西沙群岛宣德环礁波浪分布特征*

doi:10.11978/2024240

摘要/Abstract

摘要：

文章采用近海波浪数值模式(simulation wave nearshore, SWAN), 在西沙岛礁区域进行网格加密, 部分区域采用实测地形数据, 以1999—2023年第五代欧洲中期天气预报中心大气再分析资料(the fifth generation ECMWF atmospheric reanalysis of the global climate, ERA5)作为驱动, 对岛礁区域进行了波浪模拟。利用位于西沙群岛和中沙群岛的实测资料验证模型性能, 统计量显示模型在有效波高模拟上性能良好。对25a (1999—2023年)的模型结果分析表明, 空间维度上, 宣德环礁波浪呈现东北强、西南弱分布, 整体由东北向西南传播, 经礁盘阻挡, 西南部有显著的波影区; 时间维度上, 12月波浪强度最强, 5月最弱, 12月至次年5月逐渐减弱, 5月至12月逐渐增强。从量化来看, 平均有效波高在环礁大部分区域有轻微减小趋势(0~0.2cm·a^-1), 礁盘部分区域轻微增大(0~0.2cm·a^-1); 99百分位有效波高大部分区域增大(0~0.7cm·a^-1), 小部分礁盘区域减小(0~0.4cm·a^-1), 表明台风等极端天气对宣德环礁的影响呈增大趋势。逐月分析, 宣德环礁平均有效波高上升、下降趋势的月份均为6个月, 10月上升幅度最大(≤0.8cm·a^-1), 11月下降幅度最大(≤1.7cm·a^-1); 90百分位有效波高在东北季风和西南季风转换的最后一个月(2月和8月)轻微下降; 99百分位有效波高与平均有效波高相比, 8月和9月变化趋势相反, 即8月台风等恶劣天气影响逐年下降, 9月逐年上升。曼-肯德尔检验(Mann-Kendall test)表明部分区域趋势显著性水平较高, 结论具备一定可信度。

关键词: 近海波浪数值模式, 岛礁, 波浪, 波候, 宣德环礁

Abstract:

This study aims to develop a mathematical model capable of accurately simulating waves in the island and reef areas, with the objective of investigating the wave climate and its changing trends in the Xuande Atoll. The third-generation numerical wave model SWAN (simulating waves nearshore) was employed. Grid refinement was carried out to the Xisha islands and reef areas, incorporating measured terrain data in some regions. The ERA5 reanalysis wind-field data (the fifth generation ECMWF atmospheric reanalysis of the global climate) from 1999 to 2023 was utilized as the driving force for wave simulations. Model performance was validated using measured data from the Xisha and Zhongsha Islands, with statistical metrics indicating its accuracy in simulating significant wave height. Analysis of the 25-year model results revealed distinct spatial and temporal patterns. Spatially, waves in the Xuande Atoll exhibited stronger intensities in the northeast and weaker intensities in the southwest, propagating generally from the northeast to the southwest. Due to the obstruction of the reef flat, a prominent wave-shadow zone was formed in the southwest. Temporally, wave intensity was the highest in December and the lowest in May, showing a gradual decrease from December to May and a subsequent increase from May to December. Quantitatively, the average significant wave height showed a slight decreasing trend (0 ~ 0.2 cm·a^-1) in most of the atoll, while it increased slightly (0 ~ 0.2 cm·a^-1) in some parts of the reef flat. The 99th percentile significant wave height increased in most areas (0 ~ 0.7 cm·a^-1) but decreased slightly in some reef flat areas (0 ~ 0.4 cm·a^-1), indicating a rising impact of extreme weather events like typhoons on the atoll. Monthly analysis showed that the average significant wave height exhibited an upward trend in six months and a downward trend in the other six. The maximum upward trend occurred in October (≤ 0.8 cm·a^-1), while the maximum downward trend was observed in November (≤1.7 cm·a^-1). The 90th percentile significant wave height decreased slightly in February and August, coinciding with the transition between the northeast monsoon and the southwest monsoon. Compared with the average significant wave height, the 99th percentile showed opposite trends in August and September, reflecting year-by-year variations in typhoon impacts. The Mann-Kendall (MK) test indicated relatively high significance levels for trends in some regions. The conclusions have a certain degree of reliability and hold great reference value for the future development and construction of island and reef areas, such as the Xuande Atoll.

Key words: simulation wave nearshore, islands and reefs, waves, wave climate, Xuande atoll

中图分类号:

P731.22

邱立国, 梁小力, 陈斌, 王盛健, 王发云. 西沙群岛宣德环礁波浪分布特征^*[J]. 热带海洋学报, 2025, 44(5): 50-64.

QIU Liguo, LIANG Xiaoli, CHEN Bin, WANG Shengjian, WANG Fayun. Wave distribution characteristics of Xuande Atoll, Xisha Islands^*[J]. Journal of Tropical Oceanography, 2025, 44(5): 50-64.

图/表 21

图1

图2

表1

图3

图4

图5

表2

图6

图7

图8

图9

图10

图11

表3

图12

图13

图14

图15

图16

图17

图18

参考文献 21

[1]	白珍胜, 宗智, 孙泽, 等, 2020. 基于WAVEWATCH Ⅲ的近岛礁波浪演化研究[J]. 船舶力学, 24(10): 1261-1269.
	BAI ZHENSHENG, ZONG ZHI, SUN ZE, et al, 2020. Study of wave evolution near islands and reefs based on WAVEWATCH Ⅲ[J]. Journal of Ship Mechanics, 24(10): 1261-1269 (in Chinese with English abstract).
[2]	董进, 2019. 南海近岛礁波浪演化数值模拟研究[D]. 大连: 大连理工大学.
	DONG JIN, 2019. Numerical research of wave evolution near reefs in the South China Sea[D]. Dalian: Dalian University of Technology (in Chinese with English abstract).
[3]	何其江, 刘刚, 王雪木, 等, 2021. 西沙群岛宣德环礁的精细水下地貌组合特征及其成因机制[J]. 海洋学报, 43(8): 81-92.
	HE QIJIANG, LIU GANG, WANG XUEMU, et al, 2021. Submarine geomorphologic features and genetic mechanism in the Xuande atoll, Xisha Islands[J]. Haiyang Xuebao, 43(8): 81-92 (in Chinese with English abstract).
[4]	AYDOGAN B, AYAT B, 2018. Spatial variability of long-term trends of significant wave heights in the Black Sea[J]. Applied Ocean Research, 79: 20-35.
[5]	BOOIJ N, RIS R C, HOLTHUIJSEN L H, 1999. A third-generation wave model for coastal regions 1. Model description and validation[J]. Journal of Geophysical Research Atmospheres, 104(4): 7649-7666.
[6]	CHAWLA A, TOLMAN H L, 2008. Obstruction grids for spectral wave models[J]. Ocean Modelling, 22(1/2): 12-25.
[7]	CHRISTOPOULOS S, 1997. Wind-wave modelling aspects within complicate topography[J]. Annales Geophysicae, 15(10): 1340-1353.
[8]	GONCALVES M, MARTINHO P, GUEDES SOARES C, 2014. Assessment of wave energy in the canary islands[J]. Renewable Energy, 68: 774-784.
[9]	GROUP T W, 1988. The WAM model: a third generation ocean wave prediction model[J]. Journal of Physical Oceanography, 18(12): 1775-1810.
[10]	HERSBACH H, BELL B, BERRISFORD P, et al, 2018. ERA5 hourly data on single levels from 1940 to present. Copernicus Climate Change Service (C3S) Climate Data Store (CDS)[EB/OL]. doi: 10.24381/cds.adbb2d47. https://cds.climate.copernicus.eu/cdsapp#!/dataset/reanalysis-era5-single-levels 2024-10-16].
[11]	KENDALL M G, 1975. Rank Correlation Methods[M]. Oxford: Griffin.
[12]	MANN H B, 1945. Nonparametric tests against trend[J]. Econometrica, 13(3): 245.
[13]	PONCE DE LEON S, SOARES, 2005. On the sheltering effect of islands in ocean wave models[J]. Journal of Geophysical Research: Oceans, 110(C9): 110.
[14]	RUSU E, PILAR P, GUEDES SOARES C, 2008a. Evaluation of the wave conditions in Madeira Archipelago with spectral models[J]. Ocean Engineering, 35(13): 1357-1371.
[15]	RUSU L, PILAR P, GUEDES SOARES C, 2008b. Hindcast of the wave conditions along the west Iberian coast[J]. Coastal Engineering, 55(11): 906-919.
[16]	SAKET A, ETEMAD-SHAHIDI A, 2012. Wave energy potential along the northern coasts of the Gulf of Oman, Iran[J]. Renewable Energy, 40(1): 90-97.
[17]	SUN ZE, ZHANG HAICHENG, LIU XIAOLONG, et al, 2021. Wave energy assessment of the Xisha Group Islands zone for the period 2010-2019[J]. Energy, 220: 119721.
[18]	TOLMAN H L, 1989. The numerical model Wavewatch: A third generation model for hindcasting of wind waves on tides in shelf seas[J]. Communication on Hydraulic and Geo Technical Engineering, 2: 89.
[19]	TOLMAN H L, 1991. A third-generation model for wind waves on slowly varying, unsteady, and inhomogeneous depths and currents[J]. Journal of Physical Oceanography, 21(6): 782-797.
[20]	VIEIRA F, CAVALCANTE G, CAMPOS E, 2020. Analysis of wave climate and trends in a semi-enclosed basin (Persian Gulf) using a validated SWAN model[J]. Ocean Engineering, 196: 106821.
[21]	YOUNG I R, ZIEGER S, BABANIN A V, 2011. Global trends in wind speed and wave height[J]. Science, 332(6028): 451-455. doi: 10.1126/science.1197219 pmid: 21436400

站位	观测仪器	观测时间	采样频率	样本量	观测单位
七连屿站	ADCP	2017/07─2017/11	2h	1371	海南省海洋与渔业科学院
甘泉岛站	浪龙仪	2018/01─2018/04	1h	2603	中国船舶科学研究中心
晋卿岛站	浪龙仪	2014/06─2018/06	0.5h	32487	中国船舶科学研究中心
华夏暗沙站	ADCP	2018/06─2018/11	2h	1506	海南省海洋与渔业科学院

统计要素	站位	PCC	RMSE/m	bias/m	SI	斜率	n
有效波高	晋卿岛站	0.876	0.144	0.093	0.427	0.877	32487
	甘泉岛站	0.917	0.327	0.268	0.560	1.251	2603
	七连屿站	0.858	0.325	0.235	0.724	0.957	1371
	华夏暗沙站	0.909	0.382	-0.195	0.246	0.908	1506

特征点位置	平均	90百分位	99百分位
北	-0.05	-0.07	+0.41
中	-0.09	+0.01	+0.48
南	-0.10	+0.06	+0.13