Dynamics of water temperature and interfacial heat flux in lake ice and under-ice layers

IF 2.7 4区环境科学与生态学 Q2 Environmental Science

Hydrology Research Pub Date : 2023-07-14 DOI:10.2166/nh.2023.013

Jingbo Huo, Xiaohong Shi, Shengnan Zhao, Biao Sun, Guohua Li, Haifeng Yu, Shihuan Wang

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Abstract

The purpose of this study is to understand the temperature dynamics of ice and lake water under ice during ice growth. A vertical temperature monitoring system for ice and water under ice was employed for the first time in Wuliangsuhai Lake from 20 December 2016 to 15 March 2017 to obtain continuous monitoring temperature data necessary for calculating the heat flux density at the ice–water interface. During the ice growth period, the ice body temperature and the water body temperature under the ice show an obvious rising trend from the upper layer to the lower layer. As the ice body enters the melting period, the ice temperature and the water temperature under the ice begin to change rapidly. In the presence of snow over the ice, the fluctuations of ice temperature and water temperature under the ice remain stable. According to the experimental data, the analytical equation derived from the Stefan condition is used to calculate the heat flux at the intersection boundary of ice body and water body under ice, which varies from 1.73 to 19.6 W/m2. The dynamic change of ice thickness is significantly influenced by the temperature of ice and water and the heat flux density at the ice–water interface.

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湖冰和冰下层的水温和界面热通量动力学

本研究的目的是了解冰生长过程中冰和冰下湖水的温度动态。2016年12月20日至2017年3月15日，在乌梁素海首次采用冰下冰和水的垂直温度监测系统，以获得计算冰-水界面热通量密度所需的连续监测温度数据。在冰生长期，冰体温度和冰下水体温度从上层向下层呈明显上升趋势。随着冰体进入融化期，冰的温度和冰下的水温开始迅速变化。在冰上有雪的情况下，冰温度和冰下水温的波动保持稳定。根据实验数据，利用Stefan条件导出的解析方程计算了冰下水体与冰体相交边界处的热通量，其变化范围为1.73~19.6W/m2。冰厚度的动态变化受到冰和水的温度以及冰-水界面处的热通量密度的显著影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Hydrology Research Environmental Science-Water Science and Technology

CiteScore

5.30

自引率

7.40%

发文量

审稿时长

17 weeks

期刊介绍： Hydrology Research provides international coverage on all aspects of hydrology in its widest sense, and welcomes the submission of papers from across the subject. While emphasis is placed on studies of the hydrological cycle, the Journal also covers the physics and chemistry of water. Hydrology Research is intended to be a link between basic hydrological research and the practical application of scientific results within the broad field of water management.

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