Author(s): Ivan A. Kuznetsov
Series: Physics Research and Technolog
Publisher: Nova Science Pub Inc
Year: 2010
Language: English
Pages: 198
Tags: Приборостроение;Микро- и наносистемная техника;
MICROFLUIDICS: THEORY AND APPLICATIONS......Page 2
MICROFLUIDICS: THEORY AND APPLICATIONS......Page 4
CONTENTS......Page 6
PREFACE......Page 8
ABSTRACT......Page 14
1. INTRODUCTION......Page 15
2. CONCEPT OF 3D DIRECT WRITING INSIDE TRANSPARENT MATERIALS BY FEMTOSECOND LASER......Page 17
3.1. Microfluidic Components and Controlling the Aspect Ratio of Microchannels......Page 20
3.2. Micromechanics......Page 27
3.3. Microoptics......Page 29
3.4. Microelectronics......Page 39
4.1. Microfluidic Dye Laser......Page 43
4.2. Optofluidic Integration......Page 47
4.3. Electro-Optic Integration......Page 53
5.1. Concept of Nanoaquarium......Page 55
5.2. Nanoaquarium for Observing the Motion of Euglena gracilis......Page 57
6. CONCLUSIONS AND OUTLOOK......Page 61
REFERENCES......Page 63
ABSTRACT......Page 68
1.1. Introduction......Page 70
1.2. Power-Law Fluids and Governing Equations......Page 72
1.3. Exact Solutions of Electroosmosis of Power-Law Fluids in a Slit Microchannel......Page 74
1.4. Approximate Analytical Solutions of Electroosmosis of Power-Law Fluids in a Slit Microchannel......Page 79
1.5.1. Comparison of the Exact and Approximate Solutions with the Numerical Simulations......Page 83
1.5.2. Characteristics of Electroosmotic Flow of Power-Law Fluids......Page 85
1.6. Summary for Electroosmotic Flow of Power-Law Fluids......Page 91
2.1. Introduction......Page 92
2.2. Pressure Driven Flow Field of Power-Law Fluids in a Slit Microchannel with Electrokinetic Effects......Page 94
Approximate Analytical Solution......Page 97
2.3. Streaming Potential......Page 99
2.4. Apparent Viscosity and Electroviscous Effects......Page 103
2.6. Results and Discussion......Page 104
2.6.1. Velocity Distribution......Page 105
2.6.3. Volumetric Flow Rate......Page 107
2.6.4. Apparent Viscosity (Electroviscous Effects)......Page 108
2.6.5. Friction Coefficient......Page 109
2.7. Summary for Pressure Driven Flow of Power-Law Fluids with Electrokinetic Effects......Page 110
REFERENCES......Page 111
APPENDIX......Page 112
ABSTRACT......Page 116
INTRODUCTION......Page 117
UNIQUE FEATURES OF ECL......Page 119
ECL with Cоreactant......Page 121
BASIC METHODOLOGY OF CE/ECL ANALYSIS IN MICROFLUIDICS......Page 122
Diode array......Page 125
Electrochemical Part of ECL Mode......Page 126
Working Electrode Placement in CE/ECL Detection......Page 128
The Major Factors Loss of Separation Efficiency......Page 130
CE/ECL Key Specific Futures......Page 131
KEY RESEARCH FINDINGS......Page 133
POSSIBLE FUTURE DEVELOPMENTS (BASIC TENDENCIES)......Page 138
CONCLUSION......Page 140
REFERENCES......Page 141
ABSTRACT......Page 148
INTRODUCTION......Page 149
HYDROGEL VALVE......Page 150
ROTARY VALVE......Page 155
REFERENCES......Page 158
ABSTRACT......Page 162
1. INTRODUCTION......Page 163
2. DEVICE DESIGN AND FABRICATION......Page 165
1. Comparison to the Device With PDMS......Page 171
2. Signal Enhancement by Light Blockage......Page 172
4. LSPR SENSING......Page 176
5. CONCLUSION......Page 177
REFERENCES......Page 178
1. ADAPTIVE OPTICS......Page 180
2. LASER MICROFLUIDICS......Page 183
CONCLUSION AND PROSPECTS......Page 185
REFERENCES......Page 186
INDEX......Page 188