Your search keyword '"Du, Yan"' showing total 4 results

1. Vertical structures of marine heatwaves.

Author

Zhang, Ying, Du, Yan, Feng, Ming, and Hobday, Alistair J.

Subjects

MARINE heatwaves, OFFSHORE structures, GLOBAL warming, ROSSBY waves, ECOLOGICAL impact, OCEAN

Abstract

A marine heatwave (MHW) is typically defined as an anomalous warm event in the surface ocean, with wide-ranging impacts on marine and socio-economic systems. The surface warming associated with MHWs can penetrate into the deep ocean; however, the vertical structure of MHWs is poorly known in the global ocean. Here, we identify four main types of MHWs with different vertical structures using Argo profiles: shallow, subsurface-reversed, subsurface-intensified, and deep MHWs. These MHW types are characterized by different spatial distributions with hotspots of subsurface-reversed and subsurface-intensified MHWs at low latitudes and shallow and deep MHWs at middle-high latitudes. These vertical structures are influenced by ocean dynamical processes, including oceanic planetary waves, boundary currents, eddies, and mixing. The area and depth of all types of MHWs exhibit significant increasing trends over the past two decades. These results contribute to a better understanding of the physical drivers and ecological impacts of MHWs in a warming climate. The authors identify four main types of vertical structures of marine heatwaves, with different impact depths and spatio-temporal distributions, that are influenced by multiscale ocean dynamical processes. [ABSTRACT FROM AUTHOR]

Published

2023

2. Large South Equatorial Current Meander in the Southeastern Tropical Indian Ocean Captured by Surface Drifters Deployed in 2019.

Author

Wu, Wei, Du, Yan, Qian, Yu‐Kun, Chen, Ju, and Jiang, Xingwei

Subjects

*OCEAN, *ROSSBY waves, *OCEAN currents, *GEOSTROPHIC currents, *HISTORICAL analysis, KUROSHIO

Abstract

To investigate the South Equatorial Current (SEC) in the Indian Ocean, 18 drifters were deployed off Sumatra‐Java during boreal spring 2019. These drifter observations revealed a large SEC meander that swung southward about 1,100 km during 40 days along ∼100°E. The southward motion occurred on the eastern edge of the Seychelles‐Chagos thermocline ridge, accompanied by an anticyclonic eddy/Rossby wave from the east, indicated by the geostrophic velocity induced by the zonal pressure gradient. Meanwhile, the ageostrophic velocity induced by the southeasterly wind also contributes to this southward motion. This is verified by a Lagrangian Trajectory Model in which drifter trajectories are well reproduced using Chinese‐French Oceanic SATellite winds products. Further analysis of the historical drifters with similar trajectories reveals that the geostrophic and ageostrophic currents jointly drive drifters to move southward. Ageostrophic component could contribute up to 45% of the southward movement of the SEC meander. Plain Language Summary: The South Equatorial Current (SEC) is westward in the tropical Indian Ocean. During boreal spring 2019, 18 drifters were deployed off Sumatra‐Java, and their trajectories show a large SEC meander, with a typical drifter moved southward over 1,100 km during 40 days along ∼100°E. The geostrophic component, associated with the Seychelles‐Chagos thermocline ridge and an anticyclonic eddy/Rossby wave, and ageostrophic component, induced by southeasterly wind, jointly drive drifters to move southward. Further diagnoses of historical drifters show that the ageostrophic component could take up to 45% contribution in the southward movement in the SEC meander. Key Points: South Equatorial Current in the Indian Ocean advected drifters southward more than 1,100 km within 40 days (∼32 cm s−1) in 2019Combined effects of the zonal pressure gradient and the southeasterly wind contribute to the southward movementSouthward movement usually occurs in spring and summer, contributing from ageostrophic current up to ∼45% [ABSTRACT FROM AUTHOR]

Published

2022

3. Long‐Lasting Marine Heatwaves Instigated by Ocean Planetary Waves in the Tropical Indian Ocean During 2015–2016 and 2019–2020.

Author

Zhang, Ying, Du, Yan, Feng, Ming, and Hu, Shijian

Subjects

*ROSSBY waves, *OCEAN waves, *OCEAN temperature, *INTERNAL waves, *GLOBAL warming, *MODES of variability (Climatology), *OCEAN

Abstract

Marine heatwaves (MHWs) in the tropical Indian Ocean (TIO) showed remarkable increases in duration and frequency during the satellite observing era, responding to rising sea surface temperature. Long‐lasting MHWs were found in three upwelling regions of the TIO in 2015–2016 and 2019–2020, closely related to persistent downwelling oceanic planetary waves. In 2015, a prolonged MHW (149 days) in the western TIO was initiated by the downwelling Rossby waves associated with the co‐occurring super El Niño and positive Indian Ocean dipole (IOD) events. In the following year, the negative IOD sustained the longest MHW (372 days) in the southeastern TIO, prompted by the eastward‐propagating equatorial Kelvin waves. In 2019–2020, the two longest MHWs recorded in the southwestern TIO (275 days in 2019 and 149 days in 2020) were maintained by the downwelling Rossby waves associated with the 2019 extreme IOD. This study revealed the importance of ocean dynamics in long‐lasting MHWs in the TIO. Plain Language Summary: Marine heatwaves (MHWs) are extreme sea surface warming events, which can have destructive impacts on marine ecosystems and socio‐economy. The tropical Indian Ocean (TIO) has experienced the most significant sea surface temperature warming among the global oceans in the satellite observing era since the 1980s. The increases in duration and frequency of MHWs were found statistically significant in the TIO, and further increases can be expected under global warming. Several long‐lasting MHWs occurred in recent years, associated with extreme climate modes. Internal ocean waves triggered by anomalous winds deepened the thermocline through the convergence of warm upper‐ocean water and reduced upwelling of subsurface cold water, resulting in a surface warm that facilitated the MHW formation. Thus, the consecutive propagating waves during the extreme climate events sustained the prolonged MHWs in the TIO. These results expand our understanding of the physical mechanisms responsible for MHWs in the TIO under the Indo‐Pacific climate variability and global warming. Key Points: Long‐lasting marine heatwaves (MHWs) occurred in the upwelling regions of the tropical Indian Ocean during 2015–2016 and 2019–2020The recent long‐lasting MHWs are related to the super El Niño in 2015–2016 and extreme Indian Ocean dipole in 2019Oceanic downwelling waves induced‐thermocline warming plays a crucial role in the long‐lasting MHWs [ABSTRACT FROM AUTHOR]

Published

2021

4. A Surface pCO2 Increasing Hiatus in the Equatorial Pacific Ocean Since 2010.

Author

Qiu, Shuang, Feng, Yang, Zhang, Yuhong, Qi, Di, Wu, Yingxu, and Du, Yan

Subjects

ATMOSPHERIC carbon dioxide, OCEAN, TRADE winds, PARTIAL pressure, STAGNATION point

Abstract

We used multiple data sets to investigate the decadal and longer time scale variability of sea surface partial pressure of CO2 (pCO2) over the equatorial Pacific Ocean from 1990 to 2019. Unlike the increasing trend in the global oceanic pCO2, both the Niño 3.4 and warm pool regions featured distinct decadal variabilities. A pCO2 increasing stagnation, a hiatus stage, was identified in the Niño 3.4 region from 2010 to 2019. Further analysis demonstrated that low‐frequency pCO2 was negatively correlated with the Interdecadal Pacific Oscillation (IPO) index. Both the 2009/10 and 2015/16 El Niño events and an increasing phase of IPO contributed to this long pCO2 stagnation. Correspondingly, a weaker upwelling was induced in the central and eastern tropical Pacific as the trade winds weakened and thus stagnated the increase in pCO2 in the Niño 3.4 region. Our results imply a significant impact of climate variabilities on sea surface pCO2 in the equatorial Pacific. Plain Language Summary: The equatorial Pacific Ocean is one of the largest natural sources of carbon dioxide (CO2) to the atmosphere. It can partially reduce the CO2 absorbed by large areas of the ocean. Here we use a series of data sets to investigate the long‐term variations in the sea surface partial pressure of CO2 over the equatorial Pacific Ocean. Unlike the increasing trend in the global ocean surface pCO2 due to the continuous increase in atmospheric CO2 impacted by human activities, the equatorial Pacific Ocean features significant long‐term variabilities. The pCO2 observations and products that we used support a pCO2 increasing hiatus at the Niño 3.4 region (located in the central and eastern equatorial Pacific Ocean) since 2010. Further analysis found that the hiatus is related to El Niño events and the large‐scale, long period oscillation of the Pacific basin. Our results imply the impact of natural climate variabilities on sea surface pCO2 in this important sea area of the equatorial Pacific Ocean. Key Points: The pCO2 in the equatorial Pacific features a significant long‐term trend and decadal to interdecadal variabilityThe increasing pCO2 in the Niño 3.4 region shows stagnation since 2010 due to El Niño events and the increasing phase of the Interdecadal Pacific OscillationPacific natural climate variability mitigates the large CO2 source in the tropical Pacific Ocean [ABSTRACT FROM AUTHOR]

Published

2021