Microfluidic Pumps and Stirrers

Microfluidic pumps and stirrers are essential components for controlling the movement and mixing of fluids in microscale systems. Microfluidic pumps, including peristaltic, electroosmotic, and pressure-driven designs, enable precise fluid transport in lab-on-a-chip devices and biomedical applications. Stirrers, often based on magnetic, electrokinetic, or bubble-induced mixing, enhance fluid homogenization in tiny volumes, improving reaction efficiency and analysis in microfluidic assays.

2014 Ellipsoidal Particles Encapsulated In Droplets

2005 Theoretical Investigation Of Electroosmotic Flows And Chaotic Stirring In Rectangular Cavities

2005 Magneto-Hydrodynamic Stirrer For Stationary And Moving Fluids

2004 Thermosiphon-Based PCR Reactor: Experiment And Modeling

2004 Optical Microscope Study Of Liquid Transport In Carbon Nanotubes

2004 On The Translation Of A Cylinder In A Long Tube

2004 Analysis Of Lateral Flow Bio-Detectors: Competitive Format

2003 The Kinematics Of Bend-Induced Mixing In Micro-Conduits

2003 Complex Magnetohydrodynamic Low-Reynolds-Number Flows

2003 A Mathematical Model Of Lateral Flow Biooreactions Applied To Sandwich Assays

2003 A Magneto-Hydrodynamically Controlled Fluidic Network

2002 Peristaltically Induced Motion In A Closed Cavity With Two Vibrating Walls