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200 10$aRhetoric in American anthropology $egender, genre, and science /$fRisa Applegarth
210  1$aPittsburgh, Pennsylvania :$cUniversity of Pittsburgh Press,$d2014.
210  4$dİ2014
215   $a1 online resource (280 pages)
225 1 $aPittsburgh Series in Composition, Literacy, and Culture
300   $aBibliographic Level Mode of Issuance: Monograph
311   $a0-8229-6295-0 
320   $aIncludes bibliographical references and index.
330   $a"In the early twentieth century, the field of anthropology transformed itself from the "welcoming science," uniquely open to women, people of color, and amateurs, into a professional science of culture. The new field grew in rigor and prestige but excluded practitioners and methods that no longer fit a narrow standard of scientific legitimacy. In Rhetoric in American Anthropology, Risa Applegarth traces the "rhetorical archeology" of this transformation in the writings of early women anthropologists"--$cProvided by publisher.
410  0$aPittsburgh series in composition, literacy, and culture.
606   $aEthnology$xHistory
606   $aAnthropology$xPhilosophy
606   $aAnthropologists' writings
606   $aWomen anthropologists
606   $aFeminist anthropology
615  0$aEthnology$xHistory.
615  0$aAnthropology$xPhilosophy.
615  0$aAnthropologists' writings.
615  0$aWomen anthropologists.
615  0$aFeminist anthropology.
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200 00$aEmissions Control Catalysis
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2020
215   $a1 online resource (448 p.)
311 08$a3-03936-036-1 
311 08$a3-03936-037-X 
330   $aThe important advances achieved over the past years in all technological directions (industry, energy, and health) contributing to human well-being are unfortunately, in many cases, accompanied by a threat to the environment, with photochemical smog, stratospheric ozone depletion, acid rain, global warming, and finally climate change being the most well-known major issues. These are the results of a variety of pollutants emitted through these human activities. The indications show that we are already at a tipping point that might lead to non-linear and sudden environmental change on a global scale. Aiming to tackle these adverse effects in an attempt to mitigate any damage that has already occurred and to ensure that we are heading toward a cleaner (green) and sustainable future, scientists around the world are developing tools and techniques to understand, monitor, protect, and improve the environment. Emissions control catalysis is continuously advancing, providing novel, multifunctional, and optimally promoted using a variety of methods, nano-structured catalytic materials, and strategies (e.g., energy chemicals recycling, cyclic economy) that enable us to effectively control emissions, either of mobile or stationary sources, improving the quality of air (outdoor and indoor) and water and the energy economy. Representative cases include the abatement and/or recycling of CO2, CO, NOx, N2O, NH3, CH4, higher hydrocarbons, volatile organic compounds (VOCs), particulate matter, and specific industrial emissions (e.g., SOx, H2S, dioxins aromatics, and biogas). The "Emissions Control Catalysis" Special Issue has succeeded in collecting 22 high-quality contributions, included in this MDPI open access book, covering recent research progress in a variety of fields relevant to the above topics and/or applications, mainly on: (i) NOx catalytic reduction from cars (i.e., TWC) and industry (SCR) emissions; (ii) CO, CH4, and other hydrocarbons removal, and (iii) CO2 capture/recirculation combining emissions control with added-value chemicals production.
606   $aEnvironmental economics$2bicssc
606   $aPollution control$2bicssc
606   $aResearch & information: general$2bicssc
610   $a(NH4)2SO4
610   $aacetaldehyde production
610   $aalkali
610   $aalkaline earth
610   $aammonia
610   $aammonia oxidation
610   $aAu-Mo-Fe-Ni/GDC electrodes
610   $aBox-Behnken design
610   $acarbon dioxide
610   $aCatalyst
610   $acatalyst promotion
610   $acatalytic coating
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610   $aCe-based catalyst
610   $aCeO2
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610   $aCO
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610   $aCO2
610   $aCO2 electroreduction
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610   $acopper-ceria catalysts
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610   $aCu/ZSM-5
610   $aCuO
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610   $adeactivation
610   $adeNOx
610   $adeNOx chemistry
610   $adesirability function
610   $adiesel exhaust
610   $adiesel oxidation catalyst
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610   $aelectrochemical promotion
610   $aelectrochemical reduction
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610   $aH2O and SO2 poisoning
610   $aheterogeneous catalysis
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610   $ahydrogen
610   $ahydrogenation
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610   $ahydrothermal synthesis
610   $aIn-situ DRIFTS
610   $ain-situ FT-IR
610   $aionic promoter
610   $airidium
610   $akinetics
610   $alean burn conditions
610   $aLNT
610   $alow-temperature selective catalytic reduction
610   $amanganese oxides
610   $amethanation
610   $amethane
610   $amethanol production
610   $amethanol synthesis
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610   $ananoceria
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610   $anitric oxide
610   $anitrogen oxides abatement
610   $aNO
610   $aNO adsorption properties
610   $aNOx abatement
610   $aNOx storage
610   $aNSR
610   $aorganic compounds purification
610   $aoxygen carrier
610   $apalladium
610   $aparticle size
610   $aPd species
610   $aPd/BEA
610   $aPdO vs. PtO
610   $aPEM
610   $aperovskite
610   $aPGM oxide promotion
610   $aphosphorous
610   $aplasma catalysis
610   $aplatinum
610   $aplatinum group metals
610   $apoisoning
610   $aprecipitation
610   $apropene
610   $aredox properties
610   $aresponse surface methodology
610   $aRhodium
610   $aRWGS reaction kinetics
610   $aSCR
610   $aselective catalytic reduction
610   $asintered ore catalyst
610   $aSO2/H2O tolerance
610   $aSOECs
610   $astepwise precipitation
610   $asulfate
610   $asulfur-tolerant materials
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610   $atransition metal-based catalysts
610   $aTWC
610   $avalue-added chemicals
610   $avehicle exhaust
610   $ayttria-stabilized zirconia
610   $azirconium
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