Bio-Inspired Materials.:
Gespeichert in:
| Weitere Verfasser: | , , |
|---|---|
| Format: | Elektronisch E-Book |
| Sprache: | English |
| Veröffentlicht: |
Singapore :
Bentham Science Publishers,
2019.
|
| Schriftenreihe: | Frontiers in biomaterials ;
v. 6. |
| Schlagworte: | |
| Online-Zugang: | Volltext |
| Beschreibung: | 1 online resource (247 pages) |
| ISBN: | 9811406898 9789811406898 |
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| 505 | 0 | |a Cover -- Title -- Biblography -- End User License Agreement -- Contents -- Preface -- List of Contributors -- Bio-Pulse Oscillations Driven Design of Kinetic Structures -- Marios C. Phocas*, Odysseas Kontovourkis and Niki I. Georgiou -- 1. INTRODUCTION -- 2. BIOMIMETIC DESIGN -- 3. KINEMATICS -- 3.1. Soft-mechanical Approach -- 3.2. Simulation Approaches -- 4. BIO-PULSE OSCILLATIONS -- 5. CASE STUDY: HIGH-RISE AIRFLOW SYSTEM -- 5.1. Primary Structure -- 5.2. Secondary Kinetic Mechanism -- 5.2.1. Simulation Analysis -- 6. CONCLUSIONS -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Truss Material Reduction Provided by the Golden Ratio -- Ulisses Targino Bezerra* -- 1. INTRODUCTION -- 2. PRATT TRUSS MODELS -- 3. PRATT TRUSS ANALYSIS -- CONCLUSIONS -- ACKNOWLEDGEMENTS -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- REFERENCES -- Complexity and Adaptability in Nature and Society -- George Rzevski* -- 1. INTRODUCTION -- 2. WHAT IS COMPLEXITY? -- 3. SEVEN KEY PROPERTIES OF COMPLEXITY -- 3.1. Connectivity -- 3.2. Autonomy -- 3.3. Emergence -- 3.4. Nonequilibrium -- 3.5. Nonlinearity -- 3.6. Self-organization -- 3.7. Co-evolution -- 4. COMPLEXITY SCIENCE -- 4.1. Brief Overview -- Our social, economic and political environments cannot be simplified because their complexity is a result of evolutionary forces, which are not under our control. -- 5. ADAPTABILITY -- 5.1. Coping with Disruptions -- 5.2. Defending from Attacks -- 5.3. Resolving Conflicts -- 5.4. Correcting Drift into Failure and Avoiding Stagnation -- 6. DESIGNING FOR ADAPTABILITY -- 7. TECHNOLOGY FOR DESIGNING COMPLEXITY INTO ORGANIZATIONS, PROCESSES AND PRODUCTS -- 7.1. Architecture -- 7.2. How Multi-Agent Software Works -- 7.3. Organizational and Process Design Cases -- 7.4. Engineering Design Cases -- CONCLUSIONS -- CONSENT FOR PUBLICATION. | |
| 505 | 8 | |a ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Without Inner Walls: A Concept of the Café's House -- Theófilo Barreto Moreira Oliveira1,* and Ulisses Targino Bezerra2 -- 1. INTRODUCTION -- 2. OW: WITHOUT INNER WALLS -- 3. FLOOR PLAN -- 4. STUDIO -- 5. LIVING ROOM -- 6. KITCHEN AND DINING ROOM -- 7. OFFICE AND BALCONY -- 8. BATHROOM/WC -- 9. LAVATORY -- 10. GUEST ROOM -- 11. SUITE -- 12. ROOFTOP TERRACE -- 13. SERVICE AREA -- 14. THE NULLIFICATION OF OW -- NOTES -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Similarity Between Particle Packing in Concrete and in Nature -- Eng. Piet Stroeven1,* and Eng. Kai Li2 -- 1. INTRODUCTION -- 2. REALCRETE AND COMPUCRETE -- 3. AGGREGATE PACKING BY DEM -- 3.1. Bulk Packing -- 3.2. Boundary Effects -- 4. PACKING OF FIBERS IN CONCRETE -- 5. DEM PACKING OF BINDER -- DISCUSSION AND CONCLUSIONS -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Current Developments and Future Needs for Natural Earth Construction: A State-of-the-Art Review -- Ana Cecilia Vieira Nóbrega1 and Normando Perazzo Barbosa2* -- 1. INTRODUCTION -- 2. AN OVERVIEW OF NATURAL EARTH BUILDING -- 3. SOIL -- MATERIALS SELECTION FOR EARTH CONSTRUCTION -- 4. DURABILITY OF EARTHEN CONSTRUCTION -- 5. ACADEMIC AND FIELD RESEARCH IN NATURAL EARTH CONSTRUCTIONS: A STATE-OF-THE-ART REVIEW WITH CURRENT DEVELOPMENTS -- 6. DEVELOPING EARTH CONSTRUCTION BUILDING CODES, STANDARDS, AND NORMS -- 7. WORLD INNOVATIONS IN EARTHEN CONSTRUCTION -- 8. FUTURE NEEDS IN EARTH BUILDING -- FINAL CONSIDERATIONS -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Bio-inspired Design with Bamboo -- Normando Perazzo Barbosa1,*, José Augusto Gomes Neto1, Sandra Reyes Ortiz2 and Khosrow Ghavami3 -- 1. INTRODUCTION -- 2. GENERALITIES CONCERNING BAMBOO. | |
| 505 | 8 | |a 2.1. Morphology -- 2.1.1. Rhizomes and Roots -- 2.1.2. Culms -- 2.1.3. Branches -- 2.1.4. Leaves -- 2.1.5. Flowers and Fruits -- 3. HOW TO GET CULMS TO CONSTRUCTION -- 3.1. Selection -- 3.2. Cutting -- 3.3. Curing -- 3.4. Drying -- 3.5. Immunization Treatments -- 4. PHYSICAL PROPERTIES -- 4.1. Inter-nodal Distance, Outside Diameter, Wall Thickness -- 4.2. Water Absorption -- 4.3. Specific Mass -- 5. MECHANICAL PROPERTIES -- 5.1. Compressive Strength -- 5.2. Compressive Strength Parallel to Fibers -- 5.3. Shear Strength Parallel to Fibers -- 5.4. Summary of Mechanical Properties in Tension and Compression Parallel to Fibers -- 6. FUTURE PERSPECTIVES -- 6.1. Impregnation of Bamboo with Polymeric Resins -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Frontiers in Bio-Inspired Mineralization: Addressing Mimesis of Four-Dimensional, Hierarchical, and Nonclassical Growth Characteristics of Biominerals -- Stephan E. Wolf1,2,*, Martina Schüßler1, Corinna F. Böhm1 and Benedikt Demmert1 -- 1. INTRODUCTION -- 2. TOWARDS DYNAMIC CONTROL OF MINERALIZATION -- THE STATIC, QUASI-STATIC, AND DYNAMIC GENESIS OF BIOMINERALS -- 3. HIERARCHICAL MINERALIZATION -- CONTROL OF HIERARCHY AND STRUCTURES ACROSS MULTIPLE LENGTH SCALES -- 4. NONCLASSICAL MINERALIZATION -- COLLOID-MEDIATED MINERALIZATION PROCESSES AS A SOURCE OF FUNCTIONAL NANO- TO MESO-STRUCTURES -- CONCLUSION -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Sustainable and Safe Construction Biomaterials: Biocements and Biogrouts -- Volodymyr Ivanov* and Viktor Stabnikov -- 1. INTRODUCTION -- 2. BIOCEMENT/BIOGROUT FOR CRYSTALLIZATION OF CALCIUM CARBONATE BY HYDROLYSIS OF UREA AT MOLAR RATIO CA: UREA = 0.5 -- 2.0 (CAUR BIOCEMENT/BIOGROUT) -- 3. THE DIVERSITY OF BIOCEMENTS AND BIOGROUTS -- 4. MICROORGANISMS FOR BIOCEMENT/BIOGROUT. | |
| 505 | 8 | |a 5. BIOCEMENTATION BIOSAFETY: USE OF ENRICHMENT OR PURE CULTURE -- 6. PRODUCTION OF BIOSAFE BIOCEMENTS -- 7. ACTIVATED SLUDGE FROM MUNICIPAL WASTEWATER TREATMENT PLANTS USED AS RAW MATERIAL -- 8. DRY AND LIQUID CALCIUM-BASED BIOCEMENT -- 9. UNCONFINED COMPRESSIVE (UC) STRENGTH OF SAND AFTER MICP -- 10. ENGINEERING APPLICATIONS OF BIOCEMENTS -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Interaction Between Natural Fibres and Synthetic Polymers -- Alejandro Manzano-Ramírez1,*, Mario Villalón2 and José Luis Reyes Araiza3 -- 1. INTRODUCTION -- 2. REINFORCED COMPOSITE MATERIALS WITH NATURAL FIBERS -- 2.1. Natural Fibers -- 2.2. Chemical Treatments to Promote Adherence of Natural Fibers -- 3. TESTING STATIC METHODS -- 3.1. Conclusions of Static Tests -- 4. TESTING-VIBRATION METHODS -- 4.1. Dynamic Mechanical Analysis (DMA) -- 4.2. Design of Dynamic Mechanical Tests -- 4.2.1. Preparation of Treated Short Coir Fibre -- 4.2.2. Composite Materials Fabrication -- 4.2.3. Dynamic Test -- 4.3. Coir Fiber Dynamic Test Results -- CONCLUSION -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Subject Index -- Back Cover. | |
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| 700 | 1 | |a Bezerra, Ulisses Targino, |e editor. | |
| 700 | 1 | |a Ferreira, Heber Sivini, |e editor. | |
| 700 | 1 | |a Barbosa, Normando Perazzo, |e editor. | |
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| DE-BY-FWS_katkey | ZDB-4-EBA-on1101786302 |
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| _version_ | 1816882492839297024 |
| adam_text | |
| any_adam_object | |
| author2 | Bezerra, Ulisses Targino Ferreira, Heber Sivini Barbosa, Normando Perazzo |
| author2_role | edt edt edt |
| author2_variant | u t b ut utb h s f hs hsf n p b np npb |
| author_facet | Bezerra, Ulisses Targino Ferreira, Heber Sivini Barbosa, Normando Perazzo |
| building | Verbundindex |
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| callnumber-label | R857 |
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| contents | Cover -- Title -- Biblography -- End User License Agreement -- Contents -- Preface -- List of Contributors -- Bio-Pulse Oscillations Driven Design of Kinetic Structures -- Marios C. Phocas*, Odysseas Kontovourkis and Niki I. Georgiou -- 1. INTRODUCTION -- 2. BIOMIMETIC DESIGN -- 3. KINEMATICS -- 3.1. Soft-mechanical Approach -- 3.2. Simulation Approaches -- 4. BIO-PULSE OSCILLATIONS -- 5. CASE STUDY: HIGH-RISE AIRFLOW SYSTEM -- 5.1. Primary Structure -- 5.2. Secondary Kinetic Mechanism -- 5.2.1. Simulation Analysis -- 6. CONCLUSIONS -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Truss Material Reduction Provided by the Golden Ratio -- Ulisses Targino Bezerra* -- 1. INTRODUCTION -- 2. PRATT TRUSS MODELS -- 3. PRATT TRUSS ANALYSIS -- CONCLUSIONS -- ACKNOWLEDGEMENTS -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- REFERENCES -- Complexity and Adaptability in Nature and Society -- George Rzevski* -- 1. INTRODUCTION -- 2. WHAT IS COMPLEXITY? -- 3. SEVEN KEY PROPERTIES OF COMPLEXITY -- 3.1. Connectivity -- 3.2. Autonomy -- 3.3. Emergence -- 3.4. Nonequilibrium -- 3.5. Nonlinearity -- 3.6. Self-organization -- 3.7. Co-evolution -- 4. COMPLEXITY SCIENCE -- 4.1. Brief Overview -- Our social, economic and political environments cannot be simplified because their complexity is a result of evolutionary forces, which are not under our control. -- 5. ADAPTABILITY -- 5.1. Coping with Disruptions -- 5.2. Defending from Attacks -- 5.3. Resolving Conflicts -- 5.4. Correcting Drift into Failure and Avoiding Stagnation -- 6. DESIGNING FOR ADAPTABILITY -- 7. TECHNOLOGY FOR DESIGNING COMPLEXITY INTO ORGANIZATIONS, PROCESSES AND PRODUCTS -- 7.1. Architecture -- 7.2. How Multi-Agent Software Works -- 7.3. Organizational and Process Design Cases -- 7.4. Engineering Design Cases -- CONCLUSIONS -- CONSENT FOR PUBLICATION. ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Without Inner Walls: A Concept of the Café's House -- Theófilo Barreto Moreira Oliveira1,* and Ulisses Targino Bezerra2 -- 1. INTRODUCTION -- 2. OW: WITHOUT INNER WALLS -- 3. FLOOR PLAN -- 4. STUDIO -- 5. LIVING ROOM -- 6. KITCHEN AND DINING ROOM -- 7. OFFICE AND BALCONY -- 8. BATHROOM/WC -- 9. LAVATORY -- 10. GUEST ROOM -- 11. SUITE -- 12. ROOFTOP TERRACE -- 13. SERVICE AREA -- 14. THE NULLIFICATION OF OW -- NOTES -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Similarity Between Particle Packing in Concrete and in Nature -- Eng. Piet Stroeven1,* and Eng. Kai Li2 -- 1. INTRODUCTION -- 2. REALCRETE AND COMPUCRETE -- 3. AGGREGATE PACKING BY DEM -- 3.1. Bulk Packing -- 3.2. Boundary Effects -- 4. PACKING OF FIBERS IN CONCRETE -- 5. DEM PACKING OF BINDER -- DISCUSSION AND CONCLUSIONS -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Current Developments and Future Needs for Natural Earth Construction: A State-of-the-Art Review -- Ana Cecilia Vieira Nóbrega1 and Normando Perazzo Barbosa2* -- 1. INTRODUCTION -- 2. AN OVERVIEW OF NATURAL EARTH BUILDING -- 3. SOIL -- MATERIALS SELECTION FOR EARTH CONSTRUCTION -- 4. DURABILITY OF EARTHEN CONSTRUCTION -- 5. ACADEMIC AND FIELD RESEARCH IN NATURAL EARTH CONSTRUCTIONS: A STATE-OF-THE-ART REVIEW WITH CURRENT DEVELOPMENTS -- 6. DEVELOPING EARTH CONSTRUCTION BUILDING CODES, STANDARDS, AND NORMS -- 7. WORLD INNOVATIONS IN EARTHEN CONSTRUCTION -- 8. FUTURE NEEDS IN EARTH BUILDING -- FINAL CONSIDERATIONS -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Bio-inspired Design with Bamboo -- Normando Perazzo Barbosa1,*, José Augusto Gomes Neto1, Sandra Reyes Ortiz2 and Khosrow Ghavami3 -- 1. INTRODUCTION -- 2. GENERALITIES CONCERNING BAMBOO. 2.1. Morphology -- 2.1.1. Rhizomes and Roots -- 2.1.2. Culms -- 2.1.3. Branches -- 2.1.4. Leaves -- 2.1.5. Flowers and Fruits -- 3. HOW TO GET CULMS TO CONSTRUCTION -- 3.1. Selection -- 3.2. Cutting -- 3.3. Curing -- 3.4. Drying -- 3.5. Immunization Treatments -- 4. PHYSICAL PROPERTIES -- 4.1. Inter-nodal Distance, Outside Diameter, Wall Thickness -- 4.2. Water Absorption -- 4.3. Specific Mass -- 5. MECHANICAL PROPERTIES -- 5.1. Compressive Strength -- 5.2. Compressive Strength Parallel to Fibers -- 5.3. Shear Strength Parallel to Fibers -- 5.4. Summary of Mechanical Properties in Tension and Compression Parallel to Fibers -- 6. FUTURE PERSPECTIVES -- 6.1. Impregnation of Bamboo with Polymeric Resins -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Frontiers in Bio-Inspired Mineralization: Addressing Mimesis of Four-Dimensional, Hierarchical, and Nonclassical Growth Characteristics of Biominerals -- Stephan E. Wolf1,2,*, Martina Schüßler1, Corinna F. Böhm1 and Benedikt Demmert1 -- 1. INTRODUCTION -- 2. TOWARDS DYNAMIC CONTROL OF MINERALIZATION -- THE STATIC, QUASI-STATIC, AND DYNAMIC GENESIS OF BIOMINERALS -- 3. HIERARCHICAL MINERALIZATION -- CONTROL OF HIERARCHY AND STRUCTURES ACROSS MULTIPLE LENGTH SCALES -- 4. NONCLASSICAL MINERALIZATION -- COLLOID-MEDIATED MINERALIZATION PROCESSES AS A SOURCE OF FUNCTIONAL NANO- TO MESO-STRUCTURES -- CONCLUSION -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Sustainable and Safe Construction Biomaterials: Biocements and Biogrouts -- Volodymyr Ivanov* and Viktor Stabnikov -- 1. INTRODUCTION -- 2. BIOCEMENT/BIOGROUT FOR CRYSTALLIZATION OF CALCIUM CARBONATE BY HYDROLYSIS OF UREA AT MOLAR RATIO CA: UREA = 0.5 -- 2.0 (CAUR BIOCEMENT/BIOGROUT) -- 3. THE DIVERSITY OF BIOCEMENTS AND BIOGROUTS -- 4. MICROORGANISMS FOR BIOCEMENT/BIOGROUT. 5. BIOCEMENTATION BIOSAFETY: USE OF ENRICHMENT OR PURE CULTURE -- 6. PRODUCTION OF BIOSAFE BIOCEMENTS -- 7. ACTIVATED SLUDGE FROM MUNICIPAL WASTEWATER TREATMENT PLANTS USED AS RAW MATERIAL -- 8. DRY AND LIQUID CALCIUM-BASED BIOCEMENT -- 9. UNCONFINED COMPRESSIVE (UC) STRENGTH OF SAND AFTER MICP -- 10. ENGINEERING APPLICATIONS OF BIOCEMENTS -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Interaction Between Natural Fibres and Synthetic Polymers -- Alejandro Manzano-Ramírez1,*, Mario Villalón2 and José Luis Reyes Araiza3 -- 1. INTRODUCTION -- 2. REINFORCED COMPOSITE MATERIALS WITH NATURAL FIBERS -- 2.1. Natural Fibers -- 2.2. Chemical Treatments to Promote Adherence of Natural Fibers -- 3. TESTING STATIC METHODS -- 3.1. Conclusions of Static Tests -- 4. TESTING-VIBRATION METHODS -- 4.1. Dynamic Mechanical Analysis (DMA) -- 4.2. Design of Dynamic Mechanical Tests -- 4.2.1. Preparation of Treated Short Coir Fibre -- 4.2.2. Composite Materials Fabrication -- 4.2.3. Dynamic Test -- 4.3. Coir Fiber Dynamic Test Results -- CONCLUSION -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Subject Index -- Back Cover. |
| ctrlnum | (OCoLC)1101786302 |
| dewey-full | 610.28/4 |
| dewey-hundreds | 600 - Technology (Applied sciences) |
| dewey-ones | 610 - Medicine and health |
| dewey-raw | 610.28/4 |
| dewey-search | 610.28/4 |
| dewey-sort | 3610.28 14 |
| dewey-tens | 610 - Medicine and health |
| discipline | Medizin |
| format | Electronic eBook |
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Phocas*, Odysseas Kontovourkis and Niki I. Georgiou -- 1. INTRODUCTION -- 2. BIOMIMETIC DESIGN -- 3. KINEMATICS -- 3.1. Soft-mechanical Approach -- 3.2. Simulation Approaches -- 4. BIO-PULSE OSCILLATIONS -- 5. CASE STUDY: HIGH-RISE AIRFLOW SYSTEM -- 5.1. Primary Structure -- 5.2. Secondary Kinetic Mechanism -- 5.2.1. Simulation Analysis -- 6. CONCLUSIONS -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Truss Material Reduction Provided by the Golden Ratio -- Ulisses Targino Bezerra* -- 1. INTRODUCTION -- 2. PRATT TRUSS MODELS -- 3. PRATT TRUSS ANALYSIS -- CONCLUSIONS -- ACKNOWLEDGEMENTS -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- REFERENCES -- Complexity and Adaptability in Nature and Society -- George Rzevski* -- 1. INTRODUCTION -- 2. WHAT IS COMPLEXITY? -- 3. SEVEN KEY PROPERTIES OF COMPLEXITY -- 3.1. Connectivity -- 3.2. Autonomy -- 3.3. Emergence -- 3.4. Nonequilibrium -- 3.5. Nonlinearity -- 3.6. Self-organization -- 3.7. Co-evolution -- 4. COMPLEXITY SCIENCE -- 4.1. Brief Overview -- Our social, economic and political environments cannot be simplified because their complexity is a result of evolutionary forces, which are not under our control. -- 5. ADAPTABILITY -- 5.1. Coping with Disruptions -- 5.2. Defending from Attacks -- 5.3. Resolving Conflicts -- 5.4. Correcting Drift into Failure and Avoiding Stagnation -- 6. DESIGNING FOR ADAPTABILITY -- 7. TECHNOLOGY FOR DESIGNING COMPLEXITY INTO ORGANIZATIONS, PROCESSES AND PRODUCTS -- 7.1. Architecture -- 7.2. How Multi-Agent Software Works -- 7.3. Organizational and Process Design Cases -- 7.4. Engineering Design Cases -- CONCLUSIONS -- CONSENT FOR PUBLICATION.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Without Inner Walls: A Concept of the Café's House -- Theófilo Barreto Moreira Oliveira1,* and Ulisses Targino Bezerra2 -- 1. INTRODUCTION -- 2. OW: WITHOUT INNER WALLS -- 3. FLOOR PLAN -- 4. STUDIO -- 5. LIVING ROOM -- 6. KITCHEN AND DINING ROOM -- 7. OFFICE AND BALCONY -- 8. BATHROOM/WC -- 9. LAVATORY -- 10. GUEST ROOM -- 11. SUITE -- 12. ROOFTOP TERRACE -- 13. SERVICE AREA -- 14. THE NULLIFICATION OF OW -- NOTES -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Similarity Between Particle Packing in Concrete and in Nature -- Eng. Piet Stroeven1,* and Eng. Kai Li2 -- 1. INTRODUCTION -- 2. REALCRETE AND COMPUCRETE -- 3. AGGREGATE PACKING BY DEM -- 3.1. Bulk Packing -- 3.2. Boundary Effects -- 4. PACKING OF FIBERS IN CONCRETE -- 5. DEM PACKING OF BINDER -- DISCUSSION AND CONCLUSIONS -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Current Developments and Future Needs for Natural Earth Construction: A State-of-the-Art Review -- Ana Cecilia Vieira Nóbrega1 and Normando Perazzo Barbosa2* -- 1. INTRODUCTION -- 2. AN OVERVIEW OF NATURAL EARTH BUILDING -- 3. SOIL -- MATERIALS SELECTION FOR EARTH CONSTRUCTION -- 4. DURABILITY OF EARTHEN CONSTRUCTION -- 5. ACADEMIC AND FIELD RESEARCH IN NATURAL EARTH CONSTRUCTIONS: A STATE-OF-THE-ART REVIEW WITH CURRENT DEVELOPMENTS -- 6. DEVELOPING EARTH CONSTRUCTION BUILDING CODES, STANDARDS, AND NORMS -- 7. WORLD INNOVATIONS IN EARTHEN CONSTRUCTION -- 8. FUTURE NEEDS IN EARTH BUILDING -- FINAL CONSIDERATIONS -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Bio-inspired Design with Bamboo -- Normando Perazzo Barbosa1,*, José Augusto Gomes Neto1, Sandra Reyes Ortiz2 and Khosrow Ghavami3 -- 1. INTRODUCTION -- 2. GENERALITIES CONCERNING BAMBOO.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">2.1. Morphology -- 2.1.1. Rhizomes and Roots -- 2.1.2. Culms -- 2.1.3. Branches -- 2.1.4. Leaves -- 2.1.5. Flowers and Fruits -- 3. HOW TO GET CULMS TO CONSTRUCTION -- 3.1. Selection -- 3.2. Cutting -- 3.3. Curing -- 3.4. Drying -- 3.5. Immunization Treatments -- 4. PHYSICAL PROPERTIES -- 4.1. Inter-nodal Distance, Outside Diameter, Wall Thickness -- 4.2. Water Absorption -- 4.3. Specific Mass -- 5. MECHANICAL PROPERTIES -- 5.1. Compressive Strength -- 5.2. Compressive Strength Parallel to Fibers -- 5.3. Shear Strength Parallel to Fibers -- 5.4. Summary of Mechanical Properties in Tension and Compression Parallel to Fibers -- 6. FUTURE PERSPECTIVES -- 6.1. Impregnation of Bamboo with Polymeric Resins -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Frontiers in Bio-Inspired Mineralization: Addressing Mimesis of Four-Dimensional, Hierarchical, and Nonclassical Growth Characteristics of Biominerals -- Stephan E. Wolf1,2,*, Martina Schüßler1, Corinna F. Böhm1 and Benedikt Demmert1 -- 1. INTRODUCTION -- 2. TOWARDS DYNAMIC CONTROL OF MINERALIZATION -- THE STATIC, QUASI-STATIC, AND DYNAMIC GENESIS OF BIOMINERALS -- 3. HIERARCHICAL MINERALIZATION -- CONTROL OF HIERARCHY AND STRUCTURES ACROSS MULTIPLE LENGTH SCALES -- 4. NONCLASSICAL MINERALIZATION -- COLLOID-MEDIATED MINERALIZATION PROCESSES AS A SOURCE OF FUNCTIONAL NANO- TO MESO-STRUCTURES -- CONCLUSION -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Sustainable and Safe Construction Biomaterials: Biocements and Biogrouts -- Volodymyr Ivanov* and Viktor Stabnikov -- 1. INTRODUCTION -- 2. BIOCEMENT/BIOGROUT FOR CRYSTALLIZATION OF CALCIUM CARBONATE BY HYDROLYSIS OF UREA AT MOLAR RATIO CA: UREA = 0.5 -- 2.0 (CAUR BIOCEMENT/BIOGROUT) -- 3. THE DIVERSITY OF BIOCEMENTS AND BIOGROUTS -- 4. MICROORGANISMS FOR BIOCEMENT/BIOGROUT.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">5. BIOCEMENTATION BIOSAFETY: USE OF ENRICHMENT OR PURE CULTURE -- 6. PRODUCTION OF BIOSAFE BIOCEMENTS -- 7. ACTIVATED SLUDGE FROM MUNICIPAL WASTEWATER TREATMENT PLANTS USED AS RAW MATERIAL -- 8. DRY AND LIQUID CALCIUM-BASED BIOCEMENT -- 9. UNCONFINED COMPRESSIVE (UC) STRENGTH OF SAND AFTER MICP -- 10. ENGINEERING APPLICATIONS OF BIOCEMENTS -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Interaction Between Natural Fibres and Synthetic Polymers -- Alejandro Manzano-Ramírez1,*, Mario Villalón2 and José Luis Reyes Araiza3 -- 1. INTRODUCTION -- 2. REINFORCED COMPOSITE MATERIALS WITH NATURAL FIBERS -- 2.1. Natural Fibers -- 2.2. Chemical Treatments to Promote Adherence of Natural Fibers -- 3. TESTING STATIC METHODS -- 3.1. Conclusions of Static Tests -- 4. TESTING-VIBRATION METHODS -- 4.1. Dynamic Mechanical Analysis (DMA) -- 4.2. Design of Dynamic Mechanical Tests -- 4.2.1. Preparation of Treated Short Coir Fibre -- 4.2.2. Composite Materials Fabrication -- 4.2.3. Dynamic Test -- 4.3. Coir Fiber Dynamic Test Results -- CONCLUSION -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Subject Index -- Back Cover.</subfield></datafield><datafield tag="650" ind1=" " ind2="0"><subfield code="a">Biomedical materials.</subfield><subfield code="0">http://id.loc.gov/authorities/subjects/sh85014239</subfield></datafield><datafield tag="650" ind1=" " ind2="6"><subfield code="a">Biomatériaux.</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">Biomedical materials</subfield><subfield code="2">fast</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Bezerra, Ulisses Targino,</subfield><subfield code="e">editor.</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Ferreira, Heber Sivini,</subfield><subfield code="e">editor.</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Barbosa, Normando Perazzo,</subfield><subfield code="e">editor.</subfield></datafield><datafield tag="776" ind1="0" ind2="8"><subfield code="i">Print version:</subfield><subfield code="a">Bezerra, Ulisses Targino.</subfield><subfield code="t">Bio-Inspired Materials.</subfield><subfield code="d">Sharjah : Bentham Science Publishers, ©2019</subfield><subfield code="z">9789811406881</subfield></datafield><datafield tag="830" ind1=" " ind2="0"><subfield code="a">Frontiers in biomaterials ;</subfield><subfield code="v">v. 6.</subfield></datafield><datafield tag="856" ind1="4" ind2="0"><subfield code="l">FWS01</subfield><subfield code="p">ZDB-4-EBA</subfield><subfield code="q">FWS_PDA_EBA</subfield><subfield code="u">https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=2127204</subfield><subfield code="3">Volltext</subfield></datafield><datafield tag="936" ind1=" " ind2=" "><subfield code="a">BATCHLOAD</subfield></datafield><datafield tag="938" ind1=" " ind2=" "><subfield code="a">Askews and Holts Library Services</subfield><subfield code="b">ASKH</subfield><subfield code="n">AH37038483</subfield></datafield><datafield tag="938" ind1=" " ind2=" "><subfield code="a">ProQuest Ebook Central</subfield><subfield code="b">EBLB</subfield><subfield code="n">EBL5771741</subfield></datafield><datafield tag="938" ind1=" " ind2=" "><subfield code="a">YBP Library Services</subfield><subfield code="b">YANK</subfield><subfield code="n">300523473</subfield></datafield><datafield tag="938" ind1=" " ind2=" "><subfield code="a">EBSCOhost</subfield><subfield code="b">EBSC</subfield><subfield code="n">2127204</subfield></datafield><datafield tag="938" ind1=" " ind2=" "><subfield code="b">OCKB</subfield><subfield code="z">perlego.catalogue,039ef90d-80bd-4c5a-b5dd-d28ab4973070-emi</subfield></datafield><datafield tag="994" ind1=" " ind2=" "><subfield code="a">92</subfield><subfield code="b">GEBAY</subfield></datafield><datafield tag="912" ind1=" " ind2=" "><subfield code="a">ZDB-4-EBA</subfield></datafield><datafield tag="049" ind1=" " ind2=" "><subfield code="a">DE-863</subfield></datafield></record></collection> |
| id | ZDB-4-EBA-on1101786302 |
| illustrated | Not Illustrated |
| indexdate | 2024-11-27T13:29:29Z |
| institution | BVB |
| isbn | 9811406898 9789811406898 |
| language | English |
| oclc_num | 1101786302 |
| open_access_boolean | |
| owner | MAIN DE-863 DE-BY-FWS |
| owner_facet | MAIN DE-863 DE-BY-FWS |
| physical | 1 online resource (247 pages) |
| psigel | ZDB-4-EBA |
| publishDate | 2019 |
| publishDateSearch | 2019 |
| publishDateSort | 2019 |
| publisher | Bentham Science Publishers, |
| record_format | marc |
| series | Frontiers in biomaterials ; |
| series2 | Frontiers in Biomaterials Ser. |
| spelling | Bio-Inspired Materials. Singapore : Bentham Science Publishers, 2019. 1 online resource (247 pages) text txt rdacontent computer c rdamedia online resource cr rdacarrier Frontiers in Biomaterials Ser. Print version record. Cover -- Title -- Biblography -- End User License Agreement -- Contents -- Preface -- List of Contributors -- Bio-Pulse Oscillations Driven Design of Kinetic Structures -- Marios C. Phocas*, Odysseas Kontovourkis and Niki I. Georgiou -- 1. INTRODUCTION -- 2. BIOMIMETIC DESIGN -- 3. KINEMATICS -- 3.1. Soft-mechanical Approach -- 3.2. Simulation Approaches -- 4. BIO-PULSE OSCILLATIONS -- 5. CASE STUDY: HIGH-RISE AIRFLOW SYSTEM -- 5.1. Primary Structure -- 5.2. Secondary Kinetic Mechanism -- 5.2.1. Simulation Analysis -- 6. CONCLUSIONS -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Truss Material Reduction Provided by the Golden Ratio -- Ulisses Targino Bezerra* -- 1. INTRODUCTION -- 2. PRATT TRUSS MODELS -- 3. PRATT TRUSS ANALYSIS -- CONCLUSIONS -- ACKNOWLEDGEMENTS -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- REFERENCES -- Complexity and Adaptability in Nature and Society -- George Rzevski* -- 1. INTRODUCTION -- 2. WHAT IS COMPLEXITY? -- 3. SEVEN KEY PROPERTIES OF COMPLEXITY -- 3.1. Connectivity -- 3.2. Autonomy -- 3.3. Emergence -- 3.4. Nonequilibrium -- 3.5. Nonlinearity -- 3.6. Self-organization -- 3.7. Co-evolution -- 4. COMPLEXITY SCIENCE -- 4.1. Brief Overview -- Our social, economic and political environments cannot be simplified because their complexity is a result of evolutionary forces, which are not under our control. -- 5. ADAPTABILITY -- 5.1. Coping with Disruptions -- 5.2. Defending from Attacks -- 5.3. Resolving Conflicts -- 5.4. Correcting Drift into Failure and Avoiding Stagnation -- 6. DESIGNING FOR ADAPTABILITY -- 7. TECHNOLOGY FOR DESIGNING COMPLEXITY INTO ORGANIZATIONS, PROCESSES AND PRODUCTS -- 7.1. Architecture -- 7.2. How Multi-Agent Software Works -- 7.3. Organizational and Process Design Cases -- 7.4. Engineering Design Cases -- CONCLUSIONS -- CONSENT FOR PUBLICATION. ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Without Inner Walls: A Concept of the Café's House -- Theófilo Barreto Moreira Oliveira1,* and Ulisses Targino Bezerra2 -- 1. INTRODUCTION -- 2. OW: WITHOUT INNER WALLS -- 3. FLOOR PLAN -- 4. STUDIO -- 5. LIVING ROOM -- 6. KITCHEN AND DINING ROOM -- 7. OFFICE AND BALCONY -- 8. BATHROOM/WC -- 9. LAVATORY -- 10. GUEST ROOM -- 11. SUITE -- 12. ROOFTOP TERRACE -- 13. SERVICE AREA -- 14. THE NULLIFICATION OF OW -- NOTES -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Similarity Between Particle Packing in Concrete and in Nature -- Eng. Piet Stroeven1,* and Eng. Kai Li2 -- 1. INTRODUCTION -- 2. REALCRETE AND COMPUCRETE -- 3. AGGREGATE PACKING BY DEM -- 3.1. Bulk Packing -- 3.2. Boundary Effects -- 4. PACKING OF FIBERS IN CONCRETE -- 5. DEM PACKING OF BINDER -- DISCUSSION AND CONCLUSIONS -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Current Developments and Future Needs for Natural Earth Construction: A State-of-the-Art Review -- Ana Cecilia Vieira Nóbrega1 and Normando Perazzo Barbosa2* -- 1. INTRODUCTION -- 2. AN OVERVIEW OF NATURAL EARTH BUILDING -- 3. SOIL -- MATERIALS SELECTION FOR EARTH CONSTRUCTION -- 4. DURABILITY OF EARTHEN CONSTRUCTION -- 5. ACADEMIC AND FIELD RESEARCH IN NATURAL EARTH CONSTRUCTIONS: A STATE-OF-THE-ART REVIEW WITH CURRENT DEVELOPMENTS -- 6. DEVELOPING EARTH CONSTRUCTION BUILDING CODES, STANDARDS, AND NORMS -- 7. WORLD INNOVATIONS IN EARTHEN CONSTRUCTION -- 8. FUTURE NEEDS IN EARTH BUILDING -- FINAL CONSIDERATIONS -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Bio-inspired Design with Bamboo -- Normando Perazzo Barbosa1,*, José Augusto Gomes Neto1, Sandra Reyes Ortiz2 and Khosrow Ghavami3 -- 1. INTRODUCTION -- 2. GENERALITIES CONCERNING BAMBOO. 2.1. Morphology -- 2.1.1. Rhizomes and Roots -- 2.1.2. Culms -- 2.1.3. Branches -- 2.1.4. Leaves -- 2.1.5. Flowers and Fruits -- 3. HOW TO GET CULMS TO CONSTRUCTION -- 3.1. Selection -- 3.2. Cutting -- 3.3. Curing -- 3.4. Drying -- 3.5. Immunization Treatments -- 4. PHYSICAL PROPERTIES -- 4.1. Inter-nodal Distance, Outside Diameter, Wall Thickness -- 4.2. Water Absorption -- 4.3. Specific Mass -- 5. MECHANICAL PROPERTIES -- 5.1. Compressive Strength -- 5.2. Compressive Strength Parallel to Fibers -- 5.3. Shear Strength Parallel to Fibers -- 5.4. Summary of Mechanical Properties in Tension and Compression Parallel to Fibers -- 6. FUTURE PERSPECTIVES -- 6.1. Impregnation of Bamboo with Polymeric Resins -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Frontiers in Bio-Inspired Mineralization: Addressing Mimesis of Four-Dimensional, Hierarchical, and Nonclassical Growth Characteristics of Biominerals -- Stephan E. Wolf1,2,*, Martina Schüßler1, Corinna F. Böhm1 and Benedikt Demmert1 -- 1. INTRODUCTION -- 2. TOWARDS DYNAMIC CONTROL OF MINERALIZATION -- THE STATIC, QUASI-STATIC, AND DYNAMIC GENESIS OF BIOMINERALS -- 3. HIERARCHICAL MINERALIZATION -- CONTROL OF HIERARCHY AND STRUCTURES ACROSS MULTIPLE LENGTH SCALES -- 4. NONCLASSICAL MINERALIZATION -- COLLOID-MEDIATED MINERALIZATION PROCESSES AS A SOURCE OF FUNCTIONAL NANO- TO MESO-STRUCTURES -- CONCLUSION -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Sustainable and Safe Construction Biomaterials: Biocements and Biogrouts -- Volodymyr Ivanov* and Viktor Stabnikov -- 1. INTRODUCTION -- 2. BIOCEMENT/BIOGROUT FOR CRYSTALLIZATION OF CALCIUM CARBONATE BY HYDROLYSIS OF UREA AT MOLAR RATIO CA: UREA = 0.5 -- 2.0 (CAUR BIOCEMENT/BIOGROUT) -- 3. THE DIVERSITY OF BIOCEMENTS AND BIOGROUTS -- 4. MICROORGANISMS FOR BIOCEMENT/BIOGROUT. 5. BIOCEMENTATION BIOSAFETY: USE OF ENRICHMENT OR PURE CULTURE -- 6. PRODUCTION OF BIOSAFE BIOCEMENTS -- 7. ACTIVATED SLUDGE FROM MUNICIPAL WASTEWATER TREATMENT PLANTS USED AS RAW MATERIAL -- 8. DRY AND LIQUID CALCIUM-BASED BIOCEMENT -- 9. UNCONFINED COMPRESSIVE (UC) STRENGTH OF SAND AFTER MICP -- 10. ENGINEERING APPLICATIONS OF BIOCEMENTS -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Interaction Between Natural Fibres and Synthetic Polymers -- Alejandro Manzano-Ramírez1,*, Mario Villalón2 and José Luis Reyes Araiza3 -- 1. INTRODUCTION -- 2. REINFORCED COMPOSITE MATERIALS WITH NATURAL FIBERS -- 2.1. Natural Fibers -- 2.2. Chemical Treatments to Promote Adherence of Natural Fibers -- 3. TESTING STATIC METHODS -- 3.1. Conclusions of Static Tests -- 4. TESTING-VIBRATION METHODS -- 4.1. Dynamic Mechanical Analysis (DMA) -- 4.2. Design of Dynamic Mechanical Tests -- 4.2.1. Preparation of Treated Short Coir Fibre -- 4.2.2. Composite Materials Fabrication -- 4.2.3. Dynamic Test -- 4.3. Coir Fiber Dynamic Test Results -- CONCLUSION -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Subject Index -- Back Cover. Biomedical materials. http://id.loc.gov/authorities/subjects/sh85014239 Biomatériaux. Biomedical materials fast Bezerra, Ulisses Targino, editor. Ferreira, Heber Sivini, editor. Barbosa, Normando Perazzo, editor. Print version: Bezerra, Ulisses Targino. Bio-Inspired Materials. Sharjah : Bentham Science Publishers, ©2019 9789811406881 Frontiers in biomaterials ; v. 6. FWS01 ZDB-4-EBA FWS_PDA_EBA https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=2127204 Volltext |
| spellingShingle | Bio-Inspired Materials. Frontiers in biomaterials ; Cover -- Title -- Biblography -- End User License Agreement -- Contents -- Preface -- List of Contributors -- Bio-Pulse Oscillations Driven Design of Kinetic Structures -- Marios C. Phocas*, Odysseas Kontovourkis and Niki I. Georgiou -- 1. INTRODUCTION -- 2. BIOMIMETIC DESIGN -- 3. KINEMATICS -- 3.1. Soft-mechanical Approach -- 3.2. Simulation Approaches -- 4. BIO-PULSE OSCILLATIONS -- 5. CASE STUDY: HIGH-RISE AIRFLOW SYSTEM -- 5.1. Primary Structure -- 5.2. Secondary Kinetic Mechanism -- 5.2.1. Simulation Analysis -- 6. CONCLUSIONS -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Truss Material Reduction Provided by the Golden Ratio -- Ulisses Targino Bezerra* -- 1. INTRODUCTION -- 2. PRATT TRUSS MODELS -- 3. PRATT TRUSS ANALYSIS -- CONCLUSIONS -- ACKNOWLEDGEMENTS -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- REFERENCES -- Complexity and Adaptability in Nature and Society -- George Rzevski* -- 1. INTRODUCTION -- 2. WHAT IS COMPLEXITY? -- 3. SEVEN KEY PROPERTIES OF COMPLEXITY -- 3.1. Connectivity -- 3.2. Autonomy -- 3.3. Emergence -- 3.4. Nonequilibrium -- 3.5. Nonlinearity -- 3.6. Self-organization -- 3.7. Co-evolution -- 4. COMPLEXITY SCIENCE -- 4.1. Brief Overview -- Our social, economic and political environments cannot be simplified because their complexity is a result of evolutionary forces, which are not under our control. -- 5. ADAPTABILITY -- 5.1. Coping with Disruptions -- 5.2. Defending from Attacks -- 5.3. Resolving Conflicts -- 5.4. Correcting Drift into Failure and Avoiding Stagnation -- 6. DESIGNING FOR ADAPTABILITY -- 7. TECHNOLOGY FOR DESIGNING COMPLEXITY INTO ORGANIZATIONS, PROCESSES AND PRODUCTS -- 7.1. Architecture -- 7.2. How Multi-Agent Software Works -- 7.3. Organizational and Process Design Cases -- 7.4. Engineering Design Cases -- CONCLUSIONS -- CONSENT FOR PUBLICATION. ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Without Inner Walls: A Concept of the Café's House -- Theófilo Barreto Moreira Oliveira1,* and Ulisses Targino Bezerra2 -- 1. INTRODUCTION -- 2. OW: WITHOUT INNER WALLS -- 3. FLOOR PLAN -- 4. STUDIO -- 5. LIVING ROOM -- 6. KITCHEN AND DINING ROOM -- 7. OFFICE AND BALCONY -- 8. BATHROOM/WC -- 9. LAVATORY -- 10. GUEST ROOM -- 11. SUITE -- 12. ROOFTOP TERRACE -- 13. SERVICE AREA -- 14. THE NULLIFICATION OF OW -- NOTES -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Similarity Between Particle Packing in Concrete and in Nature -- Eng. Piet Stroeven1,* and Eng. Kai Li2 -- 1. INTRODUCTION -- 2. REALCRETE AND COMPUCRETE -- 3. AGGREGATE PACKING BY DEM -- 3.1. Bulk Packing -- 3.2. Boundary Effects -- 4. PACKING OF FIBERS IN CONCRETE -- 5. DEM PACKING OF BINDER -- DISCUSSION AND CONCLUSIONS -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Current Developments and Future Needs for Natural Earth Construction: A State-of-the-Art Review -- Ana Cecilia Vieira Nóbrega1 and Normando Perazzo Barbosa2* -- 1. INTRODUCTION -- 2. AN OVERVIEW OF NATURAL EARTH BUILDING -- 3. SOIL -- MATERIALS SELECTION FOR EARTH CONSTRUCTION -- 4. DURABILITY OF EARTHEN CONSTRUCTION -- 5. ACADEMIC AND FIELD RESEARCH IN NATURAL EARTH CONSTRUCTIONS: A STATE-OF-THE-ART REVIEW WITH CURRENT DEVELOPMENTS -- 6. DEVELOPING EARTH CONSTRUCTION BUILDING CODES, STANDARDS, AND NORMS -- 7. WORLD INNOVATIONS IN EARTHEN CONSTRUCTION -- 8. FUTURE NEEDS IN EARTH BUILDING -- FINAL CONSIDERATIONS -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Bio-inspired Design with Bamboo -- Normando Perazzo Barbosa1,*, José Augusto Gomes Neto1, Sandra Reyes Ortiz2 and Khosrow Ghavami3 -- 1. INTRODUCTION -- 2. GENERALITIES CONCERNING BAMBOO. 2.1. Morphology -- 2.1.1. Rhizomes and Roots -- 2.1.2. Culms -- 2.1.3. Branches -- 2.1.4. Leaves -- 2.1.5. Flowers and Fruits -- 3. HOW TO GET CULMS TO CONSTRUCTION -- 3.1. Selection -- 3.2. Cutting -- 3.3. Curing -- 3.4. Drying -- 3.5. Immunization Treatments -- 4. PHYSICAL PROPERTIES -- 4.1. Inter-nodal Distance, Outside Diameter, Wall Thickness -- 4.2. Water Absorption -- 4.3. Specific Mass -- 5. MECHANICAL PROPERTIES -- 5.1. Compressive Strength -- 5.2. Compressive Strength Parallel to Fibers -- 5.3. Shear Strength Parallel to Fibers -- 5.4. Summary of Mechanical Properties in Tension and Compression Parallel to Fibers -- 6. FUTURE PERSPECTIVES -- 6.1. Impregnation of Bamboo with Polymeric Resins -- CONSENT FOR PUBLICATION -- ACKNOWLEDGEMENTS -- CONFLICT OF INTEREST -- REFERENCES -- Frontiers in Bio-Inspired Mineralization: Addressing Mimesis of Four-Dimensional, Hierarchical, and Nonclassical Growth Characteristics of Biominerals -- Stephan E. Wolf1,2,*, Martina Schüßler1, Corinna F. Böhm1 and Benedikt Demmert1 -- 1. INTRODUCTION -- 2. TOWARDS DYNAMIC CONTROL OF MINERALIZATION -- THE STATIC, QUASI-STATIC, AND DYNAMIC GENESIS OF BIOMINERALS -- 3. HIERARCHICAL MINERALIZATION -- CONTROL OF HIERARCHY AND STRUCTURES ACROSS MULTIPLE LENGTH SCALES -- 4. NONCLASSICAL MINERALIZATION -- COLLOID-MEDIATED MINERALIZATION PROCESSES AS A SOURCE OF FUNCTIONAL NANO- TO MESO-STRUCTURES -- CONCLUSION -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Sustainable and Safe Construction Biomaterials: Biocements and Biogrouts -- Volodymyr Ivanov* and Viktor Stabnikov -- 1. INTRODUCTION -- 2. BIOCEMENT/BIOGROUT FOR CRYSTALLIZATION OF CALCIUM CARBONATE BY HYDROLYSIS OF UREA AT MOLAR RATIO CA: UREA = 0.5 -- 2.0 (CAUR BIOCEMENT/BIOGROUT) -- 3. THE DIVERSITY OF BIOCEMENTS AND BIOGROUTS -- 4. MICROORGANISMS FOR BIOCEMENT/BIOGROUT. 5. BIOCEMENTATION BIOSAFETY: USE OF ENRICHMENT OR PURE CULTURE -- 6. PRODUCTION OF BIOSAFE BIOCEMENTS -- 7. ACTIVATED SLUDGE FROM MUNICIPAL WASTEWATER TREATMENT PLANTS USED AS RAW MATERIAL -- 8. DRY AND LIQUID CALCIUM-BASED BIOCEMENT -- 9. UNCONFINED COMPRESSIVE (UC) STRENGTH OF SAND AFTER MICP -- 10. ENGINEERING APPLICATIONS OF BIOCEMENTS -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Interaction Between Natural Fibres and Synthetic Polymers -- Alejandro Manzano-Ramírez1,*, Mario Villalón2 and José Luis Reyes Araiza3 -- 1. INTRODUCTION -- 2. REINFORCED COMPOSITE MATERIALS WITH NATURAL FIBERS -- 2.1. Natural Fibers -- 2.2. Chemical Treatments to Promote Adherence of Natural Fibers -- 3. TESTING STATIC METHODS -- 3.1. Conclusions of Static Tests -- 4. TESTING-VIBRATION METHODS -- 4.1. Dynamic Mechanical Analysis (DMA) -- 4.2. Design of Dynamic Mechanical Tests -- 4.2.1. Preparation of Treated Short Coir Fibre -- 4.2.2. Composite Materials Fabrication -- 4.2.3. Dynamic Test -- 4.3. Coir Fiber Dynamic Test Results -- CONCLUSION -- CONSENT FOR PUBLICATION -- CONFLICT OF INTEREST -- ACKNOWLEDGEMENTS -- REFERENCES -- Subject Index -- Back Cover. Biomedical materials. http://id.loc.gov/authorities/subjects/sh85014239 Biomatériaux. Biomedical materials fast |
| subject_GND | http://id.loc.gov/authorities/subjects/sh85014239 |
| title | Bio-Inspired Materials. |
| title_auth | Bio-Inspired Materials. |
| title_exact_search | Bio-Inspired Materials. |
| title_full | Bio-Inspired Materials. |
| title_fullStr | Bio-Inspired Materials. |
| title_full_unstemmed | Bio-Inspired Materials. |
| title_short | Bio-Inspired Materials. |
| title_sort | bio inspired materials |
| topic | Biomedical materials. http://id.loc.gov/authorities/subjects/sh85014239 Biomatériaux. Biomedical materials fast |
| topic_facet | Biomedical materials. Biomatériaux. Biomedical materials |
| url | https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=2127204 |
| work_keys_str_mv | AT bezerraulissestargino bioinspiredmaterials AT ferreirahebersivini bioinspiredmaterials AT barbosanormandoperazzo bioinspiredmaterials |