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Chiyuan Miao
,
Qiaohong Sun
,
Dongxian Kong
, and
Qingyun Duan
Full access

NOAA'S ADVANCED HYDROLOGIC PREDICTION SERVICE

Building Pathways for Better Science in Water Forecasting

John McEnery
,
John Ingram
,
Qingyun Duan
,
Thomas Adams
, and
Lee Anderson

The National Oceanic and Atmospheric Administration (NOAA) National Weather Service (NWS) Advanced Hydrologic Prediction Service (AHPS) program was established to meet our nation's need for more precise flash-flood forecast information. AHPS uses NOAA investments in remote sensing, precipitation forecasts, climate predictions, data automation, hydrologic science, and operational forecast system technologies. AHPS establishes a pathway for the infusion of new verified science and technology, and expands the use of NWS climate, weather, and water analyses and information products. State-of-the-art science is used for improved operational forecasting of floods, and drought conditions. The objective is to deliver more precise forecast information over greater temporal scales (hours, days, and months) and to depict the magnitude and certainty of occurrence for events ranging from droughts to floods. The AHPS program improves flash-flood forecasts, and provides ensemble streamflow forecasting and flood-forecast maps. AHPS information is accessible to customers by the internet with texts and graphics. This paper describes AHPS forecasting services and their implementation status.

Full access
Qiaohong Sun
,
Chiyuan Miao
,
Amir AghaKouchak
,
Iman Mallakpour
,
Duoying Ji
, and
Qingyun Duan

Abstract

Predicting the changes in teleconnection patterns and related hydroclimate extremes can provide vital information necessary to adapt to the effects of the El Niño–Southern Oscillation (ENSO). This study uses the outputs of global climate models to assess the changes in ENSO-related dry/wet patterns and the frequency of severe dry/wet events. The results show anomalous precipitation responding asymmetrically to La Niña and El Niño, indicating the teleconnections may not simply be strengthened. A “dry to drier, wet to wetter” annual anomalous precipitation pattern was projected during La Niña phases in some regions, with drier conditions over southern North America, southern South America, and southern central Asia, and wetter conditions in Southeast Asia and Australia. These results are robust, with agreement from the 26 models and from a subset of 8 models selected for their good performance in capturing observed patterns. However, we did not observe a similar strengthening of anomalous precipitation during future El Niño phases, for which the uncertainties in the projected influences are large. Under the RCP4.5 emissions scenario, 45 river basins under El Niño conditions and 39 river basins under La Niña conditions were predicted to experience an increase in the frequency of severe dry events; similarly, 59 river basins under El Niño conditions and 61 river basins under La Niña conditions were predicted to have an increase in the frequency of severe wet events, suggesting a likely increase in the risk of floods. Our results highlight the implications of changes in ENSO patterns for natural hazards, disaster management, and engineering infrastructure.

Free access
Qiaohong Sun
,
Chiyuan Miao
,
Amir AghaKouchak
,
Iman Mallakpour
,
Duoying Ji
, and
Qingyun Duan
Full access
Peyman Abbaszadeh
,
Hamid Moradkhani
,
Keyhan Gavahi
,
Sujay Kumar
,
Christopher Hain
,
Xiwu Zhan
,
Qingyun Duan
,
Christa Peters-Lidard
, and
Sepehr Karimiziarani
Full access
Peyman Abbaszadeh
,
Hamid Moradkhani
,
Keyhan Gavahi
,
Sujay Kumar
,
Christopher Hain
,
Xiwu Zhan
,
Qingyun Duan
,
Christa Peters-Lidard
, and
Sepehr Karimiziarani
Full access
Yun Qian
,
Charles Jackson
,
Filippo Giorgi
,
Ben Booth
,
Qingyun Duan
,
Chris Forest
,
Dave Higdon
,
Z. Jason Hou
, and
Gabriel Huerta
Full access
Frédéric Hourdin
,
Thorsten Mauritsen
,
Andrew Gettelman
,
Jean-Christophe Golaz
,
Venkatramani Balaji
,
Qingyun Duan
,
Doris Folini
,
Duoying Ji
,
Daniel Klocke
,
Yun Qian
,
Florian Rauser
,
Catherine Rio
,
Lorenzo Tomassini
,
Masahiro Watanabe
, and
Daniel Williamson

Abstract

The process of parameter estimation targeting a chosen set of observations is an essential aspect of numerical modeling. This process is usually named tuning in the climate modeling community. In climate models, the variety and complexity of physical processes involved, and their interplay through a wide range of spatial and temporal scales, must be summarized in a series of approximate submodels. Most submodels depend on uncertain parameters. Tuning consists of adjusting the values of these parameters to bring the solution as a whole into line with aspects of the observed climate. Tuning is an essential aspect of climate modeling with its own scientific issues, which is probably not advertised enough outside the community of model developers. Optimization of climate models raises important questions about whether tuning methods a priori constrain the model results in unintended ways that would affect our confidence in climate projections. Here, we present the definition and rationale behind model tuning, review specific methodological aspects, and survey the diversity of tuning approaches used in current climate models. We also discuss the challenges and opportunities in applying so-called objective methods in climate model tuning. We discuss how tuning methodologies may affect fundamental results of climate models, such as climate sensitivity. The article concludes with a series of recommendations to make the process of climate model tuning more transparent.

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Efi Foufoula-Georgiou
,
Clement Guilloteau
,
Phu Nguyen
,
Amir Aghakouchak
,
Kuo-Lin Hsu
,
Antonio Busalacchi
,
F. Joseph Turk
,
Christa Peters-Lidard
,
Taikan Oki
,
Qingyun Duan
,
Witold Krajewski
,
Remko Uijlenhoet
,
Ana Barros
,
Pierre Kirstetter
,
William Logan
,
Terri Hogue
,
Hoshin Gupta
, and
Vincenzo Levizzani
Free access
Graeme Stephens
,
Jan Polcher
,
Xubin Zeng
,
Peter van Oevelen
,
Germán Poveda
,
Michael Bosilovich
,
Myoung-Hwan Ahn
,
Gianpaolo Balsamo
,
Qingyun Duan
,
Gabriele Hegerl
,
Christian Jakob
,
Benjamin Lamptey
,
Ruby Leung
,
Maria Piles
,
Zhongbo Su
,
Paul Dirmeyer
,
Kirsten L. Findell
,
Anne Verhoef
,
Michael Ek
,
Tristan L’Ecuyer
,
Rémy Roca
,
Ali Nazemi
,
Francina Dominguez
,
Daniel Klocke
, and
Sandrine Bony

Abstract

The Global Energy and Water Cycle Exchanges (GEWEX) project was created more than 30 years ago within the framework of the World Climate Research Programme (WCRP). The aim of this initiative was to address major gaps in our understanding of Earth’s energy and water cycles given a lack of information about the basic fluxes and associated reservoirs of these cycles. GEWEX sought to acquire and set standards for climatological data on variables essential for quantifying water and energy fluxes and for closing budgets at the regional and global scales. In so doing, GEWEX activities led to a greatly improved understanding of processes and our ability to predict them. Such understanding was viewed then, as it remains today, essential for advancing weather and climate prediction from global to regional scales. GEWEX has also demonstrated over time the importance of a wider engagement of different communities and the necessity of international collaboration for making progress on understanding and on the monitoring of the changes in the energy and water cycles under ever increasing human pressures. This paper reflects on the first 30 years of evolution and progress that has occurred within GEWEX. This evolution is presented in terms of three main phases of activity. Progress toward the main goals of GEWEX is highlighted by calling out a few achievements from each phase. A vision of the path forward for the coming decade, including the goals of GEWEX for the future, are also described.

Open access