Laser printing of functional materials 3D microfabrication, electronics and biomedicine
The first book on this hot topic includes such major research areas as printed electronics, sensors, biomaterials and 3D cell printing. Well-structured and with a strong focus on applications, the text is divided in three sections with the first describing the fundamentals of laser transfer. The se...
| Otros Autores: | , |
|---|---|
| Formato: | Libro electrónico |
| Idioma: | Inglés |
| Publicado: |
Weinheim, Germany :
Wiley-VCH
2018.
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| Edición: | 1st edition |
| Materias: | |
| Ver en Biblioteca Universitat Ramon Llull: | https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009631501606719 |
Tabla de Contenidos:
- Cover
- Title Page
- Copyright
- Contents
- Preface
- Part I Fundamentals
- Chapter 1 Introduction to Laser‐Induced Transfer and Other Associated Processes
- 1.1 LIFT and Its Derivatives
- 1.2 The Laser Transfer Universe
- 1.3 Book Organization and Chapter Overview
- 1.4 Looking Ahead
- Acknowledgments
- References
- Chapter 2 Origins of Laser‐Induced Transfer Processes
- 2.1 Introduction
- 2.2 Early Work in Laser‐Induced Transfer
- 2.3 Overview of Laser‐Induced Forward Transfer
- 2.3.1 Transferring Metals and Other Materials with Laser‐Induced Forward Transfer (LIFT)
- 2.3.2 Limitations of the Basic LIFT Technique
- 2.3.3 The Role of the Donor Substrate
- 2.3.4 Use of a Dynamic Release Layer (DRL)‐LIFT
- 2.3.5 LIFT with Ultrashort Laser Pulses
- 2.4 Other Laser‐Based Transfer Techniques Inspired by LIFT
- 2.4.1 Matrix‐Assisted Pulsed Laser Evaporation‐Direct Write (MAPLE‐DW) Technique
- 2.4.2 LIFT of Composite Matrix‐Based Materials
- 2.4.3 Hydrogen‐Assisted LIFT
- 2.4.4 Long‐Pulsed LIFT
- 2.4.5 Laser Molecular Implantation
- 2.4.6 Laser‐Induced Thermal Imaging
- 2.5 Other Studies on LIFT
- 2.6 Conclusions
- References
- Chapter 3 LIFT Using a Dynamic Release Layer
- 3.1 Introduction
- 3.2 Absorbing Release Layer - Triazene Polymer
- 3.3 Front‐ and Backside Ablation of the Triazene Polymer
- 3.4 Examples of Materials Transferred by TP‐LIFT
- 3.5 First Demonstration of Devices: OLEDs and Sensors
- 3.5.1 Organic Light Emitting Diode (OLEDs)
- 3.5.2 Sensors
- 3.6 Variation of the DRL Approach: Reactive LIFT
- 3.7 Conclusions and Perspectives
- Acknowledgments
- Conflict of Interest
- References
- Chapter 4 Laser‐Induced Forward Transfer of Fluids
- 4.1 Introduction to the LIFT of Fluids
- 4.1.1 Origin
- 4.1.2 Principle of Operation
- 4.1.3 Developments.
- 4.2 Mechanisms of Fluid Ejection and Deposition
- 4.2.1 Jet Formation
- 4.2.2 Droplet Deposition
- 4.3 Printing Droplets through LIFT
- 4.3.1 Role of the Laser Parameters
- 4.3.2 Role of the Fluid Properties
- 4.3.3 Setup Parameters
- 4.4 Printing Lines and Patterns with LIFT
- 4.5 Summary
- Acknowledgments
- References
- Chapter 5 Advances in Blister‐Actuated Laser‐Induced Forward Transfer (BA‐LIFT)
- 5.1 Introduction
- 5.2 BA‐LIFT Basics
- 5.3 Why BA‐LIFT?
- 5.4 Blister Formation
- 5.4.1 Dynamics of Blister Formation
- 5.4.2 Finite Element Modeling of Blister Formation
- 5.5 Jet Formation and Expansion
- 5.5.1 Computational Fluid Dynamics Model
- 5.5.2 Effect of the Laser Energy
- 5.5.3 Effect of the Ink Film Properties
- 5.6 Application to the Transfer of Delicate Materials
- 5.7 Conclusions
- References
- Chapter 6 Film‐Free LIFT (FF‐LIFT)
- 6.1 Introduction
- 6.2 Rheological Considerations in Traditional LIFT of Liquids
- 6.2.1 The Challenges behind the Preparation of a Thin Liquid Film
- 6.2.1.1 The Role of Spontaneous Instabilities
- 6.2.1.2 The Role of External Instabilities
- 6.2.2 Technologies for Thin‐Film Preparation
- 6.2.3 Wetting of the Receiver Substrate
- 6.3 Fundamentals of Film‐Free LIFT
- 6.3.1 Cavitation‐Induced Phenomena for Printing
- 6.3.2 Jet Formation in Film‐Free LIFT
- 6.3.3 Differences with LIFT of Liquids
- 6.4 Implementation and Optical Considerations
- 6.4.1 Laser Source
- 6.4.2 Forward (Inverted) versus Backward (Upright) Systems
- 6.4.3 Spherical Aberration and Chromatic Dispersion
- 6.5 Applications
- 6.5.1 Film‐Free LIFT for Printing Biomaterials
- 6.5.2 Film‐Free LIFT for Micro‐Optical Element Fabrication
- 6.6 Conclusions and Future Outlook
- References
- Part II The Role of the Laser-Material Interaction in LIFT
- Chapter 7 Laser‐Induced Forward Transfer of Metals.
- 7.1 Introduction, Background, and Overview
- 7.2 Modeling, Simulation, and Experimental Studies of the Transfer Process
- 7.2.1 Thermal Processes: Film Heating, Removal, Transfer, and Deposition
- 7.2.2 Parametric Effects
- 7.2.2.1 Laser Fluence and Film Thickness
- 7.2.2.2 Donor‐Film Gap Spacing
- 7.2.2.3 Pulse Width
- 7.2.3 Droplet‐Mode Deposition
- 7.2.4 Characterization of Deposited Structures: Adhesion, Composition, and Electrical Resistivity
- 7.3 Advanced Modeling of LIFT
- 7.4 Research Needs and Future Directions
- 7.5 Conclusions
- References
- Chapter 8 LIFT of Solid Films (Ceramics and Polymers)
- 8.1 Introduction
- 8.2 Assisted Release Processes
- 8.2.1 Optimization of LIFT Transfer of Ceramics via Laser Pulse Interference
- 8.2.1.1 Standing‐Wave Interference from Multiple Layers
- 8.2.1.2 Ballistic Laser‐Assisted Solid Transfer (BLAST)
- 8.2.2 LIFT Printing of Premachined Ceramic Microdisks
- 8.2.3 Spatial Beam Shaping for Patterned LIFT of Polymer Films
- 8.3 Shadowgraphy Studies and Assisted Capture
- 8.3.1 Shadowgraphic Studies of the Transfer of Ceramic Thin Films
- 8.3.2 Application of Polymers as Compliant Receivers
- 8.4 Applications in Energy Harvesting
- 8.4.1 LIFT of Chalcogenide Thin Films
- 8.4.2 Fabrication of a Thermoelectric Generator on a Polymer‐Coated Substrate
- 8.5 Laser‐Induced Backward Transfer (LIBT) of Nanoimprinted Polymer
- 8.5.1 Unstructured Carrier Substrate
- 8.5.2 Structured Carrier Substrate
- 8.6 Conclusions
- Acknowledgments
- References
- Chapter 9 Laser‐Induced Forward Transfer of Soft Materials
- 9.1 Introduction
- 9.2 Background
- 9.3 Jetting Dynamics during Laser Printing of Soft Materials
- 9.3.1 Jet Formation Dynamics during Laser Printing of Newtonian Glycerol Solutions
- 9.3.1.1 Typical Jetting Regimes.
- 9.3.1.2 Jetting Regime as Function of Fluid Properties and Laser Fluence
- 9.3.1.3 Jettability Phase Diagram
- 9.3.2 Jet Formation Dynamics during Laser Printing of Viscoelastic Alginate Solutions
- 9.3.2.1 Ink Coating Preparation and Design of Experiments
- 9.3.2.2 Typical Jetting Regimes
- 9.3.2.3 General Observation of the Jetting Dynamics
- 9.3.2.4 Effects of Laser Fluence on Jetting Dynamics
- 9.3.2.5 Effects of Alginate Concentration on Jetting Dynamics
- 9.3.2.6 Jettability Phase Diagram
- 9.4 Laser Printing Applications Using Optimized Printing Conditions
- 9.5 Conclusions and Future Work
- Acknowledgments
- References
- Chapter 10 Congruent LIFT with High‐Viscosity Nanopastes
- 10.1 Introduction
- 10.2 Congruent LIFT (or LDT)
- 10.3 Applications
- 10.4 Achieving Congruent Laser Transfers
- 10.5 Issues and Challenges
- 10.6 Summary
- Acknowledgment
- References
- Chapter 11 Laser Printing of Nanoparticles
- 11.1 Introduction, Setup, and Motivation
- 11.2 Laser‐Induced Transfer
- 11.3 Materials for Laser Printing of Nanoparticles
- 11.4 Laser Printing from Bulk‐Silicon and Silicon Films
- 11.5 Magnetic Resonances of Silicon Particles
- 11.6 Laser Printing from Prestructured Films
- 11.7 Applications: Sensing, Metasurfaces, and Additive Manufacturing
- 11.8 Outlook
- References
- Part III Applications
- Chapter 12 Laser Printing of Electronic Materials
- 12.1 Introduction and Context
- 12.2 Organic Thin‐Film Transistor
- 12.2.1 Operation and Characteristics of OTFTs
- 12.2.2 Laser Printing of the Semiconductor Layer
- 12.2.3 Laser Printing of Dielectric Layers
- 12.2.4 Laser Printing of Conducting Layers
- 12.2.5 Single‐Step Printing of Full OTFT Device
- 12.3 Organic Light‐Emitting Diode
- 12.4 Passive Components
- 12.5 Interconnection and Heterogeneous Integration
- 12.6 Conclusion
- References.
- Chapter 13 Laser Printing of Chemical and Biological Sensors
- 13.1 Introduction
- 13.2 Conventional Printing Methods for the Fabrication of Chemical and Biological Sensors
- 13.2.1 Contact Printing Methods
- 13.2.1.1 Pin Printing Approach
- 13.2.1.2 Microcontact Printing (or Microstamping) Technique
- 13.2.1.3 Nanotip Printing
- 13.2.2 Noncontact Printing Methods
- 13.2.2.1 Photochemistry‐Based Printing
- 13.2.2.2 Inkjet Printing Technique
- 13.2.2.3 Electrospray Deposition (ESD)
- 13.3 Laser‐Based Printing Techniques: Introduction
- 13.3.1 Laser‐Induced Forward Transfer
- 13.3.2 LIFT of Liquid Films
- 13.4 Applications of Direct Laser Printing
- 13.4.1 Biosensors
- 13.4.1.1 Background
- 13.4.1.2 Printing of Biological Materials for Biosensors
- 13.4.2 Chemical Sensors
- 13.5 Conclusions
- References
- Chapter 14 Laser Printing of Proteins and Biomaterials
- 14.1 Introduction
- 14.2 LIFT of DNA in Solid and Liquid Phase
- 14.3 LIFT of Biomolecules
- 14.3.1 Streptavidin and Avidin-Biotin Complex
- 14.3.2 Amyloid Peptides
- 14.3.3 Odorant‐Binding Proteins
- 14.3.4 Liposomes
- 14.4 Conclusions and Perspectives
- Acknowledgments
- Conflict of Interest
- References
- Chapter 15 Laser‐Assisted Bioprinting of Cells for Tissue Engineering
- 15.1 Laser‐Assisted Bioprinting of Cells
- 15.1.1 The History of Cell Bioprinting and Advantages of Laser‐Assisted Bioprinting for Tissue Engineering
- 15.1.2 Technical Specifications of Laser‐Assisted Bioprinting of Cells
- 15.1.3 Effect of Laser Process and Printing Parameters on Cell Behavior
- 15.2 Laser‐Assisted Bioprinting for Cell Biology Studies
- 15.2.1 Study of Cell-Cell and Cell-Microenvironment Interactions
- 15.2.2 Cancer Research
- 15.3 Laser‐Assisted Bioprinting for Tissue‐Engineering Applications
- 15.3.1 Skin
- 15.3.2 Blood Vessels
- 15.3.3 Heart
- 15.3.4 Bone.
- 15.3.5 Nervous System.
