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200 10$aRomance languages and linguistic theory 2010$b[electronic resource] $eselected papers from "Going Romance" Leiden 2010 /$fedited by Irene Franco, Sara Lusini, Andres Saab
210   $aAmsterdam ;$aPhiladelphia $cJohn Benjamins Pub. Co.$d2012
215   $a1 online resource (231 p.)
225 0 $aRomance Languages and Linguistic Theory,$x1574-552X ;$vvol. 4
300   $aDescription based upon print version of record.
311   $a90-272-0384-9 
320   $aIncludes bibliographical references and index.
327   $aRomance Languages and Linguistic Theory 2010; Editorial page; Title page; LCC data; Table of contents; Foreword; From Romance clitics to case; 1. Case: The oblique / dative; 1.1 Split accusativity; 2. The person case constraint; 2.1 A Case-based account; 2.2 A grammar without repairs; References; Contextual conditions on stem alternations; 1. Introduction; 1.1 Stem alternations in context; 1.2 The empirical question; 2. Conditions on contextual allomorphy; 2.1 Extension to stem alternation; 3. Two alternations in Spanish verbs; 3.1 Diphthongization; 3.2 "Raising"; 4. Interim summary
327   $a5. A Question and a conjecture6. Conclusions; References; State nouns are Kimian states*; 1. Preliminaries and background concepts: States and nouns; 1.1 Preliminaries: A working definition of state; 1.2 Kimian states and Davidsonian states; 2. Nouns coming from K-state verbs; 2.1 Incompatibility with place modifiers; 2.2 Incompatibility with manner denoting adjectives; 2.3 Unavailability of temporal readings with ambiguous adjectives; 3. From D-state verbs to nouns; 3.1 From D-state verbs to K-state nouns; 3.1.1 Asymmetries with place modifiers; 3.1.2 Asymmetries with manner modifiers
327   $a3.1.3 Asymmetries with temporal readings of modifiers3.2 Two classes of D-state verbs; 4. Analysis: Some D-states contain a K-state; 4.1 Flexible D-states contain a K-state: Semantic evidence; 4.2 Matching the semantics with the internal projections of the verb; 5. Conclusions and extensions; References; I know the answer'; 1. Introduction; 2. Some Capeverdean statives need ta for a non-past reading; 2.1 The data that resist the stativity explanation; 2.1.1 Overt temporal morphemes; 2.1.2 Why stativity is not enough; 2.2 Stative properties of these present situations
327   $a3. The relevant state is a Perfect state4. Cross-linguistic idiosyncrasies of 'know'; 5. Final remarks; References; Stressed vowel duration and stress placement in Italian; 1. Introduction; 2. Italian stress position and vowel duration; 2.1 Stress position; 2.2 Stress is contrastive; 2.3 Stressed vowel duration; 2.4 Explanations of vowel duration; 3. Experiment; 3.1 Design of the experiment; 3.2 Results; 3.2.1 Post-tonic vowels of proparoxytones: Duration; 3.2.2 Post-tonic vowels of proparoxytones: Centralization; 4. Interpretation of the results and analysis; 4.1 Stressed vowels
327   $a4.2 Duration and centralization of post-tonic vowels5. Principles of stress assignment; 5.1 Non-lexical stress and syllable weight; 5.2 Stress assignment and number of syllables; 5.2.1 Further data on stress shift; 5.3 Provisional conclusions and discussion of previous explanations; 6. Feet and stress assignment in Italian; 6.1 Foot types; 6.2 Non-lexical stress; 7. Conclusions and further directions; References; Serial prosodification and voiced stop geminates in Catalan*; 1. Introduction; 2. Data; 3. Theoretical background; 3.1 Harmonic serialism and prosodification
327   $a3.2 A theory of serial syllabification in Harmonic Serialism
330   $aI claim that scope interactions provide empirical evidence in order to establish the argument structure of the causative construction in Romance languages. Since quantifier raising adjoins a quantified argument to vP, quantified arguments interact differently if they are coarguments than if they are not. Thus, scope interactions are able to give indications on what arguments in a causative structure belong to the same vP, and, as a consequence, how vPs may occur in a causative structure. The data I discuss shows that in Romance causative structures the causee and the internal argument (if any)
410  0$aRomance Languages and Linguistic Theory
606   $aRomance languages$vCongresses
606   $aLinguistics$vCongresses
608   $aElectronic books.
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615  0$aLinguistics
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200 00$aOn solar hydrogen & nanotechnology$b[electronic resource] /$feditor, Lionel Vayssieres
210   $aSingapore ;$aHoboken, NJ, USA $cJohn Wiley & Sons (Asia)$dc2010
215   $a1 online resource (706 p.)
300   $aDescription based upon print version of record.
311   $a0-470-82397-6 
320   $aIncludes bibliographical references and index.
327   $aON SOLAR HYDROGEN & NANOTECHNOLOGY; Contents; List of Contributors; Preface; Editor Biography; Part One: Fundamentals, Modeling, and Experimental Investigation of Photocatalytic Reactions for Direct Solar Hydrogen Generation; 1 Solar Hydrogen Production by Photoelectrochemical Water Splitting: The Promise and Challenge; 1.1 Introduction; 1.2 Hydrogen or Hype?; 1.3 Solar Pathways to Hydrogen; 1.3.1 The Solar Resource; 1.3.2 Converting Sunlight; 1.3.3 Solar-Thermal Conversion; 1.3.4 Solar-Potential Conversion; 1.3.5 Pathways to Hydrogen; 1.4 Photoelectrochemical Water-Splitting
327   $a1.4.1 Photoelectrochemistry1.4.2 PEC Water-Splitting Reactions; 1.4.3 Solar-to-Hydrogen Conversion Efficiency; 1.4.4 Fundamental Process Steps; 1.5 The Semiconductor/Electrolyte Interface; 1.5.1 Rectifying Junctions; 1.5.2 A Solid-State Analogy: The np + Junction; 1.5.3 PEC Junction Formation; 1.5.4 Illuminated Characteristics; 1.5.5 Fundamental Process Steps; 1.6 Photoelectrode Implementations; 1.6.1 Single-Junction Performance Limits; 1.6.2 Multijunction Performance Limits; 1.6.3 A Shining Example; 1.7 The PEC Challenge; 1.7.1 What's Needed, Really?; 1.7.2 Tradeoffs and Compromises
327   $a1.7.3 The Race with PV-Electrolysis1.8 Facing the Challenge: Current PEC Materials Research; Acknowledgments; References; 2 Modeling and Simulation of Photocatalytic Reactions at TiO2 Surfaces; 2.1 Importance of Theoretical Studies on TiO2 Systems; 2.2 Doped TiO2 Systems: Carbon and Niobium Doping; 2.2.1 First-Principle Calculations on TiO2; 2.2.2 C-Doped TiO2; 2.2.3 Nb-Doped TiO2; 2.3 Surface Hydroxyl Groups and the Photoinduced Hydrophilicity of TiO2; 2.3.1 Speculated Active Species on TiO2 - Superoxide Anion (O2 ?) and the Hydroxyl Radical (OH ?)
327   $a2.3.2 Theoretical Calculations of TiO2 Surfaces and Adsorbents2.3.3 Surface Hydroxyl Groups and Photoinduced Hydrophilic Conversion; 2.4 Dye-Sensitized Solar Cells; 2.4.1 Conventional Sensitizers: Ruthenium Compounds and Organic Dyes; 2.4.2 Multiexciton Generation in Quantum Dots: A Novel Sensitizer for a DSSC; 2.4.3 Theoretical Estimation of the Decoherence Time between the Electronic States in PbSe QDs; 2.5 Future Directions: Ab Initio Simulations and the Local Excited States on TiO2; 2.5.1 Improvement of the DFT Functional; 2.5.2 Molecular Mechanics and Ab Initio Molecular Dynamics
327   $a2.5.3 Description of Local Excited States2.5.4 Nonadiabatic Behavior of a System and Interfacial Electron Transfer; Acknowledgments; References; 3 Photocatalytic Reactions on Model Single Crystal TiO2 Surfaces; 3.1 TiO2 Single-Crystal Surfaces; 3.2 Photoreactions Over Semiconductor Surfaces; 3.3 Ethanol Reactions Over TiO2(110) Surface; 3.4 Photocatalysis and Structure Sensitivity; 3.5 Hydrogen Production from Ethanol Over Au/TiO2 Catalysts; 3.6 Conclusions; References; 4 Fundamental Reactions on Rutile TiO2(110) Model Photocatalysts Studied by High-Resolution Scanning Tunneling Microscopy
327   $a4.1 Introduction
330   $aMore energy from the sun strikes Earth in an hour than is consumed by humans in an entire year. Efficiently harnessing solar power for sustainable generation of hydrogen requires low-cost, purpose-built, functional materials combined with inexpensive large-scale manufacturing methods. These issues are comprehensively addressed in On Solar Hydrogen & Nanotechnology - an authoritative, interdisciplinary source of fundamental and applied knowledge in all areas related to solar hydrogen. Written by leading experts, the book emphasizes state-of-the-art materials and characterization techniqu
517 3 $aOn solar hydrogen and nanotechnology
606   $aSolar energy
606   $aNanotechnology
606   $aFuel cells
606   $aHydrogen as fuel
606   $aWater$xElectrolysis
606   $aPhotocatalysis
615  0$aSolar energy.
615  0$aNanotechnology.
615  0$aFuel cells.
615  0$aHydrogen as fuel.
615  0$aWater$xElectrolysis.
615  0$aPhotocatalysis.
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