《中國科技進展叢書:啟迪於自然的遺態材料(英文版)》討論了生物啟發的策略整合生物模板,仿生礦化,和性質,採用分層bioarchitectures製作及相關性能優異的功能材料,以及在光電,光學,光催化,化學檢測,生物成像中的套用價值。可供研究人員和在材料科學領域的研究生使用。
基本介紹
- 書名:啟迪於自然的遺態材料
- 作者:張荻
- 出版日期:2011年11月1日
- 語種:簡體中文, 英語
- ISBN:9787308082648
- 外文名:Morphology Genetic Materials Templated from Nature Species
- 出版社:浙江大學出版社
- 頁數:250頁
- 開本:16
- 品牌:浙江大學出版社
內容簡介,圖書目錄,
內容簡介
《中國科技進展叢書:啟迪於自然的遺態材料(英文版)》由浙江大學出版社出版。
圖書目錄
1 Functional Materials Templated from Natural Plants
1.1 Introduction
1.2 Morphogenetic Materials from Natural Plants
1.2.1 Synthesis of (Fe203), Nickel Oxide (NiO) and Zinc Oxide (ZnO) from Natural Plants
1.2.2 Biomorphic A1203 and SnO2 by Using Cotton as BioTemplates
1.2.3 Biomorphic Synthesis of Metal Oxide Doped with Metal(N-TiO2, Ag-A1203)
1.2.4 Biotemplate Fabrication of SnO2 and TiO2 Materials by a Sonochemical Method
1.2.5 Biomorphic Functional Metal Oxides from Plant Leaves
1.3 Applications of the Synthesized Biomorphic Materials
1.3.1 Adsorbents for Copper Ions Removal with Surface Functionalized Soybean Straw
1.3.2 Polymer Functionalized Activated Carbon (from Rice Husk) for Cu2+ Removal
1.3.3 Magnetic Nanoparticles Functionalized Activated Carbon for Dye Removal
1.3.4 TiO2 with Hierarchical Structures Fabricated from Wood for Photocatalyst
1.3.5 Gas Sensing Properties of Wood-Templated Oxides
1.4 Summary
References
2 Morph-Genetie Materials Inspired from Butterfly Wing Scales
2.1 Introduction
2.2 Synthesis Approaches of Butterfly Wings Replicas
2.2.1 Chemical Solutions Soaking Method
2.2.2 Sonochemical Processing Method
2.2.3 Solvothermal Nano-Complex Processing Method
2.2.4 Summary
2.3 Optical Properties of Butterfly Wings, Hybrids or Replicas
2.3.1 Fabrication of Iridescent Zinc Oxide Replicas from Transparent Butterfly Wings Templates
2.3.2 Fabrication of Large-Area Iridescent Inorganic Replicas
2.3.3 Fabrication of Nanocomposite with Novel Optical Effect
2.4 Gas Sensor Properties of Butterfly Wings, Hybrids or Replicas
2.4.1 Characterization of the Porous Hierarchical Gas-Sensor Microstructures Template from Butterfly Wings
2.4.2 Research on the Gas-Sensor Properties of the SnO2 Replicas of Butterfly Wings
2.5 High Light Harvest Efficiency Photoanode Used in Solar Cells
2.6 Conclusion
References
3 Morph-Genetic Materials Inspired Diverse Hierarchical Bio-Architectures
3.1 Introduction
3.2 Functional Metal Oxides Nano-Architectures with Eggshell Membrane Hierarchy
3.2.1 Biotemplating Sol-Gel Techniques for Hierarchical Metal Oxides
3.2.2 Hierarchical Nanostructured SnO2 as Gas Sensors
3.2.3 Pd-PdO Nanoclusters Reinforced Hierarchical TiO2 Films with Excellent Photocatalysis
3.3 Morph-Genetic Materials with Diatom as the Templates
3.4 Morph-Genetic Materials with Bacteria as the Templates
3.5 Hybrid Nanocomposites Derived from Reactive Natural Scaffolds
3.5.1 Natural Biofibers Based Hybrid Nanocomposites
3.5.2 Hierarchical Morph-Genetic Nanocomposites
3.5.3 Iridescent Nanocomposites: Novel Photonic Crystals
References
4 Morph-Genetic Composites
4.1 Morph-Genetic Composites Based on Plant Materials
4.1.1 Synthesis of Morph-Genetic Composites from Natural Plants
4.1.2 Properties of the Synthesized Biomorphic Materials
4.1.3 Summary
4.2 Functional Nanostructures/Bioscaffolds Nanocomposies
4.2.1 Natural Biofibers Based Optical Nanocomposites
4.2.2 Hybrid Nanocomposites with Natural Photonic Crystals as the Matrices
References
Index
1.1 Introduction
1.2 Morphogenetic Materials from Natural Plants
1.2.1 Synthesis of (Fe203), Nickel Oxide (NiO) and Zinc Oxide (ZnO) from Natural Plants
1.2.2 Biomorphic A1203 and SnO2 by Using Cotton as BioTemplates
1.2.3 Biomorphic Synthesis of Metal Oxide Doped with Metal(N-TiO2, Ag-A1203)
1.2.4 Biotemplate Fabrication of SnO2 and TiO2 Materials by a Sonochemical Method
1.2.5 Biomorphic Functional Metal Oxides from Plant Leaves
1.3 Applications of the Synthesized Biomorphic Materials
1.3.1 Adsorbents for Copper Ions Removal with Surface Functionalized Soybean Straw
1.3.2 Polymer Functionalized Activated Carbon (from Rice Husk) for Cu2+ Removal
1.3.3 Magnetic Nanoparticles Functionalized Activated Carbon for Dye Removal
1.3.4 TiO2 with Hierarchical Structures Fabricated from Wood for Photocatalyst
1.3.5 Gas Sensing Properties of Wood-Templated Oxides
1.4 Summary
References
2 Morph-Genetie Materials Inspired from Butterfly Wing Scales
2.1 Introduction
2.2 Synthesis Approaches of Butterfly Wings Replicas
2.2.1 Chemical Solutions Soaking Method
2.2.2 Sonochemical Processing Method
2.2.3 Solvothermal Nano-Complex Processing Method
2.2.4 Summary
2.3 Optical Properties of Butterfly Wings, Hybrids or Replicas
2.3.1 Fabrication of Iridescent Zinc Oxide Replicas from Transparent Butterfly Wings Templates
2.3.2 Fabrication of Large-Area Iridescent Inorganic Replicas
2.3.3 Fabrication of Nanocomposite with Novel Optical Effect
2.4 Gas Sensor Properties of Butterfly Wings, Hybrids or Replicas
2.4.1 Characterization of the Porous Hierarchical Gas-Sensor Microstructures Template from Butterfly Wings
2.4.2 Research on the Gas-Sensor Properties of the SnO2 Replicas of Butterfly Wings
2.5 High Light Harvest Efficiency Photoanode Used in Solar Cells
2.6 Conclusion
References
3 Morph-Genetic Materials Inspired Diverse Hierarchical Bio-Architectures
3.1 Introduction
3.2 Functional Metal Oxides Nano-Architectures with Eggshell Membrane Hierarchy
3.2.1 Biotemplating Sol-Gel Techniques for Hierarchical Metal Oxides
3.2.2 Hierarchical Nanostructured SnO2 as Gas Sensors
3.2.3 Pd-PdO Nanoclusters Reinforced Hierarchical TiO2 Films with Excellent Photocatalysis
3.3 Morph-Genetic Materials with Diatom as the Templates
3.4 Morph-Genetic Materials with Bacteria as the Templates
3.5 Hybrid Nanocomposites Derived from Reactive Natural Scaffolds
3.5.1 Natural Biofibers Based Hybrid Nanocomposites
3.5.2 Hierarchical Morph-Genetic Nanocomposites
3.5.3 Iridescent Nanocomposites: Novel Photonic Crystals
References
4 Morph-Genetic Composites
4.1 Morph-Genetic Composites Based on Plant Materials
4.1.1 Synthesis of Morph-Genetic Composites from Natural Plants
4.1.2 Properties of the Synthesized Biomorphic Materials
4.1.3 Summary
4.2 Functional Nanostructures/Bioscaffolds Nanocomposies
4.2.1 Natural Biofibers Based Optical Nanocomposites
4.2.2 Hybrid Nanocomposites with Natural Photonic Crystals as the Matrices
References
Index
