Near-Field Characterization of Micro/Nano-Scaled Fluid Flows » książka
Near-Field Characterization of Micro/Nano-Scaled Fluid Flows
ISBN-13: 9783642267376 / Angielski / Miękka / 2014 / 156 str.
Near-Field Characterization of Micro/Nano-Scaled Fluid Flows
ISBN-13: 9783642267376 / Angielski / Miękka / 2014 / 156 str.
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The near-field region within an order of 100 nm from the solid interface is an exciting and crucial arena where many important multiscale transport phenomena are physically characterized, such as flow mixing and drag, heat and mass transfer, near-wall behavior of nanoparticles, binding of bio-molecules, crystallization, surface deposition processes, just naming a few. This monograph presents a number of label-free experimental techniques developed and tested for near-field fluid flow characterization. Namely, these include Total Internal Reflection Microscopy (TIRM), Optical Serial Sectioning Microscopy (OSSM), Surface Plasmon Resonance Microscopy (SPRM), Interference Reflection Contrast Microscopy (IRCM), Thermal Near-Field Anemometry, Scanning Thermal Microscopy (STM), and Micro-Cantilever Near-Field Thermometry. Presentation on each of these is laid out for the working principle, how to implement the system, and its example applications, to promote the readers understanding and knowledge of the specific technique that can be applied for their own research interests.
Preface
1. Introduction
1.1 Definitions of near-field
1.1.1 Evanescent wave penetration depth
1.1.3 Photon penetration skin-depth into metal
1.1.4 Penetration depth of no-slip boundary conditions
1.1.5 Equilibrium height (hm) for small particles under near-field forces
1.2 Synopsis
2. Total Internal Reflection Microscopy (TIRM)
2.1 Principles and configuration of TIRM
2.2 Ratiometric TIRM imaging analysis
2. 3 Near-field applications of TIRM
2.3.1 Near-wall hindered Brownian motion of nanoparticles
2.3.2 Slip-flows in the near-field
2.3.3 Cytoplasmic viscosity and intracellular vesicle sizes
3. Optical Serial Sectioning Microscopy (OSSM)
3.1 Point spread functions (PSFs) under aberration-free design conditions
3.2 Point spread functions (PSFs) under off-design conditions
3.3 Principles of OSSM
3.4 Near-field applications of OSSM
3.4.1 Three-dimensional particle tracking velocimetry (PTV)
3.4.2 Near-wall thermometry
3.4.3 Near-field mixture concentration measurements
4. Confocal Laser Scanning Microscopy (CLSM)
4.1 Principles of confocal imaging
4.2 Microscopic imaging resolutions
4.3 Confocal microscopic imaging resolutions
4.4 Optical slicing thickness of confocal microscopy
4.5 Confocal laser scanning microscopic particle imaging velocimetry (CLSM-PIV) system
4.6 Near-field applications of CLSM-PIV
4.6.1 Poiseuille flows in a microtube
4.6.2 Microscale rotating Couette flows
4.6.3 Moving bubbles in a microchannel
5. Surface Plasmon Resonance Microscopy (SPRM)
5.1 Surface plasmon polaritons (SPPs)
5.2 Dispersion of SPPs
5.3. Kretschmann’s three-layer configuration
5.4 Surface plasmon resonance (SPR) reflectance
5.5 Surface plasmon resonance microscopy (SPRM) imaging systems
5.6 Selection of a prism for SPRM
5.7 SPR reflectance imaging resolution
5.8 Near-field applications of SPRM
5.8.1 History and uses of SPRM
5.8.2 Label-free mapping of microfluidic mixing fields
5.8.3 Near-field mapping of salinity diffusion
5.8.4 Dynamic monitoring of nanoparticle concentration profiles
5.8.5 Unveiling the fingerprints of nanocrystalline self-assembly
5.8.6 Near-wall thermometry
6. Reflection Interference Contrast Microscopy (RICM)
6.1 Interference of plane waves
6.2 Principles and practical issues of RICM
6.3 Near-field applications of RICM
6.3.1 Thin-film thickness measurements
6.3.2 Electrohydrodynamic (EHD) control of thin liquid film
6.3.3 Dynamic fingerprinting of live-cell focal contacts
References
1. Introduction
1.1 Definitions of near-field
1.1.1 Evanescent wave penetration depth
1.1.3 Photon penetration skin-depth into metal
1.1.4 Penetration depth of no-slip boundary conditions
1.1.5 Equilibrium height (hm) for small particles under near-field forces
1.2 Synopsis
2. Total Internal Reflection Microscopy (TIRM)
2.1 Principles and configuration of TIRM
2.2 Ratiometric TIRM imaging analysis
2. 3 Near-field applications of TIRM
2.3.1 Near-wall hindered Brownian motion of nanoparticles
2.3.2 Slip-flows in the near-field
2.3.3 Cytoplasmic viscosity and intracellular vesicle sizes
3. Optical Serial Sectioning Microscopy (OSSM)
3.1 Point spread functions (PSFs) under aberration-free design conditions
3.2 Point spread functions (PSFs) under off-design conditions
3.3 Principles of OSSM
3.4 Near-field applications of OSSM3.4.1 Three-dimensional particle tracking velocimetry (PTV)
3.4.2 Near-wall thermometry
3.4.3 Near-field mixture concentration measurements
4. Confocal Laser Scanning Microscopy (CLSM)
4.1 Principles of confocal imaging
4.2 Microscopic imaging resolutions
4.3 Confocal microscopic imaging resolutions
4.4 Optical slicing thickness of confocal microscopy
4.5 Confocal laser scanning microscopic particle imaging velocimetry (CLSM-PIV) system
4.6 Near-field applications of CLSM-PIV
4.6.1 Poiseuille flows in a microtube
4.6.2 Microscale rotating Couette flows
4.6.3 Moving bubbles in a microchannel
5. Surface Plasmon Resonance Microscopy (SPRM)
5.1 Surface plasmon polaritons (SPPs)
5.2 Dispersion of SPPs
5.3. Kretschmann’s three-layer configuration
5.4 Surface plasmon resonance (SPR) reflectance
5.5 Surface plasmon resonance microscopy (SPRM) imaging systems
5.6 Selection of a prism for SPRM
5.7 SPR reflectance imaging resolution
5.8 Near-field applications of SPRM
5.8.1 History and uses of SPRM
5.8.2 Label-free mapping of microfluidic mixing fields
5.8.3 Near-field mapping of salinity diffusion
5.8.4 Dynamic monitoring of nanoparticle concentration profiles
5.8.5 Unveiling the fingerprints of nanocrystalline self-assembly
5.8.6 Near-wall thermometry
6. Reflection Interference Contrast Microscopy (RICM)
6.1 Interference of plane waves
6.2 Principles and practical issues of RICM
6.3 Near-field applications of RICM
6.3.1 Thin-film thickness measurements
6.3.2 Electrohydrodynamic (EHD) control of thin liquid film
6.3.3 Dynamic fingerprinting of live-cell focal contacts
References
3.1 Point spread functions (PSFs) under aberration-free design conditions
3.2 Point spread functions (PSFs) under off-design conditions
3.3 Principles of OSSM
3.4 Near-field applications of OSSM
3.4.1 Three-dimensional particle tracking velocimetry (PTV)
3.4.2 Near-wall thermometry
3.4.3 Near-field mixture concentration measurements
4. Confocal Laser Scanning Microscopy (CLSM)
4.1 Principles of confocal imaging
4.2 Microscopic imaging resolutions
4.3 Confocal microscopic imaging resolutions
4.4 Optical slicing thickness of confocal microscopy
4.5 Confocal laser scanning microscopic particle imaging velocimetry (CLSM-PIV) system
4.6 Near-field applications of CLSM-PIV
4.6.1 Poiseuille flows in a microtube
4.6.2 Microscale rotating Couette flows
4.6.3 Moving bubbles in a microchannel
5. Surface Plasmon Resonance Microscopy (SPRM)
5.1 Surface plasmon polaritons (SPPs)
5.2 Dispersion of SPPs
5.3. Kretschmann’s three-layer configuration
5.4 Surface plasmon resonance (SPR) reflectance
5.5 Surface plasmon resonance microscopy (SPRM) imaging systems
5.6 Selection of a prism for SPRM
5.7 SPR reflectance imaging resolution
5.8 Near-field applications of SPRM
5.8.1 History and uses of SPRM
5.8.2 Label-free mapping of microfluidic mixing fields
5.8.3 Near-field mapping of salinity diffusion
5.8.4 Dynamic monitoring of nanoparticle concentration profiles
5.8.5 Unveiling the fingerprints of nanocrystalline self-assembly
5.8.6 Near-wall thermometry
6. Reflection Interference Contrast Microscopy (RICM)
6.1 Interference of plane waves
6.2 Principles and practical issues of RICM
6.3 Near-field applications of RICM
6.3.1 Thin-film thickness measurements
6.3.2 Electrohydrodynamic (EHD) control of thin liquid film
6.3.3 Dynamic fingerprinting of live-cell focal contacts
References
4.2 Microscopic imaging resolutions
4.3 Confocal microscopic imaging resolutions
4.4 Optical slicing thickness of confocal microscopy
4.5 Confocal laser scanning microscopic particle imaging velocimetry (CLSM-PIV) system
4.6 Near-field applications of CLSM-PIV4.6.1 Poiseuille flows in a microtube
4.6.2 Microscale rotating Couette flows
4.6.3 Moving bubbles in a microchannel
5. Surface Plasmon Resonance Microscopy (SPRM)
5.1 Surface plasmon polaritons (SPPs)
5.2 Dispersion of SPPs
5.3. Kretschmann’s three-layer configuration
5.4 Surface plasmon resonance (SPR) reflectance
5.5 Surface plasmon resonance microscopy (SPRM) imaging systems
5.6 Selection of a prism for SPRM
5.7 SPR reflectance imaging resolution
5.8 Near-field applications of SPRM
5.8.1 History and uses of SPRM
5.8.2 Label-free mapping of microfluidic mixing fields
5.8.3 Near-field mapping of salinity diffusion
5.8.4 Dynamic monitoring of nanoparticle concentration profiles
5.8.5 Unveiling the fingerprints of nanocrystalline self-assembly
5.8.6 Near-wall thermometry
6. Reflection Interference Contrast Microscopy (RICM)
6.1 Interference of plane waves
6.2 Principles and practical issues of RICM
6.3 Near-field applications of RICM
6.3.1 Thin-film thickness measurements
6.3.2 Electrohydrodynamic (EHD) control of thin liquid film
6.3.3 Dynamic fingerprinting of live-cell focal contacts
References
5.5 Surface plasmon resonance microscopy (SPRM) imaging systems
5.6 Selection of a prism for SPRM
5.7 SPR reflectance imaging resolution
5.8 Near-field applications of SPRM
5.8.1 History and uses of SPRM
5.8.2 Label-free mapping of microfluidic mixing fields
5.8.3 Near-field mapping of salinity diffusion
5.8.4 Dynamic monitoring of nanoparticle concentration profiles
5.8.5 Unveiling the fingerprints of nanocrystalline self-assembly
5.8.6 Near-wall thermometry
6. Reflection Interference Contrast Microscopy (RICM)
6.1 Interference of plane waves
6.2 Principles and practical issues of RICM
6.3 Near-field applications of RICM
6.3.1 Thin-film thickness measurements
6.3.2 Electrohydrodynamic (EHD) control of thin liquid film
6.3.3 Dynamic fingerprinting of live-cell focal contacts
References
6.3 Near-field applications of RICM
6.3.1 Thin-film thickness measurements
6.3.2 Electrohydrodynamic (EHD) control of thin liquid film
6.3.3 Dynamic fingerprinting of live-cell focal contacts
References
The near-field – the region within 100 nm from a solid interface - is an exciting arena in which several important multi-scale transport phenomena are physically characterized, such as flow mixing and drag, heat and mass transfer, near-wall behavior of nanoparticles, the binding of bio-molecules, crystallization, and surface deposition processes, just to name a few. This book presents a number of microscopicimaging techniques that were implemented and tested for near-field fluidic characterizations. These methods include Total Internal Reflection Microscopy (TIRM), Optical Serial Sectioning Microscopy (OSSM), Confocal Laser Scanning Microscopy (CLSM), Surface Plasmon Resonance Microscopy (SPRM), and Reflection Interference Contrast Microscopy (RICM). The basic principles, specifics of implementation, and example applications of each method are presented in order to promote the reader’s understanding of the techniques, so that these may be applied to their own research interests.
The near-field – the region within 100 nm from a solid interface - is an exciting arena in which several important multi-scale transport phenomena are physically characterized, such as flow mixing and drag, heat and mass transfer, near-wall behavior of nanoparticles, the binding of bio-molecules, crystallization, and surface deposition processes, just to name a few. This book presents a number of microscopicimaging techniques that were implemented and tested for near-field fluidic characterizations. These methods include Total Internal Reflection Microscopy (TIRM), Optical Serial Sectioning Microscopy (OSSM), Confocal Laser Scanning Microscopy (CLSM), Surface Plasmon Resonance Microscopy (SPRM), and Reflection Interference Contrast Microscopy (RICM). The basic principles, specifics of implementation, and example applications of each method are presented in order to promote the reader’s understanding of the techniques, so that these may be applied to their own research interests.
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