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Wave energy converters as offshore wind farm guardians: a pathway to resilient ocean systems

Journal Article

Title: Wave energy converters as offshore wind farm guardians: a pathway to resilient ocean systems
Author:
Vitale, O.; Haji, M
Publication Date:
Journal:
Scientific Reports
Volume:
In Press
Publisher:
Nature
Affiliation:
Cornell University, University of Michigan
Technology:
Wave, Point Absorber, Oscillating Wave Surge Converter
Collection Method:
Lab Data, Modeling
Engineering:
Hydrodynamics
Economics:
Cost Assessment, Levelized Cost of Energy
Language:
English

Document Access

Website:
External Link

Citation

Vitale, O.; Haji, M (2026). Wave energy converters as offshore wind farm guardians: a pathway to resilient ocean systems. Scientific Reports, In Presshttps://doi.org/10.1038/s41598-026-54843-z
@article{Vitale-2026-,
author = {Vitale, O and Haji, M},
title = {Wave energy converters as offshore wind farm guardians: a pathway to resilient ocean systems},
journal = {Scientific Reports},
year = {2026},
month = {jun},
publisher = {Nature},
volume = {In Press},
doi = {10.1038/s41598-026-54843-z},
url = {https://www.nature.com/articles/s41598-026-54843-z},
keywords = {Wave, Point Absorber, Oscillating Wave Surge Converter, Lab Data, Modeling, Hydrodynamics, Cost Assessment, Levelized Cost of Energy},
}
Export Citation to BibTex
TY - JOUR
TI - Wave energy converters as offshore wind farm guardians: a pathway to resilient ocean systems
AU - Vitale, O
AU - Haji, M
T2 - Scientific Reports
AB - Maximizing the durability and reliability of offshore wind farms is essential for the clean energy transition. In this work, we demonstrate how wave energy converter (WEC) farms can shelter offshore wind farms from cyclic wave loading, resulting in significant reductions in wave-induced turbine fatigue damage. Using experimentally validated hydrodynamic models, we show that modeling WEC energy dissipation through fluid structure interactions rather than rated power provides an unbiased analysis of different architecture’s sheltering capabilities. Through the system-level model, we observe that even small reductions in wave height propagate to the levelized cost of energy (LCOE) of the wind farm, resulting in a 4.94% decrease in LCOE with a 6% reduction in wave height. Additionally, WEC farms can benefit from this co-location by sharing siting costs, operation and maintenance teams, and mooring and transmission cables with the offshore wind farm. This work advances the design of integrated wind–wave systems, supporting resilient, cost-effective offshore renewables for global deployment.
DA - 2026/06//
PY - 2026
PB - Nature
VL - In Press
UR - https://www.nature.com/articles/s41598-026-54843-z
DO - 10.1038/s41598-026-54843-z
LA - English
KW - Wave
KW - Point Absorber
KW - Oscillating Wave Surge Converter
KW - Lab Data
KW - Modeling
KW - Hydrodynamics
KW - Cost Assessment
KW - Levelized Cost of Energy
ER -
Export Citation to RIS

Abstract

Maximizing the durability and reliability of offshore wind farms is essential for the clean energy transition. In this work, we demonstrate how wave energy converter (WEC) farms can shelter offshore wind farms from cyclic wave loading, resulting in significant reductions in wave-induced turbine fatigue damage. Using experimentally validated hydrodynamic models, we show that modeling WEC energy dissipation through fluid structure interactions rather than rated power provides an unbiased analysis of different architecture’s sheltering capabilities. Through the system-level model, we observe that even small reductions in wave height propagate to the levelized cost of energy (LCOE) of the wind farm, resulting in a 4.94% decrease in LCOE with a 6% reduction in wave height. Additionally, WEC farms can benefit from this co-location by sharing siting costs, operation and maintenance teams, and mooring and transmission cables with the offshore wind farm. This work advances the design of integrated wind–wave systems, supporting resilient, cost-effective offshore renewables for global deployment.