Entropy-Driven Pumping in Zeolites and Biological Channels
- 26 April 1999
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 82 (17) , 3552-3555
- https://doi.org/10.1103/physrevlett.82.3552
Abstract
We simulate constrained dynamics of two species transport across single-file molecular-sized pores such as biomembrane channels and zeolites. We focus on diffusional pumping where one type of particle uses its entropy of mixing to drive another along its chemical potential gradient. Quantitative analyses of rates and efficiencies of transport are plotted as functions of transmembrane potential, pore length, and particle-pore interactions. Our results qualitatively explain recent measurements of “negative” osmosis and suggest new, more systematic experiments, particularly with zeolites.Keywords
All Related Versions
This publication has 15 references indexed in Scilit:
- Kinetics and thermodynamics across single-file pores: Solute permeability and rectified osmosisThe Journal of Chemical Physics, 1999
- An exactly soluble non-equilibrium system: The asymmetric simple exclusion processPhysics Reports, 1998
- How Fast Do Fluids Squeeze through Microscopic Single-File Pores?Physical Review Letters, 1998
- A triphasic analysis of negative osmotic flows through charged hydrated soft tissuesJournal of Biomechanics, 1997
- Osmotic properties of a phenolsulfonic acid formaldehyde cation exchange membrane in contact with mixed aqueous electrolyte solutionsJournal of Membrane Science, 1996
- Osmotic Properties of Polyelectrolyte Membranes: Positive and Negative OsmosisJournal of Colloid and Interface Science, 1995
- Molecular Mechanisms for Passive and Active Transport of WaterPublished by Elsevier ,1995
- Transport parameters in the human red cell membrane: Solute-membrane interactions of amides and ureasBiochimica et Biophysica Acta (BBA) - Biomembranes, 1991
- Gramicidin ChannelsAnnual Review of Physiology, 1984
- Water transport and ion-water interaction in the gramicidin channelBiophysical Journal, 1981