Arctic Summer-time Cyclones: Dynamics and Sea-ice Interaction

北极夏季气旋：动力学和海冰相互作用

• 批准号: NE/T006773/1
• 负责人: John Methven
• 金额: $ 49.56万
• 依托单位: University of Reading
• 依托单位国家: 英国
• 项目类别: Research Grant
• 财政年份: 2020
• 资助国家: 英国
• 起止时间: 2020 至 无数据
• 项目状态: 未结题
• 来源: https://gtr.ukri.org/projects?ref=NE%2FT006773%2F1
• 关键词: Arctic; Summer; time; Cyclones; Dynamics

As climate has warmed in response to increasing greenhouse gases, the distribution of Arctic sea ice has changed dramatically, becoming thinner over large portions of the Arctic Ocean basin in summer with a prominent reduction of the September minimum in sea ice extent. Human activity is increasing within the Arctic as the environment changes, with more residents and visitors making use of the increased window for shipping, offshore operations and tourism during summer. This has driven demand for coupled forecasts of weather, ocean and sea-ice state across the Arctic on the timescales needed to make risk-based decisions. Weather forecast skill for the Arctic is lower than for northern mid-latitudes, but the reasons why are multi-faceted and not fully known. Our hypothesis is that some aspects of the Arctic environment are not well forecast because the surface conditions beneath Arctic weather systems are more dynamic due to the movement of sea ice. Understanding of the physical processes that couple the atmosphere, ocean and sea ice is incomplete and the new frontier in prediction is to model this coupled system with fidelity and skill. Centres striving to improve capability in this area are our project partners: the Met Office, ECMWF and Met Norway.Arctic cyclones are the dominant type of hazardous weather system affecting the Arctic environment in summer - thus a concern for all human activities. They can also have critical impacts on the Arctic environment: in particular on sea-ice movement, sometimes resulting in 'Very Rapid Ice Loss Events' (VRILEs - timescale days to weeks) which present a major challenge to coupled forecasts; and on the baroclinicity (temperature gradients) around the Arctic, influencing subsequent weather systems and forecasts of Arctic climate from weeks out to a season ahead.Our proposed observational experiment will be the first focusing on summer-time Arctic cyclones and taking the measurements required to investigate the influence of sea-ice conditions on their development. New observations are needed comprising of turbulent near-surface fluxes of momentum, heat and moisture measured simultaneously with the sea ice or ocean surface beneath the aircraft track and along cyclone-scale transects. These fluxes dictate the impact of the surface on the development of weather systems. We will operate from Svalbard (Norway) in summer 2021, using the British Antarctic Survey's Twin Otter low-flying aircraft equipped to measure turbulence at flight level and the surface properties through infrared and lidar remote sensing.Our US partners, have designed an observational experiment, called THINICE, looking downwards on Arctic cyclone structure from an aircraft flying above the tropopause (10 km). Our projects are co-designed for summer 2021 so that the observations from the Twin Otter will form a bridge between US airborne and satellite measurements above and the properties of the surface fluxes and sea ice beneath.The project brings together expertise in observations, modelling and theoretical approaches to surface exchange, cyclone dynamics and sea-ice physics. We will use novel theoretically-based approaches to interrogate forecast models as they run and determine the mechanisms through which the surface properties alter cyclone growth. The new surface and turbulence data will be used to improve the parametrization of form drag in models that is central to wind forcing of sea-ice motion as well as decelerating surface winds. These aspects will be explored with state-of-the-art atmosphere and sea-ice dynamics models. Finally, we will close the loop through investigation of the effects of increased surface roughness on Arctic cyclones and their coupled interaction with Arctic temperature gradients. A major legacy of the project will be the unprecedented observations that will enable much needed evaluation and development of environmental forecast models for decades to come.

由于温室气体的增加导致气候变暖，北极海冰的分布发生了巨大变化，在夏季北冰洋海盆的大部分地区变得更薄，海冰范围在9月份的最小值显著减少。随着环境的变化，北极地区的人类活动正在增加，越来越多的居民和游客在夏季利用增加的窗口进行航运、海上作业和旅游。这推动了对整个北极地区天气、海洋和海冰状况的耦合预报的需求，这些预报需要在时间尺度上进行，以便做出基于风险的决策。北极地区的天气预报能力低于中纬度北部地区，但其原因是多方面的，目前还不完全清楚。我们的假设是，北极环境的某些方面无法很好地预测，因为北极天气系统下的表面条件由于海冰的运动而更加动态。对耦合大气、海洋和海冰的物理过程的了解尚不完整，预测的新前沿是用精确和技巧模拟这种耦合系统。努力提高这一领域能力的中心是我们的项目合作伙伴：英国气象局、欧洲气象局和挪威气象局。北极气旋是夏季影响北极环境的主要危险天气系统类型，因此是所有人类活动关注的问题。它们还可能对北极环境产生重大影响：特别是对海冰运动，有时会导致“非常迅速的冰损失事件”（VRILEs——时间尺度为几天到几周），这对耦合预报构成了重大挑战；以及北极周围的斜压性（温度梯度），影响随后的天气系统和未来几周到一个季节的北极气候预报。我们提出的观测实验将是第一个关注夏季北极气旋的实验，并采取必要的测量来调查海冰条件对其发展的影响。新的观测需要包括湍流近地表动量、热量和水分的通量，同时与飞机轨道下的海冰或海洋表面以及沿着气旋尺度的横断面测量。这些通量决定了地表对天气系统发展的影响。我们将于2021年夏天在斯瓦尔巴群岛（挪威）开展业务，使用英国南极调查局的双水獭低空飞行飞机，通过红外和激光雷达遥感测量飞行水平的湍流和表面特性。我们的美国合作伙伴设计了一个名为THINICE的观测实验，从对流层顶（10公里）上方飞行的飞机上向下观察北极气旋结构。我们的项目是在2021年夏季共同设计的，因此“双水獭”号的观测结果将在美国空中和卫星测量结果与地面通量和海冰特性之间架起一座桥梁。该项目汇集了观测、建模和表面交换、气旋动力学和海冰物理学的理论方法方面的专业知识。我们将使用新颖的理论为基础的方法来询问预报模型，因为他们运行和确定的机制，通过表面性质改变气旋的增长。新的地表和湍流数据将用于改进模型中形式阻力的参数化，这是海冰运动的风强迫以及地面风减速的核心。这些方面将探索与最先进的大气和海冰动力学模型。最后，我们将通过研究地表粗糙度增加对北极气旋的影响以及它们与北极温度梯度的耦合相互作用来闭合这个循环。该项目的一个主要遗产将是前所未有的观测，这将使未来几十年急需的环境预测模型的评估和开发成为可能。

项目成果

The role of tropopause polar vortices in the intensification of summer Arctic cyclones

对流层顶极地涡旋在夏季北极气旋增强中的作用

• DOI: 10.5194/wcd-2021-30
• 发表时间: 2021
• 作者: Gray S

The role of boundary layer processes in summer-time Arctic cyclones

边界层过程在夏季北极气旋中的作用

• DOI: 10.5194/wcd-2022-60
• 发表时间: 2022
• 作者: Croad H

A Climatology of Summer-Time Arctic Cyclones Using a Modified Phase Space

使用修正相空间的夏季北极气旋气候学

• DOI: 10.1029/2023gl105993
• 发表时间: 2023
• 期刊: Geophysical Research Letters
• 影响因子: 5.2
• 作者: Croad H