About 25% of the total energy used in industry is known to spend in moving vehicles through air or water, or fluids alongpipes and canals, and fluids can be a process carrier or material through which transport, separation and conversion processes occur. Thus, understanding of flows is of huge technological importance in aerodynamic and hydrodynamic applications. In this aspect, we perform research on topics of energetic flows both ranging from fundamental to applied engineering to understanding, predicting and controlling flows. The research includes studies of turbulent flows with physical modeling, fluid-structure interaction problems and multi-phase flows with computational modeling, aiming at development of high-efficient energy-generating (or -saving) systems based on numerical simulations and experimental measurement (or visualization). The long term research goal of MicroFluidics and NanoMechatronics (uFNM) lab. is to create novel micro-/nanofluidic technologies that develop a broad spectrum of interdisciplinary research fields. Currently, of uFNM lab. focuses on four research fields such as Microfluidics (Fluid Mechanics at Micro/Nano-scale), NanoMechatronics (Automation of Micro-/Nano scale Systems and Device), Multi-Physics simulation (Numerical Simulation of Fluids, Ions, Colloids and Devices) and Printing in 2D and 3D Manners (Micro/Nanofabrication)