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Electrochemical biosensor platform based on electron tunneling : 전자 터널링 기반의 전기화학 바이오센서 플랫폼
| DC Field | Value | Language |
|---|---|---|
| dc.contributor.advisor | 박병국, 박영준 | - |
| dc.contributor.author | 윤준연 | - |
| dc.date.accessioned | 2018-11-12T00:56:23Z | - |
| dc.date.available | 2018-11-12T00:56:23Z | - |
| dc.date.issued | 2018-08 | - |
| dc.identifier.other | 000000153165 | - |
| dc.identifier.uri | https://hdl.handle.net/10371/143105 | - |
| dc.description | 학위논문 (박사)-- 서울대학교 대학원 : 공과대학 전기·컴퓨터공학부, 2018. 8. 박병국, 박영준. | - |
| dc.description.abstract | We propose an electrochemical protease biosensor platform, called T-chip based on electron tunneling (electrochemistry) and the voltage pulse method to extract the pure transient tunneling current characteristics of the sensor device. By analyzing the I-V and C-V characteristics of the T-chip device with its unique structure having the 2-terminal asymmetric electrodes, the new perspective on the T-chip device describing as the metal-insulator-electrolyte (MIE) capacitor has been suggested.
The biosensor application for the detection of the Trypsin as the target molecule has been demonstrated in the imitated human serum condition with the high concentration of the nonspecific BSA protein of 500 µM. It has been found that the voltage pulse method can enhance the sensitivity and the nonspecific-to-specific ratio performances of the biosensor device than the cyclic-voltammetry measurement. In addition, the effect of the back-filling materials on the surface of the electrodes has been studied, and the optimized structure of the T-chip device has been established. The biomolecular transport in the bulk electrolyte solution and the biochemical reaction has been simulated by solving the reaction-diffusion equation and Menten-Michaelis kinetics. The equivalent circuit of the T-chip device is also proposed, and simulated by using the MNA technique. To overcome the limitation of the voltage pulse method, the generalized voltage pulse method based on the integration of the tunneling current is suggested. Finally, the pH sensor application of the T-chip device has been demonstrated by utilizing the MCH-SAM on the electrode of the device. In this research, we have focused on creating new perspectives even there are somewhat rough and radical assumptions. Even if our approach is not that much perfect and the experimental data are not that much precise, we believe that it is of great value to find new possibilities for the future device not only in the biosensor industry but also in the other scientific field developing the solid-state devices. | - |
| dc.description.tableofcontents | Chapter 1. Introduction . 1
1.1. POCT in general: trend of market and society 1 1.2. Competing technologies for POCT application. 15 1.3. Review of electrochemical biosensor (T-chip) based on electron tunneling. 19 Chapter 2. T-chip . 24 2.1. Device fabrication and structure of T-chip 24 2.2. Immobilization of probe peptide. 32 2.3. Reference electrode-free electrochemical device 36 2.4. Strategy for detection of biomarkers. 38 2.5. Target biomarker: Trypsin 40 Chapter 3. Electrochemical characteristics of T-chip. 42 3.1. I-V characteristics of T-chip. 42 3.2. C-V characteristics of T-chip 50 Chapter 4. Metal-insulator-electrolyte capacitor 57 4.1. Similarity between metal-insulator-electrolyte (MIE) and metal-oxidesemiconductor (MOS) capacitors 57 4.2. Concept of flat-band voltage 61 4.3. Flat-band voltage shifts and energy band diagram 67 4.4. Equivalent circuit model of T-chip . 75 4.5. Capacitive components of T-chip . 81 Chapter 5. Voltage pulse method. 89 5.1. Motivation . 89 5.2. Preparation of sensor device and electrical measurement 96 5.3. Extraction of transient tunneling current. 99 5.4. Verification of voltage pulse method 107 5.4.1. Practical problem: voltage and time windows 107 5.4.2. Validation of eliminating capacitive current and extracting tunneling current for voltage pulse method . 113 5.4.3. Correlation between the C-V characteristics and results of voltage pulse method 119 Chapter 6. Application to protease biosensor . 125 6.1. Trypsin detection 125 6.2. Experimental result of sensing Trypsin. 127 6.3. Effect of nonspecific adsorption . 135 Chapter 7. Conclusion 139 Appendix 1. Appendix 1. Effect of back-filling material. 143 A1.1. MB-modified peptide and back-filling materials of MCXs. 143 A1.2. Trypsin as a target molecule 145 A1.3. Measurement configuration . 145 A1.4. Experiment for optimization of device condition . 147 A1.5. Effect of the back-filling materials of MCXs. 149 Appendix 2. Appendix 2. Numerical simulation 155 A2.1. Diffusion and reaction of biomolecules in electrolyte 155 A2.2. Modified Nodal Analysis. 165 Appendix 3. Appendix 3. Generalized voltage pulse method 173 A3.1. Integration of tunneling current . 173 Appendix 4. Appendix 4. pH sensor application . 179 A4.1. MIE capacitor for pH sensor application 179 Bibliography 185 초 록 193 | - |
| dc.language.iso | en | - |
| dc.publisher | 서울대학교 대학원 | - |
| dc.subject.ddc | 621.3 | - |
| dc.title | Electrochemical biosensor platform based on electron tunneling | - |
| dc.title.alternative | 전자 터널링 기반의 전기화학 바이오센서 플랫폼 | - |
| dc.type | Thesis | - |
| dc.description.degree | Doctor | - |
| dc.contributor.affiliation | 공과대학 전기·컴퓨터공학부 | - |
| dc.date.awarded | 2018-08 | - |
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