On the Sensitivity of the Simulated Diurnal Cycle of Precipitation to 3-Hourly Radiosonde Assimilation: A Case Study over the Western Maritime Continent

The diurnal cycle is the most prominent mode of rainfall variability in the tropics, governed mainly by the strong solar heating and land–sea interactions that trigger convection. Over the western Maritime Continent, complex orographic and coastal effects can also play an important role. Weather and...

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Veröffentlicht in:	Monthly weather review 2021-10, Vol.149 (10), p.3449-3468
Hauptverfasser:	Kwang Lee, Joshua Chun, Dipankar, Anurag, Huang, Xiang-Yu
Format:	Artikel
Sprache:	eng
Schlagworte:	Atmospheric precipitations Case studies Climate models Coastal effects Coasts Convection Convection heating Data assimilation Data collection Diurnal Diurnal cycle Diurnal variations Experiments Initial conditions Moisture Moisture effects Numerical prediction Numerical weather forecasting Precipitation Radar Radiosonde data Radiosondes Rain Rain gauges Rainfall Rainfall variability Sea breezes Simulation Solar heating Topography Tropical climate Tropical environments Variables Weather forecasting Wind
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creator	Kwang Lee, Joshua Chun Dipankar, Anurag Huang, Xiang-Yu
description	The diurnal cycle is the most prominent mode of rainfall variability in the tropics, governed mainly by the strong solar heating and land–sea interactions that trigger convection. Over the western Maritime Continent, complex orographic and coastal effects can also play an important role. Weather and climate models often struggle to represent these physical processes, resulting in substantial model biases in simulations over the region. For numerical weather prediction, these biases manifest themselves in the initial conditions, leading to phase and amplitude errors in the diurnal cycle of precipitation. Using a tropical convective-scale data assimilation system, we assimilate 3-hourly radiosonde data from the pilot field campaign of the Years of Maritime Continent, in addition to existing available observations, to diagnose the model biases and assess the relative impacts of the additional wind, temperature, and moisture information on the simulated diurnal cycle of precipitation over the western coast of Sumatra. We show how assimilating such high-frequency in situ observations can improve the simulated diurnal cycle, verified against satellite-derived precipitation, radar-derived precipitation, and rain gauge data. The improvements are due to a better representation of the sea breeze and increased available moisture in the lowest 4 km prior to peak convection. Assimilating wind information alone was sufficient to improve the simulations. We also highlight how during the assimilation, certain multivariate background error constraints and moisture addition in an ad hoc manner can negatively impact the simulations. Other approaches should be explored to better exploit information from such high-frequency observations over this region.
doi_str_mv	10.1175/MWR-D-20-0423.1
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We show how assimilating such high-frequency in situ observations can improve the simulated diurnal cycle, verified against satellite-derived precipitation, radar-derived precipitation, and rain gauge data. The improvements are due to a better representation of the sea breeze and increased available moisture in the lowest 4 km prior to peak convection. Assimilating wind information alone was sufficient to improve the simulations. We also highlight how during the assimilation, certain multivariate background error constraints and moisture addition in an ad hoc manner can negatively impact the simulations. 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We show how assimilating such high-frequency in situ observations can improve the simulated diurnal cycle, verified against satellite-derived precipitation, radar-derived precipitation, and rain gauge data. The improvements are due to a better representation of the sea breeze and increased available moisture in the lowest 4 km prior to peak convection. Assimilating wind information alone was sufficient to improve the simulations. We also highlight how during the assimilation, certain multivariate background error constraints and moisture addition in an ad hoc manner can negatively impact the simulations. 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the Simulated Diurnal Cycle of Precipitation to 3-Hourly Radiosonde Assimilation: A Case Study over the Western Maritime Continent</atitle><jtitle>Monthly weather review</jtitle><date>2021-10</date><risdate>2021</risdate><volume>149</volume><issue>10</issue><spage>3449</spage><epage>3468</epage><pages>3449-3468</pages><issn>0027-0644</issn><eissn>1520-0493</eissn><abstract>The diurnal cycle is the most prominent mode of rainfall variability in the tropics, governed mainly by the strong solar heating and land–sea interactions that trigger convection. Over the western Maritime Continent, complex orographic and coastal effects can also play an important role. Weather and climate models often struggle to represent these physical processes, resulting in substantial model biases in simulations over the region. For numerical weather prediction, these biases manifest themselves in the initial conditions, leading to phase and amplitude errors in the diurnal cycle of precipitation. Using a tropical convective-scale data assimilation system, we assimilate 3-hourly radiosonde data from the pilot field campaign of the Years of Maritime Continent, in addition to existing available observations, to diagnose the model biases and assess the relative impacts of the additional wind, temperature, and moisture information on the simulated diurnal cycle of precipitation over the western coast of Sumatra. We show how assimilating such high-frequency in situ observations can improve the simulated diurnal cycle, verified against satellite-derived precipitation, radar-derived precipitation, and rain gauge data. The improvements are due to a better representation of the sea breeze and increased available moisture in the lowest 4 km prior to peak convection. Assimilating wind information alone was sufficient to improve the simulations. We also highlight how during the assimilation, certain multivariate background error constraints and moisture addition in an ad hoc manner can negatively impact the simulations. Other approaches should be explored to better exploit information from such high-frequency observations over this region.</abstract><cop>Washington</cop><pub>American Meteorological Society</pub><doi>10.1175/MWR-D-20-0423.1</doi><tpages>20</tpages><orcidid>https://orcid.org/0000-0002-3708-1532</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Atmospheric precipitations Case studies Climate models Coastal effects Coasts Convection Convection heating Data assimilation Data collection Diurnal Diurnal cycle Diurnal variations Experiments Initial conditions Moisture Moisture effects Numerical prediction Numerical weather forecasting Precipitation Radar Radiosonde data Radiosondes Rain Rain gauges Rainfall Rainfall variability Sea breezes Simulation Solar heating Topography Tropical climate Tropical environments Variables Weather forecasting Wind
title	On the Sensitivity of the Simulated Diurnal Cycle of Precipitation to 3-Hourly Radiosonde Assimilation: A Case Study over the Western Maritime Continent
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