Correlation force spectroscopy for single molecule measurements

This thesis addresses the development of a new force spectroscopy tool, correlation force spectroscopy (CFS) for the measurement of the properties of very small volumes of material (molecular to m3) at kHz-MHz frequency range. CFS measures the simultaneous thermal fluctuations of two closely-spaced atomic force microscopy (AFM) cantilevers. CFS then calculates the cross-correlation in the thermal fluctuations that gives the mechanical properties of the matter that spans the gap of the two cantilevers. The book also discusses development of CFS, its advantages over AFM, and its application in single molecule force spectroscopy and micro-rheology.

Chapter 1 - Introduction Overview of Single Molecule Force Spectroscopy Techniques Experiments Using Single molecule AFM Limitations of AFM-based single molecule force spectroscopy Summary Chapter 2- Correlation Force Spectroscopy Correlation Force Spectroscopy: Rationale Correlation Force Spectroscopy: Development Laterally Offset Configuration Vertically Offset Configuration Analysis of Correlations between Two Cantilevers Validation of Fluctuation-Dissipation Theorem for One Cantilever Analysis of Thermal Fluctuations to obtain Correlations Chapter 3- Dynamics of Single Molecules Elastic Properties of Single Molecules: Worm-Like Chain and Freely-Jointed Chain Models Hydrodynamics of Single Molecules: Dumbbell Model and Rouse Model Internal Friction Rouse with Internal Friction Model of Linear Viscoelasticity of a Semiflexible Chain Summary Chapter 4- Microrheology with Correlation Force Spectroscopy Existing Techniques of Rheometry Experimental Methods Comparison to Finite Element Analysis Comparison to Simple Harmonic Oscillator Model Summary Chapter 5- Development of Colloidal Probe Correlation Force Spectroscopy: Case Study Materials and Methods Analysis Results Discussion Summary Chapter 6- Correlation Force Spectroscopy for Single Molecule Measurements Effect of the Distance between Cantilever Tips Harmonic Oscillator Modeling of Vertically Offset Correlation Force Spectroscopy Summary Chapter 7- Single Molecule Force Spectroscopy of Dextran Materials and Methods Results Stretching a Dextran Molecule Static Force-Elongation Mode Dynamic Correlated Fluctuations Mode Discussion Summary Chapter 8- Single Molecule Force Spectroscopy of Single-Stranded DNA Rationale Introduction Materials and Methods Modal Analysis Results Discussion Summary Chapter 9- Summary An Overview of Chapters Future Work Appendix I: Simple Harmonic Oscillator Model for Laterally Offset Correlation Force Spectroscopy Appendix II: Simple Harmonic Oscillator Model for Vertically Offset Correlation Force Spectroscopy with Tethered Molecule References