Climate Assessment for 1999

Bell, Gerald D.; Halpert, Michael S.; Schnell, R. C.; Higgins, R. Wayne; Lawrimore, J. H.; Kousky, Vernon E.; Tinker, Richard; Thiaw, Wasila; Chelliah, Muthuvel; Artusa, Anthony

doi:10.1175/1520-0477(2000)81[s1:caf]2.0.co;2

Cited by 380 publications

(255 citation statements)

References 38 publications

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“…We evaluate the TC intensity as another aspect of TC representation. Here, we utilize accumulated cyclone energy (ACE) (Bell et al 2000) as the measure of TC intensity, which is defined as the simple accumulation of the TC maximum wind speed squared in a 6-hour interval, which indicates the wind energy due to TCs. The ACE is measured in units of kt 2 in its original form, but we use units of m 2 s -2 .…”

Section: Representation Of Position and Intensity Of Tropical Cyclonesmentioning

confidence: 99%

The JRA-55 Reanalysis: Representation of Atmospheric Circulation and Climate Variability

Harada

Kamahori

Kobayashi

et al. 2016

Journal of the Meteorological Society of Japan

422

248

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This study investigates the quality of the Japanese 55-year Reanalysis (JRA-55), which is the second global reanalysis constructed by the Japan Meteorological Agency (JMA), by comparing it with other reanalyses and observational datasets. Improvements were found in the representation of atmospheric circulation on an isentropic surface and in the consistency of momentum budget based on the mass-weighted isentropic zonal mean method. The representation of climate variability in several regions was also examined. In the tropics, the frequencies of high spatial correlations with precipitation, which were estimated using the Tropical Rainfall Measuring Mission Multisatellite Precipitation Analysis, are clearly higher in JRA-55 than in JRA-25. The results indicate that JRA-55 generally improved the representations of phenomena on a wide range of space-time scales, such as equatorial waves, and transient eddies in the storm track regions, compared with JRA-25 during the satellite era. Moreover, JRA-55 improved the temporal consistency compared with the older reanalyses throughout the reanalysis period. In the stratosphere, we found larger discrepancies between reanalyses for the extra-tropical stratosphere during the Southern Hemisphere (SH) winter. Comparisons with radiosonde temperature revealed that JRA-55 has a smaller bias in temperature than the other reanalyses in the extra-tropical SH winter before 1979.Some issues in JRA-55 were also identified. The amplitude of equatorial waves and Madden-Julian oscillation in JRA-55 are weaker than in the other reanalyses. JRA-55 shows unrealistic strong cooling in South America and Australia, although the spatial distribution of the long-term temperature trends in JRA-55 is the closest to an observational dataset of global historical surface temperature.

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Section: Representation Of Position and Intensity Of Tropical Cyclonesmentioning

confidence: 99%

The JRA-55 Reanalysis: Representation of Atmospheric Circulation and Climate Variability

Harada

Kamahori

Kobayashi

et al. 2016

Journal of the Meteorological Society of Japan

422

248

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“…However, these impacts may be small when considering monthly mean atmospheric circulation because TCs occur infrequently and therefore their impacts are diluted over the longer time frame. To evaluate the effect of TCs in a region, we estimated the number of TCs (NTC) and the accumulated cyclone energy (ACE; Bell et al 2000;Camargo and Sobel 2005). NTC is simply formulated as follows:…”

Section: Methodsmentioning

confidence: 99%

Covariability between the Baiu Precipitation and Tropical Cyclone Activity through Large-Scale Atmospheric Circulations

Yamaura

Tomita

2012

Journal of the Meteorological Society of Japan

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Interannual variations of both the Baiu precipitation and tropical cyclone (TC) activity in the western North Pacific (WNP) are controlled by large-scale atmospheric circulations associated with the El Niño/Southern oscillation (ENSO) and the tropospheric biennial oscillation (TBO) of the Asian monsoon. This work examines covariability between the Baiu precipitation and the TC activity in the WNP through the ENSO and the TBO.In years when sea surface temperature anomalies (SSTAs) are negative in the eastern tropical Pacific with respect to the ENSO, the number of TCs increases near the Philippines in the Baiu season, June and July. On the other hand, in years of negative SSTAs in the eastern tropical Pacific related to the TBO, the strength of TCs is enhanced to the southeast of Japan. Each of these two TC activities enhances a cyclonic circulation there, which shifts the axis of monsoon southwesterlies and contributes to form the peculiar Baiu precipitation anomalies. These modifications are, however, dependent on the phase of the ENSO and the TBO. In years of positive SSTAs in the eastern tropical Pacific, the anomalous TC activity is small and sometimes has opposing effects on the atmospheric circulations of the ENSO and TBO. Thus, the covariability is strong between the Baiu precipitation and TC activity in the WNP in the specific phase of the ENSO and the TBO, although both covary in large-scale atmospheric circulations.region. To manage water resources and mitigate the impacts of natural disasters associated with the Baiu precipitation, countries in EA need to improve their prediction scheme for the Baiu frontal activity more comprehensively. Many studies have examined the physical mechanisms of the interannual variability in the Baiu frontal activity (e.g., Tanaka 1997;Kawamura and Murakami 1998;Chang et al. 2000aChang et al. , 2000bTomita et al. 2004;Yamaura and Tomita 2011).Several studies have investigated correlation between the Baiu precipitation and El Niño/Southern oscillation (ENSO; Rasmusson and Carpenter 1982), which is established while the ENSO, with its periodicity of 3 to 4 years, affects the global climate. TanakaCorresponding author and present affiliation: Tsuyoshi Yamaura, RIKEN Advanced Institute for Computational Science, 7-1-26, Minatojima-minami-machi, Chuo-ku,

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“…The size of the deviational ellipse depends not only on track length, but also on the turning of the cyclone path. each The total accumulated cyclone energy (ACE) is a wind energy index used by the National Oceanic and Atmospheric Administration (NOAA), which is defined as the sum of the squares of the maximum sustained surface wind estimates at 6-h intervals [65]. This is a widely-used index for cyclone intensity analysis.…”

Section: Cyclone Intensity Track Length Rotation and Lifespanmentioning

confidence: 99%

Clustering Indian Ocean Tropical Cyclone Tracks by the Standard Deviational Ellipse

Rahman

Yang

2018

Climate

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Abstract:The standard deviational ellipse is useful to analyze the shape and the length of a tropical cyclone (TC) track. Cyclone intensity at each six-hour position is used as the weight at that location. Only named cyclones in the Indian Ocean since 1981 are considered for this study. The K-means clustering algorithm is used to cluster Indian Ocean cyclones based on the five parameters: x-y coordinates of the mean center, variances along zonal and meridional directions, and covariance between zonal and meridional locations of the cyclone track. Four clusters are identified across the Indian Ocean; among them, only one cluster is in the North Indian Ocean (NIO) and the rest of them are in the South Indian Ocean (SIO). Other characteristics associated with each cluster, such as wind speed, lifespan, track length, track orientation, seasonality, landfall, category during landfall, total accumulated cyclone energy (ACE), and cyclone trend, are analyzed and discussed. Cyclone frequency and energy of Cluster 4 (in the NIO) have been following a linear increasing trend. Cluster 4 also has a higher number of landfall cyclones compared to other clusters. Cluster 2, located in the middle of the SIO, is characterized by the long track, high intensity, long lifespan, and high accumulated energy. Sea surface temperature (SST) and outgoing longwave radiation (OLR) associated with genesis of TCs are also examined in each cluster. Cyclone genesis is co-located with the negative OLR anomaly and the positive SST anomaly. Localized SST anomalies are associated with clusters in the SIO; however, TC geneses of Cluster 4 are associated with SSTA all over the Indian Ocean (IO).

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Climate Assessment for 1999

Cited by 380 publications

References 38 publications

The JRA-55 Reanalysis: Representation of Atmospheric Circulation and Climate Variability

The JRA-55 Reanalysis: Representation of Atmospheric Circulation and Climate Variability

Covariability between the Baiu Precipitation and Tropical Cyclone Activity through Large-Scale Atmospheric Circulations

Clustering Indian Ocean Tropical Cyclone Tracks by the Standard Deviational Ellipse

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