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  1. Article ; Online: Experimental Modeling of Horizontal and Vertical Wave Forces on an Elevated Coastal Structure.

    Park, Hyoungsu / Tomiczek, Tori / Cox, Daniel T / van de Lindt, John W / Lomonaco, Pedro

    Coastal engineering

    2023  Volume 128, Issue October 2017, Page(s) 58–74

    Abstract: A large-scale physical model was created in Oregon State University's Large Wave Flume to collect an extensive dataset measuring wave-induced horizontal and vertical forces on an idealized coastal structure. Water depth was held constant while wave ... ...

    Abstract A large-scale physical model was created in Oregon State University's Large Wave Flume to collect an extensive dataset measuring wave-induced horizontal and vertical forces on an idealized coastal structure. Water depth was held constant while wave conditions included regular, irregular, and transient (tsunami-like) waves with different significant wave heights and peak periods for each test. The elevation of the base of the test specimen with respect to the stillwater depth (air gap) was also varied from at-grade to 0.28 m above the stillwater level to better understand the effects of raising or lowering a nearshore structure on increasing or decreasing the horizontal and vertical wave forces. Results indicate that while both horizontal and vertical forces tend to increase with increasing significant wave height, the maximum and top 0.4% of forces increased disproportionally to other characteristic values such as the mean or top 10%. As expected, the horizontal force increased as the test specimen was more deeply submerged and decreased as the structure was elevated to larger air gaps above the stillwater level. However, this trend was not true for the vertical force, which was maximized when the elevation of the base of the structure was equal to the elevation of the stillwater depth. Small wave heights were characterized by low horizontal to vertical force ratios, highlighting the importance of considering vertical wave forces in addition to horizontal wave forces in the design of coastal structures. The findings and data presented here may be used by city planners, engineers, and numerical modelers, for future analyses, informed coastal design, and numerical benchmarking to work toward enabling more resilient nearcoast structures.
    Language English
    Publishing date 2023-11-20
    Publishing country Netherlands
    Document type Journal Article
    ZDB-ID 2019650-7
    ISSN 1872-7379 ; 0378-3839
    ISSN (online) 1872-7379
    ISSN 0378-3839
    Database MEDical Literature Analysis and Retrieval System OnLINE

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  2. Article: Experimental Study of Wave Runup Variability on a Dissipative Beach

    Li, Chuan / Özkan‐Haller, H. Tuba / Lomonaco, Pedro / Maddux, Timothy B. / García‐Medina, Gabriel

    Journal of geophysical research. 2022 June, v. 127, no. 6

    2022  

    Abstract: Wave runup is an important process due to its effects on sediment transport and its role in coastal hazards. Despite decades of research on this topic, much uncertainty still exists in the estimation and prediction of runup. A recent numerical study has ... ...

    Abstract Wave runup is an important process due to its effects on sediment transport and its role in coastal hazards. Despite decades of research on this topic, much uncertainty still exists in the estimation and prediction of runup. A recent numerical study has shown that there is appreciable variability in runup among wave groups on a dissipative beach due to sequencing of bichromatic waves and the resulting merging of bores. The current work further explores, in a highly controlled laboratory setting, runup variability due to wave sequencing. It is found that considerable runup variability exists among wave groups, and that this variability can differ greatly depending on the incident wave conditions. The observations suggest that the largest runup results from a higher number of bore merging events and involves a carrier wave that is positioned behind the infragravity wave crest, while the smallest runup results from a lower number of bore merging events and a carrier wave in front of the infragravity wave. A relationship is presented between runup variability and wave height, wave length, and the number of waves in a group. It is also found that an increase in runup variability is associated with an increase, at the first bore merging event, in the surface elevation at the crest of the carrier wave. Runup variability is also larger when the first bore merging event occurs further offshore, and when the local surface slope of the infragravity wave is higher.
    Keywords geophysics ; prediction ; research ; sediment transport ; uncertainty ; wavelengths
    Language English
    Dates of publication 2022-06
    Publishing place John Wiley & Sons, Ltd
    Document type Article
    Note JOURNAL ARTICLE
    ZDB-ID 161667-5
    ISSN 2169-9291 ; 2169-9275 ; 0148-0227 ; 0196-2256
    ISSN (online) 2169-9291
    ISSN 2169-9275 ; 0148-0227 ; 0196-2256
    DOI 10.1029/2022JC018418
    Database NAL-Catalogue (AGRICOLA)

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  3. Article: Design and testing of a free floating dual flap wave energy converter

    Forbush, Dominic D. / Bacelli, Giorgio / Spencer, Steven J. / Coe, Ryan G. / Bosma, Bret / Lomonaco, Pedro

    Elsevier Ltd Energy. 2022 Feb. 01, v. 240

    2022  

    Abstract: With a wide variety of wave energy device archetypes currently under consideration, it is a major challenge to ensure that research findings and methods are broadly applicable. In particular, the design and testing of wave energy control systems, a ... ...

    Abstract With a wide variety of wave energy device archetypes currently under consideration, it is a major challenge to ensure that research findings and methods are broadly applicable. In particular, the design and testing of wave energy control systems, a process which includes experimental design, empirical modeling, control design, and performance evaluation, is of interest. This goal motivated the redesign and testing of a floating dual flap wave energy converter. As summarized in this paper, the steps taken in the design, testing, and analysis of the device mirrored those previously demonstrated on a three-degree of freedom point absorber device. The method proposed does not require locking WEC degrees of freedom to develop an excitation model, and presents a more attainable system identification procedure for at-sea deployments. The results show that the methods employed work well for this dual flap device, lending additional support for the broad applicability of the design and testing methods applied here. The aim of this paper is to demonstrate that these models are particularly useful for deducing areas of device design or controller implementation that can be reasonably improved to increase device power capture.
    Keywords energy conversion ; experimental design ; water power
    Language English
    Dates of publication 2022-0201
    Publishing place Elsevier Ltd
    Document type Article
    ZDB-ID 2019804-8
    ISSN 0360-5442 ; 0360-5442
    ISSN (online) 0360-5442
    ISSN 0360-5442
    DOI 10.1016/j.energy.2021.122485
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  4. Article ; Online: EXPERIMENTAL MODELING OF WAVE FORCES AND HYDRODYNAMICS ON ELEVATED COASTAL STRUCTURES SUBJECT TO WAVES, SURGE OR TSUNAMIS: THE EFFECT OF BREAKING, SHIELDING AND DEBRIS.

    Lomonaco, Pedro / Alam, Mohammad Shafiqual / Arduino, Pedro / Barbosa, Andre / Cox, Daniel T / Do, Trung / Eberhard, Marc / Motley, Michael / Shekhar, Krishnendu / Tomiczek, Tori / Park, Hyoungsu / van de Lindt, John W / Winter, Andrew

    Coastal engineering : proceedings of the ... international conference. International Conference on Coastal Engineering

    2023  Volume 1, Issue 36, Page(s) 58–74

    Language English
    Publishing date 2023-12-06
    Publishing country United States
    Document type Journal Article
    ZDB-ID 2628774-2
    ISSN 2156-1028 ; 2156-1028
    ISSN (online) 2156-1028
    ISSN 2156-1028
    DOI 10.9753/icce.v36.waves.53
    Database MEDical Literature Analysis and Retrieval System OnLINE

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  5. Article ; Online: Does vegetation accelerate coastal dune erosion during extreme events?

    Feagin, Rusty A / Innocenti, Rachel A / Bond, Hailey / Wengrove, Meagan / Huff, Thomas P / Lomonaco, Pedro / Tsai, Benjamin / Puleo, Jack / Pontiki, Maria / Figlus, Jens / Chavez, Valeria / Silva, Rodolfo

    Science advances

    2023  Volume 9, Issue 24, Page(s) eadg7135

    Abstract: A broadly accepted paradigm is that vegetation reduces coastal dune erosion. However, we show that during an extreme storm event, vegetation surprisingly accelerates erosion. In 104-m-long beach-dune profile experiments conducted within a flume, we ... ...

    Abstract A broadly accepted paradigm is that vegetation reduces coastal dune erosion. However, we show that during an extreme storm event, vegetation surprisingly accelerates erosion. In 104-m-long beach-dune profile experiments conducted within a flume, we discovered that while vegetation initially creates a physical barrier to wave energy, it also (i) decreases wave run-up, which creates discontinuities in erosion and accretion patterns across the dune slope, (ii) increases water penetration into the sediment bed, which induces its fluidization and destabilization, and (iii) reflects wave energy, accelerating scarp formation. Once a discontinuous scarp forms, the erosion accelerates further. These findings fundamentally alter the current understanding of how natural and vegetated features may provide protection during extreme events.
    Language English
    Publishing date 2023-06-14
    Publishing country United States
    Document type Journal Article
    ZDB-ID 2810933-8
    ISSN 2375-2548 ; 2375-2548
    ISSN (online) 2375-2548
    ISSN 2375-2548
    DOI 10.1126/sciadv.adg7135
    Database MEDical Literature Analysis and Retrieval System OnLINE

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