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 |
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PET-hydrogel heterogeneous membranes that eliminate concentration polarization for salinity gradient power generation | Li, J.; Li, C.; Dou, H.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Materials, Performance | |
Synthesis of Silver Nanoparticle-Immobilized Antibacterial Anion-Exchange Membranes for Salinity Gradient Energy Production by Reverse Electrodialysis | Eti, M.; Cihanoğlu, A.,; Hamaloğlu, K. ; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | ||
Deep utilization of salinity gradient energy between concentrated seawater and river water by multi-stage reverse electrodialysis | Guo, Z.; Cui, W.; Ji, Z.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Performance | |
Impacts of membrane fouling on nanofluidic salinity gradient energy conversion process | Mao, R.; Chen, X.; Long, R.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Performance | |
High Ionic Flux Sub-Micro Channels Membrane Model for Salinity Gradient Power Generation | Jiang, J.; Lu, B.; Xu, Y.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Performance | |
Optimal Design of the Overtopping Wave Energy Converter Based on Fluid–Structure Interaction Simulation | An, S.; Kim, G.; Lee, J. | Journal Article | Wave, Overtopping | Modeling | Hydrodynamics, Structural | |
In-depth understanding of boosting salinity gradient power generation by ionic diode | Peng, R.; Li, T.; Song, H.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Materials, Performance | |
Salinity gradient energy conversion by custom-made interpolymer ion exchange membranes utilized in reverse electrodialysis system | Altıok, E.; Kaya, T.; Smolinska-Kempisty, K.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Performance | |
Biomimetic asymmetric GO/polymer nanocomposite membrane for energy harvesting | Hao, J.; Sun, Q.; Wang, W.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data, Modeling | Materials, Performance | |
A generalized disjunctive programming model for the optimal design of reverse electrodialysis process for salinity gradient-based power generation | Tristán, C.; Fallanza, M.; Ibanez, R.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Structural | |
Numerical Study and Geometrical Investigation of an Onshore Overtopping Device Wave Energy Converter with a Seabed Coupled Structure | de Barros, A.; Fragassa, C. ; Paiva, M.; et al. | Journal Article | Wave, Overtopping | Modeling | Structural | |
Clean power generation from salinity gradient using reverse electrodialysis technologies: Recent advances, bottlenecks, and future direction | Chae, S.; Kim, H.; Hong, J.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data, Modeling | Performance | |
A charge-free and membrane-free hybrid capacitive mixing system for salinity gradient energy harvesting | Yang, B.; Yu, J.; Ma, T. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Materials, Performance, Structural | |
Experimental Proof-of-Concept of a Hybrid Wave Energy Converter Based on Oscillating Water Column and Overtopping Mechanisms | Simonetti, I.; Esposito, A.; Cappietti, L. | Journal Article | Wave, Overtopping, Oscillating Water Column | Lab Data, Scale Device | Performance | |
Numerical Analysis of the Available Power in an Overtopping Wave Energy Converter Subjected to a Sea State of the Coastal Region of Tramandaí, Brazil | Cisco, L.; Maciel, R.; Oleinik, P. ; et al. | Journal Article | Wave, Overtopping | Modeling | ||
The techno-economic flexibility investigation and enhancement for the hybrid ocean-energy supported zero-energy building and seawater-transportation system | Guo, X.; Luo, H.; Cao, S.; et al. | Journal Article | Wave, Overtopping | Modeling | Control, Hybrid Devices | |
Optimizing pore structure of nanoporous membranes for high-performance salinity gradient power conversion | Tao, H.; Li, G.; Xu, Z.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Performance | |
Heat to Hydrogen by Reverse Electrodialysis—Using a Non-Equilibrium Thermodynamics Model to Evaluate Hydrogen Production Concepts Utilising Waste Heat | Solberg, S.; Zimmermann, P.; Wilhelmsen, Ø.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Performance | |
Nanofluidic Membranes to Address the Challenges of Salinity Gradient Energy Harvesting: Roles of Nanochannel Geometry and Bipolar Soft Layer | Dartoomi, H.; Khatibi, M.; Ashrafizadeh, S | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Control, Materials, Structural | |
Numerical Analysis of an Overtopping Wave Energy Converter Subjected to the Incidence of Irregular and Regular Waves from Realistic Sea States | Hubner, R.; Fragassa, C. ; Paiva, M.; et al. | Journal Article | Wave, Overtopping | Modeling | Performance | |
Power Production from Produced Waters via Reverse Electrodialysis: A Preliminary Assessment | Cosenza, A.; Campisi, G.; Giacalone, F.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Performance | |
Effect of Gaskets Geometry on the Performance of a Reverse Electrodialysis Cell | Sandoval-Sánchez, E.; De la Cruz-Barragán, Z.; Miranda-Hernández, M.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Performance | |
Recovery of Salinity Gradient Energy with an Inorganic Sodium Superionic Conductor | Zhou, G.; Mei, Y.; Wang, Y.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Materials, Performance | |
Bio-inspired Salinity-gradient Power Generation with UiO-66-NH₂ Metal-Organic Framework based Composite membrane | Yao, L.; Li, Q.; Pan, S.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Materials, Performance | |
Comparison of Pretreatment Methods for Salinity Gradient Power Generation Using Reverse Electrodialysis (RED) Systems | Ju, J.; Choi, Y.; Lee, S.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Performance | |
Wave power extraction and coastal protection by a periodic array of oscillating buoys embedded in a breakwater | Zhang, Y.; Zhao, X.; Geng, J.; et al. | Journal Article | Wave, Overtopping, Point Absorber, Oscillating Water Column | Lab Data | Hydrodynamics, Power Take Off | |
Investigations on the effects of operational parameters in reverse electrodialysis system for salinity gradient power generation using central composite design (CCD) | Altıok, E.; Kaya, T.; Othman, N.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Performance | |
Salinity gradient energy capture for power production by reverse electrodialysis experiment in thermal desalination plants | Kang, S.; Li, J.; Wang, Z.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Hybrid Devices, Performance | |
Salinity gradient energy harvested from thermal desalination for power production by reverse electrodialysis | Li, J.; Zhang, C.; Wang, Z.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data, Modeling | Performance | |
Modeling and control strategy analysis of a hydraulic energy-storage wave energy conversion system | Li, Y.; Wang, X.; Fang, X.; et al. | Journal Article | Wave, Overtopping, Oscillating Water Column | Modeling | Control, Performance | |
Two Dimensional Nanofluidic Membranes toward Harvesting Salinity Gradient Power | Xin, W.; Jiang, L.; Wen, L. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | ||
Theoretical investigation on an oscillating buoy WEC-floating breakwater integrated system | Ning, D.; Guo, B.; Wang, R.; et al. | Journal Article | Wave, Overtopping, Oscillating Water Column | Modeling | Hydrodynamics, Performance, Power Take Off | |
Experimental study on salinity gradient energy recovery from desalination seawater based on RED | Jianbo, L.; Chen, Z.; Kai, L.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Performance | |
Transitioning from electrodialysis to reverse electrodialysis stack design for energy generation from high concentration salinity gradients | Hulme, A.; Davey, C.; Tyrrel, D.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Performance, Structural | |
Numerical simulation of salinity gradient power generation using reverse electrodialysis | Jin, D.; Xi, R.; Xu, S.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Hydrodynamics, Performance | |
Active Control of Irreversible Faradic Reactions to Enhance the Performance of Reverse Electrodialysis for Energy Production from Salinity Gradients | Oh, Y.; Han, J-Y.; Kim, H.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Control, Performance | |
Enhanced energy recovery using a cascaded reverse electrodialysis stack for salinity gradient power generation | Nam, J-Y.; Jwa, E.; Eom, H.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Performance | |
Synergy analysis for ion selectivity in nanofluidic salinity gradient energy harvesting | Long, R.; Li, M.; Chen, X.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Materials, Performance | |
A Generalized Reverse-Electrodialysis Model Incorporating Both Continuous and Recycle Modes for Energy Harvesting From Salinity Gradient Power | Yan, Z.; Huang, Y.; Jiang, C.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data, Modeling | Performance, Structural | |
Salinity gradient power by reverse electrodialysis: A multidisciplinary assessment in the Colombian context | Roldan-Carvajal, M.; Vallejo-Castaño, S.; Alvarez-Silva, O.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Field Data, Modeling, Scale Device | Performance | |
Free-Standing Covalent Organic Framework Membrane for High-Efficiency Salinity Gradient Energy Conversion | Hou, S.; Ji, W.; Chen, J.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | Materials, Performance | |
Optimizing Wave Overtopping Energy Converters by ANN Modelling: Evaluating the Overtopping Rate Forecasting as the First Step | Oliver, J.; Esteban, M.; Lopez, R.; et al. | Journal Article | Wave, Overtopping | Modeling | ||
Recovery of salinity gradient energy in desalination plants by reverse electrodialysis | Tristán, C.; Fallanza, M.; Ibanez, R.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Performance, Structural | |
The MoonWEC, a new technology for wave energy conversion in the Mediterranean Sea | Miquel, A.; Lamberti, A.; Antonini, A.; et al. | Journal Article | Wave, Overtopping, Point Absorber, Oscillating Water Column | Modeling | Hydrodynamics, Performance, Structural | |
Numerical Assessment of Onshore Wave Energy in France: Wave Energy, Conversion and Cost | Sergent, P.; Baudry, V.; De Bonviller, A.; et al. | Journal Article | Wave, Overtopping, Point Absorber, Oscillating Water Column, Oscillating Wave Surge Converter | Modeling | ||
Wave Energy Assessment at Valencia Gulf and Comparison of Energy Production of Most Suitable Wave Energy Converters | Cascajo, R. ; García, E.; Quiles, E.; et al. | Journal Article | Wave, Overtopping | Field Data, Modeling | ||
The Influence of Ramp Shape Parameters on Performance of Overtopping Breakwater for Energy Conversion | Musa, M.; Roslan, M.; Ahmad, M.; et al. | Journal Article | Wave, Overtopping | Lab Data, Modeling | Hydrodynamics, Substructure | |
Analysis on Renewable Energy Generation of From Salinity Gradient by Reverse Electro Dialysis | Govindarsu, R.; JaiGanesh, S.; Kumaar R, P. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | ||
A Simple Model to Assess the Performance of an Overtopping Wave Energy Converter Embedded in a Port Breakwater | Cavallaro, L.; Iuppa, C.; Castiglione, F.; et al. | Journal Article | Wave, Overtopping | Modeling | Control, Performance | |
Hydrodynamic slip enhanced nanofluidic reverse electrodialysis for salinity gradient energy harvesting | Long, R.; Zhao, Y.; Kuang, Z.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Modeling | Performance |
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