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200 10$aConstruction Research Congress 2018 $econstruction project management : selected papers from the Construction Research Congress 2018, April 2-4, 2018, New Orleans, Louisiana /$fedited by Chao Wang [and four others]
210  1$aReston, Virginia :$cAmerican Society of Civil Engineers,$d2018.
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200 10$aPiezoelectric ZnO nanostructure for energy harvesting /$fYamin Leprince-Wang
210  1$aHoboken, New Jersey :$ciSTE/Wiley,$d2015.
215   $a1 online resource (148 p.)
225 1 $aNanoscience and nanotechnology series. Nanotechnologies for energy recovery set ;$vvolume 1
300   $aDescription based upon print version of record.
311   $a1-119-00743-7 
311   $a1-84821-718-8 
320   $aIncludes bibliographical references and index.
327   $aCover; Title Page; Copyright; Contents; Preface; Acknowledgments; Introduction; 1: Properties of ZnO; 1.1. Crystal structure of ZnO; 1.2. Electrical properties of ZnO and Schottky junction ZnO/Au; 1.3. Optical properties of ZnO; 1.4. Piezoelectricity of ZnO; 2: ZnO Nanostructure Synthesis; 2.1. Electrochemical deposition for ZnO nanostructure; 2.1.1. Electrodeposition of monocrystalline ZnO nanowires and nanorods via template method; 2.1.1.1. Individual nanowire growth; 2.1.1.2. Nanopillar array growth; 2.1.2. ZnO nanowire array growth via electrochemical road
327   $a2.2. Hydrothermal method for ZnO nanowire array growth2.3. Comparative discussion on ZnO nanowire arrays obtained via electrodeposition and hydrothermal method; 2.4. Influence of main parameters of hydrothermal method on ZnO nanowire growth morphology; 2.4.1. Effect of the growth method; 2.4.2. Effect of the growth solution pH value; 2.4.3. Effect of the growth temperature; 2.4.4. Effect of the growth time; 2.5. Electrospinning method for ZnO micro/nanofiber synthesis; 3: Modeling and Simulation of ZnO-Nanowire-Based Energy Harvesting; 3.1. Nanowire in bending mode
327   $a3.1.1. Influence of the nanowire length3.1.2. Influence of the nanowire diameter; 3.1.3. Influence of the aspect ratio; 3.2. Nanowire in compression mode; 3.2.1. Influence of the nanowire length; 3.2.2. Influence of the nanowire diameter; 3.2.3. Influence of the aspect ratio; 3.3. Nanowire arrays in static and vibrational responses; 3.3.1. Nanowire arrays in static and compressive responses; 3.3.2. Nanowire arrays in periodic vibrational response; 4: ZnO-Nanowire-Based Nanogenerators: Principle, Characterization and Device Fabrication; 4.1. Working principle of nanogenerators
327   $a4.2. ZnO-nanowire-based energy harvesting device fabrication4.3. ZnO-nanowire-based energy harvesting device characterization; 4.4. ZnO-nanostructure-based hybrid nanogenerators; Conclusion; Bibliography; Index
330   $a Over the past decade, ZnO as an important II-VI semiconductor has attracted much attention within the scientific community over the world owing to its numerous unique and prosperous properties. This material, considered as a "future material", especially in nanostructural format, has aroused many interesting research works due to its large range of applications in electronics, photonics, acoustics, energy and sensing. The bio-compatibility, piezoelectricity & low cost fabrication make ZnO nanostructure a very promising material for energy harvesting. 
410  0$aNanoscience and nanotechnology series.$pNanotechnologies for energy recovery set ;$vv. 1.
606   $aPiezoelectric devices
606   $aPiezoelectricity
615  0$aPiezoelectric devices.
615  0$aPiezoelectricity.
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