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200 10$aKeynes and the "Classics" $ea study in language, epistemology and mistaken identities /$fMichel Verdon
210  1$aChicoutimi :$cJ.-M. Tremblay,$d2008.
215   $a1 online resource (248 pages)
225 0 $aClassiques des sciences sociales ;$v3295
320   $aIncludes bibliographical references and index.
327   $aContents; Deuxie?me de couverture; Acknowledgements; Introduction; Index.
410  0$aClassiques des sciences sociales ;$v3295.
517   $aKeynes and the "Classics"  
606   $aKeynesian economics
615  0$aKeynesian economics.
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100   $a20202207d2022      |y         0
101 0 $aeng
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181   $ctxt$2rdacontent
182   $cc$2rdamedia
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200 00$aThe Origin and Early Evolution of Life$ePrebiotic Systems Chemistry Perspective
210   $aBasel$cMDPI - Multidisciplinary Digital Publishing Institute$d2022
215   $a1 online resource (320 p.)
311 08$a3-0365-4470-4 
311 08$a3-0365-4469-0 
330   $aWhat is life? How, where, and when did life arise? These questions have remained most fascinating over the last hundred years. Systems chemistry is the way to go to better understand this problem and to try and answer the unsolved question regarding the origin of Life. Self-organization, thanks to the role of lipid boundaries, made possible the rise of protocells. The role of these boundaries is to separate and co-locate micro-environments, and make them spatially distinct; to protect and keep them at defined concentrations; and to enable a multitude of often competing and interfering biochemical reactions to occur simultaneously. The aim of this Special Issue is to summarize the latest discoveries in the field of the prebiotic chemistry of biomolecules, self-organization, protocells and the origin of life. In recent years, thousands of excellent reviews and articles have appeared in the literature and some breakthroughs have already been achieved. However, a great deal of work remains to be carried out. Beyond the borders of the traditional domains of scientific activity, the multidisciplinary character of the present Special Issue leaves space for anyone to creatively contribute to any aspect of these and related relevant topics. We hope that the presented works will be stimulating for a new generation of scientists that are taking their first steps in this fascinating field.
517   $aOrigin and Early Evolution of Life 
606   $aBiology, life sciences$2bicssc
606   $aResearch & information: general$2bicssc
610   $aacetylene
610   $aADE theory
610   $aaggregation process
610   $aamino acids
610   $aaminoacyl-tRNA synthetase classes
610   $aanalogue conditions
610   $aastrobiology
610   $aastrochemistry
610   $aautocatalytic set
610   $abending modulus
610   $abilayer structure
610   $abistable reaction system
610   $abudding
610   $acell division
610   $achemical complexity
610   $achemical evolution
610   $achirogenesis
610   $aCHNOPS
610   $acodon assignment
610   $acognition
610   $acomets
610   $acompartment
610   $acomplex organic molecules
610   $acyclic nucleotides
610   $adimerization
610   $adivision
610   $adynamic kinetic stability
610   $aearly Earth
610   $aearly metabolism
610   $aemergence of biological systems
610   $aevolution
610   $aexoplanets
610   $aFenton chemistry
610   $aFRET analysis
610   $aGC×GC-TOFMS
610   $aglucose oxidase
610   $aglycocodon theory
610   $ahot springs
610   $ahydrothermal conditions
610   $ainterstellar medium
610   $alipid
610   $alipid membrane
610   $aMars
610   $ametabolism
610   $ametal ions
610   $aminerals
610   $amolecular dynamics
610   $amolecular ices
610   $aN-acyl amino acid
610   $an/a
610   $anetwork expansion simulation
610   $aolivine
610   $aorigin of genetic code
610   $aorigin of life
610   $aorigin-of-life
610   $aorigins of life
610   $aosmotic pressure
610   $apeptidyl-transferase center
610   $apolymerization
610   $aprebiotic chemical evolution
610   $aprebiotic chemistry
610   $aprebiotic membranes
610   $aprimordial replicators
610   $aprotein-monosaccharide interactions
610   $aprotein-monosaccharide recognition
610   $aproto-metabolism
610   $aproto-ribosome
610   $aprotoamphiphiles
610   $aprotocell
610   $aprotoplanetary disks
610   $apseudo-symmetry
610   $apyrophosphate
610   $aquartz
610   $aradiation damage
610   $areduced phosphorus
610   $aribozymes
610   $aribozyviruses
610   $aRNA ligation
610   $asample return
610   $aschreibersite
610   $aselection
610   $aserpentinite
610   $asolid interface
610   $asolid state
610   $astandard genetic codes
610   $astar forming regions
610   $aSymR
610   $asystems chemistry
610   $atemperature
610   $atemplate-directed RNA synthesis
610   $athermodynamics
610   $athiophene
610   $atime order of canonical amino acids
610   $atransition elements
610   $atransition metal sulfides
610   $atRNA
610   $aulexite
610   $aurea-urease enzymatic reaction
610   $avesicles
610   $aviroids
615  7$aBiology, life sciences
615  7$aResearch & information: general
700   $aFiore$b Michele$4edt$01312140
702   $aAltamura$b Emiliano$4edt
702   $aFiore$b Michele$4oth
702   $aAltamura$b Emiliano$4oth
906   $aBOOK
912   $a9910580210103321
996   $aThe Origin and Early Evolution of Life$93038915
997   $aUNINA