Your search keyword '"van Hespen A"' showing total 4 results

1. Integrating mangrove growth and failure in coastal flood protection designs

Author

A. Gijón Mancheño, V. Vuik, B. K. van Wesenbeeck, S. N. Jonkman, R. van Hespen, J. R. Moll, S. Kazi, I. Urrutia, and M. van Ledden

Subjects

Medicine, Science

Abstract

Abstract Mangrove forests reduce wave attack along tropical and sub-tropical coastlines, decreasing the wave loads acting on coastal protection structures. Mangrove belts seaward of embankments can therefore lower their required height and decrease their slope protection thickness. Wave reduction by mangroves depends on tree frontal surface area and stability against storms, but both aspects are often oversimplified or neglected in coastal protection designs. Here we present a framework to evaluate how mangrove belts influence embankment designs, including mangrove growth over time and failure by overturning and trunk breakage. This methodology is applied to Sonneratia apetala mangroves seaward of embankments in Bangladesh, considering forest widths between 10 and 1000 m (cross-shore). For water depths of 5 m, wave reduction by mangrove forests narrower than 1 km mostly affects the slope protection and the bank erodibility, whereas the required embankment height is less influenced by mangroves. Sonneratia apetala trees experience a relative maximum in wave attenuation capacity at 10 years age, due to their large submerged canopy area. Once trees are more than 20 years old, their canopy is emergent, and most wave attenuation is caused by trunk and roots. Canopy emergence exposes mangroves to wind loads, which are much larger than wave loads, and can cause tree failure during cyclones. These results stress the importance of including tree surface area and stability models when predicting coastal protection by mangroves.

Published

2024

2. Integrating mangrove growth and failure in coastal flood protection designs

Author

Gijón Mancheño, A. (author), Vuik, V. (author), van Wesenbeeck, B (author), Jonkman, Sebastiaan N. (author), van Hespen, R. (author), Moll, J.R. (author), Kazi, S. (author), Urrutia, I. (author), van Ledden, M. (author), Gijón Mancheño, A. (author), Vuik, V. (author), van Wesenbeeck, B (author), Jonkman, Sebastiaan N. (author), van Hespen, R. (author), Moll, J.R. (author), Kazi, S. (author), Urrutia, I. (author), and van Ledden, M. (author)

Abstract

Mangrove forests reduce wave attack along tropical and sub-tropical coastlines, decreasing the wave loads acting on coastal protection structures. Mangrove belts seaward of embankments can therefore lower their required height and decrease their slope protection thickness. Wave reduction by mangroves depends on tree frontal surface area and stability against storms, but both aspects are often oversimplified or neglected in coastal protection designs. Here we present a framework to evaluate how mangrove belts influence embankment designs, including mangrove growth over time and failure by overturning and trunk breakage. This methodology is applied to Sonneratia apetala mangroves seaward of embankments in Bangladesh, considering forest widths between 10 and 1000 m (cross-shore). For water depths of 5 m, wave reduction by mangrove forests narrower than 1 km mostly affects the slope protection and the bank erodibility, whereas the required embankment height is less influenced by mangroves. Sonneratia apetala trees experience a relative maximum in wave attenuation capacity at 10 years age, due to their large submerged canopy area. Once trees are more than 20 years old, their canopy is emergent, and most wave attenuation is caused by trunk and roots. Canopy emergence exposes mangroves to wind loads, which are much larger than wave loads, and can cause tree failure during cyclones. These results stress the importance of including tree surface area and stability models when predicting coastal protection by mangroves., Hydraulic Structures and Flood Risk

Published

2024

3. Integrating mangrove growth and failure in coastal flood protection designs.

Author

Gijón Mancheño, A., Vuik, V., van Wesenbeeck, B. K., Jonkman, S. N., van Hespen, R., Moll, J. R., Kazi, S., Urrutia, I., and van Ledden, M.

Subjects

MANGROVE plants, EMBANKMENTS, FLOOD control, DESIGN protection, SHORE protection, MANGROVE forests, WIND pressure, SURFACE stability

Abstract

Mangrove forests reduce wave attack along tropical and sub-tropical coastlines, decreasing the wave loads acting on coastal protection structures. Mangrove belts seaward of embankments can therefore lower their required height and decrease their slope protection thickness. Wave reduction by mangroves depends on tree frontal surface area and stability against storms, but both aspects are often oversimplified or neglected in coastal protection designs. Here we present a framework to evaluate how mangrove belts influence embankment designs, including mangrove growth over time and failure by overturning and trunk breakage. This methodology is applied to Sonneratia apetala mangroves seaward of embankments in Bangladesh, considering forest widths between 10 and 1000 m (cross-shore). For water depths of 5 m, wave reduction by mangrove forests narrower than 1 km mostly affects the slope protection and the bank erodibility, whereas the required embankment height is less influenced by mangroves. Sonneratia apetala trees experience a relative maximum in wave attenuation capacity at 10 years age, due to their large submerged canopy area. Once trees are more than 20 years old, their canopy is emergent, and most wave attenuation is caused by trunk and roots. Canopy emergence exposes mangroves to wind loads, which are much larger than wave loads, and can cause tree failure during cyclones. These results stress the importance of including tree surface area and stability models when predicting coastal protection by mangroves. [ABSTRACT FROM AUTHOR]

Published

2024

4. An anthropomorphic thyroid phantom for ultrasound‐guided radiofrequency ablation of nodules.

Author

Boers, Tim, Brink, Wyger, Bianchi, Leonardo, Saccomandi, Paola, van Hespen, Johan, Wennemars, Germen, Braak, Sicco, Versluis, Michel, and Manohar, Srirang

Subjects

CATHETER ablation, HIGH-intensity focused ultrasound, FIBER Bragg gratings, NEEDLE biopsy, MAGNETIC resonance imaging, THYROID gland, ATRIAL flutter

Abstract

Background: Needle‐based procedures, such as fine needle aspiration and thermal ablation, are often applied for thyroid nodule diagnosis and therapeutic purposes, respectively. With blood vessels and nerves nearby, these procedures can pose risks in damaging surrounding critical structures. Purpose: The development and validation of innovative strategies to manage these risks require a test object with well‐characterized physical properties. For this work, we focus on the application of ultrasound‐guided thermal radiofrequency ablation. Methods: We have developed a single‐use anthropomorphic phantom mimicking the thyroid and surrounding anatomical and physiological structures that are relevant to ultrasound‐guided thermal ablation. The phantom was composed of a mixture of polyacrylamide, water, and egg white extract and was cast using molds in multiple steps. The thermal, acoustical, and electrical characteristics were experimentally validated. The ablation zones were analyzed via non‐destructive T2‐weighted magnetic resonance imaging scans utilizing the relaxometry changes of coagulated egg albumen, and the temperature distribution was monitored using an array of fiber Bragg grating sensors. Results: The physical properties of the phantom were verified both on ultrasound as well as in terms of the phantom response to thermal ablation. The final temperature achieved (92°C), the median percentage of the nodule ablated (82.1%), the median volume ablated outside the nodule (0.8 mL), and the median number of critical structures affected (0) were quantified. Conclusion: An anthropomorphic phantom that can provide a realistic model for development and training in ultrasound‐guided needle‐based thermal interventions for thyroid nodules has been presented. [ABSTRACT FROM AUTHOR]

Published

2024