Atmospheric Rivers, Floods and the Water Resources of California

Dettinger, Michael D.; Ralph, F. Martin; Das, Tapash; Neiman, Paul J.; Cayan, Daniel R.

doi:10.3390/w3020445

Cited by 739 publications

(820 citation statements)

References 26 publications

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“…Our model applies a warm-rain microphysical parameterization to dynamical fields derived from linear mountain wave theory (see Appendix A for details). Simulations are performed at sea level temperatures of 13 • C and 15 • C, with the former representing a typical AR in today's climate and the latter representing estimated warming by the end of the century [Dettinger, 2011]. Within ascending regions upstream of the ridge, the troposphere is assumed to be saturated and moist adiabatic, with a sea level pressure of 1000 hPa in both simulations.…”

Section: Model Description and Resultsmentioning

confidence: 99%

“…These conditions, while not representative of orographic storms in general, are a reasonable approximation of "atmospheric rivers" (ARs) [e.g., Ralph et al, 2005], which are long bands of moist, tropical air flowing poleward and eastward within the warm sectors of midlatitude cyclones [Newell et al, 1992]. ARs are responsible for up to half the total annual precipitation-and virtually all major floods-in midlatitude coastal ranges like the Cascades and the Sierra Nevada and are therefore a natural starting point for understanding the overall impact of climate change on midlatitude orographic precipitation [Guan et al, 2010;Neiman et al, 2011;Dettinger et al, 2011].…”

Section: Introductionmentioning

confidence: 99%

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How will orographic precipitation respond to surface warming? An idealized thermodynamic perspective

Siler

Roe

2014

Geophys. Res. Lett.

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Future changes in orographic precipitation will have important consequences for societies and ecosystems near mountain ranges. Here we use a simple numerical model to evaluate the response of orographic precipitation to surface warming under idealized conditions representative of the strongest orographic storms. We find an upward shift in the pattern of condensation with warming, caused by larger fractional changes in condensation at low temperature and amplified warming aloft. As a result, the distribution of precipitation shifts downwind, causing larger fractional changes in precipitation on the lee slope than on the windward slope. Total precipitation is found to increase by a smaller fraction than near‐surface water vapor, in contrast to expected changes in other types of extreme precipitation. Factors limiting the increase in orographic precipitation include the pattern of windward ascent, leeside evaporation, and thermodynamic constraints on the change in condensation with temperature.

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Section: Model Description and Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

How will orographic precipitation respond to surface warming? An idealized thermodynamic perspective

Siler

Roe

2014

Geophys. Res. Lett.

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“…[21] Furthermore, regions 1, 2, and 7 in the North Pacific Ocean and North Atlantic Ocean (Figure 2) are more important for continental precipitation in October-March, when strong advection over the relatively warm oceans brings large quantities of water to the colder continents, which is largely contributed to the existence of atmospheric rivers [see, e.g., Dettinger et al, 2011]. During AprilSeptember these oceanic source areas are weaker, and continental moisture recycling becomes important [see also, e.g., Bisselink and Dolman, 2008;Dominguez et al, 2009;van der Ent et al, 2010].…”

Section: Seasonal Variationsmentioning

confidence: 99%

Oceanic sources of continental precipitation and the correlation with sea surface temperature

Ent

Savenije

2013

Water Resources Research

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[1] Identifying the sources of continental precipitation has received increasing attention in recent years. With the use of various numerical methods, sources of precipitation have been identified from local to global scales. In this paper we identify the oceanic sources based on an atmospheric backtracking analysis of continental precipitation. We find that the strongest source areas are located close to the continents. In general, we define an oceanic area as a significant source when on average more than 20% of the total evaporation, and at least 250 mm/yr of evaporation ends up as continental precipitation. We grouped these identified source areas into 15 regions and performed a forward tracking analysis of oceanic evaporation. We identified the areas on the adjacent continents that receive this oceanic moisture and whether this is nearby or remote. Moreover, we showed how the oceanic sources vary over the year in time and space. Furthermore, we correlated sea surface temperatures (SSTs) in the 15 source regions and the Niño 3.4 region with precipitation on all continents. For South America, we found that the El Niño Southern Oscillation (altering wind patterns) has a larger effect on precipitation than local SSTs. For West Africa, however, we show that SST in the source regions is strongly correlated with precipitation in the rainy season. In Australia, both local SST and the Niño 3.4 region appear to have a big influence on precipitation. As such this research provides new insight in the oceanatmosphere-land coupling, which can be useful for studying seasonal weather predictions as well as climate change impact.Citation: van der Ent, R. J., and H. H. G. Savenije (2013), Oceanic sources of continental precipitation and the correlation with sea surface temperature, Water Resour. Res., 49,[3993][3994][3995][3996][3997][3998][3999][4000][4001][4002][4003][4004]

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“…Broadly speaking, changes in streamflow directly impact water resources and also have a variety of indirect impacts on riverine ecosystem services, such as recreation and fish habitat. In basins that experience large interannual variations in hydroclimatic drivers, year-to-year variability in streamflow can be pronounced (e.g., [14]). Such variability complicates the precise management of water resources, particularly in basins where demands on water resources are increasing [67].…”

Section: Introductionmentioning

confidence: 99%

Seasonal flows of international British Columbia-Alaska rivers: The nonlinear influence of ocean-atmosphere circulation patterns

Fleming

Hood

Dahlke

et al. 2016

Advances in Water Resources

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a b s t r a c tThe northern portion of the Pacific coastal temperate rainforest (PCTR) is one of the least anthropogenically modified regions on earth and remains in many respects a frontier area to science. Rivers crossing the northern PCTR, which is also an international boundary region between British Columbia, Canada and Alaska, USA, deliver large freshwater and biogeochemical fluxes to the Gulf of Alaska and establish linkages between coastal and continental ecosystems. We evaluate interannual flow variability in three transboundary PCTR watersheds in response to El Niño-Southern Oscillation (ENSO), Pacific Decadal Oscillation (PDO), Arctic Oscillation (AO), and North Pacific Gyre Oscillation (NPGO). Historical hydroclimatic datasets from both Canada and the USA are analyzed using an up-to-date methodological suite accommodating both seasonally transient and highly nonlinear teleconnections. We find that streamflow teleconnections occur over particular seasonal windows reflecting the intersection of specific atmospheric and terrestrial hydrologic processes. The strongest signal is a snowmelt-driven flow timing shift resulting from ENSO-and PDO-associated temperature anomalies. Autumn rainfall runoff is also modulated by these climate modes, and a glacier-mediated teleconnection contributes to a late-summer ENSO-flow association. Teleconnections between AO and freshet flows reflect corresponding temperature and precipitation anomalies. A coherent NPGO signal is not clearly evident in streamflow. Linear and monotonically nonlinear teleconnections were widely identified, with less evidence for the parabolic effects that can play an important role elsewhere. The streamflow teleconnections did not vary greatly between hydrometric stations, presumably reflecting broad similarities in watershed characteristics. These results establish a regional foundation for both transboundary water management and studies of long-term hydroclimatic and environmental change.Published by Elsevier Ltd.

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Atmospheric Rivers, Floods and the Water Resources of California

Cited by 739 publications

References 26 publications

How will orographic precipitation respond to surface warming? An idealized thermodynamic perspective

How will orographic precipitation respond to surface warming? An idealized thermodynamic perspective

Oceanic sources of continental precipitation and the correlation with sea surface temperature

Seasonal flows of international British Columbia-Alaska rivers: The nonlinear influence of ocean-atmosphere circulation patterns

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