Your search keyword '"Dingzhu, Hu"' showing total 34 results

1. Modulation of QBO on the relationship between stratospheric polar vortex and surface air temperature over Eurasia during early winter

Author

Rongzhong, Mo and Dingzhu, Hu

Published

2024

2. Drying Over Eastern China Driven by the Depletion of Arctic Stratospheric Ozone During Boreal Spring

Author

Dingzhu Hu, Zhuohua Zhang, and Zhaoyong Guan

Subjects

Geophysics. Cosmic physics, QC801-809

Abstract

Abstract Given the significant importance of spring precipitation for agricultural production in China and the presence of the spring predictability barrier, scientists have dedicated extensive efforts to understand the factors influencing spring precipitation variability and explore new predictors. However, the effects of Arctic stratospheric ozone (ASO) on precipitation in China during boreal spring, if any, and the underlying mechanisms remain unclear. We found the robust influences of March ASO on the differences in the precipitation and evaporation in April over Eastern China during 1980–2020. When ASO decreases in March, it tends to result in a higher and colder tropopause in the polar, a stronger subtropical jet stream, an intensified local Hadley circulation accompanied by anomalous downward motion over Eastern China, and consequently, drying in this region, and vice versa. These findings suggest that the likelihood of April moistening over East Asia may be potentially predicted by employing the ASO index.

Published

2024

3. The Variation Characteristics of Stratospheric Circulation under the Interdecadal Variability of Antarctic Total Column Ozone in Early Austral Spring.

Author

Jiayao Li, Shunwu Zhou, Dong Guo, Dingzhu Hu, Yao Yao, and Minghui Wu

Published

2024

4. Stratospheric PULSE–continental cold air outbreak coupling relationships: Interannual and interdecadal changes

Author

Yueyue Yu, Xueting Yu, Zhaoyong Guan, Dingzhu Hu, Chunhua Shi, Dong Guo, and Jian Rao

Subjects

cold air outbreak, stratosphere–troposphere coupling, interannual, interdecadal, ENSO, SST, Science

Abstract

Stratospheric processes and their role in weather and climate have attracted increasing interests. The correspondence between the occurrence of pulse-like, stronger stratospheric poleward warm airmass transport (PULSE) events and the continental-scale cold air outbreak (CAO) events in northern hemispheric winter is found to be unstable from year to year. This increases the difficulties in utilizing the more predictable stratospheric variability in the sub-seasonal forecasts of CAOs, which can cause cold hazards. Using the ERA5 reanalysis data covering 37 winters (November–March) in the period 1979–2015, this study categorizes the CAO events over mid-latitudes of Eurasia (CAO_EA) and those over North America (CAO_NA) into two groups: those coupled with and those decoupled with the PULSE events. The coupled CAOs are further categorized into events that are, respectively, lead-coupled and lag-coupled with PULSEs. The intensity and affected area of extremely cold temperatures tend to be larger during CAOs that are coupled with PULSEs, particularly during the CAO_NA events that are lag-coupled with PULSEs and the CAO_EA events that are lead-coupled with PULSEs. Remarkable interannual and interdecadal variations are observed in the percentage of CAOs that are coupled with PULSEs for each winter, which is an important reference for determining the window of opportunity for skillful sub-seasonal forecasts of CAO by using the stratospheric signals. At both interdecadal and interannual timescales, a warm phase of the El Niño–Southern Oscillation (ENSO) in winter is favorable for the higher lag-coupling rate of CAO_NA and the lead-coupling rate of CAO_EA, and vice versa. The ENSO signals related to the interdecadal changes of the CAO coupling rate in winter can be traced back to the previous winter, while an ENSO phase transition from the previous winter to the current winter is closely related to the interannual changes of the CAO coupling rate.

Published

2023

5. Evaluating the Brewer–Dobson circulation and its responses to ENSO, QBO, and the solar cycle in different reanalyses

Author

Jian Rao, YueYue Yu, Dong Guo, ChunHua Shi, Dan Chen, and DingZhu Hu

Subjects

residual mean meridional stream function (rmmsf), brewer-dobson circulation (bdc), el niño-southern oscillation (enso), quasi-biennial oscillation (qbo), Science, Geophysics. Cosmic physics, QC801-809, Environmental sciences, GE1-350

Abstract

This study compares the climatology and long-term trend of northern winter stratospheric residual mean meridional circulation (RMMC), as well as its responses to El Niño-Southern Oscillation (ENSO), stratospheric Quasi Biennial Oscillation (QBO), and solar cycle in ten reanalyses and a stratosphere-resolving model, CESM1-WACCM. The RMMC is a large-scale meridional circulation cell in the stratosphere, usually referred to as the estimate of the Brewer Dobson circulation (BDC). The distribution of the BDC is generally consistent among multiple reanalyses except that the NOAA twentieth century reanalysis (20RC) largely underestimates it. Most reanalyses (except ERA40 and ERA-Interim) show a strengthening trend for the BDC during 1979–2010. All reanalyses and CESM1-WACCM consistently reveal that the deep branch of the BDC is significantly enhanced in El Niño winters as more waves from the troposphere dissipate in the stratospheric polar vortex region. A secondary circulation cell is coupled to the temperature anomalies below the QBO easterly center at 50 hPa with tropical upwelling/cooling and midlatitude downwelling/warming, and similar secondary circulation cells also appear between 50–10 hPa and above 10 hPa to balance the temperature anomalies. The direct BDC response to QBO in the upper stratosphere creates a barrier near 30°N to prevent waves from propagating to midlatitudes, contributing to the weakening of the polar vortex. The shallow branch of the BDC in the lower stratosphere is intensified during solar minima, and the downwelling warms the Arctic lower stratosphere. The stratospheric responses to QBO and solar cycle in most reanalyses are generally consistent except in the two 20CRs.

Published

2019

6. Relative Effects of the Greenhouse Gases and Stratospheric Ozone Increases on Temperature and Circulation in the Stratosphere over the Arctic

Author

Dingzhu Hu and Zhaoyong Guan

Subjects

stratospheric ozone, greenhouse gases, stratospheric temperature and circulation, wave fluxes, Science

Abstract

Using a stratosphere-resolving general circulation model, the relative effects of stratospheric ozone and greenhouse gases (GHGs) increase on the temperature and circulation in the Arctic stratosphere are examined. Results show that stratospheric ozone or GHGs increase alone could result in a cooling and strengthening extratropical stratosphere during February, March and April. However, the contribution of stratospheric ozone increases alone on the cooling and strengthening Arctic stratosphere is approximately 2 fold that of the GHGs increase alone. Model simulations suggested that the larger responses of the Arctic stratosphere to the ozone increase alone are closely related to the wave fluxes in the stratosphere, rather than the wave activity in the stratosphere. In response to the ozone increase, the vertical propagation of planetary waves from the troposphere into the mid-latitude stratosphere weakens, mainly contributed by its wavenumber-1 component. The impeded planetary waves tend to result from the larger zonal wind shear and vertical gradient of the buoyancy frequency. The magnitudes of anomalies in the zonal wind shear and buoyancy frequency in response to GHGs increase alone are smaller than in response to the ozone increase, which is in accordance with the larger contribution of stratospheric ozone to the temperature and circulation in the Arctic stratosphere.

Published

2022

7. An extreme cold event over East Asia during early January 2021 and its links to the deformation of stratospheric polar vortex during sudden stratospheric warming

Author

Meichen Liu, Dingzhu Hu, and Zhaoyong Guan

Subjects

Atmospheric Science

Published

2023

8. Recent strengthening of the stratospheric Arctic vortex response to warming in the central North Pacific

Author

Dingzhu Hu, Zhaoyong Guan, Wenshou Tian, and Rongcai Ren

Subjects

Science

Abstract

The stratospheric Arctic vortex plays a critical role in forecasting cold winters in northern mid-latitudes. Here the authors show that the stratospheric Arctic vortex strengthened during 1998–2016, with ~25% of this strengthening contributed by warming in the central North Pacific.

Published

2018

9. Modulation of a long-lasting extreme cold event in Siberia by a minor sudden stratospheric warming and the dynamical mechanism involved

Author

Meichen Liu, Dingzhu Hu, and Zhaoyong Guan

Subjects

Atmospheric Science

Abstract

Previous studies have paid much attention to the impact of major sudden stratospheric warming (SSW) events on the tropospheric circulation. However, the attention to the modulation of minor SSW events on the extreme cold events is limited. In this study, the extreme cold event in Siberia in the winter of 2000/2001, the longest-lasting one from 1980/1981 to 2019/2020, and its linkages to the minor SSW event have been examined. Our results show that the largest cooling occurred in Siberia during 30 December 2000 − 10 January 2001, and then the cooling weakened and migrated to Northeast China from 11 to 18 January 2001. During the recovery stage of this minor SSW event, the stratospheric polar vortex gradually strengthened, along with strengthening of the zonal winds over the Ural region. The vertical distribution of positive zonal wind anomalies in the Ural region favored the reflection of stratospheric planetary wave in the Atlantic-Euro and Siberia region. The changes of planetary wave propagation were beneficial to the strengthening of the trough in the Atlantic-Euro and Siberia region during 26 December − 10 January, which facilitated the growth and maintenance of the Ural ridge in the same period by strengthening the meridional flow. The strengthened Ural ridge resulted in the extreme cold event breaking out and lasting from 30 December to 10 January. Because the stratospheric polar vortex did not continue to strengthen and a new ridge generated in the Atlantic region during 11 − 18 January, the Ural ridge decayed and the cold air moved to Northeast China.

Published

2022

10. Surface ocean current variations in the North Pacific related to Arctic stratospheric ozone

Author

Tao Wang, Wenshou Tian, Jiankai Zhang, Mian Xu, Tao Lian, Dingzhu Hu, and Kai Qie

Subjects

Atmospheric Science

Abstract

Using reanalysis datasets and a coupled general circulation model, the relationship between springtime Arctic total column ozone (TCO) and surface (5 m) ocean currents in the North Pacific is investigated. We found that as March Arctic TCO decreases, a statistically significant northwestward ocean current anomaly occurs in the northern North Pacific in surface layer, but an anomalous southward ocean current appears in the central North Pacific in April, and vice versa. The decreased Arctic TCO favors an enhanced Arctic stratospheric circulation, which tends to induce the tropospheric positive Arctic Oscillation anomaly with easterly anomalies over the midlatitude eastern Asia in late March through stratosphere-troposphere dynamical coupling. The easterly anomaly over eastern Asia in late March further extends eastward and induces an easterly anomaly over the midlatitude North Pacific, which favors negative North Pacific Oscillation (–NPO)-like circulation anomaly via anomalous zonal wind shear and the interactions between synoptic scale eddies and the mean flow in early-middle April. The –NPO anomaly forces anomalous northwestward/southward surface ocean currents in the northern/central North Pacific through direct friction of wind and the Coriolis force. Our coupled numerical simulations with high- and low-ozone scenarios also support that the Arctic stratospheric ozone affects the North Pacific surface ocean currents by NPO anomalies. Moreover, the ozone-related ocean current anomalies contribute to Victoria mode-like sea surface temperature anomalies in the North Pacific by horizontal heat advection. These results imply that Arctic ozone signal could be a predictor for variations of the North Pacific surface ocean currents.

Published

2022

11. Different Relationships between Arctic Oscillation and Ozone in the Stratosphere over the Arctic in January and February

Author

Meichen Liu and Dingzhu Hu

Subjects

Arctic Oscillation, ozone in the stratosphere, buoyancy frequency, planetary wave, Brewer–Dobson circulation, polar vortex, Meteorology. Climatology, QC851-999

Abstract

We compare the relationship between the Arctic Oscillation (AO) and ozone concentration in the lower stratosphere over the Arctic during 1980–1994 (P1) and 2007–2019 (P2) in January and February using reanalysis datasets. The out-of-phase relationship between the AO and ozone in the lower stratosphere is significant in January during P1 and February during P2, but it is insignificant in January during P2 and February during P1. The variable links between the AO and ozone in the lower stratosphere over the Arctic in January and February are not caused by changes in the spatial pattern of AO but are related to the anomalies in the planetary wave propagation between the troposphere and stratosphere. The upward propagation of the planetary wave in the stratosphere related to the positive phase of AO significantly weakens in January during P1 and in February during P2, which may be related to negative buoyancy frequency anomalies over the Arctic. When the AO is in the positive phase, the anomalies of planetary wave further contribute to the negative ozone anomalies via weakening the Brewer–Dobson circulation and decreasing the temperature in the lower stratosphere over the Arctic in January during P1 and in February during P2.

Published

2021

12. Dynamical mechanisms for the recent ozone depletion in the Arctic stratosphere linked to North Pacific sea surface temperatures

Author

Dingzhu Hu, Zhaoyong Guan, Meichen Liu, and Wuhu Feng

Subjects

Atmospheric Science

Published

2021

13. Model study of the impacts of emissions, chemical and dynamical processes on the CO variability in the tropical upper troposphere and lower stratosphere

Author

Chunxiao Wang, Wenshou Tian, Jiankai Zhang, Dingzhu Hu, Sandip Dhomse, Jianchuan Shu, and Jiali Luo

Subjects

carbon monoxide, tape recorder, chemistry-climate model, UTLS, BD circulation, Oceanography, GC1-1581, Meteorology. Climatology, QC851-999

Abstract

The Whole Atmosphere Community Climate Model (WACCM) is used to investigate the relative importance of CO emissions, chemical and dynamical processes on temporal variations of CO in the tropical upper troposphere (UT) and the lower stratosphere (LS). The semi-annual oscillation (SAO) in the tropical UT and the annual oscillation (AO) in the tropical LS detected in the MLS CO observations can be well captured by the model. The model simulations reveal that the CO surface emissions explain most of the SAO signals in the tropical UT, with the remainder being attributed to dynamical and chemical processes. The CO AO in the LS primarily results from combined effects of dynamical and chemical processes while the dynamical and chemical processes make opposite contributions to the CO AO signals, consistent with the previous findings. Our analysis further reveals that CO surface emissions tend to weaken the amplitude of the CO annual cycle in the tropical LS, while the annual variations in the meridional component of the Brewer–Dobson (BD) circulation can amplify the annual variations of CO above 30 hPa. The model simulations also indicate that the CO annual cycle in the LS has a mixed behaviour with the annual variations of tropical upwelling reflected in CO between ~70 and ~50 hPa and a standard tape-recorder signal above 50 hPa. Moreover, the AO signals of CO exist up to 10 hPa when the chemical processes are switched off. The temporal and spatial variations of CO in the UT and near the tropopause are mainly driven by the upward transport of CO by tropical deep convection and the Asian summer monsoon circulation. In the early stage of the South Asian summer monsoon over the Bay of Bengal and the South China in the late spring and early summer, the transport of the CO surface emissions over Southeast Asia by the South Asian summer monsoon leads to an increase in the tropical CO, but the horizontal transport from the extratropics into the tropics (termed in-mixing) driven by the Asian summer monsoon anticyclone in the boreal summer decreases the tropical CO.

Published

2015

14. Brewer–Dobson Circulation: Recent-Past and Near-Future Trends Simulated by Chemistry-Climate Models

Author

Dingzhu Hu, Yipeng Guo, Feiyang Wang, Qi Xu, Yuanpu Li, Wenjun Sang, Xudong Wang, and Meichen Liu

Subjects

Meteorology. Climatology, QC851-999

Abstract

Based on data from 16 chemistry-climate models (CCMs) and separate experimental results using a state-of-the-art CCM, the trends in the Brewer–Dobson circulation (BDC) during the second half of the 20th century (1960–2000) and the first half of the 21st century (2001–2050) are examined. From the ensemble mean of the CCMs, the BDC exhibits strengthening trends in both the 20th and 21st centuries; however, the acceleration rates of tropical upwelling and southern downwelling during 2001–2050 are smaller than those during 1960–2000, while the acceleration rate of the northern downward branch of the BDC during 2001–2050 is slightly larger than that during 1960–2000. The differences in the extratropical downwelling trends between the two periods are closely related to changes in planetary-wave propagation into the stratosphere caused by the combined effects of increases in the concentrations of greenhouse gases (GHGs) and changes in stratospheric ozone. Model simulations demonstrate that the response of southern downwelling to stratospheric ozone depletion is larger than that to the increase in GHGs, but that the latter plays a more important role in the strengthening of northern downwelling. This result suggests that, under the expected future climate, northern downwelling will play a more important role in balancing tropical upwelling.

Published

2017

15. Connections between Spring Arctic Ozone and the Summer Circulation and Sea Surface Temperatures over the Western North Pacific

Author

Jinlong Huang, Jiankai Zhang, Ruhua Zhang, Tao Wang, Fei Xie, Dingzhu Hu, and Wenshou Tian

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, Ozone, 010504 meteorology & atmospheric sciences, 010502 geochemistry & geophysics, 01 natural sciences, The arctic, Troposphere, chemistry.chemical_compound, Circulation (fluid dynamics), Arctic, chemistry, General Circulation Model, Climatology, Spring (hydrology), Environmental science, Stratosphere, 0105 earth and related environmental sciences

Abstract

Using various observations, reanalysis datasets, and a general circulation model (CESM-WACCM4), the relationship between the Arctic total column ozone (TCO) and the tropospheric circulation and sea surface temperatures (SSTs) over the western North Pacific (30°–45°N, 130°E–170°W) was investigated. We find that anomalies in the circulation and SSTs over the western North Pacific in June are closely related to anomalies in the Arctic TCO in March; that is, when the Arctic TCO in March decreases, the anomalous tropospheric cyclone and negative SST anomalies (SSTAs) will occur over the western North Pacific in June. Further analysis indicates that the decreased Arctic TCO in March tends to result in positive Victoria mode (VM)-like SSTAs over the North Pacific in April, which persist and develop an anomalous cyclone over the eastern North Pacific in May via atmosphere–ocean coupling. This anomalous cyclone over the eastern North Pacific subsequently induces an anomalous cyclone over the western North Pacific in June via westward-propagating Rossby waves in the lower troposphere. Furthermore, the negative SSTAs over the western North Pacific are enhanced by the anomalous northerly wind related to the anomalous cyclone in June. The effects of increased Arctic TCO in March on the tropospheric circulation and SSTs are almost opposite to those of decreased Arctic TCO. These results are also supported by our numerical simulations. Moreover, 10%–20% of the anomalies in the tropospheric circulation and SSTs over the western North Pacific in June are affected by the anomalies in the Arctic TCO in March.

Published

2020

16. Link between Arctic ozone and the stratospheric polar vortex

Author

Dingzhu Hu, Simin Shi, and Zhe Wang

Subjects

Atmospheric Science, Oceanography

Published

2023

17. Is the Relationship Between Stratospheric Arctic Vortex and Arctic Oscillation Steady?

Author

Zhaoyong Guan, Dingzhu Hu, Tao Wang, and Meichen Liu

Subjects

Atmospheric Science, Geophysics, Arctic oscillation, Space and Planetary Science, Polar vortex, Climatology, Earth and Planetary Sciences (miscellaneous), Environmental science

Published

2021

18. Dynamical Mechanisms for the Recent Ozone Depletion in the Arctic Stratosphere Linked to the North Pacific Sea Surface Temperatures

Author

Meichen Liu, Dingzhu Hu, Zhaoyong Guan, and Wuhu Feng

Subjects

Climatology, Environmental science, Ozone depletion, Stratosphere, The arctic

Abstract

The ozone layer, which prevents solar ultraviolet radiation from reaching the surface and thereby protects life on earth, is expected to recover from past depletion during this century due to the impact of the Montreal Protocol. However, how the ozone column over the Arctic will evolve over the next few decades is still under debate. In this study, we found that the ozone level in the Arctic stratosphere during the period of 1998–2018 exhibits a decreasing trend of –0.12±0.07 ppmv decade–1 from MERRA2, suggesting a continued depletion during this century. This ozone depletion is contributed by the second leading mode of North Pacific sea surface temperature anomalies (SSTAs) with one month leading and therefore dynamical in origin. The North Pacific SSTAs associated with this mode tend to result in a weakened Aleutian low, a strengthened Western Pacific pattern and a weakened Pacific–North American pattern, which impede the upward propagation of planetary wavenumber-1 waves into the lower stratosphere. The changes in the stratospheric wave activity tend to result in decreased ozone in the Arctic lower stratosphere through weakening the Brewer-Dobson circulation. Our findings will provide new understanding of how dynamical processes control Arctic stratospheric ozone and will help to improve prediction of how Arctic ozone will evolve in the future.

Published

2021

19. Dynamical connection between the stratospheric Arctic vortex and sea surface temperatures in the North Atlantic

Author

Zhaoyong Guan, Yipeng Guo, Dingzhu Hu, Chuhan Lu, and Dachao Jin

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Baroclinity, 010502 geochemistry & geophysics, 01 natural sciences, Latitude, Troposphere, Sea surface temperature, Polar vortex, Climatology, Tropopause, Trough (meteorology), Stratosphere, Geology, 0105 earth and related environmental sciences

Abstract

We used two long-term reanalysis datasets and time-slice simulations to examine the decadal relationship between the stratospheric Arctic vortex (SAV) and sea surface temperature anomalies (SSTAs) in the North Atlantic and the dynamic mechanisms involved in the linkage between the two. Our results show that there is a significant decadal linkage between SSTAs over the North Atlantic and the SAV, where warmed (cooled) SSTAs over the North Atlantic in association with its principal mode correspond to a weakened (strengthened) SAV. The warmed North Atlantic SSTAs tend to result in a weakened SAV via two dynamic processes: (1) constructive interference at high latitudes with a ridge in the Atlantic sector and a trough in the Pacific accompanied by a negative North Atlantic Oscillation-like pattern over the North Atlantic and a weakened Aleutian low over the North Pacific; and (2) more wavenumber-1 waves propagated into the Arctic stratosphere by modifying the baroclinic term of the zonal mean background state and altering the propagating conditions around the tropopause over the Arctic. Results from reanalysis and model simulations both suggest that a strengthening wave intensity in the high-latitude troposphere and more upward propagation of the planetary wavenumber-1 wave in response to the warmed North Atlantic SSTAs conjunctly contribute to the increased planetary wave flux in the Arctic stratosphere, facilitating a weakened SAV. These results provide a new understanding of what dynamic processes control the SAV, and will help to predict the stratosphere on decadal timescales.

Published

2019

20. Regional Characteristics of Interannual Variability of Summer Rainfall in the Maritime Continent and Their Related Anomalous Circulation Patterns

Author

Zhaoyong Guan, Dingzhu Hu, Qi Xu, and Dachao Jin

Subjects

Atmospheric Science, Global precipitation, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, 02 engineering and technology, 01 natural sciences, 020801 environmental engineering, Sea surface temperature, El Niño Southern Oscillation, Circulation (fluid dynamics), Climatology, Environmental science, Precipitation, 0105 earth and related environmental sciences

Abstract

Using the NCEP–NCAR reanalysis and Global Precipitation Climatology Project monthly rainfall, we have investigated the regional features of interannual variations of rainfall in the Maritime Continent (MC) and their related anomalous atmospheric circulation patterns during boreal summer by employing the rotated empirical orthogonal function (REOF) analysis. Our results demonstrate that the rainfall variabilities in the MC are of very striking regional characteristics. The MC is divided into four independent subregions on the basis of the leading REOF modes; these subregions are located in central-eastern Indonesia (subregion I), the oceanic area to the west of Indonesia (subregion II+V), the part of the warm pool in the equatorial western Pacific Ocean (subregion III), and Guam (subregion IV+VI).The anomalous precipitation in different subregions exhibits different variation periodicities, which are associated with different circulation patterns as a result of atmospheric response to different sea surface temperature anomaly (SSTA) patterns in the tropical Indo-Pacific sector. It is found that rainfall anomalies in subregion I are induced by the Pacific ENSO, whereas those in subregion II+V are dominated by a triple SSTA pattern with positive correlations in the MC and negative correlation centers in the tropical Pacific and tropical Indian Ocean. Rainfall anomalies in subregion III mainly resulted from an SSTA pattern with negative correlations in the eastern MC and positive correlations in the western equatorial Pacific east of the MC. A horseshoe SSTA pattern in the central Pacific is found to affect the precipitation anomalies in subregion IV+VI. All of the results of this study are helpful for us to better understand both the climate variations in the MC and monsoon variations in East Asia.

Published

2019

21. Recent Weakening in the Stratospheric Planetary Wave Intensity in Early Winter

Author

Yipeng Guo, Zhaoyong Guan, and Dingzhu Hu

Subjects

Early winter, Geophysics, Climatology, General Earth and Planetary Sciences, Environmental science, Climate change

Published

2019

22. Evaluating the Brewer–Dobson circulation and its responses to ENSO, QBO, and the solar cycle in different reanalyses

Author

Yueyue Yu, Chunhua Shi, Dong Guo, Dingzhu Hu, Jian Rao, and Dan Chen

Subjects

Quasi-biennial oscillation, Atmospheric Science, Space and Planetary Science, Downwelling, Polar vortex, Middle latitudes, Climatology, Secondary circulation, Environmental science, Astronomy and Astrophysics, Stratosphere, Brewer-Dobson circulation, Solar cycle

Abstract

This study compares the climatology and long-term trend of northern winter stratospheric residual mean meridional circulation (RMMC), as well as its responses to El Nino-Southern Oscillation (ENSO), stratospheric Quasi Biennial Oscillation (QBO), and solar cycle in ten reanalyses and a stratosphere-resolving model, CESM1-WACCM. The RMMC is a large-scale meridional circulation cell in the stratosphere, usually referred to as the estimate of the Brewer Dobson circulation (BDC). The distribution of the BDC is generally consistent among multiple reanalyses except that the NOAA twentieth century reanalysis (20RC) largely underestimates it. Most reanalyses (except ERA40 and ERA-Interim) show a strengthening trend for the BDC during 1979–2010. All reanalyses and CESM1-WACCM consistently reveal that the deep branch of the BDC is significantly enhanced in El Nino winters as more waves from the troposphere dissipate in the stratospheric polar vortex region. A secondary circulation cell is coupled to the temperature anomalies below the QBO easterly center at 50 hPa with tropical upwelling/cooling and midlatitude downwelling/warming, and similar secondary circulation cells also appear between 50–10 hPa and above 10 hPa to balance the temperature anomalies. The direct BDC response to QBO in the upper stratosphere creates a barrier near 30°N to prevent waves from propagating to midlatitudes, contributing to the weakening of the polar vortex. The shallow branch of the BDC in the lower stratosphere is intensified during solar minima, and the downwelling warms the Arctic lower stratosphere. The stratospheric responses to QBO and solar cycle in most reanalyses are generally consistent except in the two 20CRs.

Published

2019

23. Contrast Relationships Between Arctic Oscillation and Ozone in the Stratosphere Over the Arctic in Early and Mid‐to‐Late Winter

Author

Dingzhu Hu and Meichen Liu

Subjects

Atmospheric Science, Ozone, Late winter, Contrast (music), Brewer-Dobson circulation, The arctic, chemistry.chemical_compound, Geophysics, chemistry, Arctic oscillation, Space and Planetary Science, Polar vortex, Climatology, Earth and Planetary Sciences (miscellaneous), Environmental science, Stratosphere

Published

2021

24. Connections Between Stratospheric Ozone Concentrations Over the Arctic and Sea Surface Temperatures in the North Pacific

Author

Feng Zhang, Dingzhu Hu, and Meichen Liu

Subjects

Atmospheric Science, Geophysics, Space and Planetary Science, Ozone layer, Earth and Planetary Sciences (miscellaneous), Environmental science, Atmospheric sciences, The arctic

Published

2020

25. Advances in the Researches of the Middle and Upper Atmosphere in China in 2020–2022

Author

Zeyu CHEN, Jiyao XU, Hongbin CHEN, Wen CHEN, Rongcai REN, Xiong HU, Yajun ZHU, Xianghui XUE, Gaopeng LU, Shaodong ZHANG, Kaiming HUANG, Wenshou TIAN, Jiankai ZHANG, Dingzhu HU, Jian RAO, Yongyun HU, and Yan XIA

Subjects

Complementary and alternative medicine, Pharmaceutical Science, Pharmacology (medical)

Published

2022

26. Zonally asymmetric trends of winter total column ozone in the northern middle latitudes

Author

Fei Xie, Wuhu Feng, Dong Guo, Wenjun Sang, Wenshou Tian, Jiankai Zhang, Martyn P. Chipperfield, and Dingzhu Hu

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Chemical transport model, Geopotential height, 010502 geochemistry & geophysics, 01 natural sciences, Troposphere, Sea surface temperature, Climatology, Middle latitudes, Ozone layer, Environmental science, Stratosphere, 0105 earth and related environmental sciences, Teleconnection

Abstract

Using various satellite-based observations, a linear ozone transport model (LOTM), a chemistry-climate model (WACCM3) and an offline chemical transport model (SLIMCAT), zonally asymmetric trends of the total column ozone (TCO) in the northern middle latitudes during winter for the period 1979–2015 are analyzed and factors responsible for the trends are diagnosed. The results reveal that there are significant negative TCO trends over the North Pacific and positive TCO trends over the northwestern North America. The zonally asymmetric TCO trends are mainly contributed by the trends in partial column ozone in the upper troposphere and lower stratosphere (UTLS) which are closely related to the long-term changes of geopotential height in the troposphere. Furthermore, the trends of geopontential height in the UTLS are mainly modulated by pattern changes in the Arctic Oscillation (AO), the Cold Ocean–Warm Land (COWL) and the North Pacific (NP) index. Accordingly, the zonally asymmetric TCO trends can be largely reconstructed by the trends of the above three teleconnection patterns. Sea surface temperature (SST) changes over the Pacific Ocean and the Atlantic Ocean can also exert a significant contribution to the zonally asymmetric TCO trends through their influence on the COWL and NP patterns. In addition, chemical ozone loss partially offsets the positive trends in zonal TCO anomalies over Central Siberia and enhances the positive TCO trends over northwestern North America. However, the contribution of chemical processes to the zonally asymmetric TCO trends is relatively smaller than that of dynamical transport effects. Interpreting the zonally asymmetric TCO trends and their responsible factors would be helpful for accurately predicting the stratospheric ozone return date in the northern middle latitudes.

Published

2018

27. Decadal Relationship between the Stratospheric Arctic Vortex and Pacific Decadal Oscillation

Author

Zhaoyong Guan and Dingzhu Hu

Subjects

Atmospheric Science, Jet (fluid), 010504 meteorology & atmospheric sciences, Atmospheric circulation, 010502 geochemistry & geophysics, 01 natural sciences, Troposphere, Sea surface temperature, Polar vortex, Climatology, Environmental science, Stratosphere, Pacific decadal oscillation, 0105 earth and related environmental sciences

Abstract

Using reanalysis datasets and numerical simulations, the relationship between the stratospheric Arctic vortex (SAV) and the Pacific decadal oscillation (PDO) on decadal time scales was investigated. A significant in-phase relationship between the PDO and SAV on decadal time scales during 1950–2014 is found, that is, the North Pacific sea surface temperature (SST) cooling (warming) associated with the positive (negative) PDO phases is closely related to the strengthening (weakening) of the SAV. This decadal relationship between the North Pacific SST and SAV is different from their relationship on subdecadal time scales. Observational and modeling results both demonstrate that the decadal variation in the SAV is strongly affected by the North Pacific SSTs related to the PDO via modifying the upward propagation of planetary wavenumber-1 waves from the troposphere to the stratosphere. The decreased SSTs over the North Pacific tend to result in a deepened Aleutian low along with a strengthened jet stream over the North Pacific, which excites a weakened western Pacific pattern and a strengthened Pacific–North American pattern. These tropospheric circulation anomalies are in accordance with the decreased refractive index (RI) at middle and high latitudes in the northern stratosphere during the positive PDO phase. The increased RI at high latitudes in the upper troposphere impedes the planetary wavenumber-1 wave from propagating into the stratosphere, and in turn strengthens the SAV. The responses of the RI to the PDO are mainly contributions of the changes in the meridional gradient of the zonal-mean potential vorticity via alteration of the baroclinic term .

Published

2018

28. Longitudinal Asymmetric Trends of Tropical Cold-Point Tropopause Temperature and Their Link to Strengthened Walker Circulation

Author

Zhaoyong Guan, Sandip Dhomse, Dingzhu Hu, Wenshou Tian, and Yipeng Guo

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Atmospheric pressure, Tropics, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Trade wind, Sea surface temperature, Climatology, Walker circulation, Environmental science, Climate model, Tropopause, Pressure gradient, 0105 earth and related environmental sciences

Abstract

The zonal structure of trends in the tropical tropopause layer during 1979–2014 is investigated by using reanalysis datasets and chemistry–climate model simulations. The analysis herein reveals that the tropical cold-point tropopause temperature (CPTT) trends during 1979–2014 are zonally asymmetric; that is, over the tropical central and eastern Pacific (CEP; 20°S–20°N, 160°E–100°W), the CPTT shows an increasing trend of 0.22 K decade−1, whereas over the rest of the tropical regions (non-CEP regions) the CPTT shows a decreasing trend of −0.08 K decade−1. Model simulations suggest that this zonal asymmetry in the tropical CPTT trends can be partly attributed to Walker circulation (WC) changes induced by zonally asymmetric changes of the sea surface temperatures (SSTs). The increasing (decreasing) SSTs over the western Pacific (CEP) result in a larger zonal gradient in sea level pressure over the tropical Pacific and intensified surface easterlies. The increased pressure gradient leads to enhanced convection over the Indo-Pacific warm pool and weakened convection over the CEP, facilitating a stronger WC. The downward branch of the intensified WC induces a dynamical warming over the CEP and the upward branch of the intensified WC induces a dynamical cooling over the non-CEP regions below 150 hPa. The significant warming in the upper troposphere and lower stratosphere (UTLS) caused by the WC descending and wave activity changes in the UTLS over the CEP shifts the cold-point tropopause height to a higher level, while the radiative effects of greenhouse gases, ozone, and water vapor changes in the UTLS make less important contributions to the trend of the tropical CPTT than SST changes.

Published

2016

29. A Quantitative Estimation of the Transport of Surface Emissions from Different Regions into the Stratosphere

Author

Fei Xie, Jianping Li, Chunxiao Wang, Wenshou Tian, Dingzhu Hu, Jianchuan Shu, and Jiankai Zhang

Subjects

Estimation, Atmospheric Science, 010504 meteorology & atmospheric sciences, Climate change, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Population density, Southeast asia, Climatology, Environmental science, East Asia, Stratosphere, 0105 earth and related environmental sciences

Abstract

The transport of chemical compounds from surface emissions into the stratosphere is very important for stratospheric, and even global, climate change. However, the lack of observational data makes it difficult to trace these emissions back to specific regions. This study uses numerical simulations to investigate the transport of surface emissions from high population density regions into the stratosphere. In March, April and May, Southeast Asia and Australia tracers contribute similar to 1/3 and similar to 1/4 of total tracers entering the stratosphere, respectively. In June, July and August, Southwest Asia contributes similar to 1/2 of the total, which is far more than the contribution of all other source regions. In September, October and November, South America and Southeast Asia each accounts for similar to 1/4 of the total tracer budget. In December, January and February, Australia and Southeast Asia each accounts for similar to 1/4 of all tracers entering the stratosphere. A further quantitative estimation illustrates that the average proportion of a tracer entering the stratosphere compared with its total release is 2.6% for Southeast Asia, followed by 1.7% for Australia, 1.4% for Southwest Asia, 1.0% for Africa, 1.0% for South America, 0.9% for East Asia, 0.7% for North America, and 0.3% for Europe.

Published

2016

30. A Large Eddy Model Study on the Effect of Overshooting Convection on Lower Stratospheric Water Vapor

Author

Jiali Luo, Hongying Tian, Jiankai Zhang, Qian Huang, Dingzhu Hu, Jonathon S. Wright, Yuanyuan Han, Wenjun Sang, and Wenshou Tian

Subjects

Convection, Atmospheric Science, Geophysics, 010504 meteorology & atmospheric sciences, Space and Planetary Science, Model study, Earth and Planetary Sciences (miscellaneous), Environmental science, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Water vapor, 0105 earth and related environmental sciences

Published

2018

31. Impacts of stratospheric ozone depletion and recovery on wave propagation in the boreal winter stratosphere

Author

Fei Xie, Chunxiao Wang, Jiankai Zhang, Wenshou Tian, and Dingzhu Hu

Subjects

Atmospheric Science, Ozone, Sudden stratospheric warming, Atmospheric sciences, Ozone depletion, Troposphere, chemistry.chemical_compound, Geophysics, chemistry, Space and Planetary Science, Polar vortex, Climatology, Middle latitudes, Ozone layer, Earth and Planetary Sciences (miscellaneous), Environmental science, Stratosphere

Abstract

This paper uses a state-of-the-art general circulation model to study the impacts of the stratospheric ozone depletion from 1980 to 2000 and the expected partial ozone recovery from 2000 to 2020 on the propagation of planetary waves in December, January, and February. In the Southern Hemisphere (SH), the stratospheric ozone depletion leads to a cooler and stronger Antarctic stratosphere, while the stratospheric ozone recovery has the opposite effects. In the Northern Hemisphere (NH), the impacts of the stratospheric ozone depletion on polar stratospheric temperature are not opposite to that of the stratospheric ozone recovery; i.e., the stratospheric ozone depletion causes a weak cooling and the stratospheric ozone recovery causes a statistically significant cooling. The stratospheric ozone depletion leads to a weakening of the Arctic polar vortex, while the stratospheric ozone recovery leads to a strengthening of the Arctic polar vortex. The cooling of the Arctic polar vortex is found to be dynamically induced via modulating the planetary wave activity by stratospheric ozone increases. Particularly interesting is that stratospheric ozone changes have opposite effects on the stationary and transient wave fluxes in the NH stratosphere. The analysis of the wave refractive index and Eliassen-Palm flux in the NH indicates (1) that the wave refraction in the stratosphere cannot fully explain wave flux changes in the Arctic stratosphere and (2) that stratospheric ozone changes can cause changes in wave propagation in the northern midlatitude troposphere which in turn affect wave fluxes in the NH stratosphere. In the SH, the radiative cooling (warming) caused by stratospheric ozone depletion (recovery) produces a larger (smaller) meridional temperature gradient in the midlatitude upper troposphere, accompanied by larger (smaller) zonal wind vertical shear and larger (smaller) vertical gradients of buoyancy frequency. Hence, there are more (fewer) transient waves propagating into the stratosphere. The dynamical warming (cooling) caused by stratospheric ozone decreases (increases) partly offsets their radiative cooling (warming).

Published

2015

32. Brewer–Dobson Circulation: Recent-Past and Near-Future Trends Simulated by Chemistry-Climate Models

Author

Yipeng Guo, Xudong Wang, Meichen Liu, Wenjun Sang, Qi Xu, Dingzhu Hu, Yuanpu Li, and Feiyang Wang

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Article Subject, Chemistry, lcsh:QC851-999, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Pollution, Ozone depletion, Brewer-Dobson circulation, Geophysics, Geography, Downwelling, Climatology, Ozone layer, Extratropical cyclone, Upwelling, lcsh:Meteorology. Climatology, Climate model, Stratosphere, 0105 earth and related environmental sciences

Abstract

Based on data from 16 chemistry-climate models (CCMs) and separate experimental results using a state-of-the-art CCM, the trends in the Brewer–Dobson circulation (BDC) during the second half of the 20th century (1960–2000) and the first half of the 21st century (2001–2050) are examined. From the ensemble mean of the CCMs, the BDC exhibits strengthening trends in both the 20th and 21st centuries; however, the acceleration rates of tropical upwelling and southern downwelling during 2001–2050 are smaller than those during 1960–2000, while the acceleration rate of the northern downward branch of the BDC during 2001–2050 is slightly larger than that during 1960–2000. The differences in the extratropical downwelling trends between the two periods are closely related to changes in planetary-wave propagation into the stratosphere caused by the combined effects of increases in the concentrations of greenhouse gases (GHGs) and changes in stratospheric ozone. Model simulations demonstrate that the response of southern downwelling to stratospheric ozone depletion is larger than that to the increase in GHGs, but that the latter plays a more important role in the strengthening of northern downwelling. This result suggests that, under the expected future climate, northern downwelling will play a more important role in balancing tropical upwelling.

Published

2017

33. Effects of the Quasi-Biennial Oscillation and Stratospheric Semiannual Oscillation on Tracer Transport in the Upper Stratosphere

Author

Hongying Tian, Fei Xie, Wenshou Tian, Jianchuan Shu, Dingzhu Hu, Lin Shang, and Jiankai Zhang

Subjects

Quasi-biennial oscillation, Atmospheric Science, Stratopause, Downwelling, Climatology, Mixing ratio, Westerlies, Gravity wave, Atmospheric sciences, Trough (meteorology), Stratosphere, Geology

Abstract

Using satellite observations together with a chemistry–climate model (CCM), the effect of the stratospheric semiannual oscillation (SAO) and quasi-biennial oscillation (QBO) on the equatorial double peak in observed CH4 and NO2 is reexamined. It is concluded that the lower-equatorial Halogen Occultation Experiment (HALOE) CH4 mixing ratio of the April double peak in 1993 and 1995 was associated with the prominent first cycle of the SAO westerlies, which causes local vertical downwelling in the upper equatorial stratosphere. The observational evidences imply that the strong westerlies of the first cycle of the stratospheric SAO in 1993 and 1995 were driven by enhanced lower-stratospheric gravity wave activity in the early parts of those years. The CCM simulations further verify that the gravity wave source strength has a large impact on the development and strength of the SAO westerlies. This result suggests that the equatorial long-lived tracer mixing ratio near the stratopause (which is associated with the strength of the SAO westerlies) was not only modulated by the QBO phase, but was also significantly influenced by interannual variation in the gravity waves. It is also found that the deeper equatorial trough of the double peak is unlikely to be always accompanied by the more prominent Northern Hemispheric lobe, and the Northern Hemispheric lobe of the double peak can be mainly attributed to subtropical upwelling. The altitude of greatest chemical destruction anomalies associated with the SAO and QBO is below the trough of the double peak, implying that the effect of the chemical process on the double peak is insignificant.

Published

2013

34. Effects of meridional sea surface temperature changes on stratospheric temperature and circulation

Author

Jianchuan Shu, Sandip Dhomse, Fei Xie, Dingzhu Hu, and Wenshou Tian

Subjects

Atmosphere, Troposphere, Atmospheric Science, Sea surface temperature, Polar vortex, Climatology, Environmental science, Zonal and meridional, Tropopause, Atmospheric sciences, Stratosphere, Brewer-Dobson circulation

Abstract

Using a state-of-the-art chemistry-climate model, we analyzed the atmospheric responses to increases in sea surface temperature (SST). The results showed that increases in SST and the SST meridional gradient could intensify the subtropical westerly jets and significantly weaken the northern polar vortex. In the model runs, global uniform SST increases produced a more significant impact on the southern stratosphere than the northern stratosphere, while SST gradient increases produced a more significant impact on the northern stratosphere. The asymmetric responses of the northern and southern polar stratosphere to SST meridional gradient changes were found to be mainly due to different wave properties and transmissions in the northern and southern atmosphere. Although SST increases may give rise to stronger waves, the results showed that the effect of SST increases on the vertical propagation of tropospheric waves into the stratosphere will vary with height and latitude and be sensitive to SST meridional gradient changes. Both uniform and non-uniform SST increases accelerated the large-scale Brewer-Dobson circulation (BDC), but the gradient increases of SST between 60°S and 60°N resulted in younger mean age-of-air in the stratosphere and a larger increase in tropical upwelling, with a much higher tropopause than from a global uniform 1.0 K SST increase. © 2014 Chinese National Committee for International Association of Meteorology and Atmospheric Sciences, Institute of Atmospheric Physics, Science Press and Springer-Verlag Berlin Heidelberg.

Published

2014