Cloud-Resolving ICON Simulations of Secondary Ice Production in Arctic Mixed-Phase Stratocumuli Observed during M-PACE

IF 3 3区 地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES
A. Possner, K. Pfannkuch, V. Ramadoss
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Abstract

Field measurements and modeling studies suggest that secondary ice production (SIP) may close the gap between observed Arctic ice nucleating particle (INP) concentrations and ice crystal number concentrations (ni). Here, we explore sensitivities with respect to the complexity of different INP parameterizations under the premise that ni is governed by SIP. Idealized, cloud-resolving simulations are performed for the marine cold air outbreak cloud deck sampled during M-PACE with the ICOsahedralNonhydrostatic (ICON) model. The impact of the droplet shattering (DS) of raindrops and collisional breakup (BR) in addition to the existing Hallet-Mossop rime splintering mechanism were investigated. Overall, 12 different model experiments (12 h runs) were performed and analyzed. Despite the considerable amount of uncertainty remaining with regard to SIP mechanisms and their process representation in numerical models, we conclude from these experiments that: (i) only simulations where DS dominates the SIP signal (potentially amplified by BR) capture observed ice-phase and liquid-phase cloud properties, and (ii) SIP events cluster around the convective outflow region and are structurally linked to mesoscale cloud organization. In addition, interactions with primary nucleation parameterizations of varied complexity were investigated. Here, our simulations show that: (i) a stable long-lived mixed-phase cloud (MPC) can be maintained in the absence of primary nucleation once SIP is established, (ii) experiments using a computationally more efficient relaxation-based parameterization of primary nucleation are statistically invariant from simulations considering prognostic INP, and (iii) primary nucleation at cloud-top controls the areal extent of the mixed-phase cloud region, and reduces SIP efficacy via DS due increased depletion of cloud liquid throughout the entire cloud column.
M-PACE 期间观测到的北极混合相层积物中二次生冰的云解析 ICON 模拟
实地测量和建模研究表明,二次产冰(SIP)可能会缩小观测到的北极冰核粒子(INP)浓度与冰晶数量浓度(ni)之间的差距。在此,我们探讨了在 ni 受 SIP 控制的前提下,不同 INP 参数化复杂性的敏感性。我们利用 ICOsahedralNonhydrostatic(ICON)模型对 M-PACE 期间采样的海洋冷空气爆发云层进行了理想化的云解析模拟。除了现有的 Hallet-Mossop 雨滴碎裂机制外,还研究了雨滴碎裂(DS)和碰撞破裂(BR)的影响。总共进行了 12 次不同的模型实验(运行 12 小时)并进行了分析。尽管 SIP 机制及其在数值模型中的过程表示还存在相当大的不确定性,但我们从这些实验中得出以下结论(i) 只有 DS 主导 SIP 信号(可能被 BR 放大)的模拟才能捕捉到观测到的冰相和液相云特性;(ii) SIP 事件聚集在对流流出区域周围,在结构上与中尺度云组织有关。此外,我们还研究了与不同复杂程度的原核参数的相互作用。模拟结果表明(i) 一旦建立了 SIP,在没有原生核化的情况下也能维持稳定的长寿命混相云 (MPC);(ii) 使用计算效率更高的基于弛豫的原生核化参数化的实验与考虑预报 INP 的模拟在统计上是不变的;(iii) 云顶的原生核化控制混相云区域的面积范围,并通过 DS 降低 SIP 效应,因为整个云柱的云液消耗增加了。
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来源期刊
Journal of the Atmospheric Sciences
Journal of the Atmospheric Sciences 地学-气象与大气科学
CiteScore
0.20
自引率
22.60%
发文量
196
审稿时长
3-6 weeks
期刊介绍: The Journal of the Atmospheric Sciences (JAS) publishes basic research related to the physics, dynamics, and chemistry of the atmosphere of Earth and other planets, with emphasis on the quantitative and deductive aspects of the subject. The links provide detailed information for readers, authors, reviewers, and those who wish to submit a manuscript for consideration.
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