A Climatology of Atmospheric Rivers in New Zealand

The occurrence of extreme precipitation events in New Zealand regularly results in devastating impacts to the local society and environment. An automated atmospheric river (AR) detection technique (ARDT) is applied to construct a climatology (1979–2019) of extreme midlatitude moisture fluxes conduci...

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Veröffentlicht in:	Journal of climate 2021-06, Vol.34 (11), p.4383-4402
Hauptverfasser:	Prince, Hamish D., Cullen, Nicolas J., Gibson, Peter B., Conway, Jono, Kingston, Daniel G.
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Atmospheric processes Automation Climate Climatology Cold season Dipoles Extreme weather High pressure Hydrology Jet stream Jet streams (meteorology) Latitude Low pressure Moisture Moisture effects Moisture flux Precipitation Pressure Pressure anomalies Rivers Sea level Seasonal variation Seasonal variations Seasonality Southern Hemisphere
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container_issue	11
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container_title	Journal of climate
container_volume	34
creator	Prince, Hamish D. Cullen, Nicolas J. Gibson, Peter B. Conway, Jono Kingston, Daniel G.
description	The occurrence of extreme precipitation events in New Zealand regularly results in devastating impacts to the local society and environment. An automated atmospheric river (AR) detection technique (ARDT) is applied to construct a climatology (1979–2019) of extreme midlatitude moisture fluxes conducive to extreme precipitation. A distinct seasonality exists in AR occurrence aligning with seasonal variations in the midlatitude jet streams. The formation of the Southern Hemisphere winter split jet enables AR occurrence to persist through all seasons in northern regions of New Zealand, while southern regions of the country exhibit a substantial (50%) reduction in AR occurrence as the polar jet shifts southward during the cold season. ARs making landfall on the western coast of New Zealand (90% of all events) are characterized by a dominant northwesterly moisture flux associated with a distinct dipole pressure anomaly, with low pressure to the southwest and high pressure to the northeast of New Zealand. Precipitation totals during AR events increase with AR rank (five-point scale) throughout the country, with the most substantial increase on the windward side of the Southern Alps (South Island). The largest events (rank 5ARs) produce 3-day precipitation totals exceeding 1000 mm. ARs account for up to 78% of total precipitation and up to 94% of extreme precipitation on the west coast of the South Island. Assessment of the multiscale atmospheric processes associated with AR events governing extreme precipitation in the Southern Alps of New Zealand should remain a priority given their hydrological significance and impact on people and infrastructure.
doi_str_mv	10.1175/jcli-d-20-0664.1
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subjects	Algorithms Atmospheric processes Automation Climate Climatology Cold season Dipoles Extreme weather High pressure Hydrology Jet stream Jet streams (meteorology) Latitude Low pressure Moisture Moisture effects Moisture flux Precipitation Pressure Pressure anomalies Rivers Sea level Seasonal variation Seasonal variations Seasonality Southern Hemisphere
title	A Climatology of Atmospheric Rivers in New Zealand
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