Study on Acoustic Variability Affected by Upper Ocean Dynamics in South Eastern Arabian Sea

IF 2.9 3区 地球科学 Q2 ASTRONOMY & ASTROPHYSICS
Kotta Srinivasu, M. C. Sanjana, G. Latha, T. V. S. Udaya Bhaskar, Hasibur Rahaman, A. Thirunavukkarasu, R Venkatesan
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Abstract

The influence of upper ocean dynamics on the acoustic field in the South Eastern Arabian Sea (SEAS) is studied using in situ oceanographic/acoustic measurements from a moored buoy, along with satellite-derived and climatological data sets. Upper-ocean variability at the site is quantified using Mixed Layer Depth (MLD), Isothermal Layer Depth (ILD), Barrier Layer Thickness (BLT), Maximum Spice Depth (MSD), and Sonic Layer Depth (SLD), along with surface variability factors such as Sea Surface Temperature, Sea Surface Salinity, Spice, and Sea Level Anomaly. The mixed layer acoustic duct (MLAD) varies from 2 to 100 m, with BLT varying from 5 to 99 m, and a mean SLD of 43 m. A thick transition layer connects the mixed layer with the thermocline during winter. The observations reveal that maximum SLD, MSD, and BLT occurred during January–March. Unlike other seasons when SLD follows MLD, winter SLD is influenced by BLT, suggesting strong salinity stratification due to low-salinity water intrusion from the Bay of Bengal by East India Coastal Current. During these months, the SLD varies from 80 to 100 m, with the corresponding minimum cut-off frequency varying from 300 to 200 Hz. Results are correlated with estimated Sound Pressure Level (SPL) from Ambient Noise Measurements during November 2018 to November 2019. SPL variation follows SLD for low and mid-frequencies, with the highest SPL noted during January-February. Acoustic propagation simulations at 250 and 1,000 Hz revealed features like acoustic duct leakage and channeling, indicating energy transfers between the surface acoustic duct and deeper layers.

Abstract Image

受阿拉伯海东南部上层海洋动力学影响的声学可变性研究
利用系泊浮标的现场海洋学/声学测量数据以及卫星和气候学数据集,研究了上层海洋动力学对阿拉伯海东南部(SEAS)声场的影响。利用混合层深度(MLD)、等温层深度(ILD)、障碍层厚度(BLT)、最大辣度深度(MSD)和声波层深度(SLD),以及海面温度、海面盐度、辣度和海平面异常等海面变化因素,对该地点的上层海洋变化进行了量化。混合层声导管(MLAD)在 2 至 100 米之间变化,BLT 在 5 至 99 米之间变化,平均 SLD 为 43 米。观测结果表明,最大 SLD、MSD 和 BLT 出现在 1-3 月份。与其他季节的 SLD 随 MLD 变化不同,冬季 SLD 受 BLT 影响,这表明东印度沿岸流从孟加拉湾入侵的低盐度海水造成了强烈的盐度分层。在这几个月中,SLD 在 80 米至 100 米之间变化,相应的最小截止频率在 300 赫兹至 200 赫兹之间变化。结果与 2018 年 11 月至 2019 年 11 月期间环境噪声测量的估计声压级 (SPL) 相关联。低频和中频的声压级变化与 SLD 一致,1 月至 2 月期间的声压级最高。250 和 1,000 Hz 的声传播模拟显示了声导管泄漏和通道等特征,表明表层声导管和深层之间存在能量转移。
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来源期刊
Earth and Space Science
Earth and Space Science Earth and Planetary Sciences-General Earth and Planetary Sciences
CiteScore
5.50
自引率
3.20%
发文量
285
审稿时长
19 weeks
期刊介绍: Marking AGU’s second new open access journal in the last 12 months, Earth and Space Science is the only journal that reflects the expansive range of science represented by AGU’s 62,000 members, including all of the Earth, planetary, and space sciences, and related fields in environmental science, geoengineering, space engineering, and biogeochemistry.
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