Transport Phenomena (TP)
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The Transport Phenomena (TP) program, administered by the U.S. National Science Foundation, supports fundamental research aimed at understanding, modeling, and controlling the transport of mass, momentum, energy, and species across multiple scales. The program emphasizes innovative projects that integrate experiments, theory, and computational modeling to advance fundamental principles while maintaining a clear focus on engineering applications. Research areas cover the dynamics of single- and multiphase systems, including phenomena such as flow separation, turbulence transition, drag reduction, cavitation, reactive flows, and the relationship between microscale dynamics and macroscale material properties. The program addresses a broad range of fluids, including liquids, gases, suspensions, biological fluids, and active fluids. Additionally, the TP program encourages studies on physicochemical phenomena at fluid interfaces and between fluids and solids, including adsorption, rheology, capillarity, electrokinetics, porous media flow, and particle assembly. It supports research into thermodynamics and thermal transport mechanisms like conduction, diffusion, convection, phase transitions, and radiation across different scales, including microelectronics and biological systems. Combustion research targeting chemical kinetics, turbulence-chemistry interactions, sustainable fuels, pollutant control, and wildland fire behavior is also emphasized. To accelerate innovation, the program fosters partnerships with federal agencies, industry, international entities, and others. Interested applicants can find additional information and submission instructions through NSF’s official channels.
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TP projects involve experiments, theory, and/or computational modeling. They aim to improve understanding and to create novel analytical techniques. While projects focus on fundamental principles, they also have a clear vision of how research outcomes will benefit applications in engineering.
TP supports research on the dynamics of single- and multiphase systems. Special interests include flow separation, transition to turbulence, drag reduction, cavitation, instabilities, and reactive flows. The program encourages research on the connection between dynamics at the microscale and material and flow properties at the macroscale. Fluids of interest include liquids, gases, suspensions, emulsions, granular materials, active fluids, biological fluids, colloids, aerosols, bubbles and drops, and fluids with surfactants.
TP supports research on physicochemical phenomena at the interfaces between fluids and between fluids and solids. These phenomena include adsorption and desorption of nanoparticles and surfactants; bulk and interfacial rheology; wetting and capillarity phenomena; electrokinetics; flow in porous media; and directed and self-assembly of particles.
TP supports research on thermodynamics and thermal transport involving conduction, diffusion, convection, phase transition, and radiation. Research may be across scales, in complex structures and at interfaces, in microelectronic devices, and in biological systems. Projects involving phonon transport and quantum thermal phenomena are welcome.
TP encourages proposals focused on combustion of gas, liquid and solid fuels. Combustion topics of interest include chemical kinetic modeling, turbulence-chemistry interactions, detonations, plasma assisted reacting flows, sustainable fuels, mechanisms for pollutant control, and in-situ diagnostic methods. The program also supports research on wildland fire behavior that aims to prevent wildfire spread, inhibit its growth, and/or predict and mitigate fires at the wildland-urban interface.
Partnerships: To speed discovery and innovation, NSF partners with federal agencies, industry, international groups, and others. Current opportunities are at NSF ENG Partnerships.
