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Table of Contents
- Preface
- Contents
- Part I: Batteries
- State-of-Charge and State-of-Health Estimation of Commercial LiFePO4 Batteries by means of Impedance Spectroscopy
- 1 Introduction
- 2 Experimental Set-up
- 3 Results and Discussion
- 3.1 SoC Measurements
- 3.2 SoH Measurements
- 3.3 Data Modelling
- 4 Conclusions and Outlook
- 5 References
- Ageing Investigation of Lithium Ion LiFePO4 Batteries with a Combination of EIS and Structural Analysis
- 1 Introduction
- 2 Experimental
- 3 Results
- 3.1 Electrochemical Impedance Spectroscopy
- 3.2 Post-mortem Analysis
- 4 Summary and outlook
- 5 References
- Streamlining Calculation of the Distribution of Relaxation Times from Time Domain Data
- 1 Introduction
- 2 Novel Algorithm
- 3 Experimental
- 4 Conclusion and Outlook
- 5 References
- Influence of the Anode Graphite Particle Size on the SEI Film Formation in Lithium-Ion Cells
- 1 Introduction
- 2 Experimental
- 3 Results
- 4 Conclusion
- 5 References
- Frequency-Dependent Phase Correction for Impedance Measurements
- 1 Introduction
- 2 Method
- 2.1 Measurement Model
- 2.2 Phase Correction
- 3 Experimental Validation
- 4 Conclusion
- 5 References
- On-line State Estimation of Automotive Batteries using In-situ Impedance Spectroscopy
- 1 Introduction
- 2 Experimental Details
- 3 Results and Discussion
- 3.1 Impedance Measurements
- 3.2 In-situ Impedance Measurements
- 4 Conclusions
- 5 References
- State-of-Charge and State-of-Health Estimation of Commercial LiFePO4 Batteries by means of Impedance Spectroscopy
- Part II: Sensors
- Capacitive Measurements for Characterizing Thin Layers of Aqueous Solutions
- 1 Introduction
- 2 Measurement Set-up
- 3 Data Validation
- 4 Experimental Investigations
- 5 Results
- 6 Conclusion
- 7 References
- Low-Frequency Dielectric Spectroscopy Approach to Water Content in Winter Premium Diesel Fuel Assessment
- 1 Introduction
- 2 Material and Methods
- 2.1 Diesel Fuel Samples
- 2.2 Electrodes
- 2.3 Impedance Spectroscopy
- 3 Results and Discussion
- 4 Conclusion
- 5 References
- A Novel Method for Capacitive Determination of the Overall Resistance of an Aqueous Solution
- 1 Introduction
- 2 Proposed Measurement Method
- 3 Impedance Simulation
- 4 Experimental Verification
- 5 Conclusion
- 6 References
- Capacitive Measurements for Characterizing Thin Layers of Aqueous Solutions
- Part III: Material Characterization
- Nanoscale Electrochemical Characterization of Materials by means of Electrostatic Force and Current Measurements
- 1 Introduction
- 2 Experimental
- 3 Results and Discussion
- 3.1 Time-Domain Electrostatic Force Spectroscopy (TD-EFS)
- 3.2 Nanoscale Impedance Spectroscopy
- 4 Conclusion
- 5 References
- AC Impedance Investigation of weg Multi-walled Carbon Nanotubes/PEDOT:PSS Nanocomposites Fabricated with Different Sonication Times
- 1 Introduction
- 2 Experimental
- 2.1 Materials and Nanocomposite Preparation
- 2.2 Measurement Set-up
- 3 Results and Discussions
- 3.1 Morphological Analysis
- 3.2 Electrical Characteristics
- 3.3 Equivalent Circuit Modelling
- 4 Conclusions and Outlook
- 5 References
- Nanoscale Electrochemical Characterization of Materials by means of Electrostatic Force and Current Measurements
- Part IV: Bioimpedance
- From Counting Single Biological Cells to Recovering Photons: The Versatility of Contactless Impedance Sensing
- 1 Introduction
- 2 A General Equivalent Impedance Model
- 3 Impedance Sensing in Cell Biology
- 4 Impedance-Based Light Monitoring
- 5 Common Design Criteria
- 6 Conclusions
- 7 References
- Electric Impedance Measurement of Tissue Phantom Materials for Development of Medical Diagnostic Systems
- 1 Introduction
- 2 Materials and Methods
- 2.1 Gelatine Phantom Preparation
- 2.2 Plexiglas Enclosure with Electrodes
- 2.3 Van der Pauw Method
- 2.4 Measurement of Gelatine Sample Conductivity
- 3 Results
- 4 Conclusion
- 5 References
- Problems Encountered during Inappropriate Use of Commercial Bioimpedance Devices in Novel Applications
- 1 Introduction
- 2 Materials
- 2.1 Commercial Impedance Analyzers
- 2.2 Electrode–Skin Contact Impedance Measurement
- 2.3 Tissue Impedance measurement
- 2.4 Electrode–Skin Contact Impedance Electrical Model
- 2.5 Tissue Electrical Model
- 2.6 Fitting Impedance Measurements
- 2.7 Errors
- 2.8 Measurements on Healthy People
- 3 Experimental Results
- 3.1 Effect of Contact Impedance
- 3.2 Effect of Contact Impedance Mismatch
- 4 Discussion
- 5 Conclusion
- 6 References
- From Counting Single Biological Cells to Recovering Photons: The Versatility of Contactless Impedance Sensing
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