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Editorial

Shoreline Dynamics and Beach Erosion

by
Gianluigi Di Paola
1,*,
Germán Rodríguez
2 and
Carmen M. Rosskopf
1
1
Department of Biosciences and Territory, University of Molise, I-86090 Pesche, Italy
2
Departamento de Física, Institute of Environmental Studies and Natural Resources (iUNAT), Universidad de Las Palmas de Gran Canaria, E-35001 Las Palmas de Gran Canaria, Spain
*
Author to whom correspondence should be addressed.
Geosciences 2023, 13(3), 74; https://doi.org/10.3390/geosciences13030074
Submission received: 19 January 2023 / Accepted: 15 February 2023 / Published: 7 March 2023
(This article belongs to the Special Issue Shoreline Dynamics and Beach Erosion)
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Abstract

:
Coasts are highly dynamic and geomorphologic complex systems that evolve under the increasing pressure of climate change and anthropogenic activities, having direct or indirect impacts on the coastal environment. Among the major adverse effects, coastal erosion represents one of the most pressing global issues, especially in flat and low-lying coastal areas that appear to be particularly susceptible to beach erosion and related shoreline retreat. This Special Issue collects a set of twelve papers on “Shoreline Dynamics and Beach Erosion”. Of course, this collection of papers does not cover all the broad number of topics concerning the dynamics and spatial-temporal evolution of shorelines and beach systems, but, in our opinion, they contribute to the growing body of knowledge. Coastal systems of variable complexity located in different geographic and climatic contexts are investigated from various points of view by using multi- and interdisciplinary approaches, as well as new experimental ones. The major topics covered concern the morphodynamics and hydrodynamics of coastal systems, the driving factors of coastal erosion, and the use of models/indexes to study coastal vulnerability and the mitigation of human/natural pressures affecting coastal ecosystems.

1. Editorial for the Special Issue Shoreline Dynamics and Beach Erosion

The coastal zone is a unique physical space including the transition between the land and sea, whose surface area totals approximately 5% of the earth’s surface [1]. However, this percentage and the related features change based on the definitions used and the related spatial boundaries attributed to them, which can vary depending on the way they are studied, exploited, and/or managed (e.g., [2]).
Although the coastal zone represents only a narrow strip of the Earth’s surface, there is no doubt about its great socio-economic and ecological importance, as it provides a wide range of services of fundamental importance to human well-being, health, and subsistence [3,4,5]. The high socio-economic and strategic value of coastal areas explain why around two-thirds of the world’s population live within 100 km from the coastline [6] and about 17% in low-elevation coastal zones, i.e., in low-lying areas that are less than 10 m above sea level [7,8]. In particular, sandy coasts are largely preferred as places for living and leisure activities, thus playing a fundamental role in the lucrative and growing tourism market, providing easy access to the sea [9,10].
From a dynamic perspective, the coastal zone represents one of the most energetic environments on Earth. Although the physical processes governing coastal dynamics show moderate and reasonably predictable behaviors most of the time, forcing processes can undergo unexpected abrupt and rapid changes leading to extreme and dangerous events. In particular, coastal storms, during which the wave energy reaches values significantly higher than those observed under average conditions, are among the most damaging natural events, primarily due to the high number of victims, but also to huge monetary losses (e.g., [11]).
The occurrence of storm events is particularly important along open, low-lying coastlines where beach erosion is one of the most common impacts, often causing the loss of land of high socio-economic and natural value (e.g., [10,12,13,14] and references therein). To succeed in planning and developing resilient and sustainable coastal built environments [15], it is crucial that coastal planners, engineers, and decision makers are aware of the fact that coastal areas are highly dynamic and hazard-prone zones.
In the light of the above, the progressive expansion of our knowledge on coastal morphodynamics and shoreline evolution and the modelling of shoreline changes and beach erosion in response to natural and anthropogenic stressors are of enormous relevance. Progress in this direction requires advances in various branches of science and technology, including techniques used for data acquisition, processing, and analysis, as well as the development of efficient numerical procedures for the computational implementation of theoretical models based on detailed studies and monitoring the activities of investigated coastal systems.

2. Special Issue

This Special Issue collects a set of twelve contributions authored by forty researchers on the topic of “Shoreline Dynamics and Beach Erosion”. Of course, this collection of papers does not cover the entire range of subjects concerning the dynamics and spatial-temporal evolution of shorelines and beach systems, but, in our opinion, it contributes to the growing body of knowledge. In particular, these papers address the study of coastal systems of variable complexity located in different geographic areas (Figure 1) and climatic contexts from various points of view by using multi- and interdisciplinary approaches and providing new experimental data and methodologies.
We hope that the papers of this issue serve to foster additional research, stimulate scientific discussion, and promote reflections on how to achieve a better understanding of the coastal systems morphodynamics, or even present research opportunities in this field, contributing, in the end, to the safeguarding of coastal zones and beaches. From an operational point of view, we expect that their results may contribute to the development of pragmatic approaches through which the competent institutions and administrations can implement intervention strategies to eliminate, reduce, and/or compensate coastal erosion, as well as support the resilience and sustainable development of coastal areas.
The contributions included in this issue refer to different continents, from the Americas to Africa, Europe, and South East Asia (Figure 1). The review paper written by Pranzini and William [16], which deals with theoretical concepts and, therefore, does not refer to a specific geographic area, represents the only exception.
The papers have been categorized into three groups according to the major research topics addressed, as presented in Table 1.
A first group of papers (Group 1, Table 1) focuses on the morphodynamics and hydrodynamics of coastal systems. In detail, the papers written by Andreeva et al. [17] and Uda and Noshi [18] highlight that coastal morphodynamics assessed by analyzing the formation, location, and movement of coastal bars and sand spits strongly depends on the wave climate that controls the erosion and movement of sediments along the coast. Seul et al. [19], based on the petrographic analysis and characterization of beach sediments, have created an index that aids in understanding both the nature and origin of sediments, as well as the characteristics of wave climate responsible for their transport. The paper by Buccino et al. [20] illustrates how numerical modelling can be used for investigating the relationships between incident wave characteristics and beach shape. Finally, the review paper by Pranzini and William [16], which uses examples from the literature to analyze some of the major processes responsible for the evolution of a beach, highlights that the use of the term “beach equilibrium” is not entirely appropriate, since the sedimentary budget depends on numerous non-feedback-regulated factors.
A second consistent group of papers (Group 2, Table 1) analyzes some of the major driving factors of coastal erosion in different geographical and geomorphological contexts. In detail, these papers deal with the effects of subsidence [21], storm surges [22], and hurricanes [23] on the studied coastal systems, which adapt to new morphological conditions in different times. Furthermore, the paper by Guerra-Medina and Rodríguez [24] highlights how such control factors can decisively influence the economic and social decisions of a community and, especially, tourism activities.
Finally, the third group of papers (Group 3, Table 1) focuses on the development and application of models/indexes suitable for coastal erosion vulnerability assessments for developing mitigation strategies for coastal ecosystem in relation to human and natural pressures. In detail, the papers by Di Crescenzo et al. [25] and Di Paola et al. [26] illustrate the identification and application of indexes that allowed them to assess the susceptibility of the coastline to undergo erosion, respectively, in high rocky coast and sandy beach contexts. The paper by Chacón Abarca et al. [27] deals with the evaluation of a model to help the community reducing the negative effects on ecosystems caused by physical and human changes in lagoon coastal environments. It illustrates a developed tool that considers the inter-relationships between natural systems and the factors inducing alterations in the coastal lagoon environment, providing insights into human actions that can reduce these negative consequences on ecosystems.

Funding

This research received no external funding.

Data Availability Statement

No new data were created or analyzed in this study. Data sharing is not applicable to this article.

Acknowledgments

We thank our informants and supporting staff for their contribution to the Special Issue.

Conflicts of Interest

The authors declare no conflict of interest.

References

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  22. Oakley, B.A. Storm Driven Migration of the Napatree Barrier, Rhode Island, USA. Geosciences 2021, 11, 330. [Google Scholar] [CrossRef]
  23. Kelly, E.W.; Jose, F. Geomorphologic Recovery of North Captiva Island from the Landfall of Hurricane Charley in 2004. Geosciences 2021, 11, 358. [Google Scholar] [CrossRef]
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  26. Di Paola, G.; Minervino Amodio, A.; Dilauro, G.; Rodriguez, G.; Rosskopf, C.M. Shoreline Evolution and Erosion Vulnerability Assessment along the Central Adriatic Coast with the Contribution of UAV Beach Monitoring. Geosciences 2022, 12, 353. [Google Scholar] [CrossRef]
  27. Chacón Abarca, S.; Chávez, V.; Silva, R.; Martínez, M.L.; Anfuso, G. Understanding the Dynamics of a Coastal Lagoon: Drivers, Exchanges, State of the Environment, Consequences and Responses. Geosciences 2021, 11, 301. [Google Scholar] [CrossRef]
Geosciences 13 00074 g001 550
Figure 1. Geographical distribution of the contributions included in the Special Issue.
Figure 1. Geographical distribution of the contributions included in the Special Issue.
Geosciences 13 00074 g001
Table
Table 1. Grouping of contributions according to major research topics covered.
Table 1. Grouping of contributions according to major research topics covered.
Main TopicsPapers
Group 1Morphodynamics and hydrodynamics of coastal systemsPranzini and William (2021) [16]
Andreeva et al. (2021) [17]
Uda and Noshi (2021) [18]
Seul et al. (2020) [19]
Buccino et al. (2021) [20]
Group 2Driving factors of coastal erosion in different geomorphological contextsGomez et al. (2021) [21]
Oakley (2021) [22]
Kelly and Jose (2021) [23]
Guerra-Medina and Rodríguez (2021) [24]
Group 3Models/indexes for the assessment of vulnerability and risk aspects of coastal systems, and the mitigation of human/natural pressures on coastal ecosystemsDi Crescenzo et al. (2021) [25]
Di Paola et al. (2022) [26]
Chacón Abarca et al. (2021) [27]
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Di Paola, G.; Rodríguez, G.; Rosskopf, C.M. Shoreline Dynamics and Beach Erosion. Geosciences 2023, 13, 74. https://doi.org/10.3390/geosciences13030074

AMA Style

Di Paola G, Rodríguez G, Rosskopf CM. Shoreline Dynamics and Beach Erosion. Geosciences. 2023; 13(3):74. https://doi.org/10.3390/geosciences13030074

Chicago/Turabian Style

Di Paola, Gianluigi, Germán Rodríguez, and Carmen M. Rosskopf. 2023. "Shoreline Dynamics and Beach Erosion" Geosciences 13, no. 3: 74. https://doi.org/10.3390/geosciences13030074

APA Style

Di Paola, G., Rodríguez, G., & Rosskopf, C. M. (2023). Shoreline Dynamics and Beach Erosion. Geosciences, 13(3), 74. https://doi.org/10.3390/geosciences13030074

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