Response of Tropical Cyclone Activity and Structure to Global Warming in a High-Resolution Global Nonhydrostatic Model

Yamada, Yohei; Satoh, Masaki; Sugi, Masato; Kodama, Chihiro; Noda, Akira; Nakano, Masuo; Nasuno, Tomoe

doi:10.1175/jcli-d-17-0068.1

Cited by 104 publications

(126 citation statements)

References 77 publications

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“…Both SST and OHC are projected to increase in the future (IPCC, ); there will be a warmer and wetter world over oceans and more energy available for evaporation (Emanuel, ; Trenberth & Fasullo, ; USGCRP, ; Yamada et al, ), facilitating more TC activity and more rainfall (Emanuel, ; Knutson et al, , ; Knutti & Sedláček, ; Vecchi & Soden, ; Walsh et al, ; Yamada et al, ). The question is whether the atmospheric conditions, in particular its stability and wind shear, also remain favorable, but these are likely at least episodically because convection plays a major role in stabilizing the atmosphere.…”

Section: Discussionmentioning

confidence: 99%

Hurricane Harvey Links to Ocean Heat Content and Climate Change Adaptation

et al. 2018

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While hurricanes occur naturally, human‐caused climate change is supercharging them and exacerbating the risk of major damage. Here using ocean and atmosphere observations, we demonstrate links between increased upper ocean heat content due to global warming with the extreme rainfalls from recent hurricanes. Hurricane Harvey provides an excellent case study as it was isolated in space and time. We show that prior to the beginning of northern summer of 2017, ocean heat content was the highest on record both globally and in the Gulf of Mexico, but the latter sharply decreased with hurricane Harvey via ocean evaporative cooling. The lost ocean heat was realized in the atmosphere as moisture, and then as latent heat in record‐breaking heavy rainfalls. Accordingly, record high ocean heat values not only increased the fuel available to sustain and intensify Harvey but also increased its flooding rains on land. Harvey could not have produced so much rain without human‐induced climate change. Results have implications for the role of hurricanes in climate. Proactive planning for the consequences of human‐caused climate change is not happening in many vulnerable areas, making the disasters much worse.

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Section: Discussionmentioning

confidence: 99%

Hurricane Harvey Links to Ocean Heat Content and Climate Change Adaptation

et al. 2018

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“…Kodama et al (2015) used this model with 14-km mesh to conduct climate simulations. Its outputs showed that the number of simulated ITCs matched the observational data (Satoh et al, , 2018Yamada et al, 2017). NICAM was utilized for investigating a relationship between TC genesis and intraseasonal oscillations Satoh et al, 2012;Taniguchi et al, 2010).…”

Section: Supporting Informationmentioning

confidence: 99%

High‐Resolution Ensemble Simulations of Intense Tropical Cyclones and Their Internal Variability During the El Niños of 1997 and 2015

Yamada

Kodama

Satoh

et al. 2019

Geophysical Research Letters

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Extreme El Niño events affect the number of intense tropical cyclones (ITCs) over the western North Pacific (WNP). In 1997 and 2015, both extreme El Niño years, ITC numbers were above normal in the WNP. In order to clarify how, and to what extent, sea surface temperature anomaly (SSTA) distributions control the ITCs genesis, the authors conducted 50‐member ensemble simulations using a high‐resolution global nonhydrostatic model that explicitly simulates ITCs. The ensemble simulations showed a clear relationship between the number of ITCs and their genesis locations in the WNP. However, the authors found that the simulated numbers of ITCs in the WNP were also closely related to the strength of the monsoon trough, which varies under given SSTA conditions. This indicates that reliable seasonal forecasting of ITCs depends on our ability to accurately reproduce the monsoon trough, whose strength is modulated mainly by internal atmospheric variability but also by SSTA.

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“…As model resolution increases, stochastic approaches will become more valuable, as representing the interaction of the resolved scales with the subgrid through purely deterministic schemes becomes harder to justify (Dorrestijn et al 2013). 2) Global cloud-system-resolving models are a particularly important tool for understanding multiscale structures, such as the large-scale and synoptic environment of tropical cyclogenesis Yamada et al 2017) or largescale sea breezes and convection initiation (Birch et al 2015). They also demonstrate the potential of models in complementing and enhancing observations, for example, the discovery by Miyakawa et al (2012) of the three-fold structure of convective momentum transport associated with the Madden-Julian oscillation (MJO), using the high-resolution data by Miura et al (2007).…”

Section: Future Prospects and Challengesmentioning

confidence: 99%

The Benefits of Global High Resolution for Climate Simulation: Process Understanding and the Enabling of Stakeholder Decisions at the Regional Scale

Roberts

Vidale

Senior

et al. 2018

Bulletin of the American Meteorological Society

128

107

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The time scales of the Paris Climate Agreement indicate urgent action is required on climate policies over the next few decades, in order to avoid the worst risks posed by climate change. On these relatively short time scales the combined effect of climate variability and change are both key drivers of extreme events, with decadal time scales also important for infrastructure planning. Hence, in order to assess climate risk on such time scales, we require climate models to be able to represent key aspects of both internally driven climate variability and the response to changing forcings. In this paper we argue that we now have the modeling capability to address these requirements—specifically with global models having horizontal resolutions considerably enhanced from those typically used in previous Intergovernmental Panel on Climate Change (IPCC) and Coupled Model Intercomparison Project (CMIP) exercises. The improved representation of weather and climate processes in such models underpins our enhanced confidence in predictions and projections, as well as providing improved forcing to regional models, which are better able to represent local-scale extremes (such as convective precipitation). We choose the global water cycle as an illustrative example because it is governed by a chain of processes for which there is growing evidence of the benefits of higher resolution. At the same time it comprises key processes involved in many of the expected future climate extremes (e.g., flooding, drought, tropical and midlatitude storms).

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Response of Tropical Cyclone Activity and Structure to Global Warming in a High-Resolution Global Nonhydrostatic Model

Cited by 104 publications

References 77 publications

Hurricane Harvey Links to Ocean Heat Content and Climate Change Adaptation

Hurricane Harvey Links to Ocean Heat Content and Climate Change Adaptation

High‐Resolution Ensemble Simulations of Intense Tropical Cyclones and Their Internal Variability During the El Niños of 1997 and 2015

The Benefits of Global High Resolution for Climate Simulation: Process Understanding and the Enabling of Stakeholder Decisions at the Regional Scale

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