大陆坡内波环境中声传播模态耦合及强度起伏特征

高飞; 徐芳华; 李整林; 秦继兴

doi:10.7498/aps.71.20220634

摘要

大陆坡海域内波普遍存在, 其陆坡地形和内波过程都会引起显著的声场起伏. 已有研究工作主要关注内波或大陆坡单扰动因子对模态耦合和强度起伏的影响, 少见将内波和海底地形起伏同时作为影响因子进行研究. 文章考虑孤立子内波和海底地形对声传播的双重影响, 首先构建海洋波导模型, 然后基于简正波理论数值对比分析各波导模型条件下模态的耦合规律, 进而研究声场强度起伏特性及其物理机理. 研究结果表明, 当声波朝向或远离内波中心传播时, 模态耦合在内波与大陆坡的共同作用下出现耦合增强或衰减, 高号模态耦合系数振荡; 内波扰动的作用使得能量由低号模态耦合至高号模态, 提高了声场强度衰减; 斜坡的作用使得声波下坡传播时, 波导模态数增加、模态强度衰减降低; 大陆坡内波环境中的模态强度总和大于内波环境、小于大陆坡环境, 且模态组间的能量转移比只有内波或者大陆坡时更强, 高号模态从耦合中获得更多能量, 使得跃层以上水层能量增强.

关键词:

Abstract

The topographic variation underwater of the continental slope is one of the main causes for triggering off the formation of internal waves, and the continental slope internal waves are ubiquitous in the ocean. The horizontal variation of waveguide environment, caused by the internal wave and the continental slope, can lead to acoustic normal mode coupling, and then generate sound field fluctuation. Most of the existing research work focused on studying the effect of single perturbation factor of either the internal waves or the continental slope on acoustic mode coupling and intensity fluctuation, while it is hard to find some research work that takes into account both the internal waves and the topographic variations as influencing factors. In this work, numerical simulations for the sound waves to propagate through the internal waves in the downhill direction are performed by using the acoustic coupled normal-mode model in four waveguide environments: thermocline, internal wave, continental slope and continental slope internal wave. And the mode coupling and intensity fluctuation characteristics and their physical mechanisms are studied by comparing and analyzing the simulation results of the four different waveguide environment constructed. Some conclusions are obtained as follows. The intra-mode conduction coefficients are symmetric with respect to the center of the internal wave, while the inter-mode coupling coefficients are antisymmetric around it. As the sound waves propagate toward or away from the center of the internal wave, the acoustic mode coupling becomes enhanced or weakened, and the coupling coefficients curves for large mode oscillate. The influence of internal wave perturbation makes the energy transfer from the smaller modes to the larger modes, which increases the attenuation of sound field intensity. The number of the waveguide modes increases and the mode intensity attenuation decreases, when the sound waves propagate downhill. The total intensity of all modes for the continental slope internal wave environment is greater than for the internal wave environment and less than for the continental environment, and the energy transfer between mode groups is stronger than for individual effect of internal wave or continental slope, which leads more energy to transfer from the smaller to larger mode groups and the energy of the sound field above the thermocline to increase.

Keywords:

作者及机构信息

1.
清华大学全球变化研究院地球系统科学系, 地球系统数值模拟教育部重点实验室, 北京　100084

2.
海军研究院, 天津　300061

3.
中山大学海洋工程与技术学院, 珠海　519000

4.
中国科学院声学研究所, 声场声信息国家重点实验室, 北京　100190

通信作者: 徐芳华, fxu@mails.tsinghua.edu.cn ; 秦继兴, qjx@mail.ioa.ac.cn

基金项目: 国家重点研发计划(批准号: 2020YFA0607900)、国家自然科学基金(批准号: 42176019, 11874061)和中国科学院青年创新促进会资助的课题(批准号: 2021023).

Authors and contacts

1.
Ministry of Education Key Laboratory of Earth System Modeling, Department of Earth System Science, Institute for Global Change Studies, Tsinghua University, Beijing 100084, China

2.
Naval Research Institute, Tianjin 300061, China

3.
School of Ocean Engineering and technology, Sun Yat-Sen University, Zhuhai 519000, China

4.
State Key Laboratory of Acoustics, Institute of Acoustics, Chinese Academy of Sciences, Beijing 100190, China

Corresponding author: Xu Fang-Hua, fxu@mails.tsinghua.edu.cn ; Qin Ji-Xing, qjx@mail.ioa.ac.cn

Funds: Project supported by the National Key Research and Development Program of China (Grant No. 2020YFA0607900), the National Natural Science Foundation of China (Grant Nos. 42176019, 11874061), and the Youth Innovation Promotion Association, Chinese Academy of Sciences (Grant No. 2021023).

文章全文 : translate this paragraph

参考文献

[1]	Whalen C B, Lavergne C D, Garabato N A C, Klymak J M, Mackinnon J A, Sheen 2020 Nature 1 606
[2]	Alford M H, Mackinnon J A, Simmons H L Nash J D 2016 Annu. Rev. Mar. Sci. 8 95 Google Scholar
[3]	Zhao Z, Alford M H, Girton J B, Rainville L, Simmons H L 2016 J. Phys. Oceanogr. 46 1657 Google Scholar
[4]	Grisouard N, Staquet C 2010 Nonlinear Processes Geophys. 17 575 Google Scholar
[5]	张泽众, 骆文于, 庞哲, 周益清 2019 68 204302 Google Scholar Zhang Z Z, Luo W Y, Pan Z, Zhou Y Q 2019 Acta Phys. Sin. 68 204302 Google Scholar
[6]	Preisig J C, Duda T F 1997 IEEE J. Oceanic Eng. 22 256 Google Scholar
[7]	Zhou J X, Zhang X Z, Rogers P H 1991 J. Acoust. Soc. Am. 90 2042 Google Scholar
[8]	Rouseff D, Turgut A, Wolf S N, Finette S, Orr M H, Pasewark B H, Apel J R, Badiey M, Chiu C S, Headrick R H, Lynch J F, Kemp J N, Newhall A E, von der Heydt K, Tielbuerger D 2002 J. Acoust. Soc. Am. 111 1655 Google Scholar
[9]	Katsnelson B G, Pereselkov S A 2000 Acoust. Phys. 46 684 Google Scholar
[10]	Lin Y T, Duda T F, Lynch J F 2009 J. Acoust. Soc. Am. 126 1752 Google Scholar
[11]	Milone M A, DeCourcy B J, Lin Y T, Siegmann 2019 J. Acoust. Soc. Am. 146 1934 Google Scholar
[12]	秦继兴, Katsnelson Boris, 彭朝晖, 李整林, 张仁和, 骆文于 2016 65 034301 Google Scholar Qin J X, Katsnelson B G, Peng Z H, Li Z L, Zhang R H, Luo W Y 2016 Acta Phys. Sin. 65 034301 Google Scholar
[13]	Chiu C S, Ramp S R, Miller C W, Lynch J F, Duda T F, Tang T Y 2004 IEEE J. Oceanic Eng. 29 1249 Google Scholar
[14]	秦继兴, Katsnelson Boris, 李整林, 张仁和, 骆文于 2016 声学学报 41 145 Qin J X, Katsnelson B G, Li Z L, Zhang R H, Luo W Y 2016 Acta Acustia 41 145
[15]	Badiey M, Katsnelson B G, Lynch J F, Pereselkov S, Siegmann W L 2005 J. Acoust. Soc. Am. 117 613 Google Scholar
[16]	李沁然, 孙超, 谢磊 2022 71 024302 Google Scholar Li Q R, Sun C, Xie L 2022 Acta Phys. Sin. 71 024302 Google Scholar
[17]	Chiu L Y S, Chang A Y Y, Reeder D B 2015 J. Acoust. Soc. Am. 138 515 Google Scholar
[18]	刘代, 李整林, 刘若芸 2021 70 034302 Google Scholar Liu D, Li Z L, Liu R Y 2021 Acta Phys. Sin. 70 034302 Google Scholar
[19]	莫亚枭, 朴胜春, 张海刚, 李丽 2014 63 214302 Google Scholar Mo Y X, Piao S C, Zhang H G Li L 2014 Acta Phys. Sin. 63 214302 Google Scholar
[20]	Sagers J D, Ballard M S, Knobles D P 2014 J. Acoust. Soc. Am. 136 2453 Google Scholar
[21]	Chiu L Y S, Reeder D B, Chang Y Y, Chen C F, Chiu C S, Lynch J F 2013 J. Acoust. Soc. Am. 133 1306 Google Scholar
[22]	Porter M B 1991 The KRAKEN Normal Mode Program (La Spezia: SACLANT Undersea Research Centre) Technical Report SM-2
[23]	Jensen F B, Kuperman W A, Porter M B, Schmidt H 2011 Computational Ocean Acoustics (New York: Springer) pp403–408
[24]	Apel J R, Ostrovsky L A, Stepanyants Y A, Lynch J F 2007 J. Acoust. Soc. Am. 121 695 Google Scholar
[25]	Yang T C 2014 J. Acoust. Soc. Am. 135 610 Google Scholar
[26]	Dozier L B, Tappert F D 1978 J. Acoust. Soc. Am. 63 353 Google Scholar
[27]	Yang T C 2017 IEEE J. Oceanic Eng. 42 663 Google Scholar

施引文献

图 1 大陆坡内波波导环境参数示意图

Fig. 1. Diagram of parameters for continental slope internal wave waveguide environment.

下载: 全尺寸图片幻灯片

图 2 仿真用四种典型海洋环境　(a) 环境1(跃层环境); (b) 环境2(内波环境); (c)环境3(大陆坡环境); (d) 环境4(大陆坡内波环境)

Fig. 2. Four typical environments for simulation: (a) Environment 1 (thermocline); (b) environment 2 (internal wave); (c) environment 3 (continental slope); (d) environment 4 (continental slope internal wave).

下载: 全尺寸图片幻灯片

图 3 内波环境水平声速梯度分布

Fig. 3. Distributions of horizontal sound speed gradient in internal wave environment.

下载: 全尺寸图片幻灯片

图 4 第1—4号简正波在不同波导环境中水平距离2—4 km处的模内传导系数$ C_{m, m}^{j + 1} $　(a) 1号模态; (b) 2号模态; (c) 3号模态; (d) 4号模态

Fig. 4. The intra-mode conduction coefficients $ C_{m, m}^{j + 1} $ of mode 1, 2, 3 and 4 at range 2–4 km in different waveguide environments: (a) Mode 1; (b) mode 2; (c) mode 3; (d) mode 4.

下载: 全尺寸图片幻灯片

图 5 不同波导环境中水平距离2—4 km处的模间耦合系数$ C_{1, n}^{j{\text{ + }}1} $　(a) 1号与2号模态; (b) 1号与3号模态; (c) 1号与5号模态; (d) 1号与13号模态

Fig. 5. The inter-mode coupling coefficients $ C_{1, n}^{j{\text{ + }}1} $ at range of 2–4 km in different waveguide environments: (a) Mode 1 with 2; (b) mode 1 with 3; (c) mode 1 with 5; (d) mode 1 with 13.

下载: 全尺寸图片幻灯片

图 6 不同波导环境中1号局地模态函数　(a) 内波环境; (b) 大陆坡环境; (c) 大陆坡内波环境

Fig. 6. The local function of mode 1 in different waveguide environments: (a) Internal wave environment; (b) continental slope environment; (c) continental slope internal wave environment.

下载: 全尺寸图片幻灯片

图 7 不同波导环境中1—20号简正波模态强度随距离变化　(a) 跃层环境; (b) 内波环境; (c) 大陆坡环境; (d) 大陆坡内波环境, 红色点划线为1—6号模态, 蓝色实线为7—13号模态, 黑色点线为14—20号模态

Fig. 7. Modes 1–20 intensity variation with range in different waveguide environments: (a) Thermocline environment; (b) internal wave environment; (c) continental slope environment; (d) continental slope internal wave environment, the red dotted lines, blue solid lines and black dotted lines represent mode groups of 1–6, 7–13 and 14–20, respectively.

下载: 全尺寸图片幻灯片

图 8 内波波导环境中8号(a), 11号(b)简正波模态声场强度分布

Fig. 8. The mode 8 (a) and mode 11 (b) intensity versus range and depth in the internal wave environment.

下载: 全尺寸图片幻灯片

图 9 大陆坡波导环境中不同水平距离前13号简正波模态特征值分布, 特征值实部大于横虚线为波导模态

Fig. 9. Eigenvalues of the first 13 modes of different ranges in the continental slope environment.

下载: 全尺寸图片幻灯片

图 10 不同波导环境中各组模态强度之和随距离变化　(a) 所有模态$ {I_{{\text{1}}—{\max}}} $; (b) 1—6号模态$ {I_{{\text{1}}—{\text{6}}}} $; (c) 7—13号模态$ {I_{{\text{7}}—{\text{13}}}} $; (d) 14号以上模态$ {I_{{\text{14}}—{\max}}} $

Fig. 10. The sum of intensity of each mode groups versus range in different environments: (a) $ {I_{{\text{1}}—{\max}}} $; (b) $ {I_{{\text{1}}—{\text{6}}}} $; (c) ${I_{{\text{7}}—{\text{13}}}}$; (d) $ {I_{{\text{14}}—{\max}}} $.

下载: 全尺寸图片幻灯片

图 11 大陆坡内波环境中2.7—3.3 km范围内第4—8号简正波模态强度

Fig. 11. Intensity of modes 4–8 for at range 2.7–3.3 km in the continental slope internal wave environment.

下载: 全尺寸图片幻灯片

图 12 不同环境中参数变数时的模态强度之和$ {I_{{\text{1}}—{\text{6}}}} $随距离的变化　(a), (c), (e) 大陆坡内波环境; (b) 大陆坡环境; (d), (f) 内波环境

Fig. 12. The sum of intensity$ {I_{{\text{1}}—{\text{6}}}} $versus range in different environments of various parameters: (a), (c), (e) Continental slope internal wave environment; (b) continental slope environment; (d), (f) internal wave environment.

下载: 全尺寸图片幻灯片

图 13 不同环境中的声场分布　(a), (c), (e) 大陆坡环境3中的所有模态、1—6号模态、7—max号模态声场; (b), (d), (f) 大陆坡内波环境4中的所有模态、1—6号模态、7—max号模态声场. 其中, 图中虚线方框标记了0—35 m深度、2—6 km水平距离的区域

Fig. 13. The sound field in different environments: (a), (c), (e) The sound fields of the whole modes, models 1–6 and modes 7–max in continental slope environment, respectively; (b), (d), (f) the sound fields of the whole modes, models 1–6 and modes 7–max in continental slope internal wave environment, respectively. The white dashed boxes mark the area of 0–35 m and 2–6 km horizontal distance.

下载: 全尺寸图片幻灯片

表 1 仿真环境参数配置

Table 1. Configuration of environment parameters for simulations.

参数类型	参数值
跃层上边界深度$ {z_{\text{u}}}/{\text{m}} $	15
跃层下边界深度$ {z_{\text{l}}} $/m	35
水体声速$ {c_{\text{u}}} $, $ {c_{\text{l}}} $/(m·s^–1)	1530, 1500
内波的幅度$\varLambda$/m	35
内波的中心距离$ {r_0} $/km	3
内波的波宽$\varDelta$/m	300
大陆坡起点距离$ {r_{\text{s}}}/{\text{km}} $、水深$ {H_{\text{s}}}/{\text{m}} $	2, 100
大陆坡终点距离$ {r_{\text{e}}}/{\text{km}} $、水深$ {H_{\text{e}}}/{\text{m}} $	4, 200
大陆坡坡度/(°)	2.86 (1/10)

下载: 导出CSV

map

[1]	Whalen C B, Lavergne C D, Garabato N A C, Klymak J M, Mackinnon J A, Sheen 2020 Nature 1 606
[2]	Alford M H, Mackinnon J A, Simmons H L Nash J D 2016 Annu. Rev. Mar. Sci. 8 95 Google Scholar
[3]	Zhao Z, Alford M H, Girton J B, Rainville L, Simmons H L 2016 J. Phys. Oceanogr. 46 1657 Google Scholar
[4]	Grisouard N, Staquet C 2010 Nonlinear Processes Geophys. 17 575 Google Scholar
[5]	张泽众, 骆文于, 庞哲, 周益清 2019 68 204302 Google Scholar Zhang Z Z, Luo W Y, Pan Z, Zhou Y Q 2019 Acta Phys. Sin. 68 204302 Google Scholar
[6]	Preisig J C, Duda T F 1997 IEEE J. Oceanic Eng. 22 256 Google Scholar
[7]	Zhou J X, Zhang X Z, Rogers P H 1991 J. Acoust. Soc. Am. 90 2042 Google Scholar
[8]	Rouseff D, Turgut A, Wolf S N, Finette S, Orr M H, Pasewark B H, Apel J R, Badiey M, Chiu C S, Headrick R H, Lynch J F, Kemp J N, Newhall A E, von der Heydt K, Tielbuerger D 2002 J. Acoust. Soc. Am. 111 1655 Google Scholar
[9]	Katsnelson B G, Pereselkov S A 2000 Acoust. Phys. 46 684 Google Scholar
[10]	Lin Y T, Duda T F, Lynch J F 2009 J. Acoust. Soc. Am. 126 1752 Google Scholar
[11]	Milone M A, DeCourcy B J, Lin Y T, Siegmann 2019 J. Acoust. Soc. Am. 146 1934 Google Scholar
[12]	秦继兴, Katsnelson Boris, 彭朝晖, 李整林, 张仁和, 骆文于 2016 65 034301 Google Scholar Qin J X, Katsnelson B G, Peng Z H, Li Z L, Zhang R H, Luo W Y 2016 Acta Phys. Sin. 65 034301 Google Scholar
[13]	Chiu C S, Ramp S R, Miller C W, Lynch J F, Duda T F, Tang T Y 2004 IEEE J. Oceanic Eng. 29 1249 Google Scholar
[14]	秦继兴, Katsnelson Boris, 李整林, 张仁和, 骆文于 2016 声学学报 41 145 Qin J X, Katsnelson B G, Li Z L, Zhang R H, Luo W Y 2016 Acta Acustia 41 145
[15]	Badiey M, Katsnelson B G, Lynch J F, Pereselkov S, Siegmann W L 2005 J. Acoust. Soc. Am. 117 613 Google Scholar
[16]	李沁然, 孙超, 谢磊 2022 71 024302 Google Scholar Li Q R, Sun C, Xie L 2022 Acta Phys. Sin. 71 024302 Google Scholar
[17]	Chiu L Y S, Chang A Y Y, Reeder D B 2015 J. Acoust. Soc. Am. 138 515 Google Scholar
[18]	刘代, 李整林, 刘若芸 2021 70 034302 Google Scholar Liu D, Li Z L, Liu R Y 2021 Acta Phys. Sin. 70 034302 Google Scholar
[19]	莫亚枭, 朴胜春, 张海刚, 李丽 2014 63 214302 Google Scholar Mo Y X, Piao S C, Zhang H G Li L 2014 Acta Phys. Sin. 63 214302 Google Scholar
[20]	Sagers J D, Ballard M S, Knobles D P 2014 J. Acoust. Soc. Am. 136 2453 Google Scholar
[21]	Chiu L Y S, Reeder D B, Chang Y Y, Chen C F, Chiu C S, Lynch J F 2013 J. Acoust. Soc. Am. 133 1306 Google Scholar
[22]	Porter M B 1991 The KRAKEN Normal Mode Program (La Spezia: SACLANT Undersea Research Centre) Technical Report SM-2
[23]	Jensen F B, Kuperman W A, Porter M B, Schmidt H 2011 Computational Ocean Acoustics (New York: Springer) pp403–408
[24]	Apel J R, Ostrovsky L A, Stepanyants Y A, Lynch J F 2007 J. Acoust. Soc. Am. 121 695 Google Scholar
[25]	Yang T C 2014 J. Acoust. Soc. Am. 135 610 Google Scholar
[26]	Dozier L B, Tappert F D 1978 J. Acoust. Soc. Am. 63 353 Google Scholar
[27]	Yang T C 2017 IEEE J. Oceanic Eng. 42 663 Google Scholar

[1]	王俊, 蔡飞燕, 张汝钧, 李永川, 周伟, 李飞, 邓科, 郑海荣. 基于压电声子晶体板波声场的微粒操控. , 2024, 73(7): 074302. doi: 10.7498/aps.73.20231886
[2]	何兆阳, 雷波, 杨益新. 源致内波引起的声场扰动及其检测方法. , 2023, 72(14): 144301. doi: 10.7498/aps.72.20230346
[3]	霍勇刚, 严江余, 张全虎. 缪子多模态成像图像质量分析. , 2022, 71(2): 021401. doi: 10.7498/aps.71.20211083
[4]	李沁然, 孙超, 谢磊. 浅海内孤立波动态传播过程中声波模态强度起伏规律. , 2022, 71(2): 024302. doi: 10.7498/aps.71.20211132
[5]	霍勇刚, 严江余, 张全虎. 缪子多模态成像图像质量分析. , 2021, (): . doi: 10.7498/aps.70.20211083
[6]	张士钊, 朴胜春. 倾斜弹性海底条件下浅海声场的简正波相干耦合特性分析. , 2021, 70(21): 214304. doi: 10.7498/aps.70.20211013
[7]	李沁然, 孙超, 谢磊. 浅海内孤立波动态传播过程中声波模态强度起伏规律研究. , 2021, (): . doi: 10.7498/aps.70.20211132
[8]	孟瑞洁, 周士弘, 李风华, 戚聿波. 浅海波导中低频声场干涉简正模态的判别. , 2019, 68(13): 134304. doi: 10.7498/aps.68.20190221
[9]	周建波, 朴胜春, 刘亚琴, 祝捍皓. 海面随机起伏对噪声场空间特性的影响规律. , 2017, 66(1): 014301. doi: 10.7498/aps.66.014301
[10]	谢平, 杨芳梅, 李欣欣, 杨勇, 陈晓玲, 张利泰. 基于变分模态分解-传递熵的脑肌电信号耦合分析. , 2016, 65(11): 118701. doi: 10.7498/aps.65.118701
[11]	谢磊, 孙超, 刘雄厚, 蒋光禹. 陆架斜坡海域声场特性对常规波束形成阵增益的影响. , 2016, 65(14): 144303. doi: 10.7498/aps.65.144303
[12]	聂永发, 朱海潮. 利用源强密度声辐射模态重建声场. , 2014, 63(10): 104303. doi: 10.7498/aps.63.104303
[13]	张翰, 管玉平. 登陆我国大陆热带气旋的纬度分布特征. , 2012, 61(16): 169203. doi: 10.7498/aps.61.169203
[14]	张翰, 管玉平. 南海夏季风与登陆我国大陆初旋的关系. , 2012, 61(12): 129201. doi: 10.7498/aps.61.129201
[15]	石玉仁, 张娟, 杨红娟, 段文山. 耦合KdV方程的双峰孤立子及其稳定性. , 2011, 60(2): 020401. doi: 10.7498/aps.60.020401
[16]	裴利军, 邱本花. 模态分解法在非恒同耦合系统同步研究中的推广. , 2010, 59(1): 164-170. doi: 10.7498/aps.59.164
[17]	周天寿, 张锁春. 线性耦合Oregonator振子中的Echo波. , 2001, 50(1): 8-12. doi: 10.7498/aps.50.8
[18]	张民, 吴振森, 张延冬, 杨廷高. 脉冲波在强起伏湍流介质中的传播特征分析. , 2001, 50(6): 1052-1057. doi: 10.7498/aps.50.1052
[19]	闫循领, 董瑞新, 王伯运. α螺旋蛋白质螺旋线模型的耦合孤立子. , 1999, 48(4): 751-756. doi: 10.7498/aps.48.751
[20]	唐应吾. 具有随机起伏表面的正声速梯度浅海中的简正波声场. , 1976, 25(6): 481-486. doi: 10.7498/aps.25.481

计量

文章访问数: 3800
PDF下载量: 89
被引次数: 0

姓名
邮箱
手机号码
标题
留言内容
验证码

搜索

留言板