Your search keyword '"Zhuoqi He"' showing total 9 results

1. Attenuation of Central Pacific El Niño Amplitude by North Pacific Sea Surface Temperature Anomalies

Author

Chi-Yung Tam, Kang Xu, Xiao-Yi Yang, Boqi Liu, Qiang Xie, Zhuoqi He, Sheng Chen, and Weiqiang Wang

Subjects

Atmospheric Science, Sea surface temperature, Amplitude, 010504 meteorology & atmospheric sciences, El Niño, Climatology, Attenuation, 010502 geochemistry & geophysics, 01 natural sciences, Geology, 0105 earth and related environmental sciences

Abstract

There exists a pronounced asymmetry between the amplitudes of central Pacific (CP) and eastern Pacific (EP) El Niño sea surface temperature anomalies (SSTA). The present study examines such an asymmetry and its relationship with the North Pacific SSTA. Results indicate that the weaker CP El Niño amplitude can be attributed to the weaker anomalous zonal wind response to the east–west equatorial SSTA gradient during its growing phase compared with EP El Niño. Furthermore, the occurrence of CP El Niño is closely associated with southwesterly surface wind anomalies in the subtropical North Pacific, as well as ocean warming reminiscent of the North Pacific Gyre Oscillation (NPGO) pattern in its vicinity. Both the observations as well as the pacemaker experiments with a coupled global climate model suggest that the anomalous low-level southwesterlies, induced by the North Pacific Oscillation (NPO)-like atmospheric variability, can enhance anomalously positive SST signals and extend them southwestward to the central equatorial Pacific via the wind–evaporation–SST feedback. This will further attenuate the atmospheric response to zonal SSTA gradient, and hence weaken the amplitude of CP El Niño. Therefore, anomalous low-level southwesterlies over the subtropical North Pacific can effectively act as a conduit for tropical–subtropical air–sea interaction in that region, and can play an important role in limiting the intensity of CP El Niño.

Published

2020

2. Change in Coherence of Summer Rainfall Variability over the Western Pacific around the Early 2000s: ENSO Influence

Author

Renguang Wu, Chao He, Kang Xu, Sheng Chen, Zhuoqi He, Xiuzhen Li, In-Sik Kang, and Weiqiang Wang

Subjects

Atmospheric Science, El Niño Southern Oscillation, Geography, 010504 meteorology & atmospheric sciences, Climatology, Climate change, Coherence (statistics), 010502 geochemistry & geophysics, 01 natural sciences, Pacific ocean, 0105 earth and related environmental sciences

Abstract

This study is the second part of a two-part series investigating a recent decadal modulation of interannual variability over the western Pacific Ocean around the early 2000s. Observational evidence shows that the anomalous Philippine Sea cyclonic circulation retreats eastward, with the western Pacific rainfall anomaly distribution changing from a north–south tripole pattern to an east–west dipole pattern after 2003–04. These changes are attributed to a change in El Niño–Southern Oscillation (ENSO) properties and the associated Indo-Pacific sea surface temperature (SST) anomaly pattern. Before the early 2000s, slow-decaying ENSO events induce large SST anomalies in the northern Indian Ocean during the following summer. The northern Indian Ocean SST anomalies act together with the opposite-sign SST anomalies in the tropical central Pacific, leading to a zonally extended anomalous lower-level cyclonic (anticyclonic) circulation and an elongated rainfall anomaly band over the western Pacific. After the early 2000s, ENSO events have a shortened period and a weakened amplitude, and the eastern Pacific SST anomalies tend to undergo a phase transition from winter to summer. Consequently, the influence of ENSO on the Indian Ocean SST anomalies is weakened and the contribution of the northern Indian Ocean SST anomalies to the western Pacific summer rainfall variability becomes insignificant. In this case, the western North Pacific summer rainfall is mainly dominated by the well-developed tropical Pacific SST forcing following the early decay of ENSO events. The potential physical mechanism for the two types of ENSO influences is validated with regional decoupled Community Earth System Model experiments.

Published

2020

3. Change in Coherence of Interannual Variability of Summer Rainfall over the Western Pacific around the Early 2000s: Role of Indo-Pacific Ocean Forcing

Author

Zhuoqi He and Renguang Wu

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Climate change, Forcing (mathematics), Seasonality, 010502 geochemistry & geophysics, medicine.disease, 01 natural sciences, Atmosphere, Sea surface temperature, Climatology, Period (geology), medicine, Cyclone, Geology, Indo-Pacific, 0105 earth and related environmental sciences

Abstract

The observations show that the covariability between the western North Pacific (WNP) and the South China Sea (SCS) summer rainfall has experienced an obvious weakening since the early 2000s. During the period 1982–2003, the combined north Indian Ocean (NIO), central North Pacific (CNP), and central equatorial Pacific (CEP) sea surface temperature (SST) forcing results in a high coherence between the WNP and SCS summer rainfall variations via a zonally elongated anomalous lower-level cyclone over the western Pacific. During the period 2004–16, the Indian Ocean SST contribution is largely weakened, and the WNP rainfall variability is dominated by the enhanced Pacific SST forcing with an eastward retreated lower-level wind and rainfall anomalies, whereas the SCS rainfall variability is mainly associated with local air–sea interaction processes. The results obtained from observational analysis are supported by numerical experiments with atmospheric and coupled general circulation models. The change in the coherence of interannual summer rainfall variability over the WNP and SCS has important implications for regional climate prediction in South and East Asia.

Published

2018

4. Two Distinctive Processes for Abnormal Spring to Summer Transition over the South China Sea

Author

Zhuoqi He and Renguang Wu

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Tropics, Seasonality, 010502 geochemistry & geophysics, medicine.disease, 01 natural sciences, La Niña, Sea surface temperature, Oceanography, Climatology, Spring (hydrology), medicine, Period (geology), Walker circulation, Cyclone, Geology, 0105 earth and related environmental sciences

Abstract

The period from April to June signifies the transition from spring to summer over the South China Sea (SCS). The present study documents two distinct processes for abnormal spring to summer transition over the SCS. One process is related to large-scale sea surface temperature (SST) anomalies in the tropical Indo-Pacific region. During spring of La Niña decaying years, negative SST anomalies in the equatorial central Pacific (ECP) and the southwestern tropical Indian Ocean (TIO) coexist with positive SST anomalies in the tropical western North Pacific. Negative ECP SST anomalies force an anomalous Walker circulation, negative southwestern TIO SST anomalies induce anomalous cross-equatorial flows from there, and positive tropical western North Pacific SST anomalies produce a Rossby wave–type response to the west. Together, they contribute to enhanced convection and an anomalous lower-level cyclone over the SCS, leading to an advanced transition to summer there. The other process is related to regional air–sea interactions around the Maritime Continent. Preceding positive ECP SST anomalies induce anomalous descent around the Maritime Continent, leading to SST increase in the SCS and southeast TIO. An enhanced convection region moves eastward over the south TIO during spring and reaches the area northwest of Australia in May. This enhances descent over the SCS via an anomalous cross-equatorial overturning circulation and contributes to further warming in the SCS. The SST warming in turn induces convection over the SCS, leading to an accelerated transition to summer. Analysis shows that the above two processes are equally important during 1979–2015.

Published

2017

5. Contributions of Surface Heat Fluxes and Oceanic Processes to Tropical SST Changes: Seasonal and Regional Dependence

Author

Dongxiao Wang, Weiqiang Wang, Zhuoqi He, Renguang Wu, and Zhiping Wen

Subjects

Atmospheric Science, Heat budget, 010504 meteorology & atmospheric sciences, 010505 oceanography, Advection, Seasonality, medicine.disease, 01 natural sciences, Surface heat flux, Sea surface temperature, Surface heat, Climatology, medicine, Environmental science, Spatial variability, Physics::Atmospheric and Oceanic Physics, Heat flow, 0105 earth and related environmental sciences

Abstract

The present study employs six surface heat flux datasets and three ocean assimilation products to assess the relative contributions of surface heat fluxes and oceanic processes to the sea surface temperature (SST) change in the tropical oceans. Large differences are identified in the major terms of the heat budget equation. The largest discrepancies among different datasets appear in the contribution of vertical advection. The heat budget is nearly balanced in the shortwave-radiation- and horizontal-advection-dominant cases but not balanced in some of the latent-heat-flux- and vertical-advection-dominant cases. The contributions of surface heat fluxes and ocean advections to the SST tendency display remarkable seasonal and regional dependence. The contribution of surface heat fluxes covers a large geographical area. The oceanic processes dominate the SST tendency in the near-equatorial regions with large values but small spatial scales. In the Pacific and Atlantic Oceans, the SST tendency is governed by the dynamic and thermodynamic processes, respectively, while a wide variety of processes contribute to the SST tendency in the Indian Ocean. Several regions have been selected to illustrate the dominant contributions of individual terms to the SST tendency in different seasons. The seasonality and regionality of the interannual air–sea relationship indicate a physical connection with the mean state.

Published

2017

6. Attenuation of Central Pacific El Niño Amplitude by North Pacific Sea Surface Temperature Anomalies.

Author

KANG XU, CHI-YUNG TAM, BOQI LIU, SHENG CHEN,1., XIAOYI YANG, ZHUOQI HE, QIANG XIE, and WEIQIANG WANG

Subjects

OCEAN temperature, ZONAL winds, ATMOSPHERIC models

Abstract

There exists a pronounced asymmetry between the amplitudes of central Pacific (CP) and eastern Pacific (EP) El Niño sea surface temperature anomalies (SSTA). The present study examines such an asymmetry and its relationship with the North Pacific SSTA. Results indicate that the weaker CP El Niño amplitude can be attributed to the weaker anomalous zonal wind response to the east–west equatorial SSTA gradient during its growing phase compared with EP El Niño. Furthermore, the occurrence of CP El Niño is closely associated with southwesterly surface wind anomalies in the subtropical North Pacific, as well as ocean warming reminiscent of the North Pacific Gyre Oscillation (NPGO) pattern in its vicinity. Both the observations as well as the pacemaker experiments with a coupled global climate model suggest that the anomalous low-level southwesterlies, induced by the North Pacific Oscillation (NPO)-like atmospheric variability, can enhance anomalously positive SST signals and extend them southwestward to the central equatorial Pacific via the wind–evaporation–SST feedback. This will further attenuate the atmospheric response to zonal SSTA gradient, and hence weaken the amplitude of CP El Niño. Therefore, anomalous low-level southwesterlies over the subtropical North Pacific can effectively act as a conduit for tropical–subtropical air–sea interaction in that region, and can play an important role in limiting the intensity of CP El Niño. [ABSTRACT FROM AUTHOR]

Published

2020

7. Change in Coherence of Summer Rainfall Variability over the Western Pacific around the Early 2000s: ENSO Influence.

Author

ZHUOQI HE, WEIQIANG WANG, RENGUANG WU, IN-SIK KANG, CHAO HE, XIUZHEN LI, KANG XU, and SHENG CHEN

Subjects

*RAINFALL anomalies, *OCEAN temperature, *RAINFALL, *SUMMER, EL Nino

Abstract

This study is the second part of a two-part series investigating a recent decadal modulation of interannual variability over the western Pacific Ocean around the early 2000s. Observational evidence shows that the anomalous Philippine Sea cyclonic circulation retreats eastward, with the western Pacific rainfall anomaly distribution changing from a north--south tripole pattern to an east--west dipole pattern after 2003-04. These changes are attributed to a change in ElNiño-Southern Oscillation (ENSO) properties and the associated Indo-Pacific sea surface temperature (SST) anomaly pattern. Before the early 2000s, slow-decaying ENSO events induce large SST anomalies in the northern Indian Ocean during the following summer. The northern Indian Ocean SST anomalies act together with the opposite-sign SST anomalies in the tropical central Pacific, leading to a zonally extended anomalous lower-level cyclonic (anticyclonic) circulation and an elongated rainfall anomaly band over the western Pacific. After the early 2000s, ENSO events have a shortened period and a weakened amplitude, and the eastern Pacific SST anomalies tend to undergo a phase transition fromwinter to summer.Consequently, the influence of ENSO on the Indian Ocean SST anomalies is weakened and the contribution of the northern Indian Ocean SST anomalies to the western Pacific summer rainfall variability becomes insignificant. In this case, the western North Pacific summer rainfall is mainly dominated by the well-developed tropical Pacific SST forcing following the early decay of ENSO events. The potential physical mechanism for the two types of ENSO in- fluences is validated with regional decoupled Community Earth System Model experiments. [ABSTRACT FROM AUTHOR]

Published

2020

8. ENSO Contribution to Aerosol Variations over the Maritime Continent and the Western North Pacific during 2000–10

Author

Zhuoqi He, Zhiping Wen, and Renguang Wu

Subjects

Atmospheric Science, Ocean current, Subtropics, Seasonality, medicine.disease, complex mixtures, Aerosol, Atmosphere, Deposition (aerosol physics), Climatology, medicine, Period (geology), Environmental science, Precipitation

Abstract

This study investigates interannual aerosol variations over the Maritime Continent and the western North Pacific Ocean and aerosol–cloud–precipitation relationship during the period 2000–10 based on monthly-mean anomalies. The local aerosol–cloud–precipitation relationship displays strong regional characteristics. The aerosol variation is negatively correlated with cloud and precipitation variation over the Maritime Continent, but is positively correlated with cloud and precipitation variation over the region southeast of Japan. Over broad subtropical oceanic regions, the aerosol variation is positively correlated with cloud variation, but has a weak correlation with precipitation variation. Aerosol variations over the Maritime Continent and over the region southeast of Japan display a biennial feature with an obvious phase lag of about 8 months in the latter region during 2001–07. This biennial feature is attributed to the impacts of El Niño events on aerosol variations in these regions through large-scale circulation and precipitation changes. Around October of El Niño–developing years, the suppressed precipitation over the Maritime Continent favors an aerosol increase by reducing the wet deposition and setting up dry conditions favorable for fire burning. During early summer of El Niño–decaying years, suppressed heating around the Philippines as a delayed response to El Niño warming induces an anomalous lower-level cyclone over the region to the southeast of Japan through an atmospheric teleconnection, leading to an accumulation of aerosol and increase of precipitation. The aerosol–precipitation relationship shows an obvious change with time over eastern China, leading to an overall weak correlation.

Published

2013

9. ENSO Contribution to Aerosol Variations over the Maritime Continent and the Western North Pacific during 2000-10.

Author

RENGUANG WU, ZHIPING WEN, and ZHUOQI HE

Subjects

METEOROLOGICAL precipitation measurement, RAINFALL anomalies, ATMOSPHERIC aerosols, RAINFALL probabilities, TELECONNECTIONS (Climatology), EL Nino

Abstract

This study investigates interannual aerosol variations over the Maritime Continent and the western North Pacific Ocean and aerosol-cloud-precipitation relationship during the period 2000-10 based on monthly-mean anomalies. The local aerosol-cloud-precipitation relationship displays strong regional characteristics. The aerosol variation is negatively correlated with cloud and precipitation variation over the Maritime Continent, but is positively correlated with cloud and precipitation variation over the region southeast of Japan. Over broad subtropical oceanic regions, the aerosol variation is positively correlated with cloud variation, but has a weak correlation with precipitation variation. Aerosol variations over the Maritime Continent and over the region southeast of Japan display a biennial feature with an obvious phase lag of about 8 months in the latter region during 2001-07. This biennial feature is attributed to the impacts of El Nifio events on aerosol variations in these regions through large-scale circulation and precipitation changes. Around October of El Nino-developing years, the suppressed precipitation over the Maritime Continent favors an aerosol increase by reducing the wet deposition and setting up dry conditions favorable for fire burning. During early summer of El Nitio-decaying years, suppressed heating around the Philippines as a delayed response to El Nino warming induces an anomalous lower-level cyclone over the region to the southeast of Japan through an atmospheric teleconnection, leading to an accumulation of aerosol and increase of precipitation. The aerosol-precipitation relationship shows an obvious change with time over eastern China, leading to an overall weak correlation. [ABSTRACT FROM AUTHOR]

Published

2013