Sunlight-driven Ion pump for use in Solar Photo-dialysis Technology
- 技術優勢
- The electrodialysis cell is powered directly by the sunlight, using >85% less energy than other state of the art solar-driven electrodialysis cells
- 技術應用
- Desalination Integrated Solar Photo-Dialysis
- 詳細技術說明
- Potable water is a universal human need. Desalination is an important tool for creating potable water from salt water sources, either in regions that lack sufficient freshwater sources or for disaster relief. Current desalination technologies are expensive and inefficient, even on large scale. State of the art solar-driven electrodialysis cells use 5 times the minimum energy required by thermodynamics. Traditionally, a solar cell is separately used to generate electricity which is in turn used to power an electrodialysis cell. This involves inefficiencies in both the electricity generation and powering of the cell. The inventors at UCI have developed an integrated solar electrodialysis device which is driven directly by sunlight. The device uses a photoacid-dye-functionalized membrane to drive ions through separate filters, leaving behind salt-free water. The process much more efficient than separate solar and electrodialysis cells, using up to 85% less energy.
- *Abstract
-
The invention is a specialized membrane that absorbs solar energy to directly drive desalination of salt water. Compared to state of the art devices, the invention is capable of bypassing the inefficient conversion from electronic energy to ionic energy, saving up to 85% of the energy required by other state of the art electrodialysis cells.
- *IP Issue Date
- Mar 8, 2018
- *Principal Investigation
-
Name: Shane Ardo
Department:
Name: Joseph Cardon
Department:
Name: Ronald Reiter
Department:
Name: Christopher Sanborn
Department:
Name: William White
Department:
Name: Eric Schwartz
Department:
- 申請號碼
- 20180065095
- 其他
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State Of Development
The inventors have experimentally verified power generation from a light-absorbing ion exchange membrane (the major technical hurdle) and have numerically modeled the complete dialysis cell.
Related Materials
Energy Sciences at the Molecule–Material Interface
Tech ID/UC Case
27462/2017-190-0
Related Cases
2017-190-0
- 國家/地區
- 美國
