Abstract
Aimed at the explanation of clear tidal signal and storm surge signals in a closed inland lake near the coast (the Huguangyan Lake), this work uses a combined approach with observations and model experiments. Huguangyan Lake is a closed inland freshwater coneless volcanic crater lake near the coast in tropical southern China, less than 5 km from an estuary. It has a diameter of about 1.5 km and relatively deep water of up to 20 m. Bottom pressure was measured from an acoustic Doppler current profiler (ADCP) for 10 days in September 2018 and 10 days in January 2019. The observations encompass the period of Typhoon Mangkhut, which passed the region when it made its landfall. The time series demonstrate clear tidal and subtidal signals. The tidal signal remains even if we exclude the barometric pressure effect. Interestingly, the lake has no surface connection with the ocean. The astronomical tide has an amplitude of about 2 cm. The major tidal signals include the principal solar semidiurnal (S2) and lunisolar (K1) constituents. During the passage of Typhoon Mangkhut, the water level variability inside the lake increased by an order of magnitude (>0.3 m). To examine whether the lake water level change was due to the natural oscillations inside the lake (or seiche), a numerical wind-driven hydrodynamics model was designed using the 3-D Finite Volume Community Ocean Model (FVCOM). The results show that a small first-order seiche can be generated, but only with a time scale of minutes and with a magnitude much smaller than the observed surface elevation changes. This excludes any measurable seiche and the observed surface elevation change inside the lake cannot be wind-driven. Moreover, tides inside the lake are not generated by tidal potential, as the lake is too small for having a locally generated tide. The main result of our study has therefore excluded the local tidal-generating force, wind-driven seiche, and barometric effect, as possible causes of the lake oscillation which has tidal and subtidal signals. The subtidal variation is at least one order of magnitude greater than tides inside the lake and is caused by weather-induced overall coastal ocean water level oscillations transmitted into the lake through groundwater connection. All these lead to the major conclusion that the lake is connected to the coastal ocean through groundwater.
Highlights
The distinct periodical fluctuations with different frequencies can be seen in the water level record in the Huguangyan Lake
Intrigued by abnormal water level variations with apparent tidal variations in an enclosed small freshwater Huguangyan Lake, we launched a study with observations and numerical experiments
The water level variations show a mixed tidal signal, with both semi-diurnal and diurnal tidal constituents of comparable magnitudes. These are, much larger than what the local tidal potential can allow because the lake is too shallow and too small to have measurable tide generated by tide-generating force or from the Earth’s tides
Summary
A maar lake is a freshwater lake formed by groundwater and/or precipitation fillingA maarvolcanic lake is adepression.freshwater The lake distinction formed by groundwater precipitation filling an ancient of maar lakes and/or from other crater lakes are an ancient volcanic depression.The distinction of maar lakes from other crater lakes are their low-relief terrain, because the corresponding volcanic explosion occurred in plains their low-relief terrain, corresponding volcanic occurred plains and the eruption led tobecause a direct the contact of groundwater withexplosion hot lava or magma.inTypical and the eruption led to a direct contact of groundwater with hot lava or magma.Typical maar lakes have horizontal scales between 60 and 8000 m with a water depth of 10 to 200 m.maar lakeslake have scales between 60 and8000itmshould with anot water depth10 signal, to 200If a maar is horizontal not connected with the coastal ocean, have any of tidal m.If a maar lake is not connected with the coastal ocean, it should not have any tidal as tidal potential in such a small system is negligible. A maar lake is a freshwater lake formed by groundwater and/or precipitation filling. Freshwater The lake distinction formed by groundwater precipitation filling an ancient of maar lakes and/or from other crater lakes are an ancient volcanic depression. The distinction of maar lakes from other crater lakes are their low-relief terrain, because the corresponding volcanic explosion occurred in plains their low-relief terrain, corresponding volcanic occurred plains and the eruption led tobecause a direct the contact of groundwater withexplosion hot lava or magma.inTypical and the eruption led to a direct contact of groundwater with hot lava or magma. Typical maar lakes have horizontal scales between 60 and 8000 m with a water depth of 10 to 200 m. If a maar is horizontal not connected with the coastal ocean, have any of tidal m. If a maar lake is not connected with the coastal ocean, it should not have any tidal as tidal potential in such a small system is negligible
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
