Spatial and Temporal Variations of Blocking and Cyclogenesis in the 1978 / 79 Winter

Hengyi Weng

doi:10.1007/BF02677074

Impact Factor: 5.8

Volume 9 Issue 4

Oct. 1992

Article Contents

Article > ADVANCES IN ATMOSPHERIC SCIENCES > 1992 > 9(4): 411-430

Spatial and Temporal Variations of Blocking and Cyclogenesis in the 1978 / 79 Winter

Hengyi Weng

1.
Geophysical Fluid Dynamics Institute, Florida State University, Tallahassee, FL 32306, USA

Hengyi Weng

doi: 10.1007/BF02677074

Abstract
References
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Abstract:
Complex empirical orthogonal function (CEOF) and Fourier analyses are applied to 500 hPa geopotential height anomaly for two selected latitude belts in the Northern Hemisphere from Dec 1978 through Feb 1979 based on the ECMWF FGGE III-b data. The positive anomalies in the three leading CEOFs for the high-latitude belt mainly show the preferred locations for blocking activity in the North Atlantic, the North Pacific and to the west of the Ural Mountains. The negative anomalies in the three leading CEOFs for the mid-latitude belt mainly show the preferred locations for cyclogenesis in the east coasts of Asia and North America, and the Mediterranean; weak cyclogenesis is also seen in the western United States and off the coasts of Spain and Morocco. The travelling components of the pos-itive anomalies in the high-latitude belt mainly propagate westward, weakening as approaching the east side of some mountain chains while intensifying to the west side. On the contrary, the travelling components of the negative anom-alies in the mid-latitude belt mainly propagate eastward, intensifying over the lee side of mountain and / or ap-proaching the east coasts of the two continents. These preferred locations for blocking and cyclogenesis are basically consistent with the climacological results, and related to some teleconnection patterns found earlier.The temporal variation of blocking highs seems to relate with the vacillation of the potential vorticity (PV) index defined by Weng (1992). There are two build-up stages of the PV index during the winter. Each build-up stage corre?sponds to a westward propagation of a large-scale positive anomaly in the high-latitude belt, resulting in the occur?rence of a series of blocking highs over the western Eurasia, Scandinavia, Greenland and the Pacific. In general, the temporal variation of cyclogenesis is less reflected by the PV index than blocking highs. The duration of a PV index cycle of build-up and break-down is about 30-50 days. Within this low-frequency envelope, there is a global quasi-two-week vacillation of the PV index, reflecting one of the preferred time scales of mid-latitude cyclone and anticyclone activity in some preferred locations during the 1978 / 79 winter.
References

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Manuscript History

Manuscript received: 10 October 1992

Manuscript revised: 10 October 1992

通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

Spatial and Temporal Variations of Blocking and Cyclogenesis in the 1978 / 79 Winter

Hengyi Weng

1. Geophysical Fluid Dynamics Institute, Florida State University, Tallahassee, FL 32306, USA

Manuscript received: 1992-10-10
Manuscript revised: 1992-10-10

Abstract: Complex empirical orthogonal function (CEOF) and Fourier analyses are applied to 500 hPa geopotential height anomaly for two selected latitude belts in the Northern Hemisphere from Dec 1978 through Feb 1979 based on the ECMWF FGGE III-b data. The positive anomalies in the three leading CEOFs for the high-latitude belt mainly show the preferred locations for blocking activity in the North Atlantic, the North Pacific and to the west of the Ural Mountains. The negative anomalies in the three leading CEOFs for the mid-latitude belt mainly show the preferred locations for cyclogenesis in the east coasts of Asia and North America, and the Mediterranean; weak cyclogenesis is also seen in the western United States and off the coasts of Spain and Morocco. The travelling components of the pos-itive anomalies in the high-latitude belt mainly propagate westward, weakening as approaching the east side of some mountain chains while intensifying to the west side. On the contrary, the travelling components of the negative anom-alies in the mid-latitude belt mainly propagate eastward, intensifying over the lee side of mountain and / or ap-proaching the east coasts of the two continents. These preferred locations for blocking and cyclogenesis are basically consistent with the climacological results, and related to some teleconnection patterns found earlier.The temporal variation of blocking highs seems to relate with the vacillation of the potential vorticity (PV) index defined by Weng (1992). There are two build-up stages of the PV index during the winter. Each build-up stage corre?sponds to a westward propagation of a large-scale positive anomaly in the high-latitude belt, resulting in the occur?rence of a series of blocking highs over the western Eurasia, Scandinavia, Greenland and the Pacific. In general, the temporal variation of cyclogenesis is less reflected by the PV index than blocking highs. The duration of a PV index cycle of build-up and break-down is about 30-50 days. Within this low-frequency envelope, there is a global quasi-two-week vacillation of the PV index, reflecting one of the preferred time scales of mid-latitude cyclone and anticyclone activity in some preferred locations during the 1978 / 79 winter.