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 | Content type | Technology Sort descending | Collection Method | Engineering |
---|---|---|---|---|---|---|
A coupled blade element momentum – Computational fluid dynamics model for evaluating tidal stream turbine performance | Malki, R.; Williams, A.; Croft, T.; et al. | Journal Article | Current, Tidal | Modeling | Performance | |
Accelerating the development of marine energy: Exploring the prospects, benefits and challenges | Jeffery, H.; Jay, B.; Winskel, M. | Journal Article | Current, Wave | |||
The Buhl correction factor applied to high induction conditions for tidal stream turbines | Chapman, C.; Masters, I.; Togneri, M.; et al. | Journal Article | Current, Tidal | Modeling | Hydrodynamics | |
Near and far field flow disturbances induced by model hydrokinetic turbine: ADV and ADP comparison | Neary, V.; Gunawan, B.; Hill, C.; et al. | Journal Article | Current | Modeling | Hydrodynamics | |
Blade loads on tidal turbines in planar oscillatory flow | Milne, I. ; Day, A.; Sharma, R. ; et al. | Journal Article | Current, Tidal | Lab Data | Structural | |
Design and model testing of an optimized ducted marine current turbine | Luquet, R.; Bellevre, D.; Frechou, D.; et al. | Journal Article | Current, Cross Flow Turbine | Lab Data, Modeling, Scale Device | Structural | |
Influence of saline environment on creep rupture life of Nimonic-263 for marine turbine application | Bagui, S.; Ray, A.; Sahu, J.; et al. | Journal Article | Current | Lab Data | Materials | |
The influence of surface gravity waves on marine current turbine performance | Lust, E.; Luznik, L.; Flack, K.; et al. | Journal Article | Current | Lab Data | Performance | |
Assessment of the impacts of tidal stream energy through high-resolution numerical modeling | Ramos, V.; Carballo, R.; Álvarez, M.; et al. | Journal Article | Current, Tidal | Modeling | Array Effects, Hydrodynamics, Performance | |
Modeling tidal stream energy extraction and its effects on transport processes in a tidal channel and bay system using a three-dimensional coastal ocean model | Yang, Z.; Wang, T.; Copping, A. | Journal Article | Current, Tidal | Modeling | Hydrodynamics | |
Wave–current interaction effects on marine energy converters | Saruwatari, A.; Ingram, D.; Cradden, L. | Journal Article | Current, Wave | Field Data, Modeling | Hydrodynamics, Performance | |
A review of energy storage technologies for marine current energy systems | Zhou, Z.; Benbouzid, M.; Charpentier, J.; et al. | Journal Article | Current, Tidal | Grid Integration, Structural | ||
Introduction: Electricity from Wave and Tide | Lynn, P. | Book Chapter | Current, Wave | |||
Case Studies: Tidal Stream Energy Converters | Lynn, P. | Book Chapter | Current, Tidal | |||
Generating electricity | Lynn, P. | Book Chapter | Current, Wave | Control, Grid Integration | ||
Capturing marine energy | Lynn, P. | Book Chapter | Current, Tidal, Wave | Test Center | ||
Electricity from Wave and Tide: An Introduction to Marine Energy | Lynn, P. | Book | Current, Wave | Full Scale | ||
Evaluation of a model for predicting the tidal velocity in fjord entrances | Lalander, E.; Thomassen, P.; Leijon, M. | Journal Article | Current, Tidal | Field Data, Modeling | ||
Hydrodynamic performance of a vertical-axis tidal-current turbine with different preset angles of attack | Zhao, G.; Yang, R.; Liu, Y.; et al. | Journal Article | Cross Flow Turbine | Modeling, Scale Device | Hydrodynamics, Performance, Structural | |
Numerical Modeling of the Effects of a Free Surface on the Operating Characteristics of Marine Hydrokinetic Turbines | Adamski, S. | Thesis | Ocean Current, Tidal | Modeling | Power Take Off, Structural | |
Experimental studies on a closed cycle demonstration OTEC plant working on small temperature difference | Faizal, M.; Ahmed, M. | Journal Article | OTEC, Closed-Cycle | Lab Data, Scale Device | Performance | |
Ocean Thermal Energy Conversion at SBM | Kibbee, S. | Conference Paper | OTEC | |||
Multi-use offshore platform configurations in the scope of the FP7 TROPOS Project | Quevedo, E.; Cartón, M.; Delory, E.; et al. | Conference Paper | OTEC, Closed-Cycle | Hybrid Devices | ||
An assessment of global Ocean Thermal Energy Conversion resources under broad geographical constraints | Rajagopalan, K.; Nihous, G. | Journal Article | OTEC | Modeling | ||
Maximum output of an OTEC power plant | Yeh, R.; Su, T.; Yang, M. | Journal Article | OTEC | Modeling | Performance | |
Ocean Thermal Energy Conversion | Vega, L. | Book Chapter | OTEC | |||
Hydrogen production through an ocean thermal energy conversion system operating at an optimum temperature drop | Kazim, A. | Journal Article | OTEC, Closed-Cycle | Modeling | Materials, Performance | |
Energy and exergy analyses of hydrogen production via solar-boosted ocean thermal energy conversion and PEM electrolysis | Ahmadi, P.; Dincer, I.; Rosen, M. | Journal Article | OTEC, Open-Cycle | Lab Data, Modeling | Hybrid Devices, Performance | |
Experimental investigation on an ammonia-water based ocean thermal energy conversion system | Yuan, H.; Mei, N.; Hu, S.; et al. | Journal Article | OTEC, Closed-Cycle | Lab Data | Performance | |
Estimates of global Ocean Thermal Energy Conversion (OTEC) resources using an ocean general circulation model | Rajagopalan, K.; Nihous, G. | Journal Article | OTEC | Modeling | ||
An Order-of-Magnitude Estimate of Ocean Thermal Energy Conversion Resources | Nihous, G. | Journal Article | OTEC | Modeling | ||
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 | |
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 | |
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 | |
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 | |
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 | |
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 | |
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 | |
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 | |
Fouling in reverse electrodialysis under natural conditions | Vermaas, D.; Kunteng, D.; Saakes, M.; et al. | Journal Article | Salinity Gradient | 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 | ||
Real time wave prediction for WEC control system optimization using a dynamic neural network | Fernandez, H.; Vousdoukas, M.; Schimmels, S.; et al. | Conference Paper | Wave | Field Data, Modeling | Control, Performance |
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