부산대학교 도서관

The Marginal Ice Zone is a highly dynamic region where the atmosphere, ocean, waves and sea ice meet. Waves play a fundamental role in this coupled system, but progress in our understanding of wave-ice interactions is currently hindered by the lack of observations of sea ice properties in-situ. In this study we aim to estimate the ice thickness and effective elastic modulus of sea ice passively using observations of waves in ice. Specifically, we use three low-cost geophones deployed in triangular formation with sides of about 200 m on fast ice. The focus here is on three major wave events recorded, each consisting of initial high frequency vibrations with a frequency at around 10 Hz, followed by low frequency dispersive waves within a frequency range of 0.08-0.28 Hz. Based on the phase speed of the initial high frequency vibrations, we estimate the purely elastic effective modulus to be 4-4.5 GPa. By comparing the arrival times of the dispersive low frequency wave events to the dispersion relationship of waves in a thin elastic ice sheet we obtain estimates of the effective elastic modulus in the range of 0.4-0.7 GPa. This is close to the measured effective elastic modulus through cantilever experiments of 0.5 GPa but considerably smaller than the default value of 5.5 GPa currently in use in contemporary wave models. We could not, however, obtain explicit estimates of the ice thickness and effective modulus individually as their impacts on the shape of the dispersion relationship are similar in this frequency range. Distinction is only possible for dispersive wave events larger than about 1 Hz, such as for vibrations generated by (thermal) cracking, which are frequently observed in our dataset. With our results, we show that low-cost geophones can be used to estimate sea ice properties in fast ice and substantiate that this to be possible on very large ice floes as well.