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Abstract
Mangrove forests possess significant ecological and aesthetic values. Investigating the spatial distribution characteristics of beach sediments in mangrove habitats and their relationships with hydrodynamic conditions and vegetation dynamics is crucial for sustaining the health and sustainability of mangrove ecosystems. This study aims to explore the spatial distribution characteristics of sediments in the mangrove beach of Xiashan Sea-viewing Promenade, Zhanjiang, and their relationship with hydrodynamics and mangrove vegetation. A total of 59 surface sediment samples were collected from 6 transects in the study area. The elevation of the sampling points, as well as wave and current data during the sampling period, were measured. The sediment transport trends of the 6 transects were also analyzed. The results show that the average grain size of surface sediments in the study area ranges from -0.75 to 5.15 φ; the average sorting coefficient is 1.26, indicating poor sediment sorting; the average skewness is 0.19, with positively skewed and extremely positively skewed sediments widely distributed in the study area; the kurtosis values range from 0.36 to 2.31, with an average of 1.14, and narrow kurtosis is observed on the seaward side of the southern and northern parts of the study area. The significant wave height in the study area ranges from 0.05 to 0.17 m, the wave period ranges from 1.44 to 3.38 s, and the current velocity ranges from 1.44 to 7.44 cm·s−1. The surface sediment types include gravel, sand, silt, and clay, with sand being the most abundant, followed by silt, while gravel and clay are present in small amounts, with gravel only found in small quantities near the shore in the northern part of the study area. The sand content decreases from the shore to the sea, while the spatial distribution of silt shows the opposite trend. The clay content is relatively low, with a higher concentration in the seaward area. The wave action in the study area is significantly stronger than the current action, with the strongest hydrodynamic forces occurring during the early flood tide and late ebb tide, leading to an onshore sediment transport trend. This process can increase beach elevation and stability, which is beneficial for the growth and development of mangroves.
Keywords
Sediments
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Transport Trend
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Mangrove Beach
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Hydrodynamics
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Yuehua Qi, Mingming Yuan, Jieping Tang, Gaocong Li, Dezhi Chen, Yali Qi.
Study on the distribution characteristics of sediments on the mangrove beach of the sea-viewing promenade, Zhanjiang.
Anthropocene Coasts, 2025, 8(1): DOI:10.1007/s44218-025-00092-y
| [1] |
BlottJS, PyeK. GRADISTAT: a grain size distribution and statistics package for the analysis of unconsolidated sediments. Earth Surf Proc Land, 2001, 26(11): 1237-1248.
|
| [2] |
ChenB, ChenS, HeC. Grain Size Distribution Features of Surface Sediments from Mangrove Wetland of Leizhou Peninsula. Geoscience, 2019, 33(1): 198-205(in Chinese)
|
| [3] |
ChenJ, ChenJ, WuZ. Analysis of water pollution and ecological protection strategies for Lvtang River. Resources Economization & Environmental Protection, 2021, 11: 12-14(in Chinese)
|
| [4] |
FolkRL, WardWC. Brazos River bar: a study in the significance of grain size parameters. J Sediment Res, 1957, 27(1): 3-26.
|
| [5] |
GaoS, CollinsM. THE USE OF GRAIN SIZE TRENDS IN MARINE SEDIMENT DYNAMICS. Bulletin of National Natural Science Foundation of China, 1998, 4: 11-16(in Chinese)
|
| [6] |
GaoS. Grain Size Trend Analysis: Principle and Applicability. Acta Sedimentol Sin, 2009, 27(5): 826-836(in Chinese)
|
| [7] |
LiZL, XieQ, ZengZ, et al.. Enrichment and Migration of Heavy Metals in Mangrove Soil-Plant System from Sea Promenade in Zhanjiang. Tropical Geography, 2021, 41(2): 398-409(in Chinese)
|
| [8] |
Li ZQ, Xie S, Zhang H, et al (2009) Preliminary study on the impact of mangrove planting on beaches in Zhanjiang Guanhai Promenade. Proceedings of the 14th China Ocean (Coast) Engineering Symposium 1: 757-759. (in Chinese)
|
| [9] |
LibbyM, TomiczekT, CoxD, et al.. The sum of the parts: Green, gray, and green-gray infrastructure to mitigate wave overtopping. Coast Eng, 2024, 194104615.
|
| [10] |
LuoS, XingW, LiangQ, et al.. Speciation, Ecological Risk Assessment and Source Analysis of Heavy Metals in the Surface Sediments of Mangrove Wetland in Zhanjiang Bay. Ecology and Environmental Sciences, 2019, 28(2): 348-358(in Chinese)
|
| [11] |
LuoS, QuanX, ChenB, et al.. Grain Size Characteristics and Sedimentary Dynamics of Sedimentary Column of Mangrove Wetland in Zhanjiang Bay. Geoscience, 2021, 35(3): 647-656(in Chinese)
|
| [12] |
MoY, ChenB, SuW, et al.. The Present Pollution Situation and the Ecological Risk Assessment of Heavy Metal Contamination in the Sediments of Mangrove Swamp in Sea Promenade of Zhanjiang. Journal of Lingnan Normal University, 2016, 37(6): 156-163(in Chinese)
|
| [13] |
Soulsby R, Whitehouse RJS (1997) Threshold of sediment motion in coastal environments. Proc. Pacific Coasts and Ports '97 Conf, Christchurch 1:149–154
|
| [14] |
Tang D, Luo S, Li Y, et al (2022) The spatial-temporal distribution characteristics and pollution assessment of heavy metals in surface sediment of mangrove in Sea Promenade of Zhanjiang. Environmental Pollution & Control, 44(12), 1639–1642+1651. (in Chinese)
|
| [15] |
Tang, D., Li, Q., & Li Q (2023) Research Progress on Source of Heavy Metals in Sediment of Mangrove Wetlands in Zhanjiang City. Journal of Anhui Agricultural Sciences, 51(1), 5–9+12. (in Chinese)
|
| [16] |
WangYS, HeL, WangQ, et al.. Study on the chemical composition and its pharmacology of the medicinal mangrove plant. Chin J Mar Drugs, 2004, 2: 26-31(in Chinese)
|
| [17] |
WangZ, HeQ, YangS, et al.. COMPARISON AND APPLICATION OF SHEPARD'S AND FOLK'S CLASSIFICATIONS TO THE SUBSURFACE MAPPING IN THE SOUTH YELLOW SEA. Mar Geol Q Geol, 2008, 1: 1-8(in Chinese)
|
| [18] |
Wang YH (2012) Coastal Dynamic Geomorphology. Beijing: Science Press. pp. 54–55. (in Chinese)
|
| [19] |
WangR, DaiZ, WuT, et al.. Study on dynamic changes of mangrove spatial distribution inJingujiang River, Guangxi[J]. Advances in Marine Science, 2025, 43(1): 1-14
|
| [20] |
WentworthCK. A Scale of Grade and Class Terms for Clastic Sediments. J Geol, 1922, 30: 377-392.
|
| [21] |
Whitehouse R, Soulsby RL, Roberts W & Mitchener H (2000) Dynamics of Estuarine Muds: A Manual for Practical Applications.Thomas Telford Publications
|
| [22] |
YuQPrinciples of Marine Sediment Dynamics, 2024, Beijing. Science Press. 144145in Chinese
|
| [23] |
YuanJ, JiangZ, DaiY, et al.. REE Characteristics in Surface Sediments of Zhanjiang Bay and their Provenance Indicating Significance. Geoscience, 2022, 36(1): 77-87(in Chinese)
|
| [24] |
ZhangB, ZhangL, ChenB, et al.. Assessment of mangrove health based on pressure–state–response framework in Guangxi Beibu Gulf. China Ecological Indicators, 2024, 167. 112685
|
| [25] |
ZhouZ, YueW, LiH, et al.. Influence of tree species and intertidal elevations on the carbon storage of the Gaoqiao mangrove area in Zhanjiang. Guangdong Province Journal of Tropical Oceanography, 2024, 43(2): 108-120(in Chinese)
|
| [26] |
Zhu H (2024) Mangrove restoration: Afforestation on tidal flats or returning ponds to forests? China Science Daily, p. 1. (in Chinese)
|
Funding
Guangdong Basic and Applied Basic Research Foundation(2022A1515240023)
Scientific Research Start-up Fund of Guangdong Ocean University(060302112104)
Key Laboratory of Tropical Marine Ecosystems and Biological Resources, Ministry of Natural Resources(2021QN02)
Guangxi Zhuang Autonomous Region Youth Fund Project(2022GXNSFBA035566)
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