Your search keyword '"Zhao, Jiuwei"' showing total 6 results

1. Recent increase in rapid intensification events of tropical cyclones along China coast

Author

Li, Xiaomeng, Zhan, Ruifen, Wang, Yuqing, Zhao, Jiuwei, Ding, Yihui, and Song, Kexin

Published

2024

2. Relative contributions of global warming, AMO and IPO to the land precipitation variabilities since 1930s

Author

Tao, Li, Liang, X. San, Cai, Lin, Zhao, Jiuwei, and Zhang, Meng

Published

2021

3. Mutating ENSO Impact on Northwest Pacific Tropical Cyclones Under Global Warming.

Author

Shi, Liang, Zhan, Ruifen, Zhao, Jiuwei, and Kug, Jong‐Seong

Subjects

SOUTHERN oscillation, GLOBAL warming, TROPICAL cyclones, EL Nino, ATMOSPHERIC circulation, AUTUMN

Abstract

A prominent feature of the western North Pacific tropical cyclone genesis frequency (TCGF) anomaly in response to El Niño‐Southern Oscillation (ENSO) is a distinct west‐east dipole structure in the present‐day (PD) climate. Here, large ensemble high‐resolution simulations show that the current dipole may transform into a monopole under global warming (GW). In the PD climate, the ENSO‐induced dipole effect on TCGF is mainly observed in late autumn. However, GW accelerates this effect into the summer by amplifying atmospheric circulation anomalies. Consequently, this leads to a significant increase in the coastal TCGF during the development phase of El Niño under GW. Meanwhile, it weakens the anomalous anticyclonic circulation during late autumn, leading to an increase in coastal TCGF during the mature phase of El Niño, and vice versa. Therefore, the combined effect suggests a potential trend toward spatial homogenization during ENSO phases under GW. Plain Language Summary: El Niño‐Southern Oscillation (ENSO) typically has a dipole impact on tropical cyclone genesis frequency (TCGF) over the western North Pacific (WNP) in the current climate. During the warm phase of ENSO, there is a significant increase in TCGF over the southeastern part of the WNP (open‐sea region), but a decrease over its northwestern part (coastal region). The opposite pattern occurs during the cold phase of ENSO. However, under global warming (GW), this dipole pattern could transform into a basin‐uniform change in TCGF. In the present climate, ENSO primarily affects TCGF only over the open‐sea region during the summer (June to August) but causes a dipole pattern of TCGF anomalies in the autumn (September–November). The summer TCGF over the coastal region is less influenced by ENSO. Hence, the dipole pattern of TCGF anomalies from summer to autumn is mainly contributed by the anomaly in autumn TCGF over the coastal region. However, GW could extend the ENSO impact on coastal TCGF to summer. Therefore, the TCGF anomaly in summer offsets the opposite TCGF anomaly in autumn over the coastal region during the ENSO phase, resulting in a more consistent change in TCGF anomalies across the region under GW. Key Points: The dipole pattern of tropical cyclone genesis frequency (TCGF) during June–November in response to El Niño‐Southern Oscillation (ENSO) over the western North Pacific may transform into a monopole under global warming (GW)The present‐day dipole of TCGF anomaly is mainly observed in late‐autumn, while GW accelerates this impact to summerGW amplifies cyclonic (anticyclonic) circulation during warm (cold) ENSO phases, causing a basin‐uniform TCGF change [ABSTRACT FROM AUTHOR]

Published

2024

4. How Does Tropical Cyclone Genesis Frequency Respond to a Changing Climate?

Author

Zhao, Jiuwei, Wang, Fang, Zhan, Ruifen, Guo, Yipeng, Huang, Xin, and Liu, Chao

Subjects

*TROPICAL cyclones, *OCEAN temperature, *CLIMATE change, *HUMIDITY, *GLOBAL warming, *SURVIVAL rate

Abstract

Global tropical cyclone (TC) genesis frequency (TCGF) has been documented to decrease or increase linearly in a changing climate. However, our numerical experiments show that the global TCGF exhibits a parabolic relation with spatio‐uniform climate changes in sea surface temperature (SST) from −15 K to 5 K relative to the present climate, with the peak in the 5 K‐cooler climate. The parabolic relation is found in all TC basins except the eastern North Pacific where TCGF keeps increasing with the changing climate. TCGF can be expressed as the product of the frequency of TC seeds and the TC survival rate (SR). Further analysis shows that this parabolic structure in the global TCGF depends on TC seeds rather than the TC SR. The TC SR exhibits an increasing trend with the SST increase, while TC seeds show a consistent change with TCGF, which might be linked to the changes in low‐level relative humidity. Plain Language Summary: It is a hot‐debated question as to how tropical cyclone (TC) genesis frequency (TCGF) would change under global warming. To address this problem, we examine the TCGF change in response to a simplified spatio‐uniform change of sea surface temperature (SST) from −15 K to 5 K relative to the present climate. The global TCGF begins to increase with the global SST increase from −15 K, reaches peak in the 5 K‐cooler climate, and subsequently decreases with further SST warming, forming a parabolic relation between the TCGF and the SST changes. Further, we find the parabolic relationship in all TC basins except the eastern North Pacific where the TCGF keeps increasing with SST changes. TCGF can be expressed as the product of the frequency of TC seeds and the TC survival rate (SR). Further analysis shows the TC SR cannot explain the global TCGF change, while the changes in frequency of TC seeds associated with the low‐level relative humidity contribute to the parabolic change of TCGF. Key Points: The global tropical cyclone (TC) genesis frequency (TCGF) in response to uniform sea surface temperature (SST) changes shows a parabolic relation with a peak under 5 K‐cooler climate than current climateThe parabolic relation was found in all TC basins except the eastern North Pacific where the TCGF keeps increasing with SST changesSuch a parabolic relation was attributed to the change in TC seed frequency [ABSTRACT FROM AUTHOR]

Published

2023

5. A Multiscale‐Model‐Based Near‐Term Prediction of Tropical Cyclone Genesis Frequency in the Northern Hemisphere.

Author

Zhao, Jiuwei, Zhan, Ruifen, Wang, Yuqing, Jiang, Leishan, and Huang, Xin

Subjects

TROPICAL cyclones, CYCLONE forecasting, ATLANTIC multidecadal oscillation, EL Nino, ATMOSPHERIC models, OCEAN temperature

Abstract

Near‐term prediction of tropical cyclone (TC) activity is of great importance to formulate the long‐term plans for mitigating the potential TC‐induced damages. Here, we introduce a multi‐timescale regression model of TC genesis frequency (TCGF), which includes contributions by three interannual modes (El Niño‐Southern Oscillation, sea surface temperature anomalies over the eastern Indian Ocean and tropical North Atlantic), two interdecadal modes (the Atlantic Multidecadal Oscillation and the Interdecadal Pacific Oscillation), and a global warming mode. The model is shown to be able to capture well the present‐day multi‐timescale changes in TCGF in the major TC basins in the Northern Hemisphere. By combining the model and 100‐member simulations by the Max Planck Institute Earth System Model, we predict a robust increase in TCGF over the eastern North Pacific, an insignificant increase over the western North Pacific, and little change over the North Atlantic during 2020–2030 relative to 2009–2019. Plain Language Summary: How tropical cyclone (TC) activity will change in the next decade or so is especially important for government policymakers. However, the field on TC activity is very much in its infancy. Here we predict the near‐term changes in TC genesis frequency (TCGF) in the three main TC basins in the Northern Hemisphere, namely the western North Pacific, the eastern North Pacific, and the North Atlantic, by combining a new multi‐timescale regression model and the state‐of‐the‐art climate model projections. This regression model is constructed based on six key climate factors on different time scales, and can well reproduce the present‐day TCGF change during 1960–2019. The model predicts a significant increase in TCGF over the eastern North Pacific while insignificant change over the other two basins in the next 10 years. Key Points: We have developed a multi‐timescale regression model to represent changes in tropical cyclone (TC) genesis frequency (TCGF)The model can capture well the present‐day multi‐timescale changes in TCGF in the major TC basins in the Northern HemisphereThe model is used to conduct near‐term prediction of TCGF in the Northern Hemisphere by combining climate model projections [ABSTRACT FROM AUTHOR]

Published

2022

6. Different Responses of Tropical Cyclone Tracks Over the Western North Pacific and North Atlantic to Two Distinct Sea Surface Temperature Warming Patterns.

Author

Zhao, Jiuwei, Zhan, Ruifen, and Wang, Yuqing

Subjects

*OCEAN temperature, *CYCLONE tracking, *TROPICAL cyclones, *GLOBAL warming, *ATMOSPHERIC models

Abstract

How future tropical cyclone (TC) activity could change under global warming is enormously important to society, which has been widely assessed using state‐of‐the‐art climate models. However, these models were predominantly based on projection of an El Niño‐like warming pattern. Recent studies suggested that a La Niña‐like warming pattern is also possible. Here we compare the responses of TC track density (TCTD) over the western North Pacific and North Atlantic to the two distinct global warming patterns. We find that the La Niña‐like warming pattern reduces western North Pacific TCTD except in the South China Sea and along China coast and increases NA TCTD, while the El Niño‐like warming pattern generally reduces TCTD in both basins. This is due to different responses of large‐scale dynamic/thermodynamic conditions to the distinct zonal sea surface temperature gradients associated with the two warming patterns. These results help better understand potential future change in TC tracks. Key Points: The La Niña‐like warming reduces (increases) TC track density in the main WNP (NA), while the El Niño‐like warming reduces it in two basinsThe different responses are due to the different tropical zonal SST gradients associated with the two warming patternsChina and North America would experience more landfalling TCs in La Niña‐like warming pattern than in El Niño‐like warming pattern [ABSTRACT FROM AUTHOR]

Published

2020