The Knowledge Base provides access to information about technical and engineering aspects of marine energy. Relevant documents from around the world are compiled into a user-friendly table that displays all content available in Tethys Engineering. Results can be narrowed using the keyword filters on the right, or with search terms entered in the text box, including targeted searches (e.g., org:DOE, author:polagye). Content may also be sorted alphabetically by clicking on column headers. Some entries will appear on the next page.
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Title | Author | Date Sort ascending | Content type | Technology | Collection Method | Engineering |
---|---|---|---|---|---|---|
Modeling pressure-retarded osmotic power in commercial length membranes | Naguib, M.; Maisonneuve, J.; Laflamme, C.; et al. | Journal Article | Salinity Gradient, Pressure-Retarded Osmosis | Modeling, Full Scale | Materials, Performance | |
Scale-up characteristics of membrane-based salinity-gradient power production | Feinberg, B.; Ramon, G.; Hoek, E. | Journal Article | Salinity Gradient, Pressure-Retarded Osmosis | Lab Data, Modeling | Performance | |
Energy generation and abatement of Acid Orange 7 in reverse electrodialysis cells using salinity gradients | Scialdone, O.; D’Angelo, A.; Galia, A. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Materials, Performance | |
Energy and thermodynamic analysis of power generation using a natural salinity gradient based pressure retarded osmosis process | He, W. | Journal Article | Salinity Gradient, Pressure-Retarded Osmosis | Modeling | Performance | |
Comparison of Energy Efficiency and Power Density in Pressure Retarded Osmosis and Reverse Electrodialysis | Yip, N.; Elimelech, M. | Journal Article | Salinity Gradient | Materials, Performance | ||
Cathodic reduction of hexavalent chromium coupled with electricity generation achieved by reverse-electrodialysis processes using salinity gradients | Scialdone, O.; D’Angelo, A.; De Lumè, E.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Materials, Performance | |
Energy Recovery from Solutions with Different Salinities Based on Swelling and Shrinking of Hydrogels | Zhu, X.; Yang, W.; Hatzell, M.; et al. | Journal Article | Salinity Gradient | Lab Data | Performance | |
Nanocomposite reverse electrodialysis (RED) ion-exchange membranes for salinity gradient power generation | Hong, J.; Chen, Y. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Materials, Performance | |
Thermodynamic limits of extractable energy by pressure retarded osmosis | Lin, S.; Straub, A.; Elimelech, M. | Journal Article | Salinity Gradient | Performance | ||
Numerical analysis of transport phenomena in reverse electrodialysis for system design and optimization | Jeong, H.; Kim, H.; Kim, D. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Control, Performance, Structural | |
Thermodynamic, Energy Efficiency, and Power Density Analysis of Reverse Electrodialysis Power Generation with Natural Salinity Gradients | Yip, N.; Vermaas, D.; Kijmeijer, K.; et al. | Journal Article | Salinity Gradient | Modeling | Performance | |
Experimentally obtainable energy from mixing river water, seawater or brines with reverse electrodialysis | Daniilidis, A.; Vermaas, D.; Herber, R.; et al. | Journal Article | Salinity Gradient | Lab Data | Performance | |
Enhanced mixing in the diffusive boundary layer for energy generation in reverse electrodialysis | Vermaas, D.; Saakes, M.; Nijmeijer, K. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data, Scale Device | Hydrodynamics, Performance, Structural | |
Osmotic power with Pressure Retarded Osmosis: Theory, performance and trends – A review | Helfer, F.; Lemckert, C.; Anissimov, Y. | Journal Article | Salinity Gradient, Pressure-Retarded Osmosis | Performance | ||
Capacitive mixing power production from salinity gradient energy enhanced through exoelectrogen-generated ionic currents | Hatzell, M.; Cusick, R.; Logan, B. | Journal Article | Salinity Gradient | Lab Data | Performance | |
Robust and High performance hollow fiber membranes for energy harvesting from salinity gradients by pressure retarded osmosis | Chou, S.; Wang, R.; Fane, A. | Journal Article | Salinity Gradient | Lab Data, Modeling | Materials, Performance, Structural | |
High Efficiency in Energy Generation from Salinity Gradients with Reverse Electrodialysis | Vermaas, D.; Veerman, J.; Yip, N.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Performance | ||
Modeling of power generation from the mixing of simulated saline and freshwater with a reverse electrodialysis system: The effect of monovalent and multivalent ions | Hong, J.; Zhang, W.; Luo, J.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Materials, Performance | |
Influence of Natural Organic Matter Fouling and Osmotic Backwash on Pressure Retarded Osmosis Energy Production from Natural Salinity Gradients | Yip, N.; Elimelech, M. | Journal Article | Salinity Gradient | Lab Data | Performance | |
High performance thin film composite pressure retarded osmosis (PRO) membranes for renewable salinity-gradient energy generation | Han, G.; Zhang, S.; Chung, T. | Journal Article | Salinity Gradient | Lab Data | Performance | |
On-grid and off-grid batch-ED (electrodialysis) process: Simulation and experimental tests | Uche, J.; Círez, F.; Bayod, A.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling, Full Scale | Performance | |
Simulation of enhanced power generation by reverse electrodialysis stack module in serial configuration | Kim, K.; Ryoo, W. ; Chun, M. ; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Performance, Structural | |
Highly Robust Thin-Film Composite Pressure Retarded Osmosis (PRO) Hollow Fiber Membranes with High Power Densities for Renewable Salinity-Gradient Energy Generation | Han, G.; Wang, P.; Chung, T. | Journal Article | Salinity Gradient, Pressure-Retarded Osmosis | Lab Data, Modeling | Materials, Performance | |
Experimental Update of the Overtopping Model Used for the Wave Dragon Wave Energy Converter | Parmeggiani, S.; Kofoed, J.; Friis-Madsen, E. | Journal Article | Wave, Overtopping | Modeling | Performance | |
A novel hybrid process of reverse electrodialysis and reverse osmosis for low energy seawater desalination and brine management | Li, W.; Krantz, W.; Cornelissen, E.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Hydrodynamics, Performance | |
Predictability of the power output of three wave energy technologies in the Danish North Sea | Fernandez-Chozas, J.; Jensen, N.; Sorensen, H.; et al. | Journal Article | Wave, Overtopping, Point Absorber, Attenuator | Field Data | Grid Integration, Performance | |
Energy harvesting from salinity gradient by reverse electrodialysis with anodic alumina nanopores | Kim, J.; Kim, S.; Kim, D. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Materials, Performance | |
Evaluation of the Potential of Osmotic Energy as Renewable Energy Source in Realistic Conditions | Touati, K.; Schiestel, T. | Journal Article | Salinity Gradient, Pressure-Retarded Osmosis | Materials, Performance | ||
Applicability of Pressure Retarded Osmosis Power Generation Technology in Sri Lanka | Karunarathne, H.; Walpalage, S. | Journal Article | Salinity Gradient, Pressure-Retarded Osmosis | Field Data | Performance | |
Osmotic power production from salinity gradient resource by pressure retarded osmosis: Effects of operating conditions and reverse solute diffusion | She, Q.; Jin, X.; Tang, C. | Journal Article | Salinity Gradient | Lab Data, Modeling | Performance | |
The SSG Wave Energy Converter: Performance, Status and Recent Developments | Vicinanza, D.; Margheritini, L.; Kofoed, J.; et al. | Journal Article | Wave, Overtopping | Lab Data, Modeling, Scale Device | Performance, Power Take Off, Structural | |
Second law analysis of reverse osmosis desalination plants: An alternative design using pressure retarded osmosis | Sharqawy, M.; Zubair, S.; Lienhard, J. | Journal Article | Salinity Gradient, Pressure-Retarded Osmosis | Modeling | Performance, Structural | |
Performance Limiting Effects in Power Generation from Salinity Gradients by Pressure Retarded Osmosis | Yip, N.; Elimelech, M. | Journal Article | Salinity Gradient | Performance | ||
On the Effects of Geometry Control on the Performance of Overtopping Wave Energy Converters | Victor, L.; Troch, P.; Kofoed, J. | Journal Article | Wave, Overtopping | Lab Data, Modeling | Control, Performance, Structural | |
Microbial Reverse Electrodialysis Cells for Synergistically Enhanced Power Production | Kim, Y.; Logan, B. | Journal Article | Salinity Gradient | Lab Data | Performance | |
Thin-Film Composite Pressure Retarded Osmosis Membranes for Sustainable Power Generation from Salinity Gradients | Yip, N.; Tiraferri, A. ; Phillip, W.; et al. | Journal Article | Salinity Gradient, Pressure-Retarded Osmosis | Modeling | Performance | |
Influence of multivalent ions on power production from mixing salt and fresh water with a reverse electrodialysis system | Post, J.; Hamelers, H.; Buisman, C. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Materials, Performance | |
Salinity gradient power by reverse electrodialysis: effect of model parameters on electrical power output | Brauns, E. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Performance | |
Energy Recovery from Controlled Mixing Salt and Fresh Water with a Reverse Electrodialysis System | Post, J.; Hamelers, H.; Buisman, C. | Journal Article | Salinity Gradient | Performance | ||
Current status of ion exchange membranes for power generation from salinity gradients | Długołęcki, P.; Nymeijer, K.; Metz, S.; et al. | Journal Article | Salinity Gradient | Lab Data, Modeling | Materials, Performance | |
Towards a worldwide sustainable and simultaneous large-scale production of renewable energy and potable water through salinity gradient power by combining reversed electrodialysis and solar power? | Brauns, E. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Hybrid Devices, Performance | |
Designing cost-effective seawater reverse osmosis system under optimal energy options | Gilau, A.; Small, M. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Performance | ||
Renewable energy by reverse electrodialysis | Turek, M.; Bandura, B. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Materials, Performance | |
Salinity-gradient power: Evaluation of pressure-retarded osmosis and reverse electrodialysis | Post, J.; Veerman, J.; Hamelers, H.; et al. | Journal Article | Salinity Gradient | Modeling | Performance | |
Power generation by pressure-retarded osmosis | Lee, K.; Baker, R.; Lonsdale, H. | Journal Article | Salinity Gradient, Pressure-Retarded Osmosis | Modeling | Performance | |
Salinity Gradient Power: Utilizing Vapor Pressure Differences | Olsson, M.; Wick, G.; Isaacs, J. | Journal Article | Salinity Gradient | Lab Data | Materials, Performance |
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