6533b7cffe1ef96bd1259a3a

RESEARCH PRODUCT

Angular Trapping of Anisometric Nano-Objects in a Fluid

Christina RosmanMadhavi KrishnanMichele CelebranoCarsten Sönnichsen

subject

10120 Department of ChemistryOptics and Photonics3104 Condensed Matter PhysicsSilverMaterials scienceMacromolecular SubstancesSurface PropertiesStatic Electricity2210 Mechanical EngineeringMetal Nanoparticles1600 General ChemistryBioengineeringTrap (computing)OpticsOrientation (geometry)540 ChemistryNano-ElectrochemistryNanotechnologyScattering RadiationGeneral Materials ScienceFluidicsSurface chargeParticle Size1502 Bioengineeringbusiness.industryPhysicsMechanical EngineeringElectrostatic unitsDNAGeneral ChemistryCondensed Matter Physics2500 General Materials ScienceSymmetry (physics)KineticsHydrodynamicsLevitationAnisotropybusiness

description

We demonstrate the ability to trap, levitate, and orient single anisometric nanoscale objects with high angular precision in a fluid. An electrostatic fluidic trap confines a spherical object at a spatial location defined by the minimum of the electrostatic system free energy. For an anisometric object and a potential well lacking angular symmetry, the system free energy can further strongly depend on the object's orientation in the trap. Engineering the morphology of the trap thus enables precise spatial and angular confinement of a single levitating nano-object, and the process can be massively parallelized. Since the physics of the trap depends strongly on the surface charge of the object, the method is insensitive to the object's dielectric function. Furthermore, levitation of the assembled objects renders them amenable to individual manipulation using externally applied optical, electrical, or hydrodynamic fields, raising prospects for reconfigurable chip-based nano-object assemblies.

yearjournalcountryeditionlanguage
2012-01-01Nano Letters
https://doi.org/10.1021/nl303099c