Atmospheric Turbulent Intermittency Over the Arctic Sea‐Ice Surface During the MOSAiC Expedition

Liu, Changwei; Yang, Qinghua; Shupe, Matthew D.; Ren, Yan; Chen, Taigui; Han, Bo; Chen, Dake

doi:10.1029/2023jd038639

JGR Atmospheres

2023

DOI: 10.1029/2023jd038639

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Atmospheric Turbulent Intermittency Over the Arctic Sea‐Ice Surface During the MOSAiC Expedition

Changwei Liu

Qinghua Yang

Matthew D. Shupe

et al.

Abstract: Turbulent motions in the Arctic stable boundary layer are characterized by intermittency, but they are rarely investigated due to limited observations, in particular over the sea‐ice surface. In the present study, we explore the characteristics of turbulent intermittency over the Arctic sea‐ice surface using data collected during the Multidisciplinary drifting Observation for the Study of Arctic Climate expedition from October 2019 to September 2020. We first develop a new algorithm, which performs well in ide… Show more

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2024

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Cited by 3 publications

References 68 publications

(97 reference statements)

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The characteristics of turbulence intermittency and its impact on surface energy imbalance over Loess Plateau

Chang,

Ren,

Zhang

et al. 2024

Agricultural and Forest Meteorology

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The characteristics of turbulence intermittency and its impact on surface energy imbalance over Loess Plateau

Chang,

Ren,

Zhang

et al. 2024

Agricultural and Forest Meteorology

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The Vertical Structure of Turbulence Kinetic Energy Near the Arctic Sea‐Ice Surface

Peng,

Yang,

Shupe

et al. 2024

Geophysical Research Letters

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Atmospheric turbulence over the Arctic sea‐ice surface has been understudied due to the lack of observational data. In this study, we focus on the turbulence kinetic energy (TKE) over sea ice and distinguish its two different vertical structures, the “Surface” type and the “Elevated” type, using observations during the Multidisciplinary drifting Observatory for the Study of Arctic Climate expedition (MOSAiC). The “Surface” type has the maximum TKE near the surface (at 2 m), while the “Elevated” type has the maximum TKE at a higher level (6 m). The TKE budget analysis indicates that the “Elevated” type is caused by the increased shear production of TKE at 6 m. In addition, spectral analysis reveals that the contribution to TKE by horizontal large eddies is enhanced in the “Elevated” type. Finally, how the vertical structure of TKE affects the parameterization of turbulent momentum flux is discussed.

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A model-based study of the dynamics of Arctic low-level jet events for the MOSAiC drift

Heinemann,

Schefczyk,

Zentek

2024

Elem Sci Anth

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Low-level jets (LLJs) are studied for the period of the ship-based experiment MOSAiC 2019/2020 using the regional climate model Consortium for Small-scale Model—Climate Limited area Mode (CCLM). The model domain covers the whole Arctic with 14 km resolution. CCLM is run in a forecast mode (nested in ERA5) and with different configurations of sea ice data for the winter. The focus is on the study of LLJs for the MOSAiC site. LLJs are detected using model output every 1 h. We define LLJ events as LLJs that last at least 6 h. Case studies of LLJ events are shown using wind lidar and radiosonde data as well as CCLM simulations. LLJs are not local events but are embedded in large jet structures extending for hundreds of kilometers that are advected toward the MOSAiC site. CCLM simulations are used to study the statistics of LLJs of all profiles and of LLJ events as well as the dynamics. LLJs are found in about 40% of the hourly profiles, but only 26% of the hourly profiles are associated with LLJ events. Strong LLJs (≥15 m/s) are detected in 13% of the hourly profiles, which is about the same fraction as for strong LLJ events. The mean duration of events is about 12 h. The LLJ events are characterized using dynamical criteria for the wind speed profile and the evolution of the jet core. A fraction of 35% of the LLJ events are baroclinic, but more than 40% of the LLJ events show a large contribution of advection to the initial generation as well as for the evolution of the jet core. Only very few events fulfill the criteria of inertial oscillations. LLJ events occur for all months, but strong events have a higher frequency during winter. The turbulent kinetic energy in the lower atmospheric boundary layer (ABL) is twice (4 times) as large for LLJs (strong LLJs) than for situations without LLJs, which underlines the impact of LLJs on turbulent processes in the ABL.

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Atmospheric Turbulent Intermittency Over the Arctic Sea‐Ice Surface During the MOSAiC Expedition

Cited by 3 publications

References 68 publications

The characteristics of turbulence intermittency and its impact on surface energy imbalance over Loess Plateau

The characteristics of turbulence intermittency and its impact on surface energy imbalance over Loess Plateau

The Vertical Structure of Turbulence Kinetic Energy Near the Arctic Sea‐Ice Surface

A model-based study of the dynamics of Arctic low-level jet events for the MOSAiC drift

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