Mixed forests protect coastal areas from tsunami impacts better than monoculture forests

The upper panel depicts the coastal forest pre-tsunami, while the lower panel illustrates the forest post-tsunami. Each column represents the percentage decrease in coastal tree cover resulting from the tsunami event (1: no change, 5: 41-50%, 10: 91-100%). In cases where there was a 91-100% decrease in tree cover, indicated by the inset with the black frame in the bottom right image, nearly all trees were toppled by the tsunami. It is important to note that we magnified the satellite images/aerial photographs to assess the percentage decrease in coastal forest cover attributable to the tsunami event.
Credit: Yokohama National University

Coastal forests in Japan had predominantly been afforested with black pine (Pinus thunbergii), a shade-tolerant tree species that can withstand dry land ecosystems and harsh coastal environments. This afforestation initiative, dating back to the Edo period (1603~1867), aimed to mitigate the deleterious effects of robust winds and sand blowing. Subsequent to the Great East Japan Earthquake in 2011, interest shifted to the potential protective effects of coastal forests in reducing the destructive power of tsunamis.

The Great East Japan Earthquake tsunami damaged a total of 2,800 hectares (ha; 10,000 square meters) of coastal forest. While the damage was immense, the devastation provided an opportunity to study which coastal forests withstood the tsunami impact and why some forests fared better than others. The forests can only mitigate tsunami effects if trees remain intact during the tsunami. Recently, scientists from Yokohama National University discovered that coastal forests that contained mixed tree species bore the tsunami forces better and with less damage than monoculture forests made up exclusively of black pine.

The research team published their findings in the 16 October issue of Natural Hazards.

“Prior studies have established that coastal forests decrease the hydrodynamic forces exerted by tsunami on structures and alter inland debris dispersion based on the density and size structure of trees. However, limited attention has been devoted to exploring the role of species diversity in coastal forests. We revealed that mixed coastal forests with black pine exhibited a diminished vulnerability to tsunami impacts when contrasted with monoculture forests,” said Yuki Iwachido, first author of the study paper and assistant professor at Yokohama National University.

The research team determined the effects of species diversity in coastal forests by analyzing satellite images and aerial photographs of coastal forests before and after the Great East Japan Earthquake tsunami on 11 March 2011. The degree of damage between forests that contained only black pine trees was compared to the damage experienced in mixed species forests made up of black pine and other broad-leaved trees.

The researchers hypothesize that mixed forests are less susceptible to tsunami damage because the root morphologies of different tree species utilize more soil space and resources than a single species of tree. In theory, this could enhance aboveground tree growth and overall stability of the mixed species forests. One limitation of the research was that the scientists couldn’t compare their results to a monoculture of broad-leaved trees and therefore could not remove the impact of coniferous trees.

The study also found a benefit in complex tree planting arrangements compared to simple arrangements. Analysis of the visual impact of the Great East Japan Earthquake tsunami suggests that forests with complex spatial structures were more able to withstand tsunami forces.

The research team acknowledges that more studies are required to better understand the capacity of coastal forest tsunami protection and how to maximize its safeguarding effect. “This study primarily focused on analyzing only damage patterns to coastal forests caused by tsunami impacts utilizing satellite images. There is a pressing need to elucidate the mechanisms by which mixed coastal forests alleviate the impacts of tsunamis,” said Takehiro Sasaki, senior author of the study paper and the professor at Yokohama National University.

Minori Kaneko from the Graduate School of Environment and Information Sciences at Yokohama National University in Yokohama, Japan also contributed to the research study.

This work was financially supported by a Fostering Joint International Research A grant (no. 19KK0393) from the Ministry of Education, Culture, Sports, Science, and Technology of Japan.

Yokohama National University (YNU or Yokokoku) is a Japanese national university founded in 1949. YNU provides students with a practical education utilizing the wide expertise of its faculty and facilitates engagement with the global community. YNU’s strength in the academic research of practical application sciences leads to high-impact publications and contributes to international scientific research and the global society. For more information, please see: https://www.ynu.ac.jp/english/

Journal: Natural Hazards
DOI: 10.1007/s11069-023-06248-8
Article Title: Mixed coastal forests are less vulnerable to tsunami impacts than monoculture forests
Article Publication Date: 16-Oct-2023

Media Contact

Akiko Tsumura
Yokohama National University
kenkyu-koho@ynu.ac.jp
Office: 81-453-393-213

www.ynu.ac.jp

Media Contact

Akiko Tsumura
Yokohama National University

All latest news from the category: Ecology, The Environment and Conservation

This complex theme deals primarily with interactions between organisms and the environmental factors that impact them, but to a greater extent between individual inanimate environmental factors.

innovations-report offers informative reports and articles on topics such as climate protection, landscape conservation, ecological systems, wildlife and nature parks and ecosystem efficiency and balance.

Back to home

Comments (0)

Write a comment

Newest articles

Largest magnetic anisotropy of a molecule measured at BESSY II

At the Berlin synchrotron radiation source BESSY II, the largest magnetic anisotropy of a single molecule ever measured experimentally has been determined. The larger this anisotropy is, the better a…

Breaking boundaries: Researchers isolate quantum coherence in classical light systems

LSU quantum researchers uncover hidden quantum behaviors within classical light, which could make quantum technologies robust. Understanding the boundary between classical and quantum physics has long been a central question…

MRI-first strategy for prostate cancer detection proves to be safe

Active monitoring is a sufficiently safe option when prostate MRI findings are negative. There are several strategies for the early detection of prostate cancer. The first step is often a…