Statistical prediction of non‐Gaussian climate extremes in urban areas based on the first‐order difference method

Qian, Cheng; Zhou, Wen; Yang, Xiu‐Qun; Chan, Johnny C. L.

doi:10.1002/joc.5464

Cited by 8 publications

(5 citation statements)

References 41 publications

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“…With serial persistence ~2 years, thus an absolute correlation >0.35 is needed to achieve statistical significance above 90% confidence. Temporal trends were calculated by linear regression and assessed for variance with the seasonal cycle removed, following standard methods (Sneyers, 1990; Qian et al ., 2018).…”

Section: Methodsmentioning

confidence: 99%

Climate‐sensitivity of sugarcane yield in the southeastern Africa lowlands

Mbhamali

Jury

2021

Intl Journal of Climatology

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We have analysed the relationships between local and regional climate and sugarcane yield over the southeastern Africa lowlands (31°–23.5°S, 28.5°–32.5°E) for the period 1970–2017. The temporal associations for preceding December–May rainfall and temperature, and indices of the Pacific El Niño Southern Oscillation and Indian Ocean Dipole, demonstrate the climate‐sensitivity of sugarcane yield and its proxy: the Palmer Drought Severity Index (PDSI). The composite differences revealed how the atmospheric circulation over the Mozambique Channel shifts the moisture gradient over southeastern Africa. Predictors of sugarcane yield were identified in point‐to‐field maps of global sea surface temperature, sea level air pressure, and upper winds with respect to the PDSI. It was found that four climate predictors account for half of the PDSI variance at 1 year lead time. We also investigated the long‐term change using coupled model simulations. These exhibit weak drying trends but large year‐to‐year swings in soil moisture. Our research offers a basis for mitigating climate variability for the benefit of the sugar industry in southeastern Africa, through statistical forecasts that inform crop management.

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Section: Methodsmentioning

confidence: 99%

Climate‐sensitivity of sugarcane yield in the southeastern Africa lowlands

Mbhamali

Jury

2021

Intl Journal of Climatology

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“…The operational forecast skill of the summer precipitation over the MLYRV has been significantly enhanced by the year‐to‐year increment method, which is based on the quasi‐biennial oscillation of climate variables (Fan et al ., ). So far, this method has been proven to be effective in other aspects of extreme climate prediction, such as wintertime heavy snow, typhoon frequency over the western North Pacific, the number of landfalling tropical cyclones, the Atlantic storm frequency, and heat extremes (Fan, ; Fan and Wang, ; Fan, ; Fan and Tian, ; Qian et al ., ; Qian et al ., ). Comprehensive studies of quasi‐periodicities in the 2–3‐ and 3–4‐ year range of precipitation patterns or EPF in the Yangtze River have been conducted (Becker et al ., ; Hartmann et al ., ).…”

Section: Introductionmentioning

confidence: 97%

Climate prediction of summer extreme precipitation frequency in the Yangtze River valley based on sea surface temperature in the southern Indian Ocean and ice concentration in the Beaufort Sea

Tian

Fan

2019

Intl Journal of Climatology

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Three statistical prediction models for the summer extreme precipitation frequency (EPF) in the middle and lower reaches of the Yangtze River valley (MLYRV) based on the winter sea surface temperature in the southern Indian Ocean (SIO‐SST; Scheme‐SST), the spring sea‐ice concentration in the Beaufort Sea (Scheme‐SIC), and both predictors (Scheme‐SS), are established by using the year‐to‐year increment method. The winter SIO‐SST may affect the SST anomaly in the east of Australia via a teleconnection pattern. The east of Australia SST signal in winter continues until the following summer and then affects the summer EPF in the MLYRV via modulation of the meridional Hadley circulation in the western North Pacific. The positive Beaufort SIC anomaly may result in a negative summer SST anomaly by the increased surface albedo. In response, the atmospheric circulation presents a dipole anomaly distribution in the Beaufort Sea and the Barents Sea. The Arctic dipole anomaly may bring about frequent extreme precipitation in the MLYRV by adjusting the position of the East Asian westerly jet and Eurasian teleconnection pattern. The prediction skill of the summer EPF for Scheme‐SS is higher than that of Scheme‐SST and Scheme‐SIC in the cross‐validation test during 1962–2017 and the independent hindcast during 1992–2017. Scheme‐SS shows a higher prediction skill of the summer EPF than that of Scheme‐SST and Scheme‐SIC, with a time correlation coefficient of 0.62, accounting for 39% of the total variance, of which 35% is the winter SIO‐SST and 4% the spring Beaufort SIC. Scheme‐SS not only shows a rather high predictive ability for the anomalous summer EPF but can also reproduce the increasing trend of extremely heavy precipitation.

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“…In eastern and southern China, the EHEs are afected by the western Pacifc subtropical high (WPSH) anomaly [19,20]. Te atmospheric circulation anomalies that contribute to the EHEs in China are related to several elements, including the tropical Pacifc sea surface temperature (SST) [18,21], El Niño-southern oscillation [22,23], Pacifc El Niño-like pattern [24], Atlantic SST [25], tropical Indian Ocean SST [26], and sea ice [27,28]. SST anomalies in the tropical Indian Ocean enhance latent heat to excite the Rossby wave train, resulting in the anomalies of the South Asian high and WPSH, and thus afecting the summer EHEs in eastern China [23].…”

Section: Introductionmentioning

confidence: 99%

Interdecadal Variation of Spring Extreme High-Temperature Events in the Western Tianshan Mountains and Its Relationship with the Tropical SST

Ma,

Chen,

Yao

et al. 2023

Advances in Meteorology

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This study performed an observational analysis to examine the interdecadal variation in the frequency of extreme high-temperature events (EHEs) during spring over the western Tianshan mountain, China, which were characterized by relatively fewer (more) EHEs during 1983–1996 (2000–2015). A composite analysis indicated that the interdecadal increase in EHEs is closely related to a deep dynamic anomalous Iranian high. Under the control of this high system, the water vapor content decreased over the western Tianshan mountains, and atmospheric circulation was dominated by a descending motion. Both were attributed to the decreased cloud cover, inducing a cloud-forced net solar radiation increase. The short-wave radiation flux and sensible heat flux reaching the surface increased, and the net surface heat flux increased cumulatively, which was conducive to the surface temperature increase and EHE occurrence. The anomalous Iranian high responsible for ECEs occurrence was related to the air-sea interaction over the Atlantic and Indo-Pacific. The latitudinal sea surface temperature (SST) difference between the tropical western Pacific and the western Indian Ocean directly strengthens the Walker circulation and thus enhances the Iranian high. In addition, the anomalous Iranian high was affected by the atmospheric wave trains at middle latitude, which was triggered by the warm anomaly of the Atlantic SST.

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Statistical prediction of non‐Gaussian climate extremes in urban areas based on the first‐order difference method

Cited by 8 publications

References 41 publications

Climate‐sensitivity of sugarcane yield in the southeastern Africa lowlands

Climate‐sensitivity of sugarcane yield in the southeastern Africa lowlands

Climate prediction of summer extreme precipitation frequency in the Yangtze River valley based on sea surface temperature in the southern Indian Ocean and ice concentration in the Beaufort Sea

Interdecadal Variation of Spring Extreme High-Temperature Events in the Western Tianshan Mountains and Its Relationship with the Tropical SST

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