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Nanotechnologies for synthetic super...

Senez, Vincent.

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Nanotechnologies for synthetic super non-wetting surfaces

Record Type:	Electronic resources : Monograph/item
Title/Author:	Nanotechnologies for synthetic super non-wetting surfaces/ Vincent Senez, Vincent Thomy, Renaud Dufour.
Author:	Senez, Vincent.
other author:	Thomy, Vincent.
Published:	London :ISTE, Ltd. ; : 2014.,
Description:	1 online resource (190 p.)
[NT 15003449]:	Cover; Title Page; Copyright; Contents; Chapter 1: Nanotechnologies for Synthetic Super Non-wetting Surfaces; 1.1. Introduction; 1.2. Modeling of liquid-solid interaction; 1.3. Microscale and nanoscale coating processes; 1.4. Experimental characterization; 1.5. Emerging applications; 1.6. Conclusion; 1.7. Bibliography; Chapter 2: Wetting on Heterogeneous Surfaces; 2.1. Introduction; 2.2. Wetting of an ideal surface: the Young contact angle; 2.3. Real surfaces: apparent contact angle and contact angle hysteresis; 2.4. Relationship between contact angle hysteresis and drop adhesion.
[NT 15003449]:	2.5. Wetting of heterogeneous materials: the Wenzel and Cassie-Baxter models2.5.1. Impact of roughness: the Wenzel wetting state; 2.5.2. Impact of chemical heterogeneities: the Cassie-Baxter wetting state; 2.5.3. The lotus effect: toward super non-wetting surfaces; 2.6. Conclusion; 2.7. Bibliography; Chapter 3: Engineering Super Non-wetting Materials; 3.1. Introduction; 3.2. Surface robustness; 3.2.1. Stability of Cassie and Wenzel wetting states; 3.2.2. The contact line pinning criterion; 3.2.3. The Cassie to Wenzel transition; 3.2.4. Influence of sidewall angle.
[NT 15003449]:	3.2.5. Designing superoleophobic surfaces3.2.6. Conclusion; 3.3. Contact angle hysteresis on super non-wetting materials; 3.3.1. Contact line pinning on dilute micropillars; 3.3.2. Computing metastable states; 3.3.3. Contact angle hysteresis modeling: perspectives; 3.4. Conclusion; 3.5. Bibliography; Chapter 4: Fabrication of Synthetic Super Non-wetting Surfaces; 4.1. Introduction; 4.2. Full substrate technologies; 4.2.1. Thermal evaporation; 4.2.2. Pulsed laser deposition; 4.2.3. Sputtering deposition; 4.2.4. Atomic layer deposition; 4.2.5. Plasma-enhanced chemical vapor deposition.
[NT 15003449]:	4.2.6. Thermal spraying deposition4.2.7. Electrospray deposition; 4.2.8. Electrospinning; 4.2.9. Electroless plating deposition; 4.2.10. Electroplating; 4.2.11. Chemical solution deposition (spin/dip/spray/blade coating); 4.2.12. Colloidal assembly; 4.2.13. Hydrothermal synthesis; 4.2.14. Catalyst-assisted growth; 4.2.15. Controlled radical polymerizations; 4.3. Direct writing technologies; 4.3.1. Inkjet printing; 4.3.2. Drop casting; 4.3.3. Laser-assisted deposition; 4.3.4. Contact printing; 4.3.5. Dip pen lithography; 4.3.6. Pneumatic dispensing; 4.3.7. Screen printing; 4.4. Conclusion.
[NT 15003449]:	4.5. BibliographyChapter 5: Characterization Techniques for Super Non-wetting Surfaces; 5.1. Introduction; 5.2. The sessile drop method; 5.2.1. Equipment and experimental procedure; 5.2.2. Drop shape analysis; 5.2.3. The volume oscillation method; 5.2.4. The tilted plate method; 5.3. Wilhelmy method; 5.4. Robustness measurement; 5.4.1. Drop compression; 5.4.2. Drop evaporation; 5.4.3. Hydrostatic pressure; 5.4.4. Drop impact; 5.4.5. Other methods (electrowetting and surface vibrations); 5.4.6. Conclusion on the robustness measurement techniques; 5.5. Advanced techniques for better understanding of super non-wetting surfaces.
Subject:	Nanostructured materials. -
Online resource:	http://onlinelibrary.wiley.com/book/10.1002/9781119015093
ISBN:	9781119015093

Nanotechnologies for synthetic super non-wetting surfaces
Senez, Vincent.

Nanotechnologies for synthetic super non-wetting surfaces[electronic resource] /Vincent Senez, Vincent Thomy, Renaud Dufour. - London :ISTE, Ltd. ;2014. - 1 online resource (190 p.) - FOCUS Series. - FOCUS Series..

Includes bibliographical references and index.

Cover; Title Page; Copyright; Contents; Chapter 1: Nanotechnologies for Synthetic Super Non-wetting Surfaces; 1.1. Introduction; 1.2. Modeling of liquid-solid interaction; 1.3. Microscale and nanoscale coating processes; 1.4. Experimental characterization; 1.5. Emerging applications; 1.6. Conclusion; 1.7. Bibliography; Chapter 2: Wetting on Heterogeneous Surfaces; 2.1. Introduction; 2.2. Wetting of an ideal surface: the Young contact angle; 2.3. Real surfaces: apparent contact angle and contact angle hysteresis; 2.4. Relationship between contact angle hysteresis and drop adhesion.

Texturing surfaces at micro- and/or nano-scales modifies the interactions of liquids and solids. This book is a summary of the state of the art concerning the development and use of micro/nano-technologies for the design of synthetic liquid repellent surfaces with a particular focus on super-omniphobic materials. It proposes a comprehensive understanding of the physical mechanisms involved in the wetting of these surfaces and reviews emerging applications in various fields such as energy harvesting and biology, as well as highlighting the current limitations and challenges which are yet to be.

ISBN: 9781119015093Subjects--Topical Terms:

584856
Nanostructured materials.

LC Class. No.: TA418.9.N35

Dewey Class. No.: 620.115

Nanotechnologies for synthetic super non-wetting surfaces
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245 1 0 $a Nanotechnologies for synthetic super non-wetting surfaces $h [electronic resource] / $c Vincent Senez, Vincent Thomy, Renaud Dufour.
260 $a London : $b ISTE, Ltd. ; $a Hoboken : $b Wiley, $c 2014.
300 $a 1 online resource (190 p.)
490 1 $a FOCUS Series
504 $a Includes bibliographical references and index.
505 0 $a Cover; Title Page; Copyright; Contents; Chapter 1: Nanotechnologies for Synthetic Super Non-wetting Surfaces; 1.1. Introduction; 1.2. Modeling of liquid-solid interaction; 1.3. Microscale and nanoscale coating processes; 1.4. Experimental characterization; 1.5. Emerging applications; 1.6. Conclusion; 1.7. Bibliography; Chapter 2: Wetting on Heterogeneous Surfaces; 2.1. Introduction; 2.2. Wetting of an ideal surface: the Young contact angle; 2.3. Real surfaces: apparent contact angle and contact angle hysteresis; 2.4. Relationship between contact angle hysteresis and drop adhesion.
505 8 $a 2.5. Wetting of heterogeneous materials: the Wenzel and Cassie-Baxter models2.5.1. Impact of roughness: the Wenzel wetting state; 2.5.2. Impact of chemical heterogeneities: the Cassie-Baxter wetting state; 2.5.3. The lotus effect: toward super non-wetting surfaces; 2.6. Conclusion; 2.7. Bibliography; Chapter 3: Engineering Super Non-wetting Materials; 3.1. Introduction; 3.2. Surface robustness; 3.2.1. Stability of Cassie and Wenzel wetting states; 3.2.2. The contact line pinning criterion; 3.2.3. The Cassie to Wenzel transition; 3.2.4. Influence of sidewall angle.
505 8 $a 3.2.5. Designing superoleophobic surfaces3.2.6. Conclusion; 3.3. Contact angle hysteresis on super non-wetting materials; 3.3.1. Contact line pinning on dilute micropillars; 3.3.2. Computing metastable states; 3.3.3. Contact angle hysteresis modeling: perspectives; 3.4. Conclusion; 3.5. Bibliography; Chapter 4: Fabrication of Synthetic Super Non-wetting Surfaces; 4.1. Introduction; 4.2. Full substrate technologies; 4.2.1. Thermal evaporation; 4.2.2. Pulsed laser deposition; 4.2.3. Sputtering deposition; 4.2.4. Atomic layer deposition; 4.2.5. Plasma-enhanced chemical vapor deposition.
505 8 $a 4.2.6. Thermal spraying deposition4.2.7. Electrospray deposition; 4.2.8. Electrospinning; 4.2.9. Electroless plating deposition; 4.2.10. Electroplating; 4.2.11. Chemical solution deposition (spin/dip/spray/blade coating); 4.2.12. Colloidal assembly; 4.2.13. Hydrothermal synthesis; 4.2.14. Catalyst-assisted growth; 4.2.15. Controlled radical polymerizations; 4.3. Direct writing technologies; 4.3.1. Inkjet printing; 4.3.2. Drop casting; 4.3.3. Laser-assisted deposition; 4.3.4. Contact printing; 4.3.5. Dip pen lithography; 4.3.6. Pneumatic dispensing; 4.3.7. Screen printing; 4.4. Conclusion.
505 8 $a 4.5. BibliographyChapter 5: Characterization Techniques for Super Non-wetting Surfaces; 5.1. Introduction; 5.2. The sessile drop method; 5.2.1. Equipment and experimental procedure; 5.2.2. Drop shape analysis; 5.2.3. The volume oscillation method; 5.2.4. The tilted plate method; 5.3. Wilhelmy method; 5.4. Robustness measurement; 5.4.1. Drop compression; 5.4.2. Drop evaporation; 5.4.3. Hydrostatic pressure; 5.4.4. Drop impact; 5.4.5. Other methods (electrowetting and surface vibrations); 5.4.6. Conclusion on the robustness measurement techniques; 5.5. Advanced techniques for better understanding of super non-wetting surfaces.
520 $a Texturing surfaces at micro- and/or nano-scales modifies the interactions of liquids and solids. This book is a summary of the state of the art concerning the development and use of micro/nano-technologies for the design of synthetic liquid repellent surfaces with a particular focus on super-omniphobic materials. It proposes a comprehensive understanding of the physical mechanisms involved in the wetting of these surfaces and reviews emerging applications in various fields such as energy harvesting and biology, as well as highlighting the current limitations and challenges which are yet to be.
588 0 $a Description based on print version record.
650 0 $a Nanostructured materials. $3 584856
650 0 $a Wetting. $3 652009
700 1 $a Thomy, Vincent. $3 2147686
700 1 $a Dufour, Renaud. $3 2147687
830 0 $a FOCUS Series. $3 2147372
856 4 0 $u http://onlinelibrary.wiley.com/book/10.1002/9781119015093