Evaporative Self-assembly of Ordered Complex Structures:
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| Format: | Elektronisch E-Book |
| Sprache: | English |
| Veröffentlicht: |
Singapore
World Scientific
2012
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| Online-Zugang: | FAW01 FAW02 Volltext |
| Beschreibung: | 3.2.3. The effect of electrolytes and surfactants Preface; CONTENTS; 1. Drying a Sessile Droplet: Imaging and Analysis of Transport and Deposition Patterns; 1.1. Introduction; 1.2. The Basic Droplet-Drying Phenomenon; 1.3. Mathematic Models; 1.3.1. Droplet shape; 1.3.2. Governing equations; 1.3.3. Boundary conditions; 1.3.3.1. Mass transfer in the vapor phase; 1.3.3.2. Heat transfer in droplet and substrate; 1.3.3.3. Momentum transfer; 1.4. Vapor Phase Transport; 1.4.1. Analytical solutions; 1.4.2. Finite element analysis; 1.5. Height-Averaged Radial Velocity; 1.6. Full Flow Solution without Marangoni Effect 1.6.1. The derivation of the flow field1.6.2. Finite element analysis; 1.6.3. Comparison between finite element and analytical solutions; 1.6.4. Application to deposition and stretching of DNA; 1.7. Full Flow Solutions with Marangoni Effect; 1.7.1. Expressions for the velocity field with a thermal Marangoni stress boundary condition; 1.7.2. General expressions for the velocity field with Marangoni stresses; 1.7.3. Full analytical solutions; 1.7.4. Temperature field; 1.7.5. Velocity field; 1.7.6. Surface-active contaminants; 1.7.7. Marangoni stress reverses particle deposition pattern 1.8. Manipulation of Flow for Patterned Depositions1.9. Conclusions and Outlook; References; 2. Convective Assembly of Patterned Media; 2.1. Introduction; 2.2. Review of Prevailing Mechanisms in Convective Assembly; 2.2.1. Drop casting of colloidal suspensions; 2.2.2. Deposition of colloidal particles in plate-withdrawal experiments or vertical deposition; 2.3. Spontaneously Patterned Colloidal Structures; 2.3.1. Patterning by exploiting the Marangoni-Bénard instability; 2.3.2. Patterning by fingering instabilities or unstable fluid fronts; 2.3.3. Patterning by the capillary instability 2.3.4. Patterning by contact line pinning and jumping2.3.5. Patterning by spontaneous dewetting; 2.4. Templating of Colloidal Structures Using Patterned Substrates; 2.4.1. Particle patterning exploiting surfaces of patterned surface charge; 2.4.2. Particle patterning exploiting surfaces of patterned wetting; 2.4.3. Particle patterning exploiting surfaces of patterned topography; 2.4.3.1. Capillarity based assembly in surfaces of patterned topography; 2.4.3.2. Ordering in the presence of applied fields; 2.4.3.3. The use of confinement and capillary interactions to form ordered structures 2.5. Open Issues2.6. Conclusions and Outlook; References; 3. Materials Deposition in Evaporating Menisci -- Fundamentals and Engineering Applications of the Convective Assembly Process; 3.1. Introduction and Background to Convective Assembly; 3.1.1. Convective assembly in thin wetting films; 3.1.2. Drying droplets -- The dynamics of deposition and structure of the deposits; 3.2. Engineering of the Process of Convective Assembly at High Volume Fractions; 3.2.1. The effect of evaporation rate and particle concentration; 3.2.2. The effect of temperature The use of spontaneous self-assembly, as a lithographic tool and as an external field-free means to construct well-ordered and intriguing patterns, has received much attention due to its ease of producing complex, large-scale structures with small feature sizes. An extremely simple route to highly-ordered, complex structures is the evaporative self-assembly of nonvolatile solutes (e.g., polymers, nanoparticles, carbon nanotubes, and DNA) from a sessile droplet on a solid substrate. To date, a few studies have elegantly demonstrated that self-organized nanoscale, microscale, and hierarchically |
| Beschreibung: | 1 Online-Ressource (395 pages) |
| ISBN: | 9789814304689 9789814304696 9814304689 9814304697 |
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| 500 | |a 3.2.3. The effect of electrolytes and surfactants | ||
| 500 | |a Preface; CONTENTS; 1. Drying a Sessile Droplet: Imaging and Analysis of Transport and Deposition Patterns; 1.1. Introduction; 1.2. The Basic Droplet-Drying Phenomenon; 1.3. Mathematic Models; 1.3.1. Droplet shape; 1.3.2. Governing equations; 1.3.3. Boundary conditions; 1.3.3.1. Mass transfer in the vapor phase; 1.3.3.2. Heat transfer in droplet and substrate; 1.3.3.3. Momentum transfer; 1.4. Vapor Phase Transport; 1.4.1. Analytical solutions; 1.4.2. Finite element analysis; 1.5. Height-Averaged Radial Velocity; 1.6. Full Flow Solution without Marangoni Effect | ||
| 500 | |a 1.6.1. The derivation of the flow field1.6.2. Finite element analysis; 1.6.3. Comparison between finite element and analytical solutions; 1.6.4. Application to deposition and stretching of DNA; 1.7. Full Flow Solutions with Marangoni Effect; 1.7.1. Expressions for the velocity field with a thermal Marangoni stress boundary condition; 1.7.2. General expressions for the velocity field with Marangoni stresses; 1.7.3. Full analytical solutions; 1.7.4. Temperature field; 1.7.5. Velocity field; 1.7.6. Surface-active contaminants; 1.7.7. Marangoni stress reverses particle deposition pattern | ||
| 500 | |a 1.8. Manipulation of Flow for Patterned Depositions1.9. Conclusions and Outlook; References; 2. Convective Assembly of Patterned Media; 2.1. Introduction; 2.2. Review of Prevailing Mechanisms in Convective Assembly; 2.2.1. Drop casting of colloidal suspensions; 2.2.2. Deposition of colloidal particles in plate-withdrawal experiments or vertical deposition; 2.3. Spontaneously Patterned Colloidal Structures; 2.3.1. Patterning by exploiting the Marangoni-Bénard instability; 2.3.2. Patterning by fingering instabilities or unstable fluid fronts; 2.3.3. Patterning by the capillary instability | ||
| 500 | |a 2.3.4. Patterning by contact line pinning and jumping2.3.5. Patterning by spontaneous dewetting; 2.4. Templating of Colloidal Structures Using Patterned Substrates; 2.4.1. Particle patterning exploiting surfaces of patterned surface charge; 2.4.2. Particle patterning exploiting surfaces of patterned wetting; 2.4.3. Particle patterning exploiting surfaces of patterned topography; 2.4.3.1. Capillarity based assembly in surfaces of patterned topography; 2.4.3.2. Ordering in the presence of applied fields; 2.4.3.3. The use of confinement and capillary interactions to form ordered structures | ||
| 500 | |a 2.5. Open Issues2.6. Conclusions and Outlook; References; 3. Materials Deposition in Evaporating Menisci -- Fundamentals and Engineering Applications of the Convective Assembly Process; 3.1. Introduction and Background to Convective Assembly; 3.1.1. Convective assembly in thin wetting films; 3.1.2. Drying droplets -- The dynamics of deposition and structure of the deposits; 3.2. Engineering of the Process of Convective Assembly at High Volume Fractions; 3.2.1. The effect of evaporation rate and particle concentration; 3.2.2. The effect of temperature | ||
| 500 | |a The use of spontaneous self-assembly, as a lithographic tool and as an external field-free means to construct well-ordered and intriguing patterns, has received much attention due to its ease of producing complex, large-scale structures with small feature sizes. An extremely simple route to highly-ordered, complex structures is the evaporative self-assembly of nonvolatile solutes (e.g., polymers, nanoparticles, carbon nanotubes, and DNA) from a sessile droplet on a solid substrate. To date, a few studies have elegantly demonstrated that self-organized nanoscale, microscale, and hierarchically | ||
| 650 | 4 | |a Asymmetric synthesis | |
| 650 | 4 | |a Genetics | |
| 650 | 4 | |a Organic compounds | |
| 650 | 4 | |a Chemistry | |
| 650 | 4 | |a Science | |
| 650 | 7 | |a SCIENCE / Chemistry / Organic |2 bisacsh | |
| 650 | 7 | |a Self-assembly (Chemistry) |2 fast | |
| 650 | 4 | |a Chemie | |
| 650 | 4 | |a Naturwissenschaft | |
| 650 | 4 | |a Self-assembly (Chemistry) | |
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Datensatz im Suchindex
| _version_ | 1804175474070388736 |
|---|---|
| any_adam_object | |
| author | Lin, Zhiqun |
| author_facet | Lin, Zhiqun |
| author_role | aut |
| author_sort | Lin, Zhiqun |
| author_variant | z l zl |
| building | Verbundindex |
| bvnumber | BV043081530 |
| collection | ZDB-4-EBA |
| ctrlnum | (OCoLC)794328389 (DE-599)BVBBV043081530 |
| dewey-full | 547.2 |
| dewey-hundreds | 500 - Natural sciences and mathematics |
| dewey-ones | 547 - Organic chemistry |
| dewey-raw | 547.2 |
| dewey-search | 547.2 |
| dewey-sort | 3547.2 |
| dewey-tens | 540 - Chemistry and allied sciences |
| discipline | Chemie / Pharmazie |
| format | Electronic eBook |
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| illustrated | Not Illustrated |
| indexdate | 2024-07-10T07:16:51Z |
| institution | BVB |
| isbn | 9789814304689 9789814304696 9814304689 9814304697 |
| language | English |
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| spelling | Lin, Zhiqun Verfasser aut Evaporative Self-assembly of Ordered Complex Structures Singapore World Scientific 2012 1 Online-Ressource (395 pages) txt rdacontent c rdamedia cr rdacarrier 3.2.3. The effect of electrolytes and surfactants Preface; CONTENTS; 1. Drying a Sessile Droplet: Imaging and Analysis of Transport and Deposition Patterns; 1.1. Introduction; 1.2. The Basic Droplet-Drying Phenomenon; 1.3. Mathematic Models; 1.3.1. Droplet shape; 1.3.2. Governing equations; 1.3.3. Boundary conditions; 1.3.3.1. Mass transfer in the vapor phase; 1.3.3.2. Heat transfer in droplet and substrate; 1.3.3.3. Momentum transfer; 1.4. Vapor Phase Transport; 1.4.1. Analytical solutions; 1.4.2. Finite element analysis; 1.5. Height-Averaged Radial Velocity; 1.6. Full Flow Solution without Marangoni Effect 1.6.1. The derivation of the flow field1.6.2. Finite element analysis; 1.6.3. Comparison between finite element and analytical solutions; 1.6.4. Application to deposition and stretching of DNA; 1.7. Full Flow Solutions with Marangoni Effect; 1.7.1. Expressions for the velocity field with a thermal Marangoni stress boundary condition; 1.7.2. General expressions for the velocity field with Marangoni stresses; 1.7.3. Full analytical solutions; 1.7.4. Temperature field; 1.7.5. Velocity field; 1.7.6. Surface-active contaminants; 1.7.7. Marangoni stress reverses particle deposition pattern 1.8. Manipulation of Flow for Patterned Depositions1.9. Conclusions and Outlook; References; 2. Convective Assembly of Patterned Media; 2.1. Introduction; 2.2. Review of Prevailing Mechanisms in Convective Assembly; 2.2.1. Drop casting of colloidal suspensions; 2.2.2. Deposition of colloidal particles in plate-withdrawal experiments or vertical deposition; 2.3. Spontaneously Patterned Colloidal Structures; 2.3.1. Patterning by exploiting the Marangoni-Bénard instability; 2.3.2. Patterning by fingering instabilities or unstable fluid fronts; 2.3.3. Patterning by the capillary instability 2.3.4. Patterning by contact line pinning and jumping2.3.5. Patterning by spontaneous dewetting; 2.4. Templating of Colloidal Structures Using Patterned Substrates; 2.4.1. Particle patterning exploiting surfaces of patterned surface charge; 2.4.2. Particle patterning exploiting surfaces of patterned wetting; 2.4.3. Particle patterning exploiting surfaces of patterned topography; 2.4.3.1. Capillarity based assembly in surfaces of patterned topography; 2.4.3.2. Ordering in the presence of applied fields; 2.4.3.3. The use of confinement and capillary interactions to form ordered structures 2.5. Open Issues2.6. Conclusions and Outlook; References; 3. Materials Deposition in Evaporating Menisci -- Fundamentals and Engineering Applications of the Convective Assembly Process; 3.1. Introduction and Background to Convective Assembly; 3.1.1. Convective assembly in thin wetting films; 3.1.2. Drying droplets -- The dynamics of deposition and structure of the deposits; 3.2. Engineering of the Process of Convective Assembly at High Volume Fractions; 3.2.1. The effect of evaporation rate and particle concentration; 3.2.2. The effect of temperature The use of spontaneous self-assembly, as a lithographic tool and as an external field-free means to construct well-ordered and intriguing patterns, has received much attention due to its ease of producing complex, large-scale structures with small feature sizes. An extremely simple route to highly-ordered, complex structures is the evaporative self-assembly of nonvolatile solutes (e.g., polymers, nanoparticles, carbon nanotubes, and DNA) from a sessile droplet on a solid substrate. To date, a few studies have elegantly demonstrated that self-organized nanoscale, microscale, and hierarchically Asymmetric synthesis Genetics Organic compounds Chemistry Science SCIENCE / Chemistry / Organic bisacsh Self-assembly (Chemistry) fast Chemie Naturwissenschaft Self-assembly (Chemistry) http://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=457193 Aggregator Volltext |
| spellingShingle | Lin, Zhiqun Evaporative Self-assembly of Ordered Complex Structures Asymmetric synthesis Genetics Organic compounds Chemistry Science SCIENCE / Chemistry / Organic bisacsh Self-assembly (Chemistry) fast Chemie Naturwissenschaft Self-assembly (Chemistry) |
| title | Evaporative Self-assembly of Ordered Complex Structures |
| title_auth | Evaporative Self-assembly of Ordered Complex Structures |
| title_exact_search | Evaporative Self-assembly of Ordered Complex Structures |
| title_full | Evaporative Self-assembly of Ordered Complex Structures |
| title_fullStr | Evaporative Self-assembly of Ordered Complex Structures |
| title_full_unstemmed | Evaporative Self-assembly of Ordered Complex Structures |
| title_short | Evaporative Self-assembly of Ordered Complex Structures |
| title_sort | evaporative self assembly of ordered complex structures |
| topic | Asymmetric synthesis Genetics Organic compounds Chemistry Science SCIENCE / Chemistry / Organic bisacsh Self-assembly (Chemistry) fast Chemie Naturwissenschaft Self-assembly (Chemistry) |
| topic_facet | Asymmetric synthesis Genetics Organic compounds Chemistry Science SCIENCE / Chemistry / Organic Self-assembly (Chemistry) Chemie Naturwissenschaft |
| url | http://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=457193 |
| work_keys_str_mv | AT linzhiqun evaporativeselfassemblyoforderedcomplexstructures |