The Impact of Two Coupled Cirrus Microphysics–Radiation Parameterizations on the Temperature and Specific Humidity Biases in the Tropical Tropopause Layer in a Climate Model

Baran, Anthony J.; Hill, Peter; Walters, David; Hardiman, Steven C.; Furtado, Kalli; Field, Paul R.; Manners, James

doi:10.1175/jcli-d-15-0821.1

Cited by 33 publications

(36 citation statements)

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“…Consider the results of CRTM simulations in Table in which different size distributions of ice spheres of identical bulk density with identical total water content and effective radius produce significantly different scattering optical depths and some differences in brightness temperature. Similar circumstances exist for ice cloud particles and infrared radiation; Baran et al [, ] have demonstrated improvement in modeled shortwave and longwave fluxes by directly coupling particle size distributions to scattering properties instead of parameterizing this relationship via effective radius.…”

Section: Introductionmentioning

confidence: 99%

Comparison of using distribution‐specific versus effective radius methods for hydrometeor single‐scattering properties for all‐sky microwave satellite radiance simulations with different microphysics parameterization schemes

et al. 2017

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The Community Radiative Transfer Model (CRTM) presently uses one look‐up table (LUT) of cloud and precipitation single‐scattering properties at microwave frequencies, with which any particle size distribution may interface via effective radius. This may produce scattering properties insufficiently representative of the model output if the microphysics parameterization scheme particle size distribution mismatches that assumed in constructing the LUT, such as one being exponential and the other monodisperse, or assuming different particle bulk densities. The CRTM also assigns a 5 μm effective radius to all nonprecipitating clouds, an additional inconsistency. Brightness temperatures are calculated from 3 h convection‐permitting simulations of Hurricane Karl (2010) by the Weather Research and Forecasting model; each simulation uses one of three different microphysics schemes. For each microphysics scheme, a consistent cloud scattering LUT is constructed; the use of these LUTs produces differences in brightness temperature fields that would be better for analyzing and constraining microphysics schemes than using the CRTM LUT as‐released. Other LUTs are constructed which contain one of the known microphysics inconsistencies with the CRTM LUT as‐released, such as the bulk density of graupel, but are otherwise microphysics‐consistent; differences in brightness temperature to using an entirely microphysics‐consistent LUT further indicate the significance of that inconsistency. The CRTM LUT as‐released produces higher brightness temperature than using microphysics‐consistent LUTs. None of the LUTs can produce brightness temperatures that can match well to observations at all frequencies, which is likely due in part to the use of spherical particle scattering.

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Section: Introductionmentioning

confidence: 99%

Comparison of using distribution‐specific versus effective radius methods for hydrometeor single‐scattering properties for all‐sky microwave satellite radiance simulations with different microphysics parameterization schemes

et al. 2017

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“…In GA7, we parametrise the scalar optical properties of ice crystals using the scheme described in Baran et al (2016). This is based on an ensemble model of ice crystals developed by Baran and Labonnote (2007), where the bulk ice optical properties are derived by averaging habit-dependent scalar optical properties over an assumed particle size distribution function (PSD).…”

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confidence: 99%

“…This approach has the advantage that it is possible to generate ice optical properties from PSDs with the same microphysical 20 assumptions used in the model's microphysics scheme; the same mass of ice is passed into each scheme and the bulk scalar ice optical properties are parametrised as a function of ice mass and temperature as described in Baran et al (2016). This improves the self-consistency within the model in a way that is generally not achieved with scalar optical properties determined from an ice crystal effective dimension as was done in GA6 and in most other atmospheric models; as a result, those models usually assume inconsistent PSDs and mass-diameter relations in the microphysics and radiation schemes.…”

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confidence: 99%

“…The difference between the Baran et al (2016) scheme implemented in GA7 and the Baran et al (2014) scheme that was originally proposed is that in the original scheme, the derived optical properties are fitted to be functions of the spectral band (see Table 1) and the model's prognostic ice water mass mixing ratio only, whilst in GA7, and Baran et al (2016), there is an additional functional relationship to the atmospheric temperature (fitted to data sampled between -80…”

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confidence: 99%

“…Hardiman et al (2015) discuss the importance of this bias and the role of various physical and numerical processes in its development. In developing GA7, the introduction of consistent ice optical and microphysical properties (GA ticket #17) was originally proposed via the scheme described in Baran et al (2014) and the detrimental impact on the TTL temperature bias led to the additional developments made in Baran et al (2016). The inclusion of cubic Hermite interpolation for moist prognostic variables (as part of GA ticket #135) was motivated primarily by its reduction of moisture biases above the tropical tropopause.…”

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The Met Office Unified Model Global Atmosphere 7.0/7.1 and JULES Global Land 7.0 configurations

Walters¹,

Baran²,

Boutle³

et al. 2017

Preprint

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111

154

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Abstract. We describe Global Atmosphere 7.0 and Global Land 7.0 (GA7.0/GL7.0): the latest science configurations of the Met Office Unified Model and JULES land surface model developed for use across weather and climate timescales. GA7.0 and GL7.0 include incremental developments and targeted improvements that between them address four critical errors identified in previous configurations: excessive precipitation biases over India, warm/moist biases in the tropical tropopause layer, a source of energy non-conservation in the advection scheme and excessive surface radiation biases over the Southern Ocean. They also 5 include two new parametrisations, namely the UKCA Glomap-mode aerosol scheme and the JULES multi-layer snow scheme, which improve the fidelity of the simulation and were required for the coupled climate models and Earth system models that will use these configurations in submissions to CMIP6.In addition, we describe the GA7.1 branch configuration, which reduces an overly negative anthropogenic aerosol effective radiative forcing in GA7.0, whilst maintaining the quality of simulations of the present-day climate. GA7.1/GL7.0 will form 10 the physical atmosphere/land component in the HadGEM3-GC3.1 and UKESM1 climate models.

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Sensitivity of cloud‐radiative effects to cloud fraction parametrizations in tropical, midlatitude, and arctic kilometre‐scale simulations

Weverberg

Morcrette

2022

Quart J Royal Meteoro Soc

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The regional atmosphere (RA) configuration of the Met Office Unified Model currently requires different cloud fraction parametrizations (CFPs) for tropical and midlatitude simulations. To explore the scope for unification of these two RA configurations, this article presents a detailed evaluation of simulations over tropical, midlatitude, and arctic domains, with two different diagnostic CFPs: a prognostic CFP, and no CFP at all. Furthermore, a novel, hybrid approach was used that treats liquid cloud diagnostically and ice cloud prognostically. Using observations from three US Department of Energy Atmospheric Radiation Measurement supersites, it is shown that none of these CFPs stands out as superior over all domains. Over the frequently overcast Arctic, the all-or-nothing approach best captures the cloud radiative properties. Conversely, CFPs are of benefit in regions with frequent partial cloudiness, such as the midlatitudes and the Tropics. However, their improved cloud radiative properties often hide an error compensation. All models underestimate overcast, low-base cloud with small water paths in convective environments. In addition, midlatitude overcast, low-base, optically thick clouds in the morning, possibly associated with overnight convection, are frequently too broken. Diagnostic schemes compensate for these errors by producing spurious, scattered afternoon cloud, which could be due to a correct cloud response to too eager convective initiation. Winter clouds over the midlatitudes are improved when liquid cloud is represented diagnostically with a bimodal saturation-departure probability density function, without error compensation. Although it is difficult to unify the RA across the globe around a single CFP scheme, the newly proposed hybrid scheme performs reasonably well for cloud cover across all regions. It also exhibits short-wave biases that are smaller than most other configurations and is less affected by excessive liquid water paths and compensating errors than fully diagnostic schemes are. Surface precipitation is fairly insensitive to the CFP in the simulations shown here.

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The Impact of Two Coupled Cirrus Microphysics–Radiation Parameterizations on the Temperature and Specific Humidity Biases in the Tropical Tropopause Layer in a Climate Model

Cited by 33 publications

References 72 publications

Comparison of using distribution‐specific versus effective radius methods for hydrometeor single‐scattering properties for all‐sky microwave satellite radiance simulations with different microphysics parameterization schemes

Comparison of using distribution‐specific versus effective radius methods for hydrometeor single‐scattering properties for all‐sky microwave satellite radiance simulations with different microphysics parameterization schemes

The Met Office Unified Model Global Atmosphere 7.0/7.1 and JULES Global Land 7.0 configurations

Sensitivity of cloud‐radiative effects to cloud fraction parametrizations in tropical, midlatitude, and arctic kilometre‐scale simulations

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