Methods for Characterization of Composition of Fly Ashes from Coal-Fired Power Stations:  A Critical Overview

Vassilev, Stanislav V.; Vassileva, Christina G.

doi:10.1021/ef049694d

Cited by 204 publications

(100 citation statements)

References 176 publications

(342 reference statements)

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“…Coal fly ash is one of the most complex of the materials that can be characterized [28]. The major crystalline phases characterized are mullite and quartz for most ash and major components are …”

Section: Introductionmentioning

confidence: 99%

A review of the alumina recovery from coal fly ash, with a focus in China

Yao

Xia

Sarker

et al. 2014

Fuel

315

117

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Coal fly ash, an industrial by-product, is derived from coal combustion in thermal power plants. It is one of the most complex and abundant of anthropogenic materials, and its improper disposal has become an environmental concern and resulted in a waste of recoverable resources. Coal fly ash is rich in alumina, making it a potential substitute for bauxite. With the diminishing reserves of bauxite resources as well as the increasing demand for alumina, recovering alumina from fly ash has attracted extensive attentions. The present review first describes the alumina recovery history and technologies, and then focuses on the recovery status in China. Finally, the current status of fly ash recycling and directions for future research are considered.

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Section: Introductionmentioning

confidence: 99%

A review of the alumina recovery from coal fly ash, with a focus in China

Yao

Xia

Sarker

et al. 2014

Fuel

315

117

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“…Ashes are common industrial-sourced alkaline byproduct (Gerdemann et al 2007, Wilcox 2012. They contain about 90% and 99% inorganic compounds and between 1% and 9% organic compounds (Vassilev 2005). The main inorganic substances of coal combustion ashes are silicon dioxide (SiO 2 ), calcium oxide (CaO), iron oxide (Fe 2 O 3 ), magnesium oxide (MgO) and aluminium oxide (Al 2 O 3 ) (Hong et al 2009, Malik and Thapliyal 2009, Wilcox 2012.…”

Section: Introductionmentioning

confidence: 99%

CO2 adsorption on agricultural biomass combustion ashes

Lira-Zúñiga

Sáez‐Navarrete

Rodríguez-Córdova

et al. 2016

Maderas, Cienc. tecnol.

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Carbon capture and storage has become an alternative means of confronting global warming. Further research and development into adequate and low-cost materials is required for CO 2 adsorption technologies.Samples of fly ash, bottom ash and their respective pellets, produced from wheat bran combustion, were characterized and tested to assess their capacity for CO 2 adsorption at different temperatures. Neither the ashes nor their pellets were subject to prior thermochemical activation.The bottom ash sample and its pellets showed a higher adsorption capacity for the majority of the temperatures studied. The pelletized bottom ash reached the maximum adsorption capacity (0,07 mmol CO 2 /g), followed by the non-pelletized bottom ash (0,06 mmol CO 2 /g); both at an adsorption temperature of 25°C.

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“…Since fly ash is a heterogeneous and complex anthropogenic material, and, like coal, includes organic and crystalline and amorphous inorganic phases, a large number of techniques may be applied in fly ash characterization (French et al, 2007;Vassilev & Vassileva, 2005), to study FA mineralogy (Raask, 1982;Vassilev & Vassileva, 1996a;Ward & French, 2006), morphotypes (Anshits et al, 1998;Bailey et al, 1990;Fomenko et al, 1998a,b;Hower & Mastalerz, 2001;Hower et al, 2005;Sokol et al, 2002;SuarezRuiz & Valentim, 2007;Vassilev & Vassileva, 2007), Hg capture by carbon (Hower et al, 2000;Senior & Johnson, 2005), magnetic properties (Anshits et al, 2000;Hansen et al, 1981), the environmental and technological behavior of trace elements, the mechanisms for concentration enhancement, the relation between trace elements and fly ashes (Block & Dams, 1979;Clark, 1993;Conzemius et al, 1984;Danihelka et al, 2003;Donahoe et al, 2007;Finkelman et al, 1990;Haynes et al, 1982;Meij, 1994;Meij & Winkel, 2009;Swaine, 1990Swaine, , 2000Valkovic, 1983;Yan et al, 2001), and chemical classification of fly ashes (Roy & Griffin, 1982;Vassilev & Vassileva, 2007), among others. Therefore, a case study of FA from a TPP was conducted using several characterization techniques in order to see if FA variations inside a TPP are exclusive of some properties or if they cover a wide range of situations: granulometry, carbon content, major oxides and chemical classification, mineralogy and phase-mineral classification, and trace elements (Cr, Cu, Mn, Ni, ...…”

Section: Introductionmentioning

confidence: 99%