Intercomparison of methods of coupling between convection and large-scale circulation. 2: comparison over non-uniform surface conditions

Lists

Download

Preview

Daleu_et_al-2016-Journal_of_Advances_in_Modeling_Earth_Systems.pdf - Published Version (2MB) | Preview

Available under license: Creative Commons Attribution

Preview

gass_wtg2.pdf - Accepted Version (554kB) | Preview

Available under license: Creative Commons Attribution

Tools

Daleu, C. L. ORCID: https://orcid.org/0000-0003-2075-4902, Plant, R. S. ORCID: https://orcid.org/0000-0001-8808-0022, Woolnough, S. J. ORCID: https://orcid.org/0000-0003-0500-8514, Sessions, S., Herman, M. J., Sobel, A., Wang, S., Kim, D., Cheng, A., Bellon, G., Peyrille, P., Ferry, F., Siebesma, P. and van Ulft, L. (2016) Intercomparison of methods of coupling between convection and large-scale circulation. 2: comparison over non-uniform surface conditions. Journal of Advances in Modeling Earth Systems, 8 (1). pp. 387-405. ISSN 1942-2466 doi: 10.1002/2015MS000570

Abstract/Summary

As part of an international intercomparison project, the weak temperature gradient (WTG) and damped gravity wave (DGW) methods are used to parameterize large-scale dynamics in a set of cloud-resolving models (CRMs) and single column models (SCMs). The WTG or DGW method is implemented using a configuration that couples a model to a reference state defined with profiles obtained from the same model in radiative-convective equilibrium. We investigated the sensitivity of each model to changes in SST, given a fixed reference state. We performed a systematic comparison of the WTG and DGW methods in different models, and a systematic comparison of the behavior of those models using the WTG method and the DGW method. The sensitivity to the SST depends on both the large-scale parameterization method and the choice of the cloud model. In general, SCMs display a wider range of behaviors than CRMs. All CRMs using either the WTG or DGW method show an increase of precipitation with SST, while SCMs show sensitivities which are not always monotonic. CRMs using either the WTG or DGW method show a similar relationship between mean precipitation rate and column-relative humidity, while SCMs exhibit a much wider range of behaviors. DGW simulations produce large-scale velocity profiles which are smoother and less top-heavy compared to those produced by the WTG simulations. These large-scale parameterization methods provide a useful tool to identify the impact of parameterization differences on model behavior in the presence of two-way feedback between convection and the large-scale circulation.

Altmetric Badge

Item Type	Article
URI	https://reading-clone.eprints-hosting.org/id/eprint/59328
Item Type	Article
Refereed	Yes
Divisions	Science > School of Mathematical, Physical and Computational Sciences > NCAS Science > School of Mathematical, Physical and Computational Sciences > Department of Meteorology
Uncontrolled Keywords	Tropical convection Large-scale parameterized dynamics
Publisher	American Geophysical Union
Download/View statistics	View download statistics for this item

Download Statistics

Downloads

Downloads per month over past year

Funded Project

Funders:	Natural Environment Research Council	The sponsoring bodies who contributed funding for the creation of this item. Example: NERC Example: The Royal Society of Chemistry A pick list of funders may appear as you type in the funder's name in full or as an acronym. Select a correct match to complete the field or type in a new entry in full. For new entries, the full name is preferred.
Projects:	Transitions Between Suppressed and Active Convection Coupled to Large-Scale Tropical Circulations Funded by: Natural Environment Research Council (NE/K004034/1 - £378,206) Local Lead (PI): Steven Woolnough Project Lead: Steven James Woolnough 1 April 2013 - 31 March 2017	Click Add to select your project (received at Reading) from an autocomplete list.

Deposit Details

Date Deposited:	01 Apr 2016 08:17	Date item deposited into CentAUR
Last Modified:	09 Jun 2024 03:14	Date item last modified

References

Bretherton, C., P. Blossey, and M. Khairoutdinov (2005), An energy-balance analysis of 678 deep convective self-aggregation above uniform SST, J. Atmos. Sci., 62, 4273–4292. 679 Bretherton, C. S., M. E. Peters, and L. E. Back (2004), Relationships between water 680 vapor path and precipitation over the tropical ocean, J. Clim., 17, 1517–1528. 681 Cheng, A., and K.-M. Xu (2006), Simulation of shallow cumuli and their transition to 682 deep convective clouds by cloud-resolving models with different third-order turbulence 683 closures, Q. J. R. Meteorol. Soc., 132, 359–382. D R A F T February 1, 2016, 12:53pm D R A F T X - 34 DALEU ET AL.: CONVECTION AND PARAMETERIZED LARGE-SCALE DYNAMICS Daleu, C., S. Woolnough, and R. Plant 684 (2012), Cloud-resolving model simulations with 685 one and two-way couplings via the weak-temperature gradient approximation, J. Atmos. 686 Sci., 69, 3683–3699. 687 Daleu, C., S. Woolnough, and R. Plant (2014), Transition from suppressed to active 688 convection modulated by a weak-temperature gradient derived large-scale circulation, 689 J. Atmos. Sci., 72, 834–853. 690 Daleu, C., et al. (2015), Intercomparison of methods of coupling between convection and 691 large-scale circulation: I. comparison over uniform surface conditions, J. Adv. Model. 692 Earth. Syst. 693 Davies, T., M. Cullen, A. Malcolm, M. Mawson, A. Staniforth, A. White, and N. Wood 694 (2005), A new dynamical core for the Met Office’s global and regional modelling of the 695 atmosphere, Q. J. R. Meteorol. Soc., 131, 1759–1782. 696 Derbyshire, S., I. Beau, P. Bechtold, J. Grandpeix, J. Piriou, J. Redelsperger, and 697 P. Soares (2004), Sensitivity of moist convection to environmental humidity, Q. J. R. 698 Meteorol. Soc., 130, 3055–3079. 699 Dufresne, J.-L., et al. (2013), Climate change projections using the IPSL-CM5 earth 700 system model: From CMIP3 to CMIP5, Clim. Dyn., 40, 2123–2165. 701 Edman, J. P., and D. M. Romps (2015), Self-consistency tests of large-scale dynamics 702 parameterizations for single-column modeling, J. Adv. Model. Earth. Syst., 7, 320–334. 703 Hazeleger, W., et al. (2010), EC-Earth: A seamless earth-system prediction approach in 704 action, Bull. Am. Meteorol. Soc., 91, 1357–1363. 705 Herman, M. J., and D. J. Raymond (2014), WTG cloud modeling with spectral decom706 position of heating, J. Adv. Model. Earth. Syst., 6, 1121–1140. D R A F T February 1, 2016, 12:53pm D R A F T DALEU ET AL.: CONVECTION AND PARAMETERIZED LARGE-SCALE DYNAMICS X - 35 Holloway, C., S. Woolnough, and G. 707 Lister (2012), Precipitation distributions for explicit 708 versus parametrized convection in a large-domain high-resolution tropical case study, 709 Q. J. R. Meteorol. Soc., 138, 1692–1708. 710 Holloway, C. E., and J. D. Neelin (2009), Moisture vertical structure, column water vapor, 711 and tropical deep convection, J. Atmos. Sci., 66, 1665–1683. 712 Holloway, C. E., and J. D. Neelin (2010), Temporal relations of column water vapor and 713 tropical precipitation, J. Atmos. Sci., 67, 1091–1105. 714 Kuang, Z. (2008), Modeling the interaction between cumulus convection and linear grav715 ity waves using a limited-domain cloud system-resolving model, J. Atmos. Sci., 65, 716 576–591. 717 Kuang, Z. (2011), The wavelength dependence of the gross moist stability and the scale 718 selection in the instability of column-integrated moist static energy, J. Atmos. Sci., 68, 719 61–74. 720 Lafore, J. P., et al. (1997), The Meso-NH atmospheric simulation system. Part I: Adi721 abatic formulation and control simulations, in Ann. Geophys, vol. 16, pp. 90–109, 722 Springer. 723 Mapes, B. (1997), Equilibrium vs. activation control of large-scale variations of tropical 724 deep convection, The physics and parameterization of moist atmospheric convection, pp. 725 321–358. 726 Masunaga, H. (2012), A satellite study of the atmospheric forcing and response to moist 727 convection over tropical and subtropical oceans, J. Atmos. Sci., 69, 150–167. 728 Miura, H., H. Tomita, T. Nasuno, S.-i. Iga, M. Satoh, and T. Matsuno (2005), A climate 729 sensitivity test using a global cloud resolving model under an aqua planet condition, D R A F T February 1, 2016, 12:53pm D R A F T X - 36 DALEU ET AL.: CONVECTION AND PARAMETERIZED LARGE-SCALE DYNAMICS 730 Geophys. Res. Lett., 32. 731 Pauluis, O., and S. Garner (2006), Sensitivity of radiative-convective equilibrium simu732 lations to horizontal resolution, J. Atmos. Sci., 63, 1910–1923. 733 Petch, J., and M. Gray (2001), Sensitivity studies using a cloud-resolving model simula734 tion of the tropical west Pacific, Q. J. R. Meteorol. Soc., 127, 2287–2306. 735 Petch, J., A. Brown, and M. Gray (2006), The impact of horizontal resolution on the 736 simulations of convective development over land, Q. J. R. Meteorol. Soc., 132, 2031– 737 2044. 738 Ramsay, H., and A. Sobel (2011), Effects of relative and absolute sea surface temperature 739 on tropical cyclone potential intensity using a single-column model, J. Clim., 24, 183– 740 193. 741 Raymond, D., and X. Zeng (2005), Modelling tropical atmospheric convection in the 742 context of the weak temperature gradient approximation, Q. J. R. Meteorol. Soc., 131, 743 1301–1320. 744 Raymond, D. J., S. L. Sessions, A. H. Sobel, and Zˇ. Fuchs (2009), The mechanics of gross 745 moist stability, J. Adv. Model. Earth. Syst., 1. 746 Romps, D. (2012a), Weak pressure gradient approximation and its analytical solutions, 747 J. Atmos. Sci., 69, 2835–2845. 748 Romps, D. M. (2012b), Numerical tests of the weak pressure gradient approximation, J. 749 Atmos. Sci., 69, 2846–2856. 750 Schmidt, G. A., et al. (2014), Configuration and assessment of the GISS modele2 contri751 butions to the CMIP5 archive, J. Adv. Model. Earth. Syst., 6, 141–184. D R A F T February 1, 2016, 12:53pm D R A F T DALEU ET AL.: CONVECTION AND PARAMETERIZED LARGE-SCALE DYNAMICS X - 37 Sessions, S., S. Sugaya, 752 D. Raymond, and A. Sobel (2010), Multiple equilibria in a cloud753 resolving model using the weak temperature gradient approximation, J. Geophys. Res., 754 115, D12,110. 755 Sessions, S. L., M. J. Herman, and S. Senti´c (2015), Convective response to changes in 756 the thermodynamic environment in idealized weak temperature gradient simulations, J. 757 Adv. Model. Earth. Syst. 758 Shutts, G., and M. Gray (1994), A numerical modelling study of the geostrophic adjust759 ment process following deep convection, Q. J. R. Meteorol. Soc., 120, 1145–1178. 760 Skamarock, W. C., J. B. Klemp, J. Dudhia, D. O. Gill, D. M. Barker, W. Wang, and 761 J. G. Powers (2008), A description of the advanced research WRF version 3, Tech. rep., 762 DTIC Document. 763 Sobel, A., and C. Bretherton (2000), Modeling tropical precipitation in a single column, 764 J. Clim., 13, 4378–4392. 765 Sobel, A., G. Bellon, and J. Bacmeister (2007), Multiple equilibria in a single-column 766 model of the tropical atmosphere, Geophys. Res. Lett., 34, L22,804. 767 Sobel, A. H., S. E. Yuter, C. S. Bretherton, and G. N. Kiladis (2004), Large-scale Me768 teorology and Deep Convection during TRMM KWAJEX, Mon. Weather Rev., 132, 769 422–444. 770 Tompkins, A. (2000), The impact of dimensionality on long-term cloud-resolving model 771 simulations, Mon. Weather Rev., 128, 1521–1535. 772 Tompkins, A. (2001), Organization of tropical convection in low vertical wind shears: 773 The role of water vapor, J. Atmos. Sci., 58, 529–545. D R A F T February 1, 2016, 12:53pm D R A F T X - 38 DALEU ET AL.: CONVECTION AND PARAMETERIZED LARGE-SCALE DYNAMICS Vincent, D. 774 (), The south Pacific convergence zone (spcz): A review, Mon. Weather Rev., 775 122. 776 Voldoire, A., et al. (2013), The CNRM-CM5. 1 global climate model: description and 777 basic evaluation, Clim. Dyn., 40, 2091–2121. 778 Wang, S., and A. Sobel (2011), Response of convection to relative sea-surface tempera779 ture: Cloud-resolving simulations in two and three dimensions, J. Geophys. Res., 116, 780 D11,119. 781 Wang, S., and A. Sobel (2012), Impact of imposed drying on deep convection in a cloud782 resolving model, J. Geophys. Res., 117. 783 Wang, S., A. H. Sobel, and Z. Kuang (2013), Cloud-resolving simulation of TOGA784 COARE using parameterized large-scale dynamics, J. Geophys. Res., 118, 6290–6301. 785 Xu, K.-M., R. T. Cederwall, L. J. Donner, W. W. Grabowski, F. Guichard, et al. (2002), 786 An intercomparison of cloud-resolving models with the Atmospheric Radiation Mea787 surement summer 1997 intensive observation period data, Q. J. R. Meteorol. Soc., 128, 788 593–624.

University Staff: Request a correction | Centaur Editors: Update this record

Search Google Scholar