicon from biomass resources such as rice husk ash which is known to have high purity silica content has only been explored by relatively few research groups.Singh and Dhindaw 4 reported producing polycrystalline silicon of 6N purity by magnesium reduction of rice husk ash followed by successive acid leaching refining. Subsequently, Böse et al ,

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K. K. Larbi

Reduction behaviour of rice husk ash for preparation of high purity silicon

Use of rice husk for emission neutral energy generation and synthesis of solar-grade silicon feedstock

Synthesis of Solar‐Grade Silicon from Rice Husk Ash – An Integrated Process

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