FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W1562999058> ?p ?o ?g. }

• W1562999058 abstract "Arsenic and its adverse effects on the environment and society impose a serious risk as it can be observed in cases such as India, Bangladesh, Vietnam, Nepal, and Cambodia. These problems can arise from geochemical processes but also man-made activities like mining and processing of minerals (Copper, Gold, Cobalt, Nickel and Uranium) that may further contribute to the risk of environmental disasters. In either case, problems and environmental disasters maybe prevented if a detailed chemical identification and understanding of the arsenic species and their chemical properties such as solubility is understood. The processing of these mineral ores (containing various metals) generates arsenic-containing solid wastes which are disposed in tailings management facilities outside in the environment (Riveros et al., 2001; Dymov et al., 2004; Defreyne et al., 2009; Mayhew et al., 2010; Bruce at al., 2011). Most often the phases that are produced after the process is completed is often a multicomponent in nature and contains a variety of elemental and individual phases (often ≥ 3-10 phases are expected to be present at the end of the process) produced produced along the chemical process. To complicate the understanding of these phases even more, depending upon the processing conditions, the produced unwanted materials (from an economic and recyclable aspect) may also be of a poorly crystalline nature (nano-scale order) in addition to being multicomponent in nature and as such, simple tasks such as identification and then inferring understanding of its chemical properties (such as arsenic release into the environment) becomes very difficult if not nearly impossible. In general, as a result of their multicomponent nature, and perhaps due to historical relation, the use of lab based XRD has been the main tool to tackle the identification of these phases via the use of peak matching and Rietveld type of phase fitting analysis. Recently, synchrotron based soft and hard X-ray techniques (XANES and EXAFS) have been used in a similar fashion to overcome the poorly crystalline (lack of long range order) and multicomponent barrier of these industrially produced complex samples using similar types of mathematical types of fitting routines (Principal Component Analysis and Target Transformation) which still have limitations in identifying mixtures (>2-3) of similar phases with various coordination numbers/environments for the same probing atom of interest. The need to develop alternative energy storage devices has become one of the main focuses in North America and around the World as a result of the fact that as the population of the world increases, our oil energy supplies are steadily and quickly decreasing with time." @default.
• W1562999058 created "2016-06-24" @default.
• W1562999058 creator A5038384312 @default.
• W1562999058 creator A5057851239 @default.
• W1562999058 date "2012-02-24" @default.
• W1562999058 modified "2023-10-18" @default.
• W1562999058 title "Vibrational Spectroscopy of Complex Synthetic and Industrial Products" @default.
• W1562999058 cites W100592352 @default.
• W1562999058 cites W1538908379 @default.
• W1562999058 cites W1568794184 @default.
• W1562999058 cites W1897085524 @default.
• W1562999058 cites W1963633087 @default.
• W1562999058 cites W1967103437 @default.
• W1562999058 cites W1970434892 @default.
• W1562999058 cites W1972452852 @default.
• W1562999058 cites W1974930133 @default.
• W1562999058 cites W1974955141 @default.
• W1562999058 cites W1983466288 @default.
• W1562999058 cites W1985013794 @default.
• W1562999058 cites W1985386206 @default.
• W1562999058 cites W1985771488 @default.
• W1562999058 cites W1992025918 @default.
• W1562999058 cites W1992123713 @default.
• W1562999058 cites W1994888565 @default.
• W1562999058 cites W1996339064 @default.
• W1562999058 cites W2001022518 @default.
• W1562999058 cites W2004245633 @default.
• W1562999058 cites W2007680055 @default.
• W1562999058 cites W2010554968 @default.
• W1562999058 cites W2012017174 @default.
• W1562999058 cites W2013403628 @default.
• W1562999058 cites W2014541993 @default.
• W1562999058 cites W2020783655 @default.
• W1562999058 cites W2027659177 @default.
• W1562999058 cites W2031053320 @default.
• W1562999058 cites W2033872226 @default.
• W1562999058 cites W2034041298 @default.
• W1562999058 cites W2037187500 @default.
• W1562999058 cites W2042533024 @default.
• W1562999058 cites W2042804530 @default.
• W1562999058 cites W2043362565 @default.
• W1562999058 cites W2043927988 @default.
• W1562999058 cites W2044528082 @default.
• W1562999058 cites W2047573257 @default.
• W1562999058 cites W2049843907 @default.
• W1562999058 cites W2050581845 @default.
• W1562999058 cites W2053535968 @default.
• W1562999058 cites W2055459779 @default.
• W1562999058 cites W2056167820 @default.
• W1562999058 cites W2060074008 @default.
• W1562999058 cites W2066516787 @default.
• W1562999058 cites W2069588578 @default.
• W1562999058 cites W2070672388 @default.
• W1562999058 cites W2071503210 @default.
• W1562999058 cites W2075216129 @default.
• W1562999058 cites W2076790001 @default.
• W1562999058 cites W2080993356 @default.
• W1562999058 cites W2081488636 @default.
• W1562999058 cites W2084596715 @default.
• W1562999058 cites W2085289292 @default.
• W1562999058 cites W2091261161 @default.
• W1562999058 cites W2096069511 @default.
• W1562999058 cites W2103608025 @default.
• W1562999058 cites W2103778724 @default.
• W1562999058 cites W2112754374 @default.
• W1562999058 cites W2116327492 @default.
• W1562999058 cites W2121511629 @default.
• W1562999058 cites W2142347507 @default.
• W1562999058 cites W2161061779 @default.
• W1562999058 cites W2313963259 @default.
• W1562999058 cites W2506050571 @default.
• W1562999058 cites W2922101551 @default.
• W1562999058 cites W2936662904 @default.
• W1562999058 cites W2980448611 @default.
• W1562999058 doi "https://doi.org/10.5772/32982" @default.
• W1562999058 hasPublicationYear "2012" @default.
• W1562999058 type Work @default.
• W1562999058 sameAs 1562999058 @default.
• W1562999058 citedByCount "0" @default.
• W1562999058 crossrefType "book-chapter" @default.
• W1562999058 hasAuthorship W1562999058A5038384312 @default.
• W1562999058 hasAuthorship W1562999058A5057851239 @default.
• W1562999058 hasBestOaLocation W15629990581 @default.
• W1562999058 hasConcept C121332964 @default.
• W1562999058 hasConcept C1276947 @default.
• W1562999058 hasConcept C192562407 @default.
• W1562999058 hasConcept C32891209 @default.
• W1562999058 hasConceptScore W1562999058C121332964 @default.
• W1562999058 hasConceptScore W1562999058C1276947 @default.
• W1562999058 hasConceptScore W1562999058C192562407 @default.
• W1562999058 hasConceptScore W1562999058C32891209 @default.
• W1562999058 hasLocation W15629990581 @default.
• W1562999058 hasLocation W15629990582 @default.
• W1562999058 hasOpenAccess W1562999058 @default.
• W1562999058 hasPrimaryLocation W15629990581 @default.
• W1562999058 hasRelatedWork W2737498735 @default.
• W1562999058 hasRelatedWork W2744391499 @default.
• W1562999058 hasRelatedWork W2889753853 @default.
• W1562999058 hasRelatedWork W2898370298 @default.
• W1562999058 hasRelatedWork W2899084033 @default.

• next