Nanoelectromechanics in Engineering and Biology

Containing a broad survey of current research across a wide range of disciplines, Nanoelectromechanics in Engineering and Biology provides a thorough grounding in present knowledge and understanding of the phenomena of nanometer-scale particle manipulation. The book explores how electromechanics can be applied to the sorting of DNA molecules, examining viruses, constructing electronics devices with carbon nanotubes, and actuating nanoscale electric motors. It also provides a wealth of application and background knowledge, from using electric fields for particle sorting in laboratories-on-a-chip to electrode fabrication, electric field simulation, and computer analysis.

The success, growth, and virtually limitless applications of nanotechnology depend upon our ability to manipulate nanoscale objects, which in turn depends upon developing new insights into the interactions of electric fields, nanoparticles, and the molecules that surround them. In the first book to unite and directly address particle electrokinetics and nanotechnology, Nanoelectromechanics in Engineering and Biology provides a thorough grounding in the phenomena associated with nanoscale particle manipulation. The author delivers a wealth of application and background knowledge, from using electric fields for particle sorting in lab-on-a-chip devices to electrode fabrication, electric field simulation, and computer analysis. It also explores how electromechanics can be applied to sorting DNA molecules, examining viruses, constructing electronic devices with carbon nanotubes, and actuating nanoscale electric motors. The field of nanotechnology is inherently multidisciplinary-in its principles, in its techniques, and in its applications-and meeting its current and future challenges will require the kind of approach reflected in this book. Unmatched in its scope, Nanoelectromechanics in Engineering and Biology offers an outstanding opportunity for people in all areas of research and technology to explore the use and precise manipulation of nanoscale structures.

MOVEMENT FROM ELECTRICITYThe Promise of NanotechnologyElectrodynamicsElectrokinetics and NanoparticlesA Note on TerminologyELECTROKINETICSThe Laws of ElectrostaticsCoulomb's Law, Electric Field and Electrostatic PotentialGauss', Laplace's and Poisson's EquationsConductance and CapacitancePolarization and DispersionDielectric Spheres in Electric FieldsForces in Field Gradients: Dielectrophoresis and ElectrorotationCOLLOIDS AND SURFACESColloidsThe Electrical Double LayerThe Gouy-Chapman ModelThe Stern LayerParticles in Moving FluidsColloids in Electric FieldsElectrode Polarization and Fluid FlowOther Forces Affecting Colloidal ParticlesANALYSIS AND MANIPULATION OF SOLID PARTICLESDielectrophoresis of Homogeneous ColloidsFrequency-Dependent Behavior and the Crossover FrequencyDouble Layer EffectsDielectrophoresis vs. Fluid FlowSeparating SpheresTrapping Single ParticlesLimitations on Minimum Particle Trapping SizeDielectrophoresis and Laser Trapping DIELECTROPHORESIS OF COMPLEX BIOPARTICLESManipulating VirusesAnatomy of VirusesThe Multi-Shell ModelMethods of Measuring Dielectrophoretic ResponseExamining Virus Structure by DielectrophoresisThe Interpretation of Crossover DataStudying Non-Spherical VirusesSeparating VirusesUnexpected Charge EffectsDIELECTROPHORESIS, MOLECULES AND MATERIALS Manipulation at the Molecular ScaleManipulating ProteinsDielectrophoresis for Protein AnalysisDNADielectrophoretic Manipulation of DNAApplications of DNA ManipulationNanotubes, Nanowires and Carbon-60NANOENGINEERINGTowards Molecular NanotechnologyDirected Self AssemblyDevice AssemblyElectrostatic Self-AssemblyElectronics with Nanotubes, Nanowires and Carbon-60Putting it all Together: The Potential for Dielectrophoretic NanoassemblyDielectrophoresis and Materials ScienceNanoelectromechanical SystemsPRACTICAL DIELECTROPHORETIC SEPARATIONLimitations on Dielectrophoretic SeparationFlow SeparationField Flow FractionationThermal RatchetsSeparation Strategies using Dielectrophoretic RatchetsStacked Ratcheting MechanismsTraveling Wave DielectrophoresisApplications of Traveling Wave Dielectrophoresis ELECTRODE STRUCTURESMicroengineeringElectrode Fabrication TechniquesLaboratories on a ChipA Note about PatentsCOMPUTATIONAL APPLICATIONS IN ELECTROMECHANICSThe Need for SimulationPrinciples of Electric Field SimulationAnalytical MethodsNumerical MethodsFinite Element AnalysisThe Method of MomentsCommercial vs. Custom SoftwareDetermination of Dynamic Field EffectsExample: Simulation of Polynomial ElectrodesDIELECTROPHORETIC RESPONSE MODELING AND MATLABModeling the Dielectrophoretic ResponseProgramming in MATLABModeling the CLAUSIUS-MOSSOTTI FACTORDetermining the Crossover SpectrumModeling Surface Conductance EffectsMulti-Shell ObjectsFinding the Best FitMATLAB in Time-Variant Field AnalysisOther MATLAB Functions APPENDIX A. A DIELECTROPHORETIC ROTARY NANOMOTOR: A PROPOSAL