Your search keyword '"Yulei QI"' showing total 4 results

1. The North American Spring Coldness Response to the Persistent Weak Stratospheric Vortex Induced by Extreme El Niño Events

Author

Yawei Yang, Quanliang Chen, Xin Zhou, Jingtao Zhou, Yulei Qi, Yong Zhao, Yang Li, and Shaobo Zhang

Subjects

spring coldness, 010504 meteorology & atmospheric sciences, Advection, stratospheric pathway, 010502 geochemistry & geophysics, extreme El Niño, 01 natural sciences, Vortex, Troposphere, Atmosphere, Climatology, north America, Ridge (meteorology), Environmental science, General Earth and Planetary Sciences, lcsh:Q, Climate model, WACCM4, lcsh:Science, Trough (meteorology), Stratosphere, 0105 earth and related environmental sciences

Abstract

The stratospheric pathway is a major driver of El Niño–Southern Oscillation (ENSO) impacts on mid-latitude tropospheric circulation and winter weather. The weak vortex induced by El Niño conditions has been shown to increase the risk of cold spells, especially over Eurasia, but its role for North American winters is less clear. This study involved idealized experiments with the Whole Atmosphere Community Climate Model to examine how the weak winter vortex induced by extreme El Niño events is linked to North American coldness in spring. Contrary to the expected mid-latitude cooling associated with a weak vortex, extreme El Niño events do not lead to North American cooling overall, with daily cold extremes actually decreasing, especially in Canada. The expected cooling is absent in most of North America because of the advection of warmer air masses guided by an enhanced ridge over Canada and a trough over the Aleutian Peninsula. This pattern persists in spring as a result of the trapping of stationary waves from the polar stratosphere and troposphere, implying that the stratospheric influence on North America is sensitive to regional downward wave activities.

Published

2021

2. Comparison of the effect of land-sea thermal contrast on interdecadal variations in winter and summer blockings

Author

Shanshan Wang, Yongkun Xie, Dongdong Li, Yulei Qi, Jianping Huang, Sonja Totz, Yongli He, and Guolong Zhang

Subjects

Atmospheric Science, Coupled model intercomparison project, 010504 meteorology & atmospheric sciences, Blocking (radio), Global warming, Institut für Physik und Astronomie, Flux, Forcing (mathematics), 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Negative feedback, Climatology, Thermal, Environmental science, ddc:530, 0105 earth and related environmental sciences, Positive feedback

Abstract

The influence of winter and summer land-sea surface thermal contrast on blocking for 1948-2013 is investigated using observations and the coupled model intercomparison project outputs. The land-sea index (LSI) is defined to measure the changes of zonal asymmetric thermal forcing under global warming. The summer LSI shows a slower increasing trend than winter during this period. For the positive of summer LSI, the EP flux convergence induced by the land-sea thermal forcing in the high latitude becomes weaker than normal, which induces positive anomaly of zonal-mean westerly and double-jet structure. Based on the quasiresonance amplification mechanism, the narrow and reduced westerly tunnel between two jet centers provides a favor environment for more frequent blocking. Composite analysis demonstrates that summer blocking shows an increasing trend of event numbers and a decreasing trend of durations. The numbers of the short-lived blocking persisting for 5-9 days significantly increases and the numbers of the long-lived blocking persisting for longer than 10 days has a weak increase than that in negative phase of summer LSI. The increasing transient wave activities induced by summer LSI is responsible for the decreasing duration of blockings. The increasing blocking due to summer LSI can further strengthen the continent warming and increase the summer LSI, which forms a positive feedback. The opposite dynamical effect of LSI on summer and winter blocking are discussed and found that the LSI-blocking negative feedback partially reduces the influence of the above positive feedback and induce the weak summer warming rate.

Published

2017

3. Delayed effect of Arctic stratospheric ozone on tropical rainfall

Author

Fei Xie, Jiankai Zhang, Wenjun Sang, Yang Li, Yulei Qi, Cheng Sun, and Jianchuan Shu

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, viruses, virus diseases, Tropics, biochemical phenomena, metabolism, and nutrition, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Sea surface temperature, La Niña, Arctic, Climatology, Tropical climate, Ozone layer, Environmental science, Walker circulation, Precipitation, 0105 earth and related environmental sciences

Abstract

The tropical precipitation has a wide effect on the tropical economics and social life. Many studies made efforts to improve the tropical precipitation forecast using tropical climate factors. This study, based on observations, found that Arctic stratospheric ozone (ASO) could exert a significant effect on the tropical precipitation, i.e. there is more (less) rainfall over the eastern Pacific and less (more) precipitation over the western Pacific when the ASO anomalies are lower (larger) than normal. It is because a decrease (increase) in ASO could affect El Nino (La Nina) events and lead to a weakened (enhanced) Walker circulation. Time-slice experiments confirmed that the ASO anomalies can force El Nino–Southern Oscillation-like anomalies of tropical sea surface temperature and subsequent tropical precipitation anomalies. In addition, the ASO variations could also change the occurrence probability of extreme precipitation in the tropics. During the anomalously low (high) ASO events, there are more occurrences of heavier precipitation over the eastern Pacific (western Pacific) and of lighter precipitation over the western Pacific (eastern Pacific). Furthermore, the ASO variations lead tropical rainfall by approximately 21 months, suggesting that the ASO can serve as a potentially effective predictor of tropical rainfall.

Published

2017

4. Influence of the Arctic Oscillation on the Vertical Distribution of Wintertime Ozone in the Stratosphere and Upper Troposphere over the Northern Hemisphere

Author

Wuhu Feng, Jinlong Huang, Jianchuan Shu, Wenshou Tian, Fei Xie, Yuanyuan Han, Yulei Qi, Kequan Zhang, Jiankai Zhang, and Martyn P. Chipperfield

Subjects

Atmospheric Science, Ozone, 010504 meteorology & atmospheric sciences, Chemical transport model, Northern Hemisphere, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Troposphere, chemistry.chemical_compound, Arctic, chemistry, Middle latitudes, Climatology, Ozone layer, Environmental science, Stratosphere, 0105 earth and related environmental sciences

Abstract

The influence of the Arctic Oscillation (AO) on the vertical distribution of stratospheric ozone in the Northern Hemisphere in winter is analyzed using observations and an offline chemical transport model. Positive ozone anomalies are found at low latitudes (0°–30°N) and there are three negative anomaly centers in the northern mid- and high latitudes during positive AO phases. The negative anomalies are located in the Arctic middle stratosphere (~30 hPa; 70°–90°N), Arctic upper troposphere–lower stratosphere (UTLS; 150–300 hPa, 70°–90°N), and midlatitude UTLS (70–300 hPa, 30°–60°N). Further analysis shows that anomalous dynamical transport related to AO variability primarily controls these ozone changes. During positive AO events, positive ozone anomalies between 0° and 30°N at 50–150 hPa are related to the weakened meridional transport of the Brewer–Dobson circulation (BDC) and enhanced eddy transport. The negative ozone anomalies in the Arctic middle stratosphere are also caused by the weakened BDC, while the negative ozone anomalies in the Arctic UTLS are caused by the increased tropopause height, weakened BDC vertical transport, weaker exchange between the midlatitudes and the Arctic, and enhanced ozone depletion via heterogeneous chemistry. The negative ozone anomalies in the midlatitude UTLS are mainly due to enhanced eddy transport from the midlatitudes to the latitudes equatorward of 30°N, while the transport of ozone-poor air from the Arctic to the midlatitudes makes a minor contribution. Interpreting AO-related variability of stratospheric ozone, especially in the UTLS, would be helpful for the prediction of tropospheric ozone variability caused by the AO.

Published

2017