南海北部东沙岛以西陆坡区2021年秋季内波特征统计与分析*
*感谢航次全体调查人员在潜标数据获取过程中付出的辛勤努力。
谢波涛, 博士, 高级工程师, 主要从事海洋环境及工程设计标准研究。email: |
Copy editor: 林强
收稿日期: 2022-12-28
修回日期: 2023-03-09
网络出版日期: 2023-03-14
基金资助
广东省重点领域研发计划项目(2020B111102003)
南海北部内波区划及工程参数研究(YXKY-ZX 10 2021)
海上油气田精细化环境预报与参数区划关键技术(YXKY-ZX 07 2020)
深水海洋环境监测及数据平台研究(KJGG2022-0202)
Characteristic statistics and analysis of internal waves in the continental slope area west of the Dongsha Plateau on the northern South China Sea in the autumn of 2021*
Copy editor: LIN Qiang
Received date: 2022-12-28
Revised date: 2023-03-09
Online published: 2023-03-14
Supported by
Key-Area Research and Development Project of Guangdong Province(2020B111102003)
Study on Internal Wave Zoning and Engineering Parameters in the North of the South China Sea(YXKY-ZX 10 2021)
Key Technologies of Refined Environmental Prediction and Parameter Zoning for Offshore Oil and Gas Fields(YXKY-ZX 07 2020)
Research on Deepwater Marine Environmental Monitoring and Data Platform(KJGG2022-0202)
本文利用2021年9—10月布放在南海北部东沙岛以西陆坡区的3套潜标观测数据分析了流花油田区内潮和内孤立波分布特征。调和分析显示, 该海域正压潮流较弱, 明显小于表底层斜压潮流。通过与全球潮汐模型对比发现, TPXO7.2对于半日分潮的模拟结果要明显优于全日分潮, 模型结果低估了O1分潮, 而高估了K1分潮的正压潮流振幅。调查海域斜压潮流表现为表底强化的第一斜压模态, O1分潮的斜压潮流椭圆振幅要大于K1分潮。观测期间, 共有4次内孤立波群集中出现, 且发生时间滞后于吕宋海峡天文大潮期3~4d。LH2站共记录了88个内波过程, 其中内孤立波31个, 内波波列57个, 内波平均振幅31m。该站非线性内波过程集中出现于每日的4—6时、11—13时和18—20时, 同时超过45%的单孤立子内波过程发生在4—6时。通过追踪9月8—12日共计5个内孤立波依次经过LH1、LH2和LH3站的传播过程, 可以计算内波在LH1至LH2站位间的传播速度为1.23m·s-1, 在LH2至LH3站位间的传播速度为1.77m·s-1, 同时根据线性波动方程及Kdv方程计算其理论传播速度为1.55m·s-1。本文的统计分析结果进一步加强了对典型秋季环境下南海北部流花油田区内波特征的理解和认识。
谢波涛 , 黄必桂 , 杨威 , 李锐祥 , 张燕 , 刘同木 , 李向一 . 南海北部东沙岛以西陆坡区2021年秋季内波特征统计与分析*[J]. 热带海洋学报, 2023 , 42(6) : 29 -41 . DOI: 10.11978/2022265
Observations from three moorings deployed in the continental slope area west of the Dongsha Plateau on the northern South China Sea (NSCS) from September to October 2021 are collected for the characteristic analysis of internal waves and internal solitary waves in the Liuhua oilfield area. Harmonic analysis shows the barotropic currents are obviously less than the baroclinic currents on the surface and bottom water layer. By comparison with the barotropic tidal currents obtained from TOPEX/Poseidon Global Inver Solution (TPXO7.2), it is found that the model results of semidiurnal tides are significantly better than that of diurnal tides, and the simulated results underestimate the current amplitude of O1 tidal constituent, but overestimate that of K1 tidal constituent. The internal tides show surface-bottom intensified baroclinic mode-1 structure, and the major axis of tidal ellipse of O1 tidal constituent is larger than that of K1. During the whole observation period, there are four internal solitary waves (ISWs) clusters passed by the Liuhua oilfield area in total, and the appearance time lags 3~4 days behind the astronomical spring tide of Luzon Strait. There are a total of 88 ISWs recorded at mooring of LH2, including 31 solitons and 57 ISW packets, and the averaged amplitude is 31 m. The daily appearance time for the ISWs concentrates between 4~6 am, 11 am-1 pm and 6~8 pm, and more than 45% of solitons appears between 4~6 am. By tracking the propagation process passed by LH1, LH2 and LH3 of 5 ISWs appeared between 8~12 September, the calculated phase speed for the ISWs is 1.23 m·s-1 between LH1 and LH2 and 1.77 m·s-1 between LH2 and LH3, and the theoretical propagation speed is 1.55 m·s-1 based on the linear wave equation and Kdv equation. The statistical results in this paper further strengthen the understanding of the internal waves in the Liuhua oilfield area on the NSCS under the typical autumn environment.
图1 南海北部东沙岛以西陆坡区潜标观测站位分布基于国家测绘地理信息局标准地图服务网站下载的审图号为GS(2019)1825号的标准地图制作。五角星为3套观测潜标LH1—LH3, 地形数据来自etopo2(https://www.ngdc.noaa.gov/mgg/global/relief/ETOPO2/ETOPO2v2-2006/) Fig. 1 Sampling locations of the three moorings (LH1-LH3, pentagrams) on the shelf area west of the Dongsha plateau, northern South China Sea. The bathymetry (black contours) is taken from etopo2 (https://www.ngdc.noaa.gov/mgg/global/relief/ETOPO2/ETOPO2v2-2006/) |
表1 LH1—LH3站潜标位置信息、观测设备、观测时长及观测深度统计表Tab. 1 Location information, observation period, instrument, and sample depth of moorings at the sites LH1-LH3 |
站位 | 经度 | 纬度 | 水深/m | 观测设备 | 观测时段 | 流速剖面深度范围/m |
---|---|---|---|---|---|---|
LH1 | 115°58.230′E | 20°51.605′N | 368 | 300 & 150kHz ADCP | 08.28—11.03 | 12~328 |
LH2 | 115°44.422′E | 20°42.006′N | 378 | 4*300 & 600kHz ADCP 4* SBE37 & 15* SBE 56 | 08.27—10.29 | 12~370 |
LH3 | 115°34.828′E | 20°28.774′N | 440 | 2* 300kHz ADCP | 09.02—11.05 | 12~180 |
注: ADCP全称为声学多普勒流速剖面仪(acoustic Doppler current profiler); SBE 37和SBE 56均为美国Sea-Bird公司的SBE系列温盐深测量仪 |
图2 LH2站主要全日和半日分潮正压潮流椭圆分布全日: O1、K1; 半日: M2、S2; 黑色椭圆来自潜标观测, 红色椭圆来自模型计算; 左上角为2cm·s-1的速度标尺 Fig. 2 Barotropic tidal ellipses of the principal diurnal (O1, K1) and semidiurnal (M2, S2) constituents at LH2 (Black ellipses is calculated from moor data, red ellipses is from TPXO 7.2, the upper-left icon is the current scale of 2 cm·s-1) |
表2 LH2站主要全日和半日分潮正压和斜压潮流椭圆参数Tab. 2 Ellipse parameters of the principal diurnal and semidiurnal barotropic and baroclinic tidal constituents of LH2 |
长轴/(cm·s-1) | 短轴/(cm·s-1) | 倾角/° | 相位/° | |||
---|---|---|---|---|---|---|
O1 | 正压潮流 | 3.5 | 1.6 | 81 | 97 | |
TPXO 7.2 | 2.3 | 0.5 | 19 | 15 | ||
斜压潮流 | 25m | 21.3 | -14.9 | 137 | 340 | |
105m | 5.6 | -1.4 | 118 | 335 | ||
200m | 2.0 | -1.0 | 66 | 25 | ||
300m | 13.6 | -9.7 | 116 | 163 | ||
350m | 13.4 | -9.5 | 117 | 188 | ||
K1 | 正压潮流 | 1.1 | 0.5 | 142 | 247 | |
TPXO 7.2 | 2.1 | 0.6 | 24 | 59 | ||
斜压潮流 | 25m | 13.3 | -10.2 | 132 | 127 | |
105m | 1.7 | -0.8 | 96 | 161 | ||
200m | 4.4 | -4.2 | 170 | 226 | ||
300m | 5.8 | -5.2 | 144 | 312 | ||
350m | 5.6 | -4.1 | 112 | 330 | ||
M2 | 正压潮流 | 1.8 | 0.4 | 155 | 194 | |
TPXO 7.2 | 2.2 | 0.7 | 175 | 199 | ||
斜压潮流 | 25m | 4.6 | -3.0 | 176 | 131 | |
105m | 0.5 | 0.1 | 61 | 263 | ||
200m | 1.0 | -0.2 | 149 | 282 | ||
300m | 2.2 | -1.0 | 9 | 149 | ||
350m | 1.9 | -1.3 | 136 | 12 | ||
S2 | 正压潮流 | 1.1 | 0.6 | 163 | 232 | |
TPXO 7.2 | 1.1 | 0.6 | 170 | 225 | ||
斜压潮流 | 25m | 1.9 | -1.7 | 34 | 244 | |
105m | 1.6 | -0.6 | 137 | 43 | ||
200m | 0.4 | -0.2 | 156 | 5 | ||
300m | 0.5 | -0.2 | 8 | 141 | ||
350m | 1.4 | -0.8 | 95 | 316 |
图6 LH2站内孤立波特征统计a. 观测期间农历月中逐日内孤立波发生频率统计; b. 逐时内孤立波发生频率统计; c. 内孤立波振幅分布统计; d. 波致流速分布统计 Fig. 6 Characteristic statistics of NIWs at LH2. (a) Daily frequency statistics in the lunar month; (b) hourly frequency statistics; (c) amplitude distribution statistics; (d) wave-induce current distribution statistics of NIWs during the observation period |
图8 LH2站10月10日内孤立波(a)和9月21日内波波列(b)温度剖面及纬向—垂向海流分布图白色实线为25℃等温线 Fig. 8 Distributions of temperature profile and current field consisting of zonal and vertical velocity at LH2. (a) Single internal wave observed on 10th October; (b) internal wave packets observed on 21st September. White solid line indicates isotherm for 25 ℃ |
图9 2021年9月8—12日LH1、LH2和LH3站40~60m层平均纬向和经向6h高通滤波流速时间过程线Fig. 9 Time series of 6h high-pass filtered zonal and meridional velocity (cm·s-1) at the 40~60m depths of LH1, LH2 and LH3 during 8-12 September 2021 |
表 3 2021年9月8—12日LH1、LH2和LH3站内孤立波发生时间、波致水平流速流向和持续时间统计表Tab. 3 Statistics of the occurrence time, wave-induced velocity and direction, duration for the ISWs along LH1-LH2-LH3 during 8-12 September 2021 |
站位 | 日期 | 时间 | 波致流速/(cm·s-1) | 波致流向/° | 持续时间/min |
---|---|---|---|---|---|
LH1 | 09-08 | 03:10 | 54.3 | 332 | 22 |
09-09 | 02:26 | 58.1 | 329 | 20 | |
09-10 | 02:50 | 80.8 | 332 | 18 | |
09-11 | 04:12 | 65.3 | 323 | 20 | |
09-12 | 04:26 | 46.1 | 343 | 20 | |
LH2 | 09-08 | 05:26 | 55.6 | 325 | 26 |
09-09 | 04:10 | 88.0 | 302 | 24 | |
09-10 | 04:20 | 64.1 | 307 | 22 | |
09-11 | 05:28 | 53.6 | 300 | 26 | |
09-12 | 05:52 | 49.7 | 313 | 20 | |
LH3 | 09-08 | 06:26 | 83.0 | 294 | 30 |
09-09 | 05:26 | 72.2 | 269 | 26 | |
09-10 | 05:18 | 70.1 | 287 | 22 | |
09-11 | 06:38 | 64.2 | 278 | 20 | |
09-12 | 07:04 | 76.3 | 293 | 28 |
[1] |
蔡树群, 何建玲, 谢皆烁, 2011. 近10年来南海孤立内波的研究进展[J]. 地球科学进展, 26(7): 703-710.
|
[2] |
蒋暑民, 戴德君, 乔方利, 等, 2019. 南海北部陆架海域内潮特征的观测研究[J]. 海洋与湖沼, 50(1): 1-11.
|
[3] |
石新刚, 刘耀华, 兰志刚, 等, 2013. 南海北部流花海域内孤立波特征研究[J]. 热带海洋学报, 32(6): 22-27.
|
[4] |
张效谦, 梁鑫峰, 田纪伟, 2005. 南海北部450m以浅水层内潮和近惯性运动研究[J]. 科学通报, 50(18): 2027-2031.
|
[5] |
|
[6] |
|
[7] |
|
[8] |
|
[9] |
|
[10] |
|
[11] |
|
[12] |
|
[13] |
|
[14] |
|
[15] |
|
[16] |
|
[17] |
|
[18] |
|
[19] |
|
[20] |
|
[21] |
|
[22] |
|
[23] |
|
[24] |
|
[25] |
|
[26] |
|
[27] |
|
[28] |
|
[29] |
|
[30] |
|
[31] |
|
[32] |
|
[33] |
|
[34] |
|
[35] |
|
[36] |
|
[37] |
|
[38] |
|
/
〈 | 〉 |