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ISSN  2096-3955

CN  10-1502/P

Citation: Li, Y., Sheng Z., and Jing, J. R. (2019). Feature analysis of stratospheric wind and temperature fields over the Antigua site by rocket data. Earth Planet. Phys., 3(5), 414–424.doi: 10.26464/epp2019040

2019, 3(5): 414-424. doi: 10.26464/epp2019040


Feature analysis of stratospheric wind and temperature fields over the Antigua site by rocket data


College of Meteorology and Oceanography, National University of Defense Technology, Nanjing 211100, China


Collaborative Innovation Center on Forecast and Evaluation of Meteorological Disasters, Nanjing University of Information Science and Technology, Nanjing 211100, China

Corresponding author: Zheng Sheng,

Received Date: 2019-04-01
Web Publishing Date: 2019-09-01

The wind and temperature fields at 20 to 55 km above the Antigua launch site (17°N, 61°W) were analyzed by using sounding rocket data published by the research organization on Stratosphere-Troposphere Processes and their Role in Climate (SPARC). The results showed distinct variations in the wind and temperature fields at different heights from the 1960s to the 1990s. The overall zonal wind speed showed a significant increasing trend with the year, and the overall change in meridional wind speed showed a falling trend from 1976 to 1990, whereas the temperature field showed a significant cooling trend from 1964 to 1990. The times the trends mutated varied at different levels. By taking the altitudes at 20, 35, and 50 km as representatives, we found that the zonal wind speed trend had mutated in 1988, 1986, and 1986, respectively; that the meridional wind speed trend had mutated in 1990, 1986, and 1990, respectively; and that the temperature trend had mutated separately in 1977, 1973, and 1967, respectively. Characteristics of the periodic wind and temperature field variations at different heights were also analyzed, and obvious differences were found in time scale variations across the different layers. The zonal and meridional wind fields were basically characterized as having a significant periodic variation of 5 years across the three layers, and each level was characterized as having a periodic variation of less than 5 years. Temperature field variation at the three levels was basically characterized as occurring in 10-year and 5-year cycles.

Key words: wind field change, temperature change, empirical orthogonal function (EOF), wavelet analysis

Brasseur, G., Hitchman, M. H., Simon, P. C., and De Rudder, A. (1988). Ozone reduction in the 1980's: a model simulation of anthropogenic and solar perturbations. Geophys. Res. Lett., 15(12), 1361–1364.

Brühl, C., and Crutzen, P. J. (1988). Scenarios of possible changes in atmospheric temperatures and ozone concentrations due to man′s activities, estimated with a one-dimensional coupled photochemical climate model. Climate Dyn., 2(3), 173–203.

Chang, Q. H., Yang, G. T., Song, J., and Gong, S. S. (2006). The stability of the middle atmosphere (30–60 km) over Wuhan by Rayleigh lidar. Chin. Sci. Bull., 51(21), 2657–2661.

Chen, B. Q., Liu, Y., Liu, L. K., Shen, X. Y., and Zhang, Y. L. (2018). Characteristics of spatial-temporal distribution of the stratospheric quasi-zero wind layer in low-latitude regions. Climatic Environ. Res., 23(6), 657–669.

Frierson, D. M. W. (2006). Robust increases in midlatitude static stability in simulations of global warming. Geophys. Res. Lett., 33(24), L24816.

Frierson, D. M. W., and Davis, N. A. (2011). The seasonal cycle of midlatitude static stability over land and ocean in global reanalyses. Geophys. Res. Lett., 38(13), L13803.

Han, P. C., and Jian, M. Q. (2016). Interdecadal variability of quasi-biennial oscillation of stratospheric zonal wind. J. Trop. Meteor., 32(4), 458–466.

Held, I. M., and O'Brien, E. (1992). Quasigeostrophic turbulence in a three-layer model: effects of vertical structure in the mean shear. J. Atmos. Sci., 49(19), 1861–1870.;2

Huang, R. H., Chen, W., Wei, K., Wang, L., and Huangpu, J. L. (2018). Atmospheric dynamics in the stratosphere and its interaction with tropospheric processes: progress and problems. Chin. J. Atmos. Sci., 42(3), 463–487.

Juckes, M. N. (2000). The static stability of the midlatitude troposphere: the relevance of moisture. J. Atmos. Sci., 57(18), 3050–3057.<3050:TSSOTM>2.0.CO;2

Liu, J., Chen, J. Y., Wu, S. J., and Luo, C. (2017). Research on the characteristics and laws of wind field environmental changes in the stratosphere in Xinjiang. In The Fourth China High Resolution Earth Observation Conference — CHREOC. Wuhan.222

Liu, M. Z., Ma, M., and Liu, X. (2016). Rocket sounding observations of stratospheric winds in Kwajalein Island (8°N, 167°E) and their comparisons with HWM07 and CIRA86. J. Henan Normal Univ. (Nat. Sci. Ed.) , 44(6), 1–8.

Ramaswamy, V., Chanin, M. L., Angell, J., Barnett, J., Gaffen, D., Gelman, M., Keckhut, P., Koshelkov, Y., Labitzke K., … Swinbank, R. (2001). Stratospheric temperature trends: observations and model simulations. Rev. Geophys., 39(1), 71–122.

Santer, B. D., Taylor, K. E., Wigley, T. M. L., Johns, T. C., Jones, P. D., Karoly, D. J., Mitchell, J. F. B., Oort, A. H., Penner, J. E., … Tett, S. (1996). A search for human influences on the thermal structure of the atmosphere. Nature, 382(6586), 39–46.

Trenberth, K. E., and Stepaniak, D. P. (2003). Seamless poleward atmospheric energy transports and implications for the Hadley circulation. J. Climate, 16(22), 3706–3722.<3706:spaeta>;2

Wang, L. J., Chen, Z. Y., Ling, C., and Lü, R. D. (2015). Decreasing trend of the middle atmospheric static stability in historical data from rocketsonde network. Acta Phys. Sin., 64(16), 169201.

Wei, F. Y. (1999). Modern Climate Statistical Diagnosis and Prediction Technology (in Chinese). Beijing: Meteorological Press.222

Wu, Y. F. (1994). Observations of small scale wind shears in the mesosphere. Chin. J. Space Sci., 14(2), 151–156.

Xiao, W. H., Fu, Y., Du, X. Y., and Gao, T. C. (2012). Analysis of deriving stratospheric atmospheric winds from COSMIC radio occultation data. Geomatics Inf. Sci. Wuhan Univ., 37(2), 199–204.

Xiao, Y. S. (1984). The effects of vertical stratification of temperature and of vertical wind shear on the development of synoptic systems. Acta Meteor. Sin., 42(3), 279–289.

Xu, B. Q., Wu, T. T., and Li, W. H. (2014). Screening of calculation methods for wind shear exponent. Trans. Chin. Soc. Agric. Eng., 30(16), 188–194.

Xu, J., and Powell, A. M. (2010). Inter-comparison of temperature variability from multiple radiosondes, reanalyses products and CMIP5/IPCC climate model simulation. In Fall Meeting 2010. Washington: American Geophysical Union.222

Zhang, M., Xu, X. F., Min, J. Z., and Gao, Q. J. (2015). Advances in low frequency modes studies in middle-high latitude. J. Meteor. Sci., 35(6), 799–806.


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Feature analysis of stratospheric wind and temperature fields over the Antigua site by rocket data

Yang Li, Zheng Sheng, JinRui Jing