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370 results on '"Pu, Z. Y."'

1. Earth wind as a possible source of lunar surface hydration

Author

Wang, H. Z., Zhang, J., Shi, Q. Q., Saito, Y., Degeling, A. W., Rae, I. J., Liu, J., Guo, R. L., Yao, Z. H., Tian, A. M., Fu, X. H., Zong, Q. G., Liu, J. Z., Ling, Z. C., Sun, W. J., Bai, S. C., Chen, J., Yao, S. T., Zhang, H., Wei, Y., Liu, W. L., Xia, L. D., Chen, Y., Feng, Y. Y., Fu, S. Y., and Pu, Z. Y.

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

Understanding the sources of lunar water is crucial for studying the history of lunar evolution, and also the solar wind interaction with the Moon and other airless bodies. Recent observations revealed lunar hydration is very likely a surficial dynamic process driven by solar wind. Solar wind is shielded over a period of 3-5 days as the Moon passes through the Earth's magnetosphere, during which a significant loss of hydration is expected from previous works.Here we study lunar hydration inside the magnetosphere using orbital spectral data, which unexpectedly found that the polar surficial OH/H2O abundance remains at the same level when in the solar wind and in the magnetosphere. We suggest that particles from the magnetosphere (Earth wind, naturally different from solar wind) contribute to lunar hydration. From lunar orbital plasma observations, we find the existence of optimal energy ranges, other than 1 keV as previously thought, for surface hydration formation. These optimal energy ranges deduced from space observations may provide strong implications for laboratory experiments simulating lunar hydration processes.

Published
2019

2. Corotating Magnetic Reconnection Site in Saturn's Magnetosphere

Author

Yao, Zhonghua, Coates, A. J., Ray, L. C., Rae, I. J., Grodent, D., Jones, G. H., Dougherty, M. K., Owen, C. J., Guo, R. L., Dunn, W., Radioti, A., Pu, Z. Y., Lewis, G. R., Waite, J. H., and Gerard, J. -C.

Subjects
Physics - Space Physics
Abstract

Using measurements from the Cassini spacecraft in Saturn's magnetosphere, we propose a 3D physical picture of a corotating reconnection site, which can only be driven by an internally generated source. Our results demonstrate that the corotating magnetic reconnection can drive an expansion of the current sheet in Saturn's magnetosphere and, consequently, can produce Fermi acceleration of electrons. This reconnection site lasted for longer than one of Saturn's rotation period. The long-lasting and corotating natures of the magnetic reconnection site at Saturn suggest fundamentally different roles of magnetic reconnection in driving magnetospheric dynamics (e.g., the auroral precipitation) from the Earth. Our corotating reconnection picture could also potentially shed light on the fast rotating magnetized plasma environments in the solar system and beyond., Comment: 7 pages, 5 figures

Published
2017
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3. Observations of kinetic-size magnetic holes in the magnetosheath

Author

Yao, S. T., Wang, X. G., Shi, Q. Q., Pitkänen, T., Hamrin, M., Yao, Z. H., Li, Z. Y., Ji, X. F., De Spiegeleer, A., Xiao, Y. C., Tian, A. M., Pu, Z. Y., Zong, Q. G., Xiao, C. J., Fu, S. Y., Zhang, H., Russell, C. T., Giles, B. L., Guo, R. L., Sun, W. J., Li, W. Y., Zhou, X. Z., Huang, S. Y., Vaverka, J., Nowada, M., Bai, S. C., Wang, M. M., and Liu, J.

Subjects
Physics - Space Physics
Abstract

Magnetic holes (MHs), with a scale much greater than \r{ho}i (proton gyroradius), have been widely reported in various regions of space plasmas. On the other hand, kinetic-size magnetic holes (KSMHs), previously called small size magnetic holes (SSMHs), with a scale of the order of magnitude of or less than \r{ho}i have only been reported in the Earth's magnetospheric plasma sheet. In this study, we report such KSMHs in the magnetosheath whereby we use measurements from the Magnetospheric Multiscale (MMS) mission, which provides three-dimensional (3D) particle distribution measurements with a resolution much higher than previous missions. The MHs have been observed in a scale of 10 ~ 20 \r{ho}e (electron gyroradii) and lasted 0.1 ~ 0.3 s. Distinctive electron dynamics features are observed, while no substantial deviations in ion data are seen. It is found that at the 90{\deg} pitch angle, the flux of electrons with energy 34 ~ 66 eV decreased while for electrons of energy 109 ~ 1024 eV increased inside the MHs. We also find the electron flow vortex perpendicular to the magnetic field, a feature self-consistent with the magnetic depression. Moreover, the calculated current density is mainly contributed by the electron diamagnetic drift, and the electron vortex flow is the diamagnetic drift flow. The electron magnetohydrodynamics (EMHD) soliton is considered as a possible generation mechanism for the KSMHs with the scale size of 10 ~ 20 \r{ho}e., Comment: The paper need to be removed as some data is not corrected

Published
2017
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4. Satellite Observations of Separator Line Geometry of Three-Dimensional Magnetic Reconnection

Author

Xiao, C. J., Wang, X. G., Pu, Z. Y., Ma, Z. W., Zhao, H., Zhou, G. P., Wang, J. X., Kivelson, M. G., Fu, S. Y., Liu, Z. X., Zong, Q. G., Dunlop, M. W., Glassmeier, K-H., Lucek, E., Reme, H., Dandouras, I., and Escoubet, C. P.

Subjects
Physics - Plasma Physics, Physics - Space Physics
Abstract

Detection of a separator line that connects magnetic nulls and the determination of the dynamics and plasma environment of such a structure can improve our understanding of the three-dimensional (3D) magnetic reconnection process. However, this type of field and particle configuration has not been directly observed in space plasmas. Here we report the identification of a pair of nulls, the null-null line that connects them, and associated fans and spines in the magnetotail of Earth using data from the four Cluster spacecraft. With di and de designating the ion and electron inertial lengths, respectively, the separation between the nulls is found to be ~0.7di and an associated oscillation is identified as a lower hybrid wave with wavelength ~ de. This in situ evidence of the full 3D reconnection geometry and associated dynamics provides an important step toward to establishing an observational framework of 3D reconnection., Comment: 10 pages, 3 figures and 1 table

Published
2007
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5. In situ evidence for the structure of the magnetic null in a 3D reconnection event in the Earth's magnetotail

Author

Xiao, C. J., Wang, X. G., Pu, Z. Y., Zhao, H., Wang, J. X., Ma, Z. W., Fu, S. Y., Kivelson, M. G., Liu, Z. X., Zong, Q. G., Glassmeier, K. H., Balogh, A., Korth, A., Reme, H., and Escoubet, C. P.

Subjects
Physics - Plasma Physics, Physics - Space Physics
Abstract

Magnetic reconnection is one of the most important processes in astrophysical, space and laboratory plasmas. Identifying the structure around the point at which the magnetic field lines break and subsequently reform, known as the magnetic null point, is crucial to improving our understanding reconnection. But owing to the inherently three-dimensional nature of this process, magnetic nulls are only detectable through measurements obtained simultaneously from at least four points in space. Using data collected by the four spacecraft of the Cluster constellation as they traversed a diffusion region in the Earth's magnetotail on 15 September, 2001, we report here the first in situ evidence for the structure of an isolated magnetic null. The results indicate that it has a positive-spiral structure whose spatial extent is of the same order as the local ion inertial length scale, suggesting that the Hall effect could play an important role in 3D reconnection dynamics., Comment: 14 pages, 4 figures

Published
2006
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14. A Rotating Azimuthally Distributed Auroral Current System on Saturn Revealed by the Cassini Spacecraft

Author

Guo, R. L., primary, Yao, Z. H., additional, Dunn, W. R., additional, Palmaerts, B., additional, Sergis, N., additional, Grodent, D., additional, Badman, S. V., additional, Ye, S. Y., additional, Pu, Z. Y., additional, Mitchell, D. G., additional, Zhang, B. Z., additional, Achilleos, N., additional, Coates, A. J., additional, Wei, Y., additional, Waite, J. H., additional, Krupp, N., additional, and Dougherty, M. K., additional

Published
2021
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17. Earth Wind as a Possible Exogenous Source of Lunar Surface Hydration

Author

Wang, H. Z., primary, Zhang, J., additional, Shi, Q. Q., additional, Saito, Y., additional, Degeling, A. W., additional, Rae, I. J., additional, Zong, Q. G., additional, Wei, Y., additional, Liu, J., additional, Guo, R. L., additional, Yao, Z. H., additional, Tian, A. M., additional, Fu, X. H., additional, Liu, J. Z., additional, Ling, Z. C., additional, Fu, S. Y., additional, Sun, W. J., additional, Bai, S. C., additional, Chen, J., additional, Yao, S. T., additional, Zhang, H., additional, Liu, W. L., additional, Xia, L. D., additional, Feng, Y. Y., additional, and Pu, Z. Y., additional

Published
2021
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19. Electron Energization and Energy Dissipation in Microscale Electromagnetic Environments

Author

Liu, J., primary, Yao, S. T., additional, Shi, Q. Q., additional, Wang, X. G., additional, Zong, Q. G., additional, Feng, Y. Y., additional, Liu, H., additional, Guo, R. L., additional, Yao, Z. H., additional, Rae, I. J., additional, Degeling, A. W., additional, Tian, A. M., additional, Russell, C. T., additional, Zhang, Y. T., additional, Wang, Y. X., additional, Woodham, L. D., additional, Pu, Z. Y., additional, Xiao, C. J., additional, Fu, S. Y., additional, and Giles, B. L., additional

Published
2020
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22. Unusual Location of the Geotail Magnetopause Near Lunar Orbit: A Case Study

Author

Shang, W. S., primary, Tang, B. B., additional, Shi, Q. Q., additional, Tian, A. M., additional, Zhou, X.‐Y., additional, Yao, Z. H., additional, Degeling, A. W., additional, Rae, I. J., additional, Fu, S. Y., additional, Lu, J. Y., additional, Pu, Z. Y., additional, Fazakerley, A. N., additional, Dunlop, M. W., additional, Facskó, G., additional, Liu, J., additional, and Wang, M., additional

Published
2020
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25. Inner Plasma Structure of the Low-Latitude Reconnection Layer

Author

Zhang, Q.-H, Dunlop, M. W, Lockwood, M, Lavraud, B, Bogdanova, Y. V, Hasegawa, H, Yang, H. -G, Liu, R. -Y, Hu, H. -Q, Zhang, B. -C, Pu, Z. -Y, Yang, Z. -W, Wang, J, Taylor, M. G. G. T, Berchem, J, Constantinescu, D, Volwerk, M, Frey, H, Fazakerley, A. N, Shen, C, Shi, J. -K, Sibeck, D, Escoubet, P, and Wild, J. A

Subjects
Geophysics
Abstract

We report a clear transition through a reconnection layer at the low-latitude magnetopause which shows a complete traversal across all reconnected field lines during northwestward interplanetary magnetic field (IMF) conditions. The associated plasma populations confirm details of the electron and ion mixing and the time history and acceleration through the current layer. This case has low magnetic shear with a strong guide field and the reconnection layer contains a single density depletion layer on the magnetosheath side which we suggest results from nearly field-aligned magnetosheath flows. Within the reconnection boundary layer, there are two plasma boundaries, close to the inferred separatrices on the magnetosphere and magnetosheath sides (Ssp and Ssh) and two boundaries associated with the Alfvén waves (or Rotational Discontinuities, RDsp and RDsh). The data are consistent with these being launched from the reconnection site and the plasma distributions are well ordered and suggestive of the time elapsed since reconnection of the field lines observed. In each sub-layer between the boundaries the plasma distribution is different and is centered around the current sheet, responsible for magnetosheath acceleration. We show evidence for a velocity dispersion effect in the electron anisotropy that is consistent with the time elapsed since reconnection. In addition, new evidence is presented for the occurrence of partial reflection of magnetosheath electrons at the magnetopause current layer.

Published
2012
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26. Spatial Distribution of Rolled up Kelvin-Helmholtz Vortices at Earth's Dayside and Flank Magnetopause

Author

Taylor, M. G. G. T, Hasegawa, H, Lavraud, B, Phan, T, Escoubet, C. P, Dunlop, M. W, Bogdanova, Y. V, Borg, A. L, Volwerk, M, Berchem, J, Constantinescu, O. D, Eastwood, J. P, Masson, A, Laakso, H, Soucek, J, Fazakerley, A. N, Frey, H. U, Panov, E. V, Shen, C, Shi, J. K, Sibeck, D. G, Pu, Z. Y, Wang, J, and Wild, J. A

Subjects
Space Sciences (General), Geophysics
Abstract

The Kelvin-Helmholtz Instability (KHI) can drive waves at the magnetopause. These waves can grow to form rolled-up vortices and facilitate transfer of plasma into the magnetosphere. To investigate the persistence and frequency of such waves at the magnetopause we have carried out a survey of all Double Star 1 magnetopause crossings, using a combination of ion and magnetic field measurements. Using criteria originally used in a Geotail study made by Hasegawa et al. (2006) (forthwith referred to as H2006), 17 candidate events were identified from the entire TC-1 mission (covering 623 orbits where the magnetopause was sampled), a majority of which were on the dayside of the terminator. The relationship between density and shear velocity was then investigated, to identify the predicted signature of a rolled up vortex from H2006 and all 17 events exhibited some level of rolled up behavior. The location of the events had a clear dawn-dusk asymmetry, with 12 (71 %) on the post noon, dusk flank suggesting preferential growth in this region.

Published
2012
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38. On the Relation Between Jovian Aurorae and the Loading/Unloading of the Magnetic Flux: Simultaneous Measurements From Juno, Hubble Space Telescope, and Hisaki

Author

Yao, Z. H., primary, Grodent, D., additional, Kurth, W. S., additional, Clark, G., additional, Mauk, B. H., additional, Kimura, T., additional, Bonfond, B., additional, Ye, S.‐Y., additional, Lui, A. T., additional, Radioti, A., additional, Palmaerts, B., additional, Dunn, W. R., additional, Ray, L. C., additional, Bagenal, F., additional, Badman, S. V., additional, Rae, I. J., additional, Guo, R. L., additional, Pu, Z. Y., additional, Gérard, J.‐C., additional, Yoshioka, K., additional, Nichols, J. D., additional, Bolton, S. J., additional, and Levin, S. M., additional

Published
2019
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40. A physical explanation for the magnetic decrease ahead of dipolarization fronts

Author

Yao, Z. H., Liu, J., Owen, C. J., Forsyth, C., Rae, I. J., Pu, Z. Y., Fu, H. S., Zhou, X.-Z., Shi, Q. Q., Du, A. M., Guo, R. L., and Chu, X. N.

Subjects
lcsh:Geophysics. Cosmic physics, lcsh:QC801-809, lcsh:Q, lcsh:Science, lcsh:Physics, lcsh:QC1-999
Abstract

Recent studies have shown that the ambient plasma in the near-Earth magnetotail can be compressed by the arrival of a dipolarization front (DF). In this paper we study the variations in the characteristics of currents flowing in this compressed region ahead of the DF, particularly the changes in the cross-tail current, using observations from the THEMIS satellites. Since we do not know whether the changes in the cross-tail current lead to a field-aligned current formation or just form a current loop in the magnetosphere, we thus use redistribution to represent these changes of local current density. We found that (1) the redistribution of the cross-tail current is a common feature preceding DFs; (2) the redistribution of cross-tail current is caused by plasma pressure gradient ahead of the DF and (3) the resultant net current redistributed by a DF is an order of magnitude smaller than the typical total current associated with a moderate substorm current wedge (SCW). Moreover, our results also suggest that the redistributed current ahead of the DF is closed by currents on the DF itself, forming a closed current loop around peaks in plasma pressure, what is traditionally referred to as a banana current.

Published
2015

43. A Comparative Study of the Proton Properties of Magnetospheric Substorms at Earth and Mercury in the Near Magnetotail

Author

Sun, W. J., Slavin, J. A., Dewey, R. M., Raines, J. M., Fu, S. Y., Wei, Y., Karlsson, Tomas, Poh, G. K., Jia, X., Gershman, D. J., Zong, Q. G., Wan, W. X., Shi, Q. Q., Pu, Z. Y., Zhao, D., Sun, W. J., Slavin, J. A., Dewey, R. M., Raines, J. M., Fu, S. Y., Wei, Y., Karlsson, Tomas, Poh, G. K., Jia, X., Gershman, D. J., Zong, Q. G., Wan, W. X., Shi, Q. Q., Pu, Z. Y., and Zhao, D.

Abstract

The variations of plasma sheet proton properties during magnetospheric substorms at Earth and Mercury are comparatively studied. This study utilizes kappa distributions to interpret proton properties at both planets. Proton number densities are found to be around an order of magnitude higher, temperatures several times smaller, and kappa values broader at Mercury than at Earth. Protons become denser and cooler during the growth phase, and are depleted and heated after the dipolarizations in both magnetospheres. The changes of kappa at Earth are generally small (<20%), indicating that spectrum-preserving processes, like adiabatic betatron acceleration, play an important role there, while variations of kappa at Mercury are large (>60%), indicating the importance of spectrum-altering processes there, such as acceleration due to nonadiabatic cross-tail particle motions and wave-particle interactions. This comparative study reveals important intrinsic properties on the energization of protons in both magnetospheres. Plain Language Summary Earth and Mercury are the only two planets possessing global intrinsic magnetic fields among the four inner planets, which are Mercury, Venus, Earth, and Mars, within the solar system. The interactions between the intrinsic magnetic fields and the continual flow of high-speed solar wind from the Sun form similar magnetospheres at the two planets, although the scale of the magnetosphere is much smaller at Mercury than at Earth. Magnetospheric substorms, a result of solar wind-magnetosphere coupling, occur in both magnetospheres. Comparative study of a similar process between different planets is meaningful as it can help us in understanding the specific process further as well as help us in understanding the intrinsic properties of the magnetospheres. This research paper characterizes the proton properties of magnetospheric substorms of both planets, revealing that different mechanisms control the behavior of protons during the mag, QC 20181012

Published
2018
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44. Recurrent Magnetic Dipolarization at Saturn: Revealed by Cassini

Author

Yao, Z. H., primary, Radioti, A., additional, Grodent, D., additional, Ray, L. C, additional, Palmaerts, B., additional, Sergis, N., additional, Dialynas, K., additional, Coates, A. J., additional, Arridge, C. S., additional, Roussos, E., additional, Badman, S. V., additional, Ye, Sheng‐Yi, additional, Gérard, J.‐C., additional, Delamere, P. A., additional, Guo, R. L., additional, Pu, Z. Y., additional, Waite, J. H., additional, Krupp, N., additional, Mitchell, D. G., additional, and Dougherty, M. K., additional

Published
2018
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45. A Comparative Study of the Proton Properties of Magnetospheric Substorms at Earth and Mercury in the Near Magnetotail

Author

Sun, W. J., primary, Slavin, J. A., additional, Dewey, R. M., additional, Raines, J. M., additional, Fu, S. Y., additional, Wei, Y., additional, Karlsson, T., additional, Poh, G. K., additional, Jia, X., additional, Gershman, D. J., additional, Zong, Q. G., additional, Wan, W. X., additional, Shi, Q. Q., additional, Pu, Z. Y., additional, and Zhao, D., additional

Published
2018
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47. Electron Dynamics in Magnetosheath Mirror‐Mode Structures

Author

Yao, S. T., primary, Shi, Q. Q., additional, Liu, J., additional, Yao, Z. H., additional, Guo, R. L., additional, Ahmadi, N., additional, Degeling, A. W., additional, Zong, Q. G., additional, Wang, X. G., additional, Tian, A. M., additional, Russell, C. T., additional, Fu, H. S., additional, Pu, Z. Y., additional, Fu, S. Y., additional, Zhang, H., additional, Sun, W. J., additional, Li, L., additional, Xiao, C. J., additional, Feng, Y. Y., additional, and Giles, B. L., additional

Published
2018
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48. MESSENGER Observations of Rapid and Impulsive Magnetic Reconnection in Mercury's Magnetotail

Author

Zhong, J., primary, Wei, Y., additional, Pu, Z. Y., additional, Wang, X. G., additional, Wan, W. X., additional, Slavin, J. A., additional, Cao, X., additional, Raines, J. M., additional, Zhang, H., additional, Xiao, C. J., additional, Du, A. M., additional, Wang, R. S., additional, Dewey, R. M., additional, Chai, L. H., additional, Rong, Z. J., additional, and Li, Y., additional

Published
2018
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49. Magnetospheric Multiscale Observations of Electron Scale Magnetic Peak

Author

Yao, S. T., primary, Shi, Q. Q., additional, Guo, R. L., additional, Yao, Z. H., additional, Tian, A. M., additional, Degeling, A. W., additional, Sun, W. J., additional, Liu, J., additional, Wang, X. G., additional, Zong, Q. G., additional, Zhang, H., additional, Pu, Z. Y., additional, Wang, L. H., additional, Fu, S. Y., additional, Xiao, C. J., additional, Russell, C. T., additional, Giles, B. L., additional, Feng, Y. Y., additional, Xiao, T., additional, Bai, S. C., additional, Shen, X. C., additional, Zhao, L. L., additional, and Liu, H., additional

Published
2018
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