Evaluating Arctic clouds modelled with the Unified Model and Integrated Forecasting System

Abstract. By synthesising remote-sensing measurements made in the central Arctic into a model-gridded Cloudnet cloud product, we evaluate how well the Met Office Unified Model (UM) and European Centre for Medium-Range Weather Forecasting Integrated Forecasting System (IFS) capture Arctic clouds and their associated interactions with the surface energy balance and the thermodynamic structure of the lower troposphere. This evaluation was conducted using a four-week observation period from the Arctic Ocean 2018 expedition, where the transition from sea ice melting to freezing conditions was measured. Three different cloud schemes were tested within a nested limited area model (LAM) configuration of the UM – two regionally-operational single-moment schemes (UM_RA2M and UM_RA2T), and one novel double-moment scheme (UM_CASIM-100) – while one global simulation was conducted with the IFS, utilising its default cloud scheme (ECMWF_IFS). Consistent weaknesses were identified across both models, with both the UM and IFS overestimating cloud occurrence below 3 km. This overestimation was also consistent across the three cloud configurations used within the UM framework, with > 90 % mean cloud occurrence simulated between 0.15 and 1 km in all model simulations. However, the cloud microphysical structure, on average, was modelled reasonably well in each simulation, with the cloud liquid water content (LWC) and ice water content (IWC) comparing well with observations over much of the vertical profile. The key microphysical discrepancy between the models and observations was in the LWC between 1 and 3 km, where most simulations (all except UM_RA2T) overestimated the observed LWC. Despite this reasonable performance in cloud physical structure, both models failed to adequately capture cloud-free episodes: this consistency in cloud cover likely contributes to the ever-present near-surface temperature bias simulated in every simulation. Both models also consistently exhibited temperature and moisture biases below 3 km, with particularly strong cold biases coinciding with the overabundant modelled cloud layers. These biases are likely due to too much cloud top radiative cooling from these persistent modelled cloud layers and were interestingly consistent across the three UM configurations tested, despite differences in their parameterisations of cloud on a sub-grid-scale. Alarmingly, our findings suggest that these biases in the regional model were inherited from the driving model, thus triggering too much cloud formation within the lower troposphere. Using representative cloud condensation nuclei concentrations in our double-moment UM configuration, while improving cloud microphysical structure, does little to alleviate these biases; therefore, no matter how comprehensive we make the cloud physics in the nested LAM configuration used here, its cloud and thermodynamic structure will continue to be overwhelmingly biased by the meteorological conditions of its driving model.

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A New Double-Moment Microphysics Parameterization for Application in Cloud and Climate Models. Part II: Single-Column Modeling of Arctic Clouds

Journal of the Atmospheric Sciences ◽

10.1175/jas3447.1 ◽

2005 ◽

Vol 62 (6) ◽

pp. 1678-1693 ◽

Cited By ~ 72

Author(s):

H. Morrison ◽

J. A. Curry ◽

M. D. Shupe ◽

P. Zuidema

Keyword(s):

Climate Models ◽

Heat Budget ◽

Number Concentration ◽

The Arctic ◽

Liquid Water Path ◽

Microphysics Scheme ◽

Radiative Fluxes ◽

Arctic Clouds ◽

Single Column ◽

Double Moment

Abstract The new double-moment microphysics scheme described in Part I of this paper is implemented into a single-column model to simulate clouds and radiation observed during the period 1 April–15 May 1998 of the Surface Heat Budget of the Arctic (SHEBA) and First International Satellite Cloud Climatology Project (ISCCP) Regional Experiment–Arctic Clouds Experiment (FIRE–ACE) field projects. Mean predicted cloud boundaries and total cloud fraction compare reasonably well with observations. Cloud phase partitioning, which is crucial in determining the surface radiative fluxes, is fairly similar to ground-based retrievals. However, the fraction of time that liquid is present in the column is somewhat underpredicted, leading to small biases in the downwelling shortwave and longwave radiative fluxes at the surface. Results using the new scheme are compared to parallel simulations using other microphysics parameterizations of varying complexity. The predicted liquid water path and cloud phase is significantly improved using the new scheme relative to a single-moment parameterization predicting only the mixing ratio of the water species. Results indicate that a realistic treatment of cloud ice number concentration (prognosing rather than diagnosing) is needed to simulate arctic clouds. Sensitivity tests are also performed by varying the aerosol size, solubility, and number concentration to explore potential cloud–aerosol–radiation interactions in arctic stratus.

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Supplementary material to "Evaluating Arctic clouds modelled with the Unified Model and Integrated Forecasting System"

10.5194/acp-2021-662-supplement ◽

2021 ◽

Author(s):

Gillian Young ◽

Jutta Vüllers ◽

Peggy Achtert ◽

Paul Field ◽

Jonathan J. Day ◽

...

Keyword(s):

Unified Model ◽

Arctic Clouds ◽

Forecasting System ◽

Supplementary Material

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Seasonal Prediction Skill of Northern Extratropical Surface Temperature Driven by the Stratosphere

Journal of Climate ◽

10.1175/jcli-d-16-0475.1 ◽

2017 ◽

Vol 30 (12) ◽

pp. 4463-4475 ◽

Cited By ~ 26

Author(s):

Liwei Jia ◽

Xiaosong Yang ◽

Gabriel Vecchi ◽

Richard Gudgel ◽

Thomas Delworth ◽

...

Keyword(s):

Climate Model ◽

Lower Troposphere ◽

Polar Vortex ◽

Seasonal Prediction ◽

The Arctic ◽

Northern Eurasia ◽

Stratospheric Polar Vortex ◽

Near Surface ◽

Predictive Skill

This study explores the role of the stratosphere as a source of seasonal predictability of surface climate over Northern Hemisphere extratropics both in the observations and climate model predictions. A suite of numerical experiments, including climate simulations and retrospective forecasts, are set up to isolate the role of the stratosphere in seasonal predictive skill of extratropical near-surface land temperature. It is shown that most of the lead-0-month spring predictive skill of land temperature over extratropics, particularly over northern Eurasia, stems from stratospheric initialization. It is further revealed that this predictive skill of extratropical land temperature arises from skillful prediction of the Arctic Oscillation (AO). The dynamical connection between the stratosphere and troposphere is also demonstrated by the significant correlation between the stratospheric polar vortex and sea level pressure anomalies, as well as the migration of the stratospheric zonal wind anomalies to the lower troposphere.

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In-situ sounding of radiation flux profiles through the Arctic lower troposphere

10.5194/amt-2018-173 ◽

2018 ◽

Cited By ~ 1

Author(s):

Ralf Becker ◽

Marion Maturilli ◽

Rolf Philipona ◽

Klaus Behrens

Keyword(s):

Surface Composition ◽

Lower Troposphere ◽

Time Frame ◽

The Arctic ◽

Heating Rates ◽

Heterogeneous Terrain ◽

Near Surface ◽

Clear Sky ◽

Radiation Fluxes

Abstract. In-situ profiles of all four net radiation components were obtained at Ny Ålesund/Svalbard (78.9° N, 11.9° E) in the time frame May 04–21, 2015. Measurements could be performed using adapted high quality instrumentation classified as secondary standard carried by a tethered balloon system. Balloon lifted measurements of albedo under clear sky conditions demonstrate the altitude dependence of this parameter over heterogeneous terrain. Depending on the surface composition within the sensor's footprint, the albedo over predominantly snow covered surfaces was found to decrease to 53.4 % and 35.8 % compared to 73.1 % and 78.8 % measured with near surface references, respectively. Albedo profiles show an all-sky maximum at 150 m above surface level, and an averaged vertical change rate of −2.1 %/100 m (clear sky) and −3.4 %/100 m (overcast) above. Profiling of arctic low-level clouds reveals distinct vertical gradients in all radiation fluxes but longwave upward. Observed radiative cooling at cloud top with heating rates of −53 to −84 K/d in subsequent observations tend to be lower than suggested by 1-D simulations.

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Evaluating Arctic meteorology modelled with the Unified Model and Integrated Forecasting System

10.5194/egusphere-egu2020-9643 ◽

2020 ◽

Author(s):

Gillian Young ◽

Jutta Vüllers ◽

Peggy Achtert ◽

Paul Field ◽

Jonathan Day ◽

...

Keyword(s):

Boundary Layer ◽

Sea Ice ◽

Weather Forecasting ◽

Numerical Models ◽

Model Performance ◽

High Arctic ◽

Unified Model ◽

Surface Energy Budget ◽

The Arctic ◽

Forecasting System

State-of-the-art numerical models such as the UK Met Office Unified Model and European Centre for Medium-Range Weather Forecasting Integrated Forecasting System are crucial tools for forecasting future Arctic warming. However, their ability to reproduce clouds and boundary layer meteorology in the high Arctic has not been thoroughly evaluated following significant model developments over the last 10 years. Model evaluation is key to understanding where remaining process weaknesses lie, thus informing further parametrization developments to improve the simulated surface energy budget.Here, we evaluate model performance with comparison to observations made during the Arctic Ocean 2018 expedition, where a suite of remote-sensing instrumentation was active aboard the Swedish icebreaker Oden measuring summertime Arctic cloud and boundary layer properties. We find that both models do not reproduce cloud fractions well at altitude (up to 8 km) and overestimate the occurrence of low (<1 km) clouds during the sea ice melt period of the expedition. Low cloud agreement with observations improves when the sea ice begins to refreeze; however, the underestimation of cloud aloft remains consistent regardless of sea ice conditions. In this presentation, we will indicate which model processes need to be improved to capture these summertime Arctic clouds more effectively.

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Modulation of PDO in the Arctic tropospheric warming

10.5194/egusphere-egu2020-9281 ◽

2020 ◽

Author(s):

Lingling Suo ◽

Yongqi Gao ◽

Guillaume Gastineau ◽

Yu-Chiao Liang ◽

Rohit Ghosh ◽

...

Keyword(s):

Model Simulation ◽

Winter Season ◽

Lower Troposphere ◽

Warming Trend ◽

Arctic Sea Ice ◽

The Arctic ◽

Joint Analysis ◽

Near Surface ◽

Arctic Warming ◽

Surface Warming

The Arctic amplified warming under global warming is one of the prominent climate change events during the past several decades. Arctic sea ice retreat contributed the majority of the near-surface warming, and little to the mid-troposphere warming. The remote factors might contribute to or modulate the aloft Arctic warming.Here we performed a multi-model joint-analysis to study the role of the Pacific decadal oscillation, which is one of the most important recurring ocean-atmosphere variability in the climate system, in the tropospheric Arctic warming. In the multi-model simulation, PDO reduced the Arctic warming trend during 1979-2013 significantly in spring, Autumn and early winter season from the near-surface to the upper troposphere. The reduction of warming reaches 0.3 / 0.2 &#176;C per decade in the upper / lower troposphere.

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Evaluating the Lower Tropospheric COSMIC GPS Radio Occultation Sounding Quality over the Arctic

10.5194/amt-2017-230 ◽

2017 ◽

Author(s):

Xiao Yu ◽

Feiqin Xie ◽

Chi O. Ao

Keyword(s):

Data Processing ◽

Radio Occultation ◽

Lower Troposphere ◽

Parametric Uncertainty ◽

Ocean Surface ◽

Specific Humidity ◽

The Arctic ◽

Near Surface ◽

High Vertical Resolution ◽

Active Research

Abstract. Lower tropospheric moisture and temperature measurements are crucial for understanding weather predication and climate change. Global Positioning System radio occultation (GPS RO) has been demonstrated as a high-quality observation with high-vertical-resolution and sub-Kelvin temperature precision from the upper troposphere to the stratosphere. In the tropical lower troposphere, particularly the lowest 2 km, the quality of RO retrievals is known to be degraded and is a topic of active research. However, it is not clear whether similar problems exist in the high latitudes, particularly over the Artic, which is characterized by smooth ocean surface and often negligible moisture in the atmosphere. In this study, three-year (2008–2010) GPS RO soundings from COSMIC (Constellation Observing System for Meteorology, Ionosphere, and Climate) over the Arctic (65° N-90° N) show uniform spatial sampling with average penetration depth within 300 m above the ocean surface. Over 70 % soundings penetrate below 300 m in all non-summer seasons but only about 50–60 % in summer, when near-surface moisture and its variation increase. Both structural and parametric uncertainties of GPS RO soundings were also analyzed. The structural uncertainty (due to different data processing approaches) is estimated to be within 0.07 % in refractivity, 0.72 K in temperature and −0.029 g/kg in specific humidity below 10 km, which is derived by comparing RO retrievals from two independent data processing centers. The parametric uncertainty (internal uncertainty of RO sounding) is quantified by comparing GPS RO with near-coincident radiosonde and ECMWF ERA-Interim profiles. A systematic negative bias up to ~ 1 % in refractivity below 2 km is only seen in the summer, which confirms the moisture impact on GPS RO quality.

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Evaluation of Arctic cloud products from the EUMETSAT Climate Monitoring Satellite Application Facility based on CALIPSO-CALIOP observations

Atmospheric Chemistry and Physics Discussions ◽

10.5194/acpd-9-16755-2009 ◽

2009 ◽

Vol 9 (4) ◽

pp. 16755-16810 ◽

Cited By ~ 4

Author(s):

K.-G. Karlsson ◽

A. Dybbroe

Keyword(s):

Weather Prediction ◽

Lower Troposphere ◽

Arctic Region ◽

Numerical Weather Prediction Model ◽

The Arctic ◽

Cloud Type ◽

Near Surface ◽

Noaa Avhrr ◽

Climate Monitoring ◽

June July

Abstract. The performance of the three cloud products cloud fractional cover, cloud type and cloud top height, derived from NOAA AVHRR data and produced by the EUMETSAT Climate Monitoring Satellite Application Facility, has been evaluated in detail over the Arctic region for four months in 2007 using CALIPSO-CALIOP observations. The evaluation was based on 142 selected NOAA/Metop overpasses allowing almost 400 000 individual matchups between AVHRR pixels and CALIOP measurements distributed approximately equally over the studied months (June, July, August and December 2007). Results suggest that estimations of cloud amounts are very accurate during the polar summer season while a substantial loss of detected clouds occurs in the polar winter. Evaluation results for cloud type and cloud top products point at specific problems related to the existence of near isothermal conditions in the lower troposphere in the polar summer and the use of reference vertical temperature profiles from Numerical Weather Prediction model analyses. The latter are currently not detailed enough in describing true conditions relevant on the pixel scale. This concerns especially the description of near-surface temperature inversions which are often too weak leading to large errors in interpreted cloud top heights.

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Airborne in-situ observations of Arctic clouds in spring and summer above sea ice and the open ocean

10.5194/egusphere-egu21-7749 ◽

2021 ◽

Author(s):

Manuel Moser ◽

Christiane Voigt ◽

Valerian Hahn ◽

Olivier Jourdan ◽

Christophe Gourbeyre ◽

...

Keyword(s):

Sea Ice ◽

Water Content ◽

Late Summer ◽

Open Ocean ◽

The Arctic ◽

Arctic Clouds ◽

Cloud Properties ◽

Cloud Water Content ◽

Median Volume ◽

Ice Water

Two airborne campaigns (AFLUX and MOSAiC-ACA) were conducted in spring 2019 and late summer 2020 to investigate low- and midlevel clouds and related atmospheric parameters in the central Arctic. The measurements aim at better understanding the role of Arctic clouds and their interactions with the surface - open ocean or sea ice - in light of amplified climate change in the Arctic. During the campaigns the Basler BT-67 research aircraft Polar 5 based in Svalbard (78.24 N, 15.49 E) equipped with a comprehensive in-situ cloud payload performed in total 24 flights over the Arctic ocean and in the Fram Strait. A combination of size spectrometers (CDP and CAS) and 2-dimensional imaging probes (CIP and PIP) covering the size range of Arctic cloud hydrometeors from 0.5&#181;m to 6.2mm measured the total particle number concentration, the particle size distribution and the median volume diameter. Liquid water content and ice water content were measured with the Nevzorov bulk probe. The cloud water content (liquid and ice water content) from the Nevzorov probe is compared to the cloud water content derived from particle size measurements using consistent mass-dimension relationships. Here we give an overview of the microphysical cloud properties measured in spring and late summer in high northern latitudes at altitudes up to 4 km. We derive the temperature and altitude dependence of liquid, mixed phase and ice cloud properties and investigate their seasonal variability. Differences in cloud properties above the sea ice and the open ocean are examined, supporting the hypothesis of an enhanced median volume diameter over open ocean compared to clouds formed over the sea ice. The comprehensive data set on microphysical cloud properties enhances our understanding of cloud formation and mixed phase cloud processes over the Arctic ocean, it can be used to validate remote sensing retrievals and models and helps to assess the role of clouds for stronger impact of climate change in the Arctic.&#160;

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