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267 results on '"He, Maosheng"'

1. Nonlinear Interactions of Planetary-Scale Waves in Mesospheric Winds Observed at 52{\deg}N Latitude and Two Longitudes

Author

He, Maosheng, Forbes, Jeffrey M., Stober, Gunter, Jacobi, Christoph, Li, Guozhu, Liu, Libo, and Xu, Jiyao

Subjects
Physics - Space Physics
Abstract

Nine years of mesospheric wind data from two meteor radars at 52{\deg}N latitude were analyzed to investigate planetary waves (PWs) and tides by estimating their zonal wavenumber through longitudinal phase differences. Our results reveal that PW normal modes (NMs) primarily drive multi-day oscillations, showing seasonal variability and statistical associations with Sudden Stratospheric Warming (SSW) events. Specifically, a significant 6-day NM emerges in April, followed by predominant 4- and 2-day NMs until June, with peaks of 2-, 4-, and 6-day NMs spanning July to October. Furthermore, our study provides the first observational verification of frequency and zonal wavenumber of over ten secondary waves from nonlinear interactions among planetary-scale waves. One notable finding is the prevalence of non-migrating components in winter 24-hour and summer 8-hour tides, attributed to these nonlinear interactions. Our findings underscore the diverse nonlinear dynamics of planetary-scale waves, triggering a variety of periodic oscillations.

Published
2024

5. Spatially high-resolved solar-wind-induced magnetic field on Venus

Author

He, Maosheng, Vogt, Joachim, Dubinin, Eduard, Zhang, Tielong, and Rong, Zhaojin

Subjects
Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics
Abstract

The current work investigates the Venusian solar-wind-induced magnetosphere at a high spatial resolution using all Venus Express (VEX) magnetic observations through an unbiased statistical method. We first evaluate the predictability of the interplanetary magnetic field (IMF) during VEX's magnetospheric transits, and then map the induced field in a cylindrical coordinate system under different IMF conditions. Our high-resolution mapping enables resolving structures on various scales, ranging from the thin ionopause and the associated electric currents to the classical global-scale draped IMF. Our mapping also resolves two recently-reported structures, a low ionospheric magnetization over the terminator and a global "looping" structure in the near magnetotail, both of which are not depicted in the classical draping configuration. In contrast to the reported IMF-independent cylindrical magnetic field of both structures, our results illustrate their IMF dependence. In both structures, the cylindrical magnetic component is stronger in the hemisphere with an upward solar wind electric field ($E^{SW}$) than in the opposite hemisphere. Under downward $E^{SW}$, the "looping" structure even breaks, which is attributable to an additional draped magnetic field structure wrapping toward $-E^{SW}$. In addition, our results suggest that these two structures are spatially not overlapping with each other. The low ionospheric structure occurs in a very narrow region, at about 87--95$^\circ$ solar zenith angle and 190--210~km altitude, implying that future simulation to reproduce the structure entails at least a spatial resolution of about 10 km. We discuss this narrow structure in terms of a Cowling channel., Comment: submitted to The Astrophysical Journal

Published
2021
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16. East–West Difference in the Ionospheric Response During the Recovery Phase of May 2024 Super Geomagnetic Storm Over the East Asian.

Author

Guo, Xu, Zhao, Biqiang, Yu, Tingting, Hao, Honglian, Sun, Wenjie, Wang, Guojun, He, Maosheng, Mao, Tian, Li, Guozhu, and Ren, Zhipeng

Subjects
ELECTRON distribution, MAGNETIC storms, ELECTRON density, IONOSPHERIC disturbances, LATITUDE
Abstract

In this study, we offer an extensive examination of the F‐region ionospheric disturbances during the May 2024 superstorm, focusing primarily on the middle‐low latitude regions of East Asia. Our analysis is grounded in a wealth of data sources including Total Electron Content (TEC), ionospheric parameters NmF2 and hmF2, Electron Density Profile (EDP) retrieved from Radio Occultation (RO) data, and ∑[O]/[N2] from the Global Ultraviolet Imager (GUVI), among others, complemented by model simulations. The observed negative ionospheric storm effect, characterized by a significant and long‐lasting reduction in electron density across the entire China, commenced immediately following the sudden storm commencement (SSC) on 10 May and continued through the main and early recovery phase of the storm on 11 May. On 11–12 May, positive ionospheric storm impacts were initially observed in a restricted geographical area from the post‐midnight to sunrise, first manifesting over the eastern regions of China and then shifting to the central regions. Subsequently, a pronounced negative storm effect persisted throughout the later stages of recovery phase. In contrast, the western regions of China experienced a positive storm effect on 12 May followed by a comparatively mild negative storm phase. This persistent extensive zonal gradient in electron density across the East Asian region resembles the scenarios depicted in prior superstorms attributed to the thermospheric circulation patterns. The disparity in the ionospheric response from east to west in this area is probably a common feature during superstorms, potentially resulting from an arch‐shaped structure of elevated ∑[O]/[N2]. Key Points: The superstorm in May 2024 led to a significant and persistent decrease in electron density at middle‐low latitude over Eastern ChinaPositive ionospheric effects spread from post‐midnight eastern China to central China, with western China seeing a weaker positive stormThe disparity in ionospheric response from east to west mainly arose from an arch‐shaped structure of elevated ∑[O]/[N2] [ABSTRACT FROM AUTHOR]

Published
2024
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20. Empirical Modeling of Planetary Magnetospheres in Response to Solar Wind Dynamics Using EOF Analysis and Multivariate Linear Regression

Author

He, Maosheng, Vogt, Joachim, Bertola, F., Editorial Board Member, Cesarsky, C. J., Editorial Board Member, Ehrenfreund, P., Editorial Board Member, Engvold, O., Editorial Board Member, van den Heuvel, E. P. J., Editorial Board Member, Kaspi, V. M., Editorial Board Member, Kuijpers, J. M. E., Editorial Board Member, van der Laan, H., Editorial Board Member, Murdin, P. G., Editorial Board Member, Somov, B. V., Editorial Board Member, Sunyaev, R. A., Editorial Board Member, Lühr, Hermann, editor, Wicht, Johannes, editor, Gilder, Stuart A., editor, and Holschneider, Matthias, editor

Published
2018
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27. The Evolution of Solar Tide‐Like Signatures in the Ionospheric Total Electron Content During Major Sudden Stratospheric Warming Events.

Author

Ma, Han, Liu, Libo, He, Maosheng, Yu, You, Zhang, Ruilong, Lyu, Haixia, Li, Wenbo, Chen, Yiding, and Le, Huijun

Subjects
THERMOSPHERE, EQUATORIAL ionization anomaly, ATMOSPHERIC boundary layer, ATMOSPHERIC temperature, OZONE layer, ELECTRONS
Abstract

By using total electron content (TEC) from the global ionospheric maps, the solar tide‐like signatures in the ionosphere are explored. We further study how the main components evolve during the 2009 and 2018 major stratospheric sudden warming events (SSWs). The method of a least‐square fit is applied for extracting the solar tide‐like components. The three predominant components are SW2, D0, and SW1, amplitude of which increase in the equatorial ionization anomaly region after the onset of both SSW events, especially in the northern hemisphere. During the SSW events, the solar tide‐like components vary significantly with latitude and their evolutions show hemispherical asymmetries. Each same component presents similar evolutionary trend during both events. The characteristics of ionospheric tide‐like signatures and related mechanisms are discussed. The SW2 tide‐like responses in TEC closely follow the changes in the tidal wind fields in the lower thermosphere, which provide evidences of the atmosphere‐ionosphere coupling during SSW events. In addition, the latitudinal asymmetric distributing of stratospheric ozone and ionospheric TEC background during the SSW may be influence factors for the hemispherical asymmetries in tide‐like signatures responses in TEC. Plain Language Summary: Stratosphere sudden warming (SSW) is a meteorological event in which the stratospheric atmospheric temperature will increase dramatically within a matter of days even in the northern polar winter. Although it is a stratospheric phenomenon, the tidal variations from the lower atmosphere can impose their influences even at the ionospheric height during SSW events. We present the evolutions of dominant tide‐like components in the total electron content data. In addition, the changes of the ionospheric migrating tide‐like components are like those in the mesospheric neutral winds. These similarities imply a strong atmosphere‐ionosphere coupling during a major SSW event. Key Points: The predominant ionospheric tide‐like components were SW2, D0, and SW1 during the 2009 and 2018 major stratospheric sudden warming (SSW) eventsAfter the SSWs onset, there were enhancements for the three tide‐like components in the equatorial ionization anomaly region, especially for the northern hemisphereThe SW2 tide‐like responses in total electron content had similar responses with the changes in the tidal winds in the lower thermosphere [ABSTRACT FROM AUTHOR]

Published
2023
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28. Vertical Variations in Thermospheric O/N2 and the Relationship Between O and N2 Perturbations During a Geomagnetic Storm.

Author

Yu, Tingting, Wang, Wenbin, Ren, Zhipeng, Cai, Xuguang, and He, Maosheng

Subjects
MAGNETIC storms, GENERAL circulation model, GEOMAGNETISM, IONOSPHERIC plasma, ELECTRON density, PLASMA density
Abstract

The ratio of O to N2 number densities (O/N2) at different altitudes is an important parameter in describing thermospheric neutral composition changes and their effects on the ionosphere during geomagnetic storms. However, storm‐induced vertical variations in O/N2 and its dependence on the O and N2 perturbations are still not fully understood. Here, the Thermosphere/Ionosphere Electrodynamics General Circulation Model simulations were used to investigate the responses of thermospheric composition at different pressure levels to the super geomagnetic storm occurred on November 20 and 21 in 2003. Our analysis shows that the behaviors of O/N2 perturbations on different pressure levels are similar above ∼180 km altitude. In the middle and low thermosphere of below ∼300 km, the storm‐time O/N2 decrease is mainly caused by a large reduction of O number density. However, N2 enhancement plays a vital role in O/N2 decreases in the upper thermosphere. The O/N2 enhancement is mainly attributed to the N2 decreases at all pressure levels. The changes of O and N2 number densities at a constant pressure level can be explained by the perturbations of their mass mixing ratio (mmr) and total mass density (ρ). The regions of the O/N2 decrease are characterized by the O mmr decrease and N2 mmr enhancement, whereas the regions of the O/N2 increase are characterized by the O mmr increase and N2 mmr decrease. The ρ value that shows the decrease globally at most pressure levels during the storm either enhance or reduce the O and N2 perturbations. Plain Language Summary: The column O/column N2 density ratio (∑O/N2) was usually used to describe thermospheric neutral composition responses to geomagnetic storms and the storm effects on ionospheric plasma density. However, thermospheric circulation changed considerably during the storm, resulting in discrepancies in composition at different altitudes. Additionally, the daytime electron density changes during geomagnetic storms are more related to those of local O/N2 at a given altitude, not the ∑O/N2. Therefore, it is important to fully understand the storm‐induced vertical variations in O, N2 and O/N2 perturbations. In this paper, the vertical variations in O/N2 and its dependence on the O and N2 perturbations during the 20–21 November 2003 storm are investigated by the numerical simulations. Our results shows that the behaviors of O and N2 perturbations depend much on the altitude, but those of O/N2 on different pressure levels are similar, especially above ∼180 km. This study helps us better understand the physical process of storm‐time ∑O/N2 variations based on the observations. Key Points: In middle and low thermosphere of below ∼300 km, storm‐time decreases of the ratio of O/N2 volume density are mainly caused by O reductionIn the upper thermosphere, N2 enhancement plays a vital role in the decreases of the ratio of O/N2 volume density during the stormAt all pressure levels, storm‐time increases of the ratio of O/N2 volume density depend more on the N2 decreases [ABSTRACT FROM AUTHOR]

Published
2023
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33. Long-term studies of mesosphere and lower-thermosphere summer length definitions based on mean zonal wind features observed for more than one solar cycle at middle and high latitudes in the Northern Hemisphere

Author

Jaen, Juliana, Renkwitz, Toralf, Chau, Jorge L., He, Maosheng, Hoffmann, Peter, Yamazaki, Yosuke, Jacobi, Christoph, Tsutsumi, Masaki, Matthias, Vivien, and Hall, Chris

Subjects
QC801-809, summer length, Science, Physics, QC1-999, zonal wind, Geophysics. Cosmic physics, mesosphere
Abstract

Specular meteor radars (SMRs) and partial reflection radars (PRRs) have been observing mesospheric winds for more than a solar cycle over Germany (∼ 54∘ N) and northern Norway (∼ 69∘ N). This work investigates the mesospheric mean zonal wind and the zonal mean geostrophic zonal wind from the Microwave Limb Sounder (MLS) over these two regions between 2004 and 2020. Our study focuses on the summer when strong planetary waves are absent and the stratospheric and tropospheric conditions are relatively stable. We establish two definitions of the summer length according to the zonal wind reversals: (1) the mesosphere and lower-thermosphere summer length (MLT-SL) using SMR and PRR winds and (2) the mesosphere summer length (M-SL) using the PRR and MLS. Under both definitions, the summer begins around April and ends around middle September. The largest year-to-year variability is found in the summer beginning in both definitions, particularly at high latitudes, possibly due to the influence of the polar vortex. At high latitudes, the year 2004 has a longer summer length compared to the mean value for MLT-SL as well as 2012 for both definitions. The M-SL exhibits an increasing trend over the years, while MLT-SL does not have a well-defined trend. We explore a possible influence of solar activity as well as large-scale atmospheric influences (e.g., quasi-biennial oscillation (QBO), El Niño–Southern Oscillation (ENSO), major sudden stratospheric warming events). We complement our work with an extended time series of 31 years at middle latitudes using only PRR winds. In this case, the summer length shows a breakpoint, suggesting a non-uniform trend, and periods similar to those known for ENSO and QBO.

Published
2022

41. The potential to use variations in tree-ring geometric center to estimate past wind speed change

Author

Chinese Academy of Sciences, National Natural Science Foundation of China, Natural Science Foundation of Fujian Province, Agencia Estatal de Investigación (España), Ministerio de Ciencia, Innovación y Universidades (España), Fang, Keyan, He, Maosheng, Bai, Maowei, Dong, Zhipeng, Linderholm, Hans W., Azorín-Molina, César, Guo, Zhengtang, Chinese Academy of Sciences, National Natural Science Foundation of China, Natural Science Foundation of Fujian Province, Agencia Estatal de Investigación (España), Ministerio de Ciencia, Innovación y Universidades (España), Fang, Keyan, He, Maosheng, Bai, Maowei, Dong, Zhipeng, Linderholm, Hans W., Azorín-Molina, César, and Guo, Zhengtang

Abstract

Tree radial growth is characterized by not only the annual ring-width increment but also shifts in the tree-ring geometric center (TRGC) if subjected to asymmetric external forcing, such as gravity downslope or prevailing winds. Previous dendrochronological studies have used the asymmetric growth derived from tree-ring widths to reconstruct wind speed changes. Here we propose a novel method that uses quantitative TRGC measurements to estimate wind speed. We investigated TRGC shifts in northeast China, where the prevailing westerly winds are strong and persistent. We found that the TRGC showed significant correlations (r ​= ​0.64, p ​< ​0.01) with wind speed in May–September. The higher tree geometry sensitivity to wind speed obtained with the new method compared to previous ones, suggests the possibility of reconstructing historical wind change and variability in prevailing winds using TRGC. In addition, by correcting tree-ring radius according to their TRGC shifts, the basal area increment (BAI) was calculated. Our new BAI estimation provided stronger correlations with climate than both the standard tree-ring width chronology and a traditional BAI estimation. We suggest that future dendrochronological studies should consider TRGC shifts to increase the accuracy in climate reconstructions.

Published
2022

44. Quasi-2-Day Wave in Low-Latitude Atmospheric Winds as Viewed From the Ground and Space During January–March, 2020

Author

He, Maosheng, primary, Chau, Jorge L., additional, Forbes, Jeffrey M., additional, Zhang, Xiaoli, additional, Englert, Christoph R., additional, Harding, Brian J., additional, Immel, Thomas J., additional, Lima, Lourivaldo M., additional, Rao, S. Vijaya Bhaskar, additional, Ratnam, M. Venkat, additional, Li, Guozhu, additional, Harlander, John M., additional, Marr, Kenneth D., additional, and Makela, Jonathan J., additional

Published
2022
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47. Suppressing Residual Lead Iodide and Defects in Sequential‐Deposited Perovskite Solar Cell via Bidentate Potassium Dichloroacetate Ligand

Author

Yang, Yajuan, primary, Liang, Jianghu, additional, Zhang, Zhanfei, additional, Tian, Congcong, additional, Wu, Xueyun, additional, Zheng, Yiting, additional, Huang, Ying, additional, Wang, Jianli, additional, Zhou, Zhuang, additional, He, Maosheng, additional, Chen, Zhenhua, additional, and Chen, Chun‐Chao, additional

Published
2022
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