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 |
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Synergy of Multiple Cylinders in Flow Induced Motion for Hydrokinetic Energy Harnessing | Kim, E-S. | Thesis | Current, Vortex-Induced Vibration, Ocean Current | Lab Data, Modeling | Hydrodynamics, Performance, Structural | |
Bio-Inspired adaptive damping in hydrokinetic energy harnessing using flow-induced oscillations | Sun, H.; Bernitsas, M. | Journal Article | Current, Vortex-Induced Vibration | Lab Data | Control, Performance | |
Hydrokinetic power conversion using Flow Induced Vibrations with nonlinear (adaptive piecewise-linear) springs | Sun, H.; Ma, C.; Bernitsas, M. | Journal Article | Current, Vortex-Induced Vibration | Lab Data | Control, Structural | |
Hydrokinetic power conversion using Flow Induced Vibrations with cubic restoring force | Sun, H.; Ma, C.; Bernitsas, M. | Journal Article | Current, Vortex-Induced Vibration | Lab Data, Modeling | Control, Performance | |
Numerical analysis and experiments of an underwater magnetic nonlinear energy harvester based on vortex-induced vibration | Shan, X.; Sui, G.; Tian, H.; et al. | Journal Article | Current, Vortex-Induced Vibration | Lab Data, Modeling | Performance, Structural | |
Investigations into efficiency of vortex induced vibration hydro-kinetic energy device | Narendran, K.; Murali, K.; Sundar, V. | Journal Article | Current, Vortex-Induced Vibration | Lab Data, Modeling | Performance | |
Development of a renewable energy system utilizing vortex induced vibration of a cylinder and principle of leverage aiming for application in deep sea | Nishi, Y.; Ono, K.; Kokubun, K. | Journal Article | Current, Vortex-Induced Vibration | Lab Data, Modeling | Performance, Structural | |
Analysis of biomimetic stream energy device based on flapping foils | Malefaki, I.; Anevlavi, D.; Belibassakis, K. | Conference Paper | Current, Oscillating Hydrofoil, Vortex-Induced Vibration | Lab Data, Modeling | Performance | |
Numerical simulation and experimental validation for energy harvesting of single-cylinder VIVACE converter with passive turbulence control | Ding, L.; Zhang, L.; Bernitsas, M.; et al. | Journal Article | Current, Vortex-Induced Vibration | Lab Data, Modeling | Control | |
Effect of mass-ratio, damping, and stiffness on optimal hydrokinetic energy conversion of a single, rough cylinder in flow induced motions | Sun, H.; Kim, E.; Nowakowski, G.; et al. | Journal Article | Current, Vortex-Induced Vibration | Lab Data | ||
Development of an alternating lift converter utilizing flow-induced oscillations to harness horizontal hydrokinetic energy | Kim, E.; Sun, H.; Park, H.; et al. | Journal Article | Current, Vortex-Induced Vibration | Field Data, Lab Data, Full Scale, Scale Device | Performance | |
Hydrokinetic energy conversion by two rough tandem-cylinders in flow induced motions: Effect of spacing and stiffness | Sun, H.; Ma, C.; Kim, E.; et al. | Journal Article | Current, Vortex-Induced Vibration | Lab Data | Performance | |
Vortex-induced piezoelectric cantilever beam vibration for ocean wave energy harvesting via airflow from the orifice of oscillation water column chamber | Du, X.; Wang, Y.; Chen, H.; et al. | Journal Article | Current, Vortex-Induced Vibration, Wave, Oscillating Water Column | Lab Data, Modeling | Performance | |
Effect of the geometric configuration of the pendulum system of tandem cylinders (PSTC) on the hydrokinetic energy conversion efficiency of wake-induced vibration | Jang, Y.; Kim, H.; Lee, C.; et al. | Journal Article | Current, Vortex-Induced Vibration | Lab Data | Performance, Structural | |
Hydrokinetic energy harvesting from flow-induced motion of oscillators with different combined sections | Lian, J.; Ran, D.; Yan, X.; et al. | Journal Article | Current, Vortex-Induced Vibration | Lab Data, Modeling | Performance, Structural | |
Optimal energy harvesting efficiency from vortex-induced vibration of a circular cylinder | Han, P.; Huang, Q.; Pan, G.; et al. | Journal Article | Current, Vortex-Induced Vibration | Lab Data, Modeling | Performance, Structural | |
Impacts of soft marine fouling on the hydrokinetic energy harvesting from one-degree-of-freedom vortex-induced vibrations | Rashki, M.; Hejazi, K.; Tamimi, V.; et al. | Journal Article | Current, Vortex-Induced Vibration | Lab Data, Modeling | Performance | |
Surface protrusion based mechanisms of augmenting energy extraction from vibrating cylinders at Reynolds number 3 × 10^3–3 × 10^4 | Vinod, A.; Banerjee, A. | Journal Article | Current, Vortex-Induced Vibration | Lab Data | Hydrodynamics, Materials, Performance | |
Influence of hard marine fouling on energy harvesting from Vortex-Induced Vibrations of a single-cylinder | Jadidi, P.; Zeinoddini, M. | Journal Article | Current, Vortex-Induced Vibration | Lab Data | Performance | |
On Passive Control of Transition to Galloping of a Circular Cylinder Undergoing Vortex Induced Vibration Using Thick Stripsticle | Vinod, A.; Auvil A.; Banerjee, A. | Journal Article | Current, Vortex-Induced Vibration | Lab Data, Modeling, Scale Device | ||
Numerical investigation on interactive FIO of two-tandem cylinders for hydrokinetic energy harnessing | Ding, W.; Sun, H.; Xu, W.; et al. | Journal Article | Current, Vortex-Induced Vibration | Lab Data, Modeling | Performance | |
WITT: Harvesting Energy From Subsea, Vortex-Induced Vibration | Wickett, M.; Hindley, S. | Journal Article | Current, Vortex-Induced Vibration | Lab Data, Modeling | Performance, Structural | |
Harvesting Energy by Flow Included Motions | Bernitsas, M. | Book Chapter | Current, Vortex-Induced Vibration | Lab Data, Modeling | Hydrodynamics, Performance, Structural | |
Mass ratio effect on vortex induced vibration of a flexibly mounted circular cylinder, an experimental study | Modir, A.; Kahrom, M.; Farshidianfar, A. | Journal Article | Current, Vortex-Induced Vibration | Lab Data, Modeling | Structural | |
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 | |
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 | |
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 | |
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 | |
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 | |
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 | |
Two Dimensional Nanofluidic Membranes toward Harvesting Salinity Gradient Power | Xin, W.; Jiang, L.; Wen, L. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data | ||
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 | |
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 | |
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 | |
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 | |
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 | |
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 | |
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 | |
Reverse Electrodialysis Energy Harvesting System Using High-Gain Step-Up DC/DC Converter | Huang, Y.; Mei, Y.; Xiong, S.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data, Modeling | Structural | |
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 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 | |
Low cost carbon electrodes to produce salinity gradient energy using reverse electrodialysis membranes: Effect of feed flow velocities and addition of Mg2+ | Najmiyah, T. ; Aziyah, L.; Hendrawan, Y. ; et al. | Conference Paper | Salinity Gradient, Reverse Electrodialysis | Lab Data | 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 | |
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 | |
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 | |
Study on capacitive flow electrodes used as energy conversion systems for scaled-up reverse electrodialysis devices | González, A.; Ríos, M.; Sanchez, C. | Presentation | Salinity Gradient, Reverse Electrodialysis | Lab Data | Performance | |
Energy Harvesting from Salinity Gradient | Muhthassim, B. ; Thian, X. ; Hasan, K. | Journal Article | Salinity Gradient, Pressure-Retarded Osmosis, Reverse Electrodialysis | Lab Data | Performance | |
Modelling the Reverse ElectroDialysis process with seawater and concentrated brines | Tedesco, M.; Cipollina, A.; Tamburini, A.; et al. | Journal Article | Salinity Gradient, Reverse Electrodialysis | Lab Data, Modeling | ||
Unlocking synergies: comprehensive analysis and challenges in the integration of reverse osmosis with reverse electrodialysis | Rojano, S.; Marchena, R.; Maturana, A. | Conference Paper | Salinity Gradient, Reverse Electrodialysis | Lab Data | Hybrid Devices, 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 |
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