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1. Operational Dust Prediction

Author

Benedetti, Angela, Baldasano, José Maria, Basart, Sara, Benincasa, Francesco, Boucher, Olivier, Brooks, Malcolm E., Chen, Jen-Ping, Colarco, Peter R., Gong, Sunlin, Huneeus, Nicolas, Jones, Luke, Lu, Sarah, Menut, Laurent, Morcrette, Jean-Jacques, Mulcahy, Jane, Nickovic, Slobodan, Pérez García-Pando, Carlos, Reid, Jeffrey S., Sekiyama, Thomas T., Tanaka, Taichu Y., Terradellas, Enric, Westphal, Douglas L., Zhang, Xiao-Ye, Zhou, Chun-Hong, Knippertz, Peter, editor, and Stuut, Jan-Berend W., editor

Published
2014
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2. The Iceland Greenland Seas Project

Author

Renfrew, Ian A., Pickart, Robert S., Vage, Kjetil, Moore, G. W. K., Bracegirde, Thomas J., Elvidge, Andrew D., Jeansson, Emil, Lachlan-Cope, Thomas, McRaven, Leah T., Papritz, Lukas, Reuder, Joachim, Sodemann, Harald, Terpstra, Annick, Waterman, Stephanie N., Valdimarsson, Héðinn, Weiss, Albert, Almansi, Mattia, Bahr, Frank B., Brakstad, Ailin, Barrell, Christopher, Brooke, Jennifer K., Brooks, Barbara J., Brooks, Ian M., Brooks, Malcolm E., Bruvik, Erik Magnus, Duscha, Christiane, Fer, Ilker, Golid, H. M., Hallerstig, M., Hessevik, Idar, Huang, Jie, Houghton, Leah A., Jonsson, Steingrimur, Jonassen, Marius, Jackson, K., Kvalsund, K., Kolstad, Erik W., Konstali, K., Kristiansen, Jorn, Ladkin, Russell, Lin, Peigen, Macrander, Andreas, Mitchell, Alexandra, Olafsson, H., Pacini, Astrid, Payne, Chris, Palmason, Bolli, Perez-Hernandez, M. Dolores, Peterson, Algot K., Petersen, Guðrún N., Pisareva, Maria N., Pope, James O., Seidl, Andrew D., Semper, Stefanie, Sergeev, Denis, Skjelsvik, Silje, Søiland, Henrik, Smith, D., Spall, Michael A., Spengler, Thomas, Touzeau, Alexandra, Tupper, George H., Weng, Y., Williams, Keith D., Yang, Xiaohau, Zhou, Shenjie, Renfrew, Ian A., Pickart, Robert S., Vage, Kjetil, Moore, G. W. K., Bracegirde, Thomas J., Elvidge, Andrew D., Jeansson, Emil, Lachlan-Cope, Thomas, McRaven, Leah T., Papritz, Lukas, Reuder, Joachim, Sodemann, Harald, Terpstra, Annick, Waterman, Stephanie N., Valdimarsson, Héðinn, Weiss, Albert, Almansi, Mattia, Bahr, Frank B., Brakstad, Ailin, Barrell, Christopher, Brooke, Jennifer K., Brooks, Barbara J., Brooks, Ian M., Brooks, Malcolm E., Bruvik, Erik Magnus, Duscha, Christiane, Fer, Ilker, Golid, H. M., Hallerstig, M., Hessevik, Idar, Huang, Jie, Houghton, Leah A., Jonsson, Steingrimur, Jonassen, Marius, Jackson, K., Kvalsund, K., Kolstad, Erik W., Konstali, K., Kristiansen, Jorn, Ladkin, Russell, Lin, Peigen, Macrander, Andreas, Mitchell, Alexandra, Olafsson, H., Pacini, Astrid, Payne, Chris, Palmason, Bolli, Perez-Hernandez, M. Dolores, Peterson, Algot K., Petersen, Guðrún N., Pisareva, Maria N., Pope, James O., Seidl, Andrew D., Semper, Stefanie, Sergeev, Denis, Skjelsvik, Silje, Søiland, Henrik, Smith, D., Spall, Michael A., Spengler, Thomas, Touzeau, Alexandra, Tupper, George H., Weng, Y., Williams, Keith D., Yang, Xiaohau, and Zhou, Shenjie

Abstract

© The Author(s), 2019. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Renfrew, I. A., Pickart, R. S., Vage, K., Moore, G. W. K., Bracegirdle, T. J., Elvidge, A. D., Jeansson, E., Lachlan-Cope, T., McRaven, L. T., Papritz, L., Reuder, J., Sodemann, H., Terpstra, A., Waterman, S., Valdimarsson, H., Weiss, A., Almansi, M., Bahr, F., Brakstad, A., Barrell, C., Brooke, J. K., Brooks, B. J., Brooks, I. M., Brooks, M. E., Bruvik, E. M., Duscha, C., Fer, I., Golid, H. M., Hallerstig, M., Hessevik, I., Huang, J., Houghton, L., Jonsson, S., Jonassen, M., Jackson, K., Kvalsund, K., Kolstad, E. W., Konstali, K., Kristiansen, J., Ladkin, R., Lin, P., Macrander, A., Mitchell, A., Olafsson, H., Pacini, A., Payne, C., Palmason, B., Perez-Hernandez, M. D., Peterson, A. K., Petersen, G. N., Pisareva, M. N., Pope, J. O., Seidl, A., Semper, S., Sergeev, D., Skjelsvik, S., Soiland, H., Smith, D., Spall, M. A., Spengler, T., Touzeau, A., Tupper, G., Weng, Y., Williams, K. D., Yang, X., & Zhou, S. The Iceland Greenland Seas Project. Bulletin of the American Meteorological Society, 100(9), (2019): 1795-1817, doi:10.1175/BAMS-D-18-0217.1., The Iceland Greenland Seas Project (IGP) is a coordinated atmosphere–ocean research program investigating climate processes in the source region of the densest waters of the Atlantic meridional overturning circulation. During February and March 2018, a field campaign was executed over the Iceland and southern Greenland Seas that utilized a range of observing platforms to investigate critical processes in the region, including a research vessel, a research aircraft, moorings, sea gliders, floats, and a meteorological buoy. A remarkable feature of the field campaign was the highly coordinated deployment of the observing platforms, whereby the research vessel and aircraft tracks were planned in concert to allow simultaneous sampling of the atmosphere, the ocean, and their interactions. This joint planning was supported by tailor-made convection-permitting weather forecasts and novel diagnostics from an ensemble prediction system. The scientific aims of the IGP are to characterize the atmospheric forcing and the ocean response of coupled processes; in particular, cold-air outbreaks in the vicinity of the marginal ice zone and their triggering of oceanic heat loss, and the role of freshwater in the generation of dense water masses. The campaign observed the life cycle of a long-lasting cold-air outbreak over the Iceland Sea and the development of a cold-air outbreak over the Greenland Sea. Repeated profiling revealed the immediate impact on the ocean, while a comprehensive hydrographic survey provided a rare picture of these subpolar seas in winter. A joint atmosphere–ocean approach is also being used in the analysis phase, with coupled observational analysis and coordinated numerical modeling activities underway., The IGP has received funding from the U.S. National Science Foundation: Grant OCE-1558742; the U.K.’s Natural Environment Research Council: AFIS (NE/N009754/1); the Research Council of Norway: MOCN (231647), VENTILATE (229791), SNOWPACE (262710) and FARLAB (245907); and the Bergen Research Foundation (BFS2016REK01). We thank all those involved in the field work associated with the IGP, particularly the officers and crew of the Alliance, and the operations staff of the aircraft campaign.

Published
2020

3. Parameterizing the difference in cloud fraction defined by area and by volume as observed with radar and lidar

Author

Brooks, Malcolm E., Hogan, Robin J., and Illingworth, Anthony J.

Subjects
Clouds -- Research, Atmosphere -- Research, Earth -- Atmosphere, Earth -- Research, Earth sciences, Science and technology
Abstract

Most current general circulation models (GCMs) calculate radiative fluxes through partially cloudy grid boxes by weighting clear and cloudy fluxes by the fractional area of cloud cover ([C.sub.a]), but most GCM cloud schemes calculate cloud fraction as the volume of the grid box that is filled with cloud ([C.sub.v]). In this paper, 1 yr of cloud radar and lidar observations from Chilbolton in southern England, are used to examine this discrepancy. With a vertical resolution of 300 m it is found that, on average, [C.sub.a] is 20% greater than [C.sub.v], and with a vertical resolution of 1 km, [C.sub.a] is greater than [C.sub.v] by a factor of 2. The difference is around a factor of 2 larger for liquid water clouds than for ice clouds, and also increases with wind shear. Using [C.sub.a] rather than [C.sub.v], calculated on an operational model grid, increases the mean total cloud cover from 53% to 63%. and so is of similar importance to the cloud overlap assumption. A simple parameterization, [C.sub.a] = [1 + [e.sup.(-f) ([[C.sup.-1.sub.v])].sup.-1], is proposed to correct for this underestimate based on the observation that the observed relationship between the mean [C.sub.a] and [C.sub.v] is symmetric about the line [C.sub.a] = 1 - [C.sub.v]. The parameter f is a simple function of the horizontal (H) and vertical (V) grid-box dimensions, where for ice clouds f = 0.0880 [V.sup.0.7696] [H.sup.-0.2254] and for liquid clouds f = 0.1635 [V.sup.0.6694] [H.sup.-0.1882]. Implementing this simple parameterization, which excludes the effect of wind shear, on an independent 6-month dataset of cloud radar and lidar observations, accounts for the mean underestimate of [C.sub.a] for all horizontal and vertical resolutions considered to within 3% of the observed [C.sub.a], and reduces the rms error for each individual box from typically 100% to approximately 30%. Small biases remain for both weakly and strongly sheared cases, but this is significantly reduced by incorporating a simple shear dependence in the calculation of the parameter f. which also slightly improves the overall performance of the parameterization for all of the resolutions considered.

Published
2005

6. Current state of the global operational aerosol multi‐model ensemble: An update from the International Cooperative for Aerosol Prediction (ICAP)

Author

Xian, Peng, primary, Reid, Jeffrey S., additional, Hyer, Edward J., additional, Sampson, Charles R., additional, Rubin, Juli I., additional, Ades, Melanie, additional, Asencio, Nicole, additional, Basart, Sara, additional, Benedetti, Angela, additional, Bhattacharjee, Partha S., additional, Brooks, Malcolm E., additional, Colarco, Peter R., additional, da Silva, Arlindo M., additional, Eck, Tom F., additional, Guth, Jonathan, additional, Jorba, Oriol, additional, Kouznetsov, Rostislav, additional, Kipling, Zak, additional, Sofiev, Mikhail, additional, Perez Garcia‐Pando, Carlos, additional, Pradhan, Yaswant, additional, Tanaka, Taichu, additional, Wang, Jun, additional, Westphal, Douglas L., additional, Yumimoto, Keiya, additional, and Zhang, Jianglong, additional

Published
2019
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7. Forecasting the monsoon on daily to seasonal time‐scales in support of a field campaign.

Author

Martin, Gill M., Brooks, Malcolm E., Johnson, Ben, Milton, Sean F., Webster, Stuart, Jayakumar, A., Mitra, Ashis K., Rajan, D., and Hunt, Kieran M. R.

Subjects
*MONSOONS, *WEATHER forecasting, *SCIENTISTS, *FORECASTING
Abstract

The successful planning and execution of a major field campaign relies on the availability and reliability of weather forecasts on a range of time‐scales. Here, we describe the wide range of forecast products generated in support of a field campaign that took place in India in 2016 as part of the Interaction of Convective Organization with Monsoon Precipitation, Atmosphere, Surface and Sea (INCOMPASS) project. We show examples of the suite of plots generated every day from the forecasts and supplied to the mission scientists, and describe how these were used to plan the flights. We highlight the benefits of having access to forecasts from a range of model resolutions and configurations; these allowed judgements to be made about uncertainty, particularly in the amount and location of deep convective rainfall, which is an important consideration for flight planning. Finally, we discuss the legacy of the forecasting activity, which has not only advanced our understanding of monsoon forecasting but also created a large database of targeted model forecast products for the whole of the 2016 monsoon season. These can be used by researchers for comparisons with in situ observations as well as future modelling studies. [ABSTRACT FROM AUTHOR]

Published
2020
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8. The 2015 Indian summer monsoon onset - phenomena, forecasting and research flight planning

Author

Willetts, Peter D., Turner, Andrew G., Martin, Gill M., Mrudula, G., Hunt, Kieran M.R., Parker, Douglas J., Taylor, Christopher M., Birch, Cathryn E., Mitra, Ashis K., Heming, Julian T., Brooks, Malcolm E., Willetts, Peter D., Turner, Andrew G., Martin, Gill M., Mrudula, G., Hunt, Kieran M.R., Parker, Douglas J., Taylor, Christopher M., Birch, Cathryn E., Mitra, Ashis K., Heming, Julian T., and Brooks, Malcolm E.

Abstract

From May to July 2016, as part of the INCOMPASS project, the Facility for Airborne Atmospheric Measurements (FAAM, jointly funded by the Met Office and Natural Environment Research Council (NERC)) BAe-146 research aircraft travelled to India to record key aspects of the Indian summer monsoon onset and evolution. As part of the planning for the campaign, partners in the UK and India took part in a ‘dry-run’ forecasting exercise during 2015, to assess the reliability of the forecast products and develop a set of flight plans, in advance of the real campaign, and to get a real-time feel for the monsoon onset. The 5-day forecasts from the Met Office and the Indian National Centre for Medium Range Weather Forecasting (NCMRWF) showed good skill in terms of predicting the advance of rainfall in regions key for the campaign in north and south India, and captured transitions from active (wet) monsoon conditions to break (dry) periods and back again. Key phenomena seen during the dry-run exercise include (1) a ‘western disturbance’, which had a major effect on the extreme pre-monsoon heatwave conditions over India, (2) dry intrusions, which are thought to be important in the progression of the monsoon onset against the synoptic flow, and (3) cyclones Ashobaa and Komen.

Published
2017

10. Evaluation of the Met Office global forecast model using Geostationary Earth Radiation Budget (GERB) data

Author

Allan, Richard P., Slingo, Anthony, Milton, Sean F., and Brooks, Malcolm E.

Subjects
Physics::Atmospheric and Oceanic Physics
Abstract

Simulations of the top-of-atmosphere radiative-energy budget from the Met Office global numerical weather-prediction model are evaluated using new data from the Geostationary Earth Radiation Budget (GERB) instrument on board the Meteosat-8 satellite. Systematic discrepancies between the model simulations and GERB measurements greater than 20 Wm-2 in outgoing long-wave radiation (OLR) and greater than 60 Wm-2 in reflected short-wave radiation (RSR) are identified over the period April-September 2006 using 12 UTC data. Convective cloud over equatorial Africa is spatially less organized and less reflective than in the GERB data. This bias depends strongly on convective-cloud cover, which is highly sensitive to changes in the model convective parametrization. Underestimates in model OLR over the Gulf of Guinea coincide with unrealistic southerly cloud outflow from convective centres to the north. Large overestimates in model RSR over the subtropical ocean, greater than 50 Wm-2 at 12 UTC, are explained by unrealistic radiative properties of low-level cloud relating to overestimation of cloud liquid water compared with independent satellite measurements. The results of this analysis contribute to the development and improvement of parametrizations in the global forecast model.

Published
2007

15. The Iceland Greenland Seas Project

Author

Renfrew, Ian A., Pickart, Robert S., Våge, Kjetil, Moore, George W.K., Bracegirdle, Thomas J., Elvidge, Andrew D., Jeansson, Emil, Lachlan-Cope, Tom A., McRaven, Leah T., Papritz, Lukas, Reuder, Joachim, Sodemann, Harald, Terpstra, Annick, Waterman, Stephanie N., Valdimarsson, Héđinn, Weiss, Alexandra, Almansi, Mattia, Bahr, Frank B., Brakstad, Ailin, Barrell, C., Brooke, Jennifer K., Brooks, Barbara J., Brooks, Ian M., Brooks, Malcolm E., Bruvik, Erik M., Duscha, C., Fer, Ilker, Hallerstig, M., Hessevik, Idar, Huang, Jie, Houghton, Leah A., Jónsson, Steingrímur, Jonassen, Marius O., Jackson, K., Kvalsund, Karsten, Kolstad, Erik W., Konstali, K., Kristiansen, Jørn, Ladkin, Russell, Lin, Peigen, MacRander, Andreas, Mitchell, A., Ólafsson, Haraldur, Pacini, Astrid, Payne, C., Palmason, B., Pérez-Hernández, María D., Peterson, Algot K., Petersen, Gudrún N., Pisareva, Maria N., Pope, James O., Seidl, Andrew, Semper, Stefanie, Sergeev, Denis E., Skjelsvik, S., Søiland, Henrik, Smith, Doug M., Spall, Michael A., Spengler, Thomas, Touzeau, Alexandra, Weng, Y., Williams, Keith D., Yang, X., and Zhou, S.

Subjects
13. Climate action, 14. Life underwater
Abstract

The Iceland Greenland Seas Project (IGP) is a coordinated atmosphere–ocean research program investigating climate processes in the source region of the densest waters of the Atlantic meridional overturning circulation. During February and March 2018, a field campaign was executed over the Iceland and southern Greenland Seas that utilized a range of observing platforms to investigate critical processes in the region, including a research vessel, a research aircraft, moorings, sea gliders, floats, and a meteorological buoy. A remarkable feature of the field campaign was the highly coordinated deployment of the observing platforms, whereby the research vessel and aircraft tracks were planned in concert to allow simultaneous sampling of the atmosphere, the ocean, and their interactions. This joint planning was supported by tailor-made convection-permitting weather forecasts and novel diagnostics from an ensemble prediction system. The scientific aims of the IGP are to characterize the atmospheric forcing and the ocean response of coupled processes; in particular, cold-air outbreaks in the vicinity of the marginal ice zone and their triggering of oceanic heat loss, and the role of freshwater in the generation of dense water masses. The campaign observed the life cycle of a long-lasting cold-air outbreak over the Iceland Sea and the development of a cold-air outbreak over the Greenland Sea. Repeated profiling revealed the immediate impact on the ocean, while a comprehensive hydrographic survey provided a rare picture of these subpolar seas in winter. A joint atmosphere–ocean approach is also being used in the analysis phase, with coupled observational analysis and coordinated numerical modeling activities underway., Bulletin of the American Meteorological Society, 100 (9), ISSN:0003-0007, ISSN:1520-0477

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