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010   $a9786612365225
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010   $a0-470-29000-5
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035   $a(OCoLC)609847579
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100   $a20000901d2001      ub             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aConservation tillage and cropping innovation$b[electronic resource] $econstructing the new culture of agriculture /$fC. Milton Coughenour, Shankariah Chamala
205   $a1st ed.
210   $aAmes, Iowa $cIowa State University Press$d2001
215   $a1 online resource (376 p.)
300   $aDescription based upon print version of record.
311   $a0-8138-1947-4 
320   $aIncludes bibliographical references (p. 329-351).
327   $aConservation Tillage and Cropping Innovation: Constructing the New Culture of Agriculture; Contents; Foreword; Preface; Acknowledgments; 1 Introduction; 2 Conceptualizing System Innovation: Social Construction of Conservation Tillage and Cropping; 3 Plow Culture in the United States and Australia; 4 Farming in the 1950s: The Driving Forces; 5 The Social Construction of Innovative Networks; 6 Social Construction of New Tillage and Cropping Systems in the United States; 7 The Construction of New Tillage Systems in Australia; 8 The Spread of Conservation Tillage in Kentucky and Queensland
327   $a9 Reconstructing the Farm Landscape: The Spread of Conservation Tillage in the United States10 Planning Conservation Cropping: Implications for Research, Development, and Extension; 11 The New Agriculture of Conservation Cropping: Present and Future; Bibliography; Acronyms; Index
330   $aA sociological study of changing farming methods, Conservation Tillage and Cropping Innovation investigates those techniques that have gradually continued to replace the plow culture.   With thorough documentation of the conservation tillage and cropping revolution, this book features chapters on: The Social Construction of Innovative Networks; Planning Conservation Cropping: Implications for Research, Development, and Extension; The New Agriculture of Conservation Cropping: Present and Future.
606   $aAgricultural innovations
606   $aConservation tillage
615  0$aAgricultural innovations.
615  0$aConservation tillage.
676   $a631.451
700   $aCoughenour$b C. Milton$0905997
701   $aChamala$b Shankariah$0905998
801  0$bMiAaPQ
801  1$bMiAaPQ
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906   $aBOOK
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996   $aConservation tillage and cropping innovation$92026344
997   $aUNINA

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100   $a20202205d2022      |y         0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 00$aCatalytic Applications of Clay Minerals and Hydrotalcites
210   $aBasel$cMDPI - Multidisciplinary Digital Publishing Institute$d2022
215   $a1 online resource (108 p.)
311 08$a3-0365-3552-7 
311 08$a3-0365-3551-9 
330   $aClay minerals are inexpensive and available materials with a wide range of applications (adsorbent, ion exchanger, support, catalyst, paper coating, ceramic, and pharmaceutical applications, among others). Clay minerals can be easily modified through acid/basic treatments, the insertion of bulky ions or pillars into the interlayer spacing, and acid treatment, improving their physicochemical properties.Considering their low cost and high availability, clay minerals display a relatively high specific surface area in such a way that they have a great potential to be used as catalytic supports, since they can disperse expensive active phases as noble metals on the porous structures of their surfaces. In addition, the low cost of these supports allows their implementation on an industrial scale more easily than other supports, which are only feasible at the laboratory scale. Hydrotalcites (considered as anionic or basic clays) are also inexpensive materials with a great potential to be used as catalysts, since their textural properties could also be modified easily through the insertion of anions in their interlayer spacing. In the same way, these hydrotalcites, formed by layered double hydroxides, can lead to their respective mixed oxides after thermal treatment. These mixed oxides are considered basic catalysts with a high surface area, so they can also be used as catalytic support.
606   $aChemistry$2bicssc
606   $aInorganic chemistry$2bicssc
606   $aResearch and information: general$2bicssc
610   $a1,2-propanediol
610   $acoke deposition
610   $aCu-based catalysts
610   $aCu/ZnO/Al2O3
610   $aCuMgFe
610   $aesterification
610   $aexcellent durability
610   $afurfural
610   $afurfuryl alcohol
610   $aheterogeneous catalyst
610   $ahierarchical microstructure
610   $ahigh selectivity
610   $ahydrogenolysis of glycerol
610   $ahydrotalcite-derived composites
610   $aisobutane dehydrogenation
610   $akaolin
610   $alayered double hydroxides
610   $ameixnerite
610   $amesoporous
610   $aMgF2 promoter
610   $an/a
610   $apropane dehydrogenation
610   $aPtIn/Mg(Al)O/ZnO
610   $areconstruction
610   $arecycled
610   $areduction atmosphere
610   $asupported Pt-In catalysts
610   $awaste valorization
615  7$aChemistry
615  7$aInorganic chemistry
615  7$aResearch and information: general
700   $aCecilia$b Juan$4edt$01319551
702   $aJime?nez Go?mez$b Carmen Pilar$4edt
702   $aCecilia$b Juan$4oth
702   $aJime?nez Go?mez$b Carmen Pilar$4oth
906   $aBOOK
912   $a9910566463303321
996   $aCatalytic Applications of Clay Minerals and Hydrotalcites$93033956
997   $aUNINA