Direct power production from a water salinity difference in a membrane-modified supercapacitor flow cell

B.B. Sales; M. Saakes; J.W. Post; C.J.N. Buisman; P.M. Biesheuvel; H.V.M. Hamelers

doi:10.1021/es100852a

Direct power production from a water salinity difference in a membrane-modified supercapacitor flow cell

B.B. Sales
, M. Saakes
, J.W. Post
, C.J.N. Buisman
, P.M. Biesheuvel
, H.V.M. Hamelers

Research output: Contribution to journal › Article › Academic › peer-review

220 Citations (Scopus)

Abstract

The entropy increase of mixing two solutions of different salt concentrations can be harnessed to generate electrical energy. Worldwide, the potential of this resource, the controlled mixing of river and seawater, is enormous, but existing conversion technologies are still complex and expensive. Here we present a small-scale device that directly generates electrical power from the sequential flow of fresh and saline water, without the need for auxiliary processes or converters. The device consists of a sandwich of porous “supercapacitor” electrodes, ion-exchange membranes, and a spacer and can be further miniaturized or scaled-out. Our results demonstrate that alternating the flow of saline and fresh water through a capacitive cell allows direct autogeneration of voltage and current and consequently leads to power generation. Theoretical calculations aid in provid

Original language	English
Pages (from-to)	5661-5665
Journal	Environmental Science and Technology
Volume	44
DOIs	https://doi.org/10.1021/es100852a
Publication status	Published - 2010

Keywords

pressure retarded osmosis
reverse electrodialysis
energy
generation
sea

Access to Document

10.1021/es100852a

Cite this

@article{9838856e16104e9db98e4304dab491a7,

title = "Direct power production from a water salinity difference in a membrane-modified supercapacitor flow cell",

abstract = "The entropy increase of mixing two solutions of different salt concentrations can be harnessed to generate electrical energy. Worldwide, the potential of this resource, the controlled mixing of river and seawater, is enormous, but existing conversion technologies are still complex and expensive. Here we present a small-scale device that directly generates electrical power from the sequential flow of fresh and saline water, without the need for auxiliary processes or converters. The device consists of a sandwich of porous “supercapacitor” electrodes, ion-exchange membranes, and a spacer and can be further miniaturized or scaled-out. Our results demonstrate that alternating the flow of saline and fresh water through a capacitive cell allows direct autogeneration of voltage and current and consequently leads to power generation. Theoretical calculations aid in provid",

keywords = "pressure retarded osmosis, reverse electrodialysis, energy, generation, sea",

author = "B.B. Sales and M. Saakes and J.W. Post and C.J.N. Buisman and P.M. Biesheuvel and H.V.M. Hamelers",

year = "2010",

doi = "10.1021/es100852a",

language = "English",

volume = "44",

pages = "5661--5665",

journal = "Environmental Science and Technology",

issn = "0013-936X",

publisher = "American Chemical Society (ACS)",

}

TY - JOUR

T1 - Direct power production from a water salinity difference in a membrane-modified supercapacitor flow cell

AU - Sales, B.B.

AU - Saakes, M.

AU - Post, J.W.

AU - Buisman, C.J.N.

AU - Biesheuvel, P.M.

AU - Hamelers, H.V.M.

PY - 2010

Y1 - 2010

N2 - The entropy increase of mixing two solutions of different salt concentrations can be harnessed to generate electrical energy. Worldwide, the potential of this resource, the controlled mixing of river and seawater, is enormous, but existing conversion technologies are still complex and expensive. Here we present a small-scale device that directly generates electrical power from the sequential flow of fresh and saline water, without the need for auxiliary processes or converters. The device consists of a sandwich of porous “supercapacitor” electrodes, ion-exchange membranes, and a spacer and can be further miniaturized or scaled-out. Our results demonstrate that alternating the flow of saline and fresh water through a capacitive cell allows direct autogeneration of voltage and current and consequently leads to power generation. Theoretical calculations aid in provid

AB - The entropy increase of mixing two solutions of different salt concentrations can be harnessed to generate electrical energy. Worldwide, the potential of this resource, the controlled mixing of river and seawater, is enormous, but existing conversion technologies are still complex and expensive. Here we present a small-scale device that directly generates electrical power from the sequential flow of fresh and saline water, without the need for auxiliary processes or converters. The device consists of a sandwich of porous “supercapacitor” electrodes, ion-exchange membranes, and a spacer and can be further miniaturized or scaled-out. Our results demonstrate that alternating the flow of saline and fresh water through a capacitive cell allows direct autogeneration of voltage and current and consequently leads to power generation. Theoretical calculations aid in provid

KW - pressure retarded osmosis

KW - reverse electrodialysis

KW - energy

KW - generation

KW - sea

U2 - 10.1021/es100852a

DO - 10.1021/es100852a

M3 - Article

SN - 0013-936X

VL - 44

SP - 5661

EP - 5665

JO - Environmental Science and Technology

JF - Environmental Science and Technology

ER -

Direct power production from a water salinity difference in a membrane-modified supercapacitor flow cell

Abstract

Keywords

Access to Document

Fingerprint

Cite this