DOI: 10.5194/tc-14-3707-2020
论文题名: High-resolution simulations of interactions between surface ocean dynamics and frazil ice
作者: Herman A. ; Dojczman M. ; Åšwiszcz K.
刊名: Cryosphere
ISSN: 19940416
出版年: 2020
卷: 14, 期: 11 起始页码: 3707
结束页码: 3729
语种: 英语
英文关键词: air temperature
; buoyancy
; heat transfer
; hydrodynamics
; mixed layer
; sea ice
; sea surface
; three-dimensional modeling
; volume change
英文摘要: Frazil and grease ice forms in the ocean mixed layer (OML) during highly turbulent conditions (strong wind, large waves) accompanied by intense heat loss to the atmosphere. Three main velocity scales that shape the complex, three-dimensional (3D) OML dynamics under those conditions are the friction velocity u* at the ocean-atmosphere interface, the vertical velocity w* associated with convective motion, and the vertical velocity w*; L associated with Langmuir turbulence. The fate of buoyant particles, e.g., frazil crystals, in that dynamic environment depends primarily on their floatability, i.e., the ratio of their rising velocity wt to the characteristic vertical velocity, which is dependent on w* and w*; L. In this work, the dynamics of frazil ice is investigated numerically with the high-resolution, nonhydrostatic hydrodynamic model CROCO (Coastal and Regional Ocean COmmunity Model), extended to account for frazil transport and its interactions with surrounding water. An idealized model setup is used (a square computational domain with periodic lateral boundaries, spatially uniform atmospheric and wave forcing). The model reproduces the main features of buoyancy- and wave-forced OML circulation, including the preferential concentration of frazil particles in elongated patches at the sea surface. Two spatial patterns are identified in the distribution of frazil volume fraction at the surface: one related to individual surface convergence zones, very narrow, and oriented approximately parallel to the wind/wave direction and one in the form of wide streaks with a separation distance of a few hundred meters, oriented obliquely to the direction of the forcing. Several series of simulations are performed, differing in terms of the level of coupling between the frazil and hydrodynamic processes, from a situation when frazil has no influence on hydrodynamics (as in most models of material transport in the OML) to a situation in which frazil modifies the net density, effective viscosity, and transfer coefficients at the ocean-atmosphere interface and exerts a net drag force on the surrounding water. The role of each of those effects in shaping the bulk OML characteristics and frazil transport is assessed, and the density of the ice-water mixture is found to have the strongest influence on those characteristics. © Author(s) 2020. Citation statistics:
资源类型: 期刊论文
标识符: http://119.78.100.158/handle/2HF3EXSE/164477
Appears in Collections: 气候变化与战略
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作者单位: Institute of Oceanography, University of Gdańsk, Gdańsk, Poland; Faculty of Physics, University of Warsaw, Warsaw, Poland
Recommended Citation:
Herman A.,Dojczman M.,Åšwiszcz K.. High-resolution simulations of interactions between surface ocean dynamics and frazil ice[J]. Cryosphere,2020-01-01,14(11)