Energy Harvesting with Single‐Ion‐Selective Nanopores: A Concentration‐Gradient‐Driven Nanofluidic Power Source

Inspired by biological systems that have the inherent skill to generate considerable bioelectricity from the salt content in fluids with highly selective ion channels and pumps on cell membranes, herein, a fully abiotic single-pore nanofluidic energy-harvesting system that efficiently converts Gibbs free energy in the form of a salinity gradient into electricity is demonstrated. The maximum power output with the individual nanopore approaches ∼26 pW. By exploiting parallelization, the estimated power density can be enhanced by one to three orders over previous ion-exchange membranes. A theoretical description is proposed to explain the power generation with the salinity-gradient-driven nanofluidic system. Calculation results suggest that the electric-power generation and its efficiency can be further optimized by enhancing the surface-charge density (up to 100 mC m−2) and adopting the appropriate nanopore size (between 10 and 50 nm). This facile and cost-efficient energy-harvesting system has the potential to power biomedical tiny devices or construct future clean-energy recovery plants.

[1]  Z. Siwy,et al.  Asymmetric diffusion through synthetic nanopores. , 2005, Physical review letters.

[2]  Charles M. Lieber,et al.  Coaxial silicon nanowires as solar cells and nanoelectronic power sources , 2007, Nature.

[3]  Javier Cervera,et al.  Ionic conduction, rectification, and selectivity in single conical nanopores. , 2006, The Journal of chemical physics.

[4]  S Pacala,et al.  Stabilization Wedges: Solving the Climate Problem for the Next 50 Years with Current Technologies , 2004, Science.

[5]  Reinhard Neumann,et al.  Synthetic proton-gated ion channels via single solid-state nanochannels modified with responsive polymer brushes. , 2009, Nano letters.

[6]  C. Dekker,et al.  Surface-charge-governed ion transport in nanofluidic channels. , 2004, Physical review letters.

[7]  David Needham,et al.  Functional bionetworks from nanoliter water droplets. , 2007, Journal of the American Chemical Society.

[8]  Reimar Spohr,et al.  Diode-like single-ion track membrane prepared by electro-stopping , 2001 .

[9]  Bo Zhang,et al.  Electrostatic-gated transport in chemically modified glass nanopore electrodes. , 2006, Journal of the American Chemical Society.

[10]  Charles R. Martin,et al.  Nanotubule-Based Molecular-Filtration Membranes , 1997 .

[11]  Róbert E. Gyurcsányi,et al.  Chemically-modified nanopores for sensing , 2008 .

[12]  J. Post,et al.  Salinity-gradient power : Evaluation of pressure-retarded osmosis and reverse electrodialysis , 2007 .

[13]  Z. Siwy,et al.  Ion‐Current Rectification in Nanopores and Nanotubes with Broken Symmetry , 2006 .

[14]  Zuzanna Siwy,et al.  DNA-nanotube artificial ion channels. , 2004, Journal of the American Chemical Society.

[15]  Jennifer Griffiths,et al.  The Realm of the Nanopore , 2008 .

[16]  D. Brogioli Extracting renewable energy from a salinity difference using a capacitor. , 2009, Physical review letters.

[17]  Zuzanna Siwy,et al.  Ionic selectivity of single nanochannels. , 2008, Nano letters.

[18]  J. Eijkel,et al.  Energy conversion in microsystems: is there a role for micro/nanofluidics? , 2007, Lab on a chip.

[19]  M. Colombini,et al.  Zero-current potentials in a large membrane channel: a simple theory accounts for complex behavior. , 1993, Biophysical journal.

[20]  Katsuhiro Shirono,et al.  Theoretical study on the efficiency of nanofluidic batteries , 2006 .

[21]  P. Kamat Meeting the Clean Energy Demand: Nanostructure Architectures for Solar Energy Conversion , 2007 .

[22]  Q. Ouyang,et al.  How the geometric configuration and the surface charge distribution influence the ionic current rectification in nanopores , 2007 .

[23]  Jennifer Griffiths,et al.  The realm of the nanopore. Interest in nanoscale research has skyrocketed, and the humble pore has become a king. , 2008, Analytical chemistry.

[24]  Zhong Lin Wang,et al.  Self-powered nanotech. , 2008, Scientific American.

[25]  N. Nguyen,et al.  Nanofluidic devices and their applications. , 2008, Analytical chemistry.

[26]  Xu Hou,et al.  Gating of single synthetic nanopores by proton-driven DNA molecular motors. , 2008, Journal of the American Chemical Society.

[27]  Fred J Sigworth,et al.  Synthetic Protocells to Mimic and Test Cell Function , 2010, Advanced materials.

[28]  Jennifer N Cha,et al.  Approaches for biological and biomimetic energy conversion. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[29]  J. Eijkel,et al.  Principles and applications of nanofluidic transport. , 2009, Nature nanotechnology.

[30]  S. Bezrukov,et al.  Salting out the ionic selectivity of a wide channel: the asymmetry of OmpF. , 2004, Biophysical journal.

[31]  J. Weinstein,et al.  Electric Power from Differences in Salinity: The Dialytic Battery , 1976, Science.

[32]  Guang Zhu,et al.  Converting biomechanical energy into electricity by a muscle-movement-driven nanogenerator. , 2009, Nano letters.

[33]  David Lindley The energy should always work twice , 2009, Nature.

[34]  Xu Hou,et al.  A biomimetic potassium responsive nanochannel: G-quadruplex DNA conformational switching in a synthetic nanopore. , 2009, Journal of the American Chemical Society.

[35]  Q. Ouyang,et al.  Asymmetric properties of ion transport in a charged conical nanopore. , 2007, Physical review. E, Statistical, nonlinear, and soft matter physics.

[36]  Reinhard Neumann,et al.  Electro-responsive asymmetric nanopores in polyimide with stable ion-current signal , 2003 .

[37]  J. Post,et al.  Energy recovery from controlled mixing salt and fresh water with a reverse electrodialysis system. , 2008, Environmental science & technology.

[38]  Serge G Lemay,et al.  Nanopore-based biosensors: the interface between ionics and electronics. , 2009, ACS nano.

[39]  C. Dekker Solid-state nanopores. , 2007, Nature nanotechnology.

[40]  Basit Yameen,et al.  Facile molecular design of hybrid functional assemblies with controllable transport properties: mesoporous films meet polyelectrolyte brushes. , 2009, Chemical Communications.

[41]  Arun Majumdar,et al.  Ion transport in nanofluidic channels , 2004 .

[42]  Matsuhiko Nishizawa,et al.  Metal Nanotubule Membranes with Electrochemically Switchable Ion-Transport Selectivity , 1995, Science.

[43]  L. Guo,et al.  Rectified ion transport through concentration gradient in homogeneous silica nanochannels. , 2007, Nano letters.

[44]  David A. LaVan,et al.  Designing artificial cells to harness the biological ion concentration gradient. , 2008, Nature nanotechnology.

[45]  Reinhard Neumann,et al.  Single conical nanopores displaying pH-tunable rectifying characteristics. manipulating ionic transport with zwitterionic polymer brushes. , 2009, Journal of the American Chemical Society.

[46]  H. White,et al.  The nanopore electrode. , 2004, Analytical chemistry.

[47]  C. Dekker,et al.  Power generation by pressure-driven transport of ions in nanofluidic channels. , 2007, Nano letters.

[48]  Warren K. Mino,et al.  A method for reproducibly preparing synthetic nanopores for resistive-pulse biosensors. , 2007, Small.

[49]  R. Neumann,et al.  Asymmetric selectivity of synthetic conical nanopores probed by reversal potential measurements , 2007 .