Turbulence Characteristics of Ice-Free Radiatively Driven Convection in a Deep, Unstratified Lake

IF 4.6 1区地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY

Geophysical Research Letters Pub Date : 2025-04-01 DOI:10.1029/2024GL112607

Kenneth Larrieu, Oscar Sepúlveda Steiner, Drew M. Friedrichs, Jasmin B. T. McInerney, Jay A. Austin, Alexander L. Forrest

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Abstract

This study examines data collected with an autonomous underwater glider during a period of vigorous radiatively driven convection (RDC) and low winds in deep, unstratified Lake Superior. Conductivity, temperature and depth (CTD) measurements reveal distinct convective plumes of warm downwelling water with temperature anomalies of $\sim 0.1 °$ C and width scales on the order of $10 - 100$ m, consistent with theoretical scalings for the unstratified convective regime. Shear and temperature microstructure measurements indicate turbulent kinetic energy (TKE) dissipation $(ε)$ and temperature variance dissipation rates $(χ_{T})$ orders of magnitude greater in thermal plumes than laterally adjacent waters. Decay timescales of $ε$ indicate highly efficient mixing is sustained throughout the night. Energetics, mixing efficiency, and constraints on convective plume scales are also discussed. These observations demonstrate that RDC can dominate vertical mixing dynamics even in deep ice-free systems, and these systems can serve as a real-scale laboratory for investigation of convective dynamics.

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深非分层湖泊无冰辐射驱动对流的湍流特征

本研究考察了在深无分层的苏必利尔湖强烈辐射驱动对流（RDC）和低风期间用自主水下滑翔机收集的数据。电导率，温度和深度（CTD）测量显示明显的对流羽流，温度异常为～ 0.1°${\sim} 0.1{}^{\circ}$ C，宽度尺度为10−100 $10-100$M，与非分层对流状态的理论标度一致。剪切和温度微观结构测量表明湍流动能（TKE）耗散（ε） $(\varepsilon )$和温度方差耗散率χ T$\left({\chi }_{T}\right)$在热羽流中的数量级大于横向相邻水域。ε $\varepsilon $的衰减时间尺度表明，整个晚上都保持着高效的混合。讨论了对流羽流尺度的能量学、混合效率和约束条件。这些观测结果表明，即使在深层无冰系统中，RDC也可以主导垂直混合动力学，这些系统可以作为研究对流动力学的真实尺度实验室。

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来源期刊

Geophysical Research Letters 地学-地球科学综合

CiteScore

9.00

自引率

9.60%

发文量

1588

审稿时长

2.2 months

期刊介绍： Geophysical Research Letters (GRL) publishes high-impact, innovative, and timely research on major scientific advances in all the major geoscience disciplines. Papers are communications-length articles and should have broad and immediate implications in their discipline or across the geosciences. GRLmaintains the fastest turn-around of all high-impact publications in the geosciences and works closely with authors to ensure broad visibility of top papers.