珠江河口潮汐不对称研究

刘金贵; 李硕; 李谊纯; 张佳薇; 仉天宇; 李高琛

doi:10.12284/hyxb2025079

珠江河口潮汐不对称研究

doi: 10.12284/hyxb2025079

刘金贵^{1, 2, 3, 4, 5,},
李硕¹,
李谊纯¹,
张佳薇¹,
仉天宇^{1, 2, 3, 4, 5, ,},
李高琛¹

1.
广东海洋大学广东省近海海洋变化与灾害预警实验室，广东湛江 524088
2.
南方海洋科学与工程广东省实验室（珠海），广东珠海 519000
3.
广东省粤西热带海洋生态环境野外科学观测研究站，广东湛江 524088
4.
自然资源部空间海洋遥感与应用重点实验室，北京 100081
5.
广东海洋大学，广东省高等学校陆架及深远海气候、资源与环境重点实验室，广东湛江 524088

基金项目: 广东海洋大学科研启动经费项目（060302032202）；南方海洋科学与工程广东省实验室（珠海）自主项目（SML2024SP023）。

详细信息

作者简介:
刘金贵（1981—），男，甘肃省泾川县人，副教授，主要从事河口海岸水动力学、泥沙输运及近海生态动力学研究。E-mail：jinguiliu1981@hotmail.com

通讯作者:
仉天宇，教授，主要从事海洋环境预警预报和海洋防灾减灾研究。E-mail: zhangty@gdou.edu.cn

中图分类号: P721.22
计量
- 文章访问数: 10
- HTML全文浏览量: 4
- PDF下载量: 1
- 被引次数: 0
出版历程
- 收稿日期: 2025-03-24
- 修回日期: 2025-07-01
- 刊出日期: 2025-08-31

A study on tidal asymmetry in the Zhujiang River Estuary

Liu Jingui^{1, 2, 3, 4, 5
,},
Li Shuo¹,
Li Yichun¹,
Zhang Jiawei¹,
Zhang Tianyu^{1, 2, 3, 4, 5
, ,},
Li Gaochen¹

1.
Guangdong key laboratory for Coastal Ocean Variation and Disaster Prediction, Guangdong Ocean University, Zhanjiang 524088, China
2.
Southern Marine Science and Engineering Guangdong Laboratory (Zhuhai), Zhuhai 519000, China
3.
Guangdong Provincial Observation and Research Station for Tropical Ocean Environment in Western Coastal Waters, Zhanjiang 524088, China
4.
Key Laboratory of Climate, Resources and Environment in Continental Shelf Sea and Deep Sea of Department of Education of Guangdong Province, Zhanjiang 524088, China
5.
Key Laboratory of Space Ocean Remote Sensing and Application, Ministry of Natural Resources, Beijing 100081, China

摘要

摘要: 珠江口是典型的亚热带大型河口，全日潮与半日潮相互作用显著，在全球气候变化和高强度人类活动叠加影响下，潮汐系统呈现显著变异特征。本研究针对全日潮（K₁、O₁）和半日潮（M₂、S₂）的非线性耦合机制，构建融合分潮振幅比、相对相位解析法与偏度理论的综合评估方法，系统揭示珠江河口正压潮变形的时空特征及其驱动机制。结果表明：潮汐不对称呈现湾口（落潮主导）向湾顶（涨潮主导）的转变特征，其主控机制由外海段的天文分潮组合（O₁/K₁/M₂）主导逐步过渡为上游段的半日分潮（S₂、M₂）和浅水分潮（M₄、MS₄）共同作用；2010−2020年间上游分潮振幅衰减、相位增大，潮汐不对称由涨潮主导转为落潮主导，天文分潮相互作用的负不对称性增强，高频分潮的贡献减小；外海海域落潮主导的不对称性趋向减弱，天文−浅水分潮的相互作用表现为正不对称性；受大型基础设施建设、水资源配置工程及海平面上升等因素共同影响，岸线和地形特征均发生了显著改变，进而引发了潮汐动力系统的中长期调整。本研究为理解多尺度扰动下潮汐系统演变规律提供了新的分析框架，对河口综合治理具有重要参考价值。
- 潮汐不对称 /
- 倍潮 /
- 复合潮 /
- 偏度 /
- 珠江河口
Abstract: The Zhujiang River Estuary, a typical subtropical large-scale estuary, exhibits significant interactions between diurnal and semi-diurnal tides. Under the combined impacts of global climate change and intensive human activities, its tidal dynamics system has undergone notable variations. This study focuses on the nonlinear coupling mechanisms between diurnal tides (K₁, O₁) and semi-diurnal tides (M₂, S₂), developing an integrated evaluation framework that combines constituent amplitude ratios, relative phase analysis, and skewness method. This approach systematically reveals the spatiotemporal characteristics and driving mechanisms of barotropic tidal deformation in the Pearl River Estuary. The results include: (1) Tidal asymmetry transitions from ebb dominance at the estuary mouth to flood dominance at the upper estuary, with the controlling mechanism shifting from astronomical constituent interactions (O₁/K₁/M₂) in the outer estuary to synergistic effects of semi-diurnal constituents (S₂, M₂) and shallow-water constituents (M₄, MS₄) in the upper reaches; (2) From 2010 to 2020, upstream constituents exhibited amplitude attenuation and phase increases, leading to a reversal from flood-to-ebb dominated asymmetry. Negative asymmetry induced by astronomical constituent interactions intensified, while the contribution of high-frequency constituents decreased; (3) In offshore areas, ebb-dominated asymmetry weakened, with emerging positive asymmetry driven by interactions between astronomical and shallow-water constituents; (4) The tidal dynamics system of the Pearl River Estuary has undergone significant long-term adaptive adjustments. Due to the combined influences of large-scale infrastructure construction, water resource allocation projects, and sea level rise, coastline and terrain both occur significant changes, which further has driven middle-to-long term adjustment of tidal dynamics. This study provides a novel analytical framework for understanding tidal system evolution under multi-scale perturbations and offers crucial insights for integrated estuarine management.
- tidal asymmetry /
- overtides /
- compound tides /
- skewness /
- Zhujiang River Estuary

HTML全文

图 1 珠江河网−河口与海洋站位置（红色五角星）

Fig. 1 Zhujiang River network-estuary and tidal gauge stations (red pentagram)

下载: 全尺寸图片幻灯片

图 2 4个海洋站逐日潮汐不对称（上）和大小潮过程（下）

Fig. 2 Daily tidal asymmetry at the four tidal gauge stations (upper) and a spring-neap tidal cycle (lower)

下载: 全尺寸图片幻灯片

图 3 珠江三角洲关键断面冲淤年代际变化

Fig. 3 Erosion-deposition decadal variations of key cross-sections in the Zhujiang River Delta

下载: 全尺寸图片幻灯片

图 4 珠江河口主要验潮站潮汐不对称特性、主要分潮振幅与冲淡水示意图

Fig. 4 Tidal asymmetry, constituents amplitude and diluted water sketch in the Zhujiang River Estuary

下载: 全尺寸图片幻灯片

表 1 主要分潮调和常数

Tab. 1 Harmonic constants of the main tidal constituents

海洋站分潮	广州		赤湾		珠海		大万山
海洋站分潮	振幅/ cm	相位/ (°)	振幅/ cm	相位/ (°)	振幅/ cm	相位/ (°)	振幅/ cm	相位/ (°)
M₂	63.7	324.8	57.1	301.6	47.9	291.9	39.8	273.7
S₂	23.2	357.4	21.4	332.0	18.9	322.7	15.7	308.2
K₁	40.8	321.0	39.6	309.4	37.7	307.8	40.7	303.7
O₁	31.8	270.5	31.2	260.1	30.1	258.1	28.6	254.6
MK₃	3.3	185.7	1.7	150.8	1.3	60.6	1.4	24.5
MO₃	3.1	153.2	1.3	100.9	0.4	350.4	1.0	296.5
M₄	5.8	141.4	4.2	87.1	4.6	34.0	2.9	346.9
MS₄	3.4	208.8	2.7	146.4	2.5	89.5	1.5	51.8
M₆	1.5	353.6	0.6	275.0	0.8	205.2	0.4	214.2
MS_f	3.9	35.0	1.9	86.8	2.7	30.8	3.6	45.6

下载: 导出CSV

表 2 4个验潮站正压潮不对称性

Tab. 2 Barotropic tidal asymmetry at the four tidal gauge stations

海洋站参数	广州	赤湾	珠海	大万山
$ {a}_{{{\mathrm{M}}}_{4}}/{a}_{{{\mathrm{M}}}_{2}} $	0.091	0.074	0.096	0.073
$ 2{\varphi }_{{{\mathrm{M}}}_{2}}-{\varphi }_{{{\mathrm{M}}}_{4}} $	148.2	156.1	189.8	200.5
$ {\varphi }_{{{\mathrm{K}}}_{1}}+{\varphi }_{{{\mathrm{O}}}_{1}}-{\varphi }_{{{\mathrm{M}}}_{2}} $	266.7	267.9	274.0	284.6
$ \gamma $	0.164	−0.142	−0.139	−0.690

下载: 导出CSV

表 3 总不对称性与分潮组合贡献（C1、C2和C3）

Tab. 3 Total asymmetry (skewness) and the three major combinations (C1, C2 and C3)

参数验潮站	$ {\gamma }_{N} $	C1	$ {\beta }_{1} $	C2	$ {\beta }_{2} $	C3	$ {\beta }_{3} $
大万山	−0.442	O₁/K₁/M₂	−0.350	M₂/M₄	−0.050	O₁/M₂/MO₃	−0.020
珠海	−0.273	O₁/K₁/M₂	−0.264	M₂/M₄	−0.035	M₂/S₂/MS₄	−0.024
赤湾	−0.007	O₁/K₁/M₂	−0.222	M₂/M₄	0.070	M₂/S₂/MS₄	0.069
广州	0.179	O₁/K₁/M₂	−0.189	M₂/M₄	0.113	M₂/S₂/MS₄	0.089

下载: 导出CSV

表 4 主要分潮振幅和迟角年际变化

Tab. 4 Decadal variations of amplitudes and phases of the four major tidal constituents

分潮验潮站	M₂		S2		K1		O1
分潮验潮站	振幅/ cm	迟角/ (°)	振幅/ cm	迟角/ (°)	振幅/ cm	迟角/ (°)	振幅/ cm	迟角/ (°)
大万山	1.6	−1.1	2.2	1.4	−7.4	5.3	0.6	−3.0
珠海	−0. 1	−0.4	−0. 2	−0.5	0.0	−1.1	0.0	−0.4
广州	−10.3	18.4	−3.9	17.0	−3.4	12.1	−0.2	5.5
注：表中数据为2020年相对2010年的变化。

下载: 导出CSV

表 5 验潮站潮汐不对称和分潮组合贡献的年代际变化

Tab. 5 Decadal variations of tidal asymmetry and the major combinations at tidal gauge stations

参数验潮站	年代	$ {\gamma }_{N} $	C1	$ {\beta }_{1} $	C2	$ {\beta }_{2} $
大万山	2010	−0.442	O₁/K₁/M₂	−0.350	M₂/M₄	−0.050
	2020	−0.233	O₁/K₁/M₂	−0.282	M₂/S₂/MS₄	0.062
珠海	2010	−0.273	O₁/K₁/M₂	−0.264	M₂/M₄	−0.035
	2020	−0.273	O₁/K₁/M₂	−0.267	M₂/M₄	−0.025
广州	2010	0.179	O₁/K₁/M₂	−0.189	M₂/M₄	0.113
	2020	−0.219	O₁/K₁/M₂	−0.237	O₁/M₂/MO₃	0.012

下载: 导出CSV

表 6 珠江三角洲输沙量和海平面变化

Tab. 6 Variations of sediment and sea level rise in the Zhujiang River Delta

	多年平均	近10 a平均（2011−2020年）	2020年
年径流量/（10⁸ m³）	2487	3042	2831.8
年输沙量/（10⁴ t）	6645	2549.4	2718.3
年平均含沙量/（kg·m^-3）	0.207	/	0.088
输沙模数/（t·a⁻¹·km⁻²）	383.8	/	174.6
海平面/mm	0	60	68
注：“/”表示数据缺失；年平均含沙量为马口站和三水站平均值。

下载: 导出CSV

表 7 珠江三角洲潮汐不对称相关性分析

Tab. 7 Correlation Analysis of tidal asymmetry in the Zhujiang River Delta

	局地坡度	河道深宽比	海平面高度	流量	输沙率	偏度
局地坡度	1	0.32	0.23	−0.02	−0.29	−0.46
河道深宽比	0.32	1	0.11	0.43	0.08	−0.02
海平面高度	0.23	0.11	1	0.67	0.30	0.27
流量	−0.02	0.43	0.67	1	0.54	0.31
输沙率	−0.29	0.08	0.30	0.54	1	0.32
偏度	−0.46	−0.02	0.27	0.31	0.32	1

下载: 导出CSV

参考文献(27)

[1]	Friedrichs C T, Aubrey D G. Non-linear tidal distortion in shallow well-mixed estuaries: a synthesis[J]. Estuarine, Coastal and Shelf Science, 1988, 27(5): 521−545. doi: 10.1016/0272-7714(88)90082-0
[2]	Prandle D. Relationships between tidal dynamics and bathymetry in strongly convergent estuaries[J]. Journal of Physical Oceanography, 2003, 33(12): 2738−2750. doi: 10.1175/1520-0485(2003)033<2738:RBTDAB>2.0.CO;2
[3]	李谊纯, 徐群. 瓯江口内外潮汐不对称研究[J]. 水利水运工程学报, 2013(5): 61−65. doi: 10.3969/j.issn.1009-640X.2013.05.009 Li Yichun, Xu Qun. A study of tidal asymmetry in Oujiang estuary[J]. Hydro-Science and Engineering, 2013(5): 61−65. doi: 10.3969/j.issn.1009-640X.2013.05.009
[4]	李谊纯, 李庆, 林振良. 正规半日潮海域潮汐不对称性及量化[J]. 海洋工程, 2019, 37(6): 86−93. Li Yichun, Li Qing, Lin Zhenliang. Tidal asymmetry and its quantification in regular semidiurnal tide zones[J]. The Ocean Engineering, 2019, 37(6): 86−93.
[5]	Wang Z B, Jeuken C, De Vriend H J. Tidal asymmetry and residual sediment transport in estuaries[R/OL]. https://www.researchgate.net/publication/236846938_Tidal_asymmetry_and_residual_sediment_transport_in_estuaries.
[6]	Li Zhanhai, Jia Jianjun, Wang Yaping, et al. Net suspended sediment transport modulated by multiple flood-ebb asymmetries in the progressive tidal wave dominated and partially stratified Changjiang Estuary[J]. Marine Geology, 2022, 443: 106702. doi: 10.1016/j.margeo.2021.106702
[7]	乔立新, 张国安, 何青, 等. 长江分汊河口涨、落潮悬沙不对称特征及季节性差异[J]. 海洋学报, 2020, 42(3): 107−117. doi: 10.3969/j.issn.0253-4193.2020.03.010 Qiao Lixin, Zhang Guoan, He Qing, et al. Tidal and seasonal asymmetry of suspended sediment concentration in branched channels of the Changjiang River Estuary[J]. Haiyang Xuebao, 2020, 42(3): 107−117. doi: 10.3969/j.issn.0253-4193.2020.03.010
[8]	Jewell S A, Walker D J, Fortunato A B. Tidal asymmetry in a coastal lagoon subject to a mixed tidal regime[J]. Geomorphology, 2012, 138(1): 171−180. doi: 10.1016/j.geomorph.2011.08.032
[9]	Du Jiabi, Shen Jian, Zhang Yinglong, et al. Tidal response to sea-level rise in different types of estuaries: the importance of length, bathymetry, and geometry[J]. Geophysical Research Letters, 2018, 45(1): 227−235. doi: 10.1002/2017GL075963
[10]	Huang Haosheng, Chen Changsheng, Blanton J O, et al. A numerical study of tidal asymmetry in Okatee Creek, South Carolina[J]. Estuarine, Coastal and Shelf Science, 2008, 78(1): 190−202. doi: 10.1016/j.ecss.2007.11.027
[11]	Nidzieko N J. Tidal asymmetry in estuaries with mixed semidiurnal/diurnal tides[J]. Journal of Geophysical Research: Oceans, 2010, 115(C8): C08006.
[12]	Manoj N T, Unnikrishnan A S, Sundar D. Tidal asymmetry in the Mandovi and Zuari Estuaries, the West Coast of India[J]. Journal of Coastal Research, 2009, 256(6): 1187−1197.
[13]	Song Dehai, Wang Xiaohua, Kiss A E, et al. The contribution to tidal asymmetry by different combinations of tidal constituents[J]. Journal of Geophysical Research Atmospheres, 2011, 116(C12): C12007. doi: 10.1029/2011JC007270
[14]	李谊纯, 董德信, 王一兵. 防城港湾潮余流及潮汐不对称特征[J]. 广东海洋大学学报, 2021, 41(4): 50−57. doi: 10.3969/j.issn.1673-9159.2021.04.006 Li Yichun, Dong Dexin, Wang Yibing. Characteristics of tidal residual current and tidal asymmetry in Fangchenggang Gulf[J]. Journal of Guangdong Ocean University, 2021, 41(4): 50−57. doi: 10.3969/j.issn.1673-9159.2021.04.006
[15]	Mao Qingwen, Shi Ping, Yin Kedong, et al. Tides and tidal currents in the Pearl River Estuary[J]. Continental Shelf Research, 2004, 24(16): 1797−1808. doi: 10.1016/j.csr.2004.06.008
[16]	Cai Huayang, Yang Qingshu, Zhang Zihao, et al. Impact of river-tide dynamics on the temporal-spatial distribution of residual water level in the Pearl River channel networks[J]. Estuaries and Coasts, 2018, 41(7): 1885−1903. doi: 10.1007/s12237-018-0399-2
[17]	Zhang Wei, Cao Yu, Zhu Yuliang, et al. Unravelling the causes of tidal asymmetry in deltas[J]. Journal of Hydrology, 2018, 564: 588−604. doi: 10.1016/j.jhydrol.2018.07.023
[18]	童朝锋, 司家林, 张蔚, 等. 伶仃洋洪季潮波传播变形及不对称性规律分析[J]. 热带海洋学报, 2020, 39(1): 36−52. Tong Chaofeng, Si Jialin, Zhang Wei, et al. Analysis of tidal wave propagation distortion and asymmetry in Lingding Bay during wet season[J]. Journal of Tropical Oceanography, 2020, 39(1): 36−52.
[19]	许炜铭, 包芸. 重大工程引起的珠江河口潮波逆向不稳定传播现象[J]. 计算力学学报, 2011, 28(S1): 208−214. Xu Weiming, Bao Yun. Unsteady reverse transmission of tide wave by huge human activity in the estuary of Pearl River[J]. Chinese Journal of Computational Mechanics, 2011, 28(S1): 208−214.
[20]	Wu Z Y, Saito Y, Zhao D N, et al. Impact of human activities on subaqueous topographic change in Lingding Bay of the Pearl River estuary, China, during 1955−2013[J]. Scientific Reports, 2016, 6(1): 37742 doi: 10.1038/srep37742
[21]	Pawlowicz R, Beardsley B, Lentz S. Classical tidal harmonic analysis including error estimates in MATLAB using T_TIDE[J]. Computers & Geosciences, 2002, 28(8): 929−937.
[22]	Jay D A, Leffler K, Diefenderfer H L, et al. Tidal-fluvial and estuarine processes in the lower Columbia River: I. Along-channel water level variations, Pacific Ocean to Bonneville Dam[J]. Estuaries and Coasts, 2015, 38(2): 415−433. doi: 10.1007/s12237-014-9819-0
[23]	Garel E, Zhang Ping, Cai Huayang. Dynamics of fortnightly water level variations along a tide-dominated estuary with negligible river discharge[J]. Ocean Science, 2021, 17(6): 1605−1621. doi: 10.5194/os-17-1605-2021
[24]	Blanton J O, Lin Guoqing, Elston S A. Tidal current asymmetry in shallow estuaries and tidal creeks[J]. Continental Shelf Research, 2002, 22(11/13): 1731−1743.
[25]	Leuven J R F W, Pierik H J, Van Der Vegt M, et al. Sea-level-rise-induced threats depend on the size of tide-influenced estuaries worldwide[J]. Nature Climate Change, 2019, 9(12): 986−992. doi: 10.1038/s41558-019-0608-4
[26]	章卫胜, 张金善, 林瑞栋, 等. 中国近海潮汐变化对外海海平面上升的响应[J]. 水科学进展, 2013, 24(2): 243−250. Zhang Weisheng, Zhang Jinshan, Lin Ruidong, et al. Tidal response of sea level rise in marginal seas near China[J]. Advances in Water Science, 2013, 24(2): 243−250.
[27]	Yang Qingshu, Hu Shuai, Fu Linxi, et al. Responses of tidal duration asymmetry to morphological changes in Lingding Bay of the Pearl River Estuary[J]. Frontiers in Marine Science, 2022, 9: 983182. doi: 10.3389/fmars.2022.983182