IFLP 13074
INSTITUTO DE FISICA LA PLATA
Unidad Ejecutora - UE
artículos
Título:
Water flow through nanopore
Autor/es:
JULIO MARAÑÓN DI LEO; JULIO MARAÑÓN
Revista:
INTERNATIONAL JOURNAL OF QUANTUM CHEMISTRY
Editorial:
John Wiley
Referencias:
Año: 2007
ISSN:
0020-7608
Resumen:
A Molecular Dynamics Simulation of water flow through a prismatic surface of van der Waals particles at (300 K) is reported.
The application of different pressure gradients to a waterproduces a large spectrum of average velocities from Poiseuille to turbulent flow.
A Molecular Dynamics Simulation of water flow through a prismatic surface of van der Waals particles at (300 K) is reported.
The application of different pressure gradients to a waterproduces a large spectrum of average velocities from Poiseuille to turbulent flow.
A Molecular Dynamics Simulation of water flow through a prismatic surface of van der Waals particles at (300 K) is reported.
The application of different pressure gradients to a waterproduces a large spectrum of average velocities from Poiseuille to turbulent flow.
A Molecular Dynamics Simulation of water flow through a prismatic surface of van der Waals particles at (300 K) is reported.
The application of different pressure gradients to a waterproduces a large spectrum of average velocities from Poiseuille to turbulent flow.
A Molecular Dynamics Simulation of water flow through a prismatic surface of van der Waals particles at (300 K) is reported.
The application of different pressure gradients to a waterproduces a large spectrum of average velocities from Poiseuille to turbulent flow.
A Molecular Dynamics Simulation of water flow through a prismatic surface of van der Waals particles at (300 K) is reported.
The application of different pressure gradients to a waterproduces a large spectrum of average velocities from Poiseuille to turbulent flow.
A Molecular Dynamics Simulation of water flow through a prismatic surface of van der Waals particles at (300 K) is reported.
The application of different pressure gradients to a waterproduces a large spectrum of average velocities from Poiseuille to turbulent flow.
A Molecular Dynamics Simulation of water flow through a prismatic surface of van der Waals particles at (300 K) is reported.
The application of different pressure gradients to a waterproduces a large spectrum of average velocities from Poiseuille to turbulent flow.
A Molecular Dynamics Simulation of water flow through a prismatic surface of van der Waals particles at (300 K) is reported.
The application of different pressure gradients to a waterproduces a large spectrum of average velocities from Poiseuille to turbulent flow.
A Molecular Dynamics Simulation of water flow through a prismatic surface of van der Waals particles at (300 K) is reported.
The application of different pressure gradients to a waterproduces a large spectrum of average velocities from Poiseuille to turbulent flow.
A Molecular Dynamics Simulation of water flow through a prismatic surface of van der Waals particles at (300 K) is reported.
The application of different pressure gradients to a waterproduces a large spectrum of average velocities from Poiseuille to turbulent flow.
A Molecular Dynamics Simulation of water flow through a prismatic surface of van der Waals particles at (300 K) is reported.
The application of different pressure gradients to a waterproduces a large spectrum of average velocities from Poiseuille to turbulent flow.
A Molecular Dynamics Simulation of water flow through a prismatic surface of van der Waals particles at (300 K) is reported.
The application of different pressure gradients to a waterproduces a large spectrum of average velocities from Poiseuille to turbulent flow.
