This book focuses on chemical reactions and processing under extreme conditions―how materials react with highly concentrated active species and/or in a very confined high-temperature and high-pressure volume. Those ultimate reaction environments created by a focused laser beam, discharges, ion bombardments, or microwaves provide characteristic nano- and submicron-sized products and functional nanostructures. The book explores the chemistry and processing of metals and non-metals as well as molecules that are strongly dependent on the energy deposition processes and character of the materials. Descriptions of a wide range of topics are given from the perspective of a variety of research methodologies, material preparations, and applications. The reader is led to consider and review how a high-energy source interacts with materials, and what the key factors are that determine the quality and quantity of nanoproducts and nano-processing.
Author(s): Yoshie Ishikawa, Takahiro Nakamura, Morihisa Saeki, Tadatake Sato, Teruki Sugiyama, Hiroyuki Wada, Tomoyuki Yatsuhashi
Publisher: Springer
Year: 2022
Language: English
Pages: 364
City: Singapore
Preface
Contents
Part I High-Energy Chemistry and Processing of Metals
1 Laser-Induced Bubble Generation on Excitation of Gold Nanoparticles
1.1 Introduction
1.2 Bubble Generation on Short Pulsed-Laser Excitation of Colloidal Au NPs
1.3 Recent Applications
1.3.1 High-Speed Movement of Au NPs Encapsulated in a Nanoscale Bubble
1.3.2 Micro- and Nano-Lasers Encapsulated in Bubble
1.3.3 Plasmonic Nanobubble Can Disrupt Cell Membrane and Biofilm
1.4 Summary and Future Outlook
References
2 Metal and Alloy Nanoparticles Formed by Laser-Induced Nucleation Method
2.1 Introduction
2.2 Formation Mechanism of NPs by Laser-Induced Nucleation Method
2.3 Formation of Solid-Solution Alloy Nanoparticles from Mixed Solutions by Laser-Induced Nucleation Method
2.4 Summary
References
3 Laser-Induced Particle Formation: Its Applications to Precious Metal Recovery from Spent Nuclear Fuel and Fundamental Studies
3.1 Introduction
3.2 Basic Principles of LIPF-Based PM Separation
3.3 Background of LIPF-Based PM Separation
3.4 Application of LIPF-Based PM Separation to SNF Solution
3.4.1 LIPF-Based Separation of Pd, Rh, and Ru from a Mixture Solution with Nd
3.4.2 Recovery of Pd from a Simulated SNF Solution Containing 14 Metals
3.4.3 Recovery of Pd from Real SNF Solution
3.5 Fundamentals of the LIPF Process in a Pd Solution
3.5.1 Dependence of LIPF Efficiency on Laser Pulse Conditions
3.5.2 LIPF Process in Pd Solution Using in Situ Time-Resolved XAS
3.6 Summary
References
4 Synthesis of Metal Nanoparticles Induced by Plasma-Assisted Electrolysis
4.1 Introduction
4.2 Plasma-Assisted Electrolysis
4.3 Synthesis of Ag Nanoparticles
4.4 Synthesis of Au Nanoparticles
4.5 Synthesis of Core–Shell Nanoparticles
4.6 Synthesis of Magnetic Nanoparticles
4.7 Synthesis of Copper Oxide Nanoparticles
4.8 Conclusion
References
5 Controllable Surface Modification of Colloidal Nanoparticles Using Laser Ablation in Liquids and Its Utilization
5.1 Introduction
5.2 Utilization of Colloidal Silver NPs Prepared Using LAL for Investigating Photo-Induced Shape Conversion
5.3 Utilization of LAL for Efficient Preparation of Submicrometer-Sized Spherical Particles
5.4 Control of Electric Properties of Colloidal NPs Using LAL in Organic Solvents
5.5 Summary
References
Part II High-Energy Processing of Nonmetals
6 Fabrication and Control of Semiconductor Random Lasers Using Laser Processing Techniques
6.1 Introduction
6.2 Realization of Single Mode Random Lasing Using a Laser-Induced Melting Method
6.3 Nanorod Array Random Lasers Fabricated by Laser-Induced Hydrothermal Synthesis
6.4 Random Lasers Fabricated by a Laser-Induced Periodic Surface Structures
6.5 Conclusions
References
7 Formation Mechanism of Spherical Submicrometer Particles by Pulsed Laser Melting in Liquid
7.1 Pulsed Laser Melting in Liquid
7.2 Adiabatic Approach
7.3 Heat Dissipation Effect
7.4 Observation of Thermally Induced Nanobubbles
7.5 Chemical Reaction Mediated by Thermally Induced Nanobubbles
7.6 Summary
References
8 Mass Production of Spherical Submicrometer Particles by Pulsed Laser Melting in Liquid
8.1 Uniqueness and Functions of Spherical Submicrometer Particles Obtained by PLML
8.2 Process Parameters Affecting the Productivity
8.2.1 Unfocused Laser Irradiation
8.2.2 Requirement of Lasers
8.2.3 Required Pulse Number
8.2.4 Effective Depth for Spherical Submicrometer Particle Formation
8.3 Flow System for Continuous Particle Production by PLML
8.3.1 PLAL Versus PLML
8.3.2 Cylindrical Liquid Flow with Low Pulse Energy
8.3.3 Cylindrical Liquid Flow with High Pulse Energy
8.3.4 Thin Liquid Film Flow with High Pulse Energy
8.3.5 Flow Rate Dependence and Yield
8.4 Controlled Pulse Number Irradiation in Flow System for PLML Process Analysis
8.4.1 Controlled Pulse Number Irradiation by Viscosity Change
8.4.2 PLML Process Analysis by Controlled Pulse Number Irradiation
8.5 Batch-Type Iterative Particle Production
8.5.1 Advantages and Disadvantages of PLML Batch Process
8.5.2 Numerical Simulation of PLML Batch Process
8.5.3 Automated Iterative Batch Process for PLML Process
8.6 Summary
References
9 Material Processing for Colloidal Silicon Quantum Dot Formation
9.1 Introduction
9.2 Bulk Silicon Targets
9.3 Silica Matrix Targets
9.4 Porous Silicon Targets
9.5 Summary
References
10 Processing of Transparent Materials Using Laser-Induced High-Energy State in Liquid
10.1 Introduction: High-Energy States in Liquid for Laser Processing
10.2 Laser-Induced Backside Wet Etching (LIBWE) in the Initial Study
10.3 Variation in Combination of Lasers and Materials
10.4 Variation in Experimental Setups for LIBWE
10.4.1 Mask Projection with Excimer Laser
10.4.2 Etching on Interference
10.4.3 Direct-Writing by Scanning with High Repetition
10.5 Various Studies Regarding the Elucidation of the LIBWE Mechanisms
10.5.1 Estimation of Temperature Rise
10.5.2 Etch Rates and Threshold Values
10.5.3 Characterization of Etched Surface.
10.5.4 Diagnostic Studies on LIBWE
10.6 Summary
References
11 Functional Nanomaterials Synthesized by Femtosecond Laser Pulses
11.1 Introduction
11.2 Effective Synthesis of Nanoparticles by Femtosecond Laser Ablation in Liquid
11.3 Synthesis of Fluorescent Nanodiamonds by Femtosecond Laser Ablation in Liquid
11.3.1 Nanodiamond Synthesis from Solid-State Carbon Source
11.3.2 Nanodiamond Synthesis from Solvent Molecules
11.4 Conclusion
References
12 Preparation of Functional Nanoparticles by Laser Process in Liquid and Their Optical Applications
12.1 Introduction
12.2 Upconversion Nanoparticle
12.3 Afterglow Nanoparticle
12.4 Semiconductor Nanoparticle
12.5 Organic Nanoparticle
12.6 Summary
References
Part III High-Energy Chemistry of Nonmetals
13 Novel Ingenious and High-Quality Utilization of Microwave High Energy in Chemical Reactions: Heterogeneous Microscopic Heating, Promoted Electron Transfer by Electromagnetic Wave Energy, and Generation of In-Liquid Plasma
13.1 Microwaves and Microwave Energy
13.2 Microwave Chemistry Rules
13.3 Microwave Heterogeneous Microscopic-Thermal Effects (MHMEs) in Catalytic Chemistry
13.4 Microwave Electromagnetic Wave Effects (MEMEs) in Photocatalytic Reactions
13.5 Microwave-Induced In-Liquid Plasma (MILP) in Green Gel Synthesis
13.6 Concluding Remarks
References
14 Defect Engineering Using the High-Energy Laser-Processing Techniques and Their Application to Photocatalysis
14.1 Introduction
14.2 Experimental Methods
14.3 Laser Ablation to the Water-Splitting Photocatalysts and Photocurrent Measurements
14.4 Preparation of Black TiO2 Using the Laser Ablation Techniques and the Photocatalytic Activity
14.5 Laser Ablation to the Photocatalytic Oxide Semiconductors: Defect Formation Versus Photocatalytic Activities
14.6 Conclusions
References
15 Crystallization and Polymorphism of Amino Acids Controlled by High-Repetition-Rate Femtosecond Laser Pulses
15.1 Laser-Induced Crystallization and Polymorphism
15.2 Comparison of Physical Phenomena Under cw and fs Laser Irradiation
15.3 Theoretical Treatments
15.3.1 Optical Trapping with High-Repetition-Rate Femtosecond Laser Pulses
15.3.2 Nucleation Rate Based on Classical Nucleation Theory
15.4 Crystallization and Polymorphism of L-phenylalanine via High-Repetition-Rate Femtosecond Laser Pulses
15.4.1 Bidirectional Polymorphic Conversion [27]
15.4.2 Polymorphic Transition Mechanisms
15.5 Crystallization and Polymorphism of L-serine Under a High-Repetition-Rate Femtosecond Laser
15.5.1 Crystallization and Polymorphism Dynamics of L-serine [36]
15.5.2 Laser Polarization-Controlled Polymorphism
15.6 Conclusion
References
16 Electrocatalysts Developed from Ion-Implanted Carbon Materials
16.1 Introduction
16.2 Research Trend in NP Synthesis Using Ion Implantation
16.3 Ion-Implanted NP Electrocatalysts on Carbon Materials for HER and ORR Catalysts
16.3.1 Nickel-Ion Implantation in CFC
16.3.2 Tungsten-Ion Implantation in GC
16.4 Surface/Interface States Controlled by Impurity Doping in HOPG
16.4.1 Surface Modification by Nitrogen-Ion Implantation for Carbon-Alloy ORR Electrocatalysts
16.4.2 Interface Structures Between Platinum-NPs and a Nitrogen-Ion-Implanted Support
16.5 Defect-Controlled Interface Between Platinum-NPs and Carbon Support
16.5.1 Structures of Ion-Implanted and Platinum-Deposited HOPG Surfaces
16.5.2 Electronic Structure of Platinum-NPs on Defective Graphite Structure for Electrocatalytic Applications
16.6 Summary and Perspective
References
17 Bottom-up Synthetic Approaches to Carbon Nanomaterial Production in Liquid Phase by Femtosecond Laser Pulses
17.1 Introduction
17.2 Femtosecond Laser Pulses in Condensed Medium
17.3 Synthesis of Characteristic Carbon Nanomaterials in Neat Organic Liquids
17.4 Production of Carbon Nanomaterials in Aqueous Solution, Bilayer of Organic Liquid and Water, and Living Cells
17.5 Summary
References