High‐resolution dynamically downscaled projections of precipitation in the mid and late 21st century over North America

Wang, Jiali; Kotamarthi, V. R.

doi:10.1002/2015ef000304

Cited by 107 publications

(67 citation statements)

References 85 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Their study uses present‐day and three forecast scenarios from the Intergovernmental Panel on Climate Change, and combines them with LULC changes and downscaled data from three climate models in a way that allows intercomparisons to be made. While the individual climate models have disagreement on future rainfall seasonal patterns [e.g., Janssen et al, and Wang and Kotamarthi, ], they agree that peak runoff and minimum sediment loading will be shifted earlier in the year as compared to present‐day conditions. Further, LULC changes did not affect runoff, but the shift from forested to agricultural and urban areas will increase the sediment loading in the estuarine system.…”

Section: Integrated Models With Dynamic Results and Assessmentsmentioning

confidence: 99%

An Earth's Future Special Collection: Impacts of the coastal dynamics of sea level rise on low‐gradient coastal landscapes

et al. 2017

View full text Add to dashboard Cite

Rising sea level represents a significant threat to coastal communities and ecosystems, including altered habitats and increased vulnerability to coastal storms and recurrent inundation. This threat is exemplified in the northern Gulf of Mexico, where low topography, marshes, and a prevalence of tropical storms have resulted in extensive coastal impacts. The ability to facilitate adaptation and mitigation measures relies, in part, on the development of robust predictive capabilities that incorporate complex biological processes with physical dynamics. Initiated in 2010, the 6-year Ecological Effects of Sea Level Rise-Northern Gulf of Mexico project applied a transdisciplinary science approach to develop a suite of integrated modeling platforms informed by empirical data that are capable of evaluating a range of climate change scenarios. This special issue highlights resultant integrated models focused on tidal hydrodynamics, shoreline morphology, oyster ecology, coastal wetland vulnerability, and storm surges that demonstrate the need for dynamic models to incorporate feedbacks among physical and biological processes in assessments of sea level rise effects on coastal systems. Effects are projected to be significant, spatially variable and nonlinear relative to sea level rise rates. Scenarios of higher sea level rise rates are projected to exceed thresholds of wetland sustainability, and many regions will experience enhanced storm surges. Influenced by an extensive collaborative stakeholder engagement process, these assessments on the coastal dynamics of sea level rise provide a strong foundation for resilience measures in the northern Gulf of Mexico and a transferable approach for application to other coastal regions throughout the world.

show abstract

Section: Integrated Models With Dynamic Results and Assessmentsmentioning

confidence: 99%

An Earth's Future Special Collection: Impacts of the coastal dynamics of sea level rise on low‐gradient coastal landscapes

et al. 2017

View full text Add to dashboard Cite

show abstract

“…This dipole behavior is hypothesized to be contributory to an enhanced long-term trend toward greater aridity in SoCal (Figures 1 and S10). In projections of precipitation change in the Coupled Model Intercomparison Project Phases 3 and 5, precipitation reductions are predicted for the subtropics and increases for middle to high latitudes along the Pacific coast of North America (Chang et al, 2015;Neelin et al, 2013;Seager et al, 2013;Wang & Kotamarthi, 2015). The climatic drying might be partly attributed to the anthropogenic warming-induced increase of atmospheric evaporative demand (MacDonald et al, 2016;Naumann et al, 2018;Williams et al, 2015).…”

Section: Drought and Climate Change In Californiamentioning

confidence: 99%

Vegetation Responses to 2012–2016 Drought in Northern and Southern California

Dong

MacDonald

Willis

et al. 2019

Geophysical Research Letters

View full text Add to dashboard Cite

The prolonged 2012–2016 California drought has raised many issues including concerns over reduced vegetation health. Drought impacts are complicated by geographical differences in hydroclimatic variability due to a climatic dipole influenced by the Pacific. Analysis of MODIS‐derived Normalized Difference Vegetation Index and self‐calibrated Palmer Drought Severity Index from 2000 to 2018 reveals differences in drought and vegetation responses in Northern versus Southern California (NorCal vs SoCal, see definition in section ). The greatest declines in Normalized Difference Vegetation Index were focused in the SoCal, while NorCal appears not severely affected thus far. It appears that both the strength of drought and the sensitivity of the vegetation to drought are larger in SoCal. The exacerbated aridity in SoCal is a trend extending throughout the past and present century. The spatial differences in hydroclimatology and vegetation responses are important considerations for statewide climate change adaptation—with SoCal potentially facing greater challenges.

show abstract

“…In order to understand the uncertainties in future projections, it is important to also carefully evaluate the biases in historical periods (Bukovsky, ; Christensen et al, ; Loikith et al, ; Lorenz & Jacob, ; Wang & Kotamarthi, ; Zobel et al, ). Zobel et al () have conducted a historical evaluation of this ensemble used in this study, using several metrics to evaluate the biases present in both the climatological mean as well as the temperature extremes from 1995 to 2004.…”

Section: Introductionmentioning

confidence: 99%

High‐Resolution Dynamical Downscaling Ensemble Projections of Future Extreme Temperature Distributions for the United States

et al. 2017

Self Cite

View full text Add to dashboard Cite

The aim of this study is to examine projections of extreme temperatures over the continental United States (CONUS) for the 21st century using an ensemble of high spatial resolution dynamically downscaled model simulations with different boundary conditions. The downscaling uses the Weather Research and Forecast model at a spatial resolution of 12 km along with outputs from three different Coupled Model Intercomparison Project Phase 5 global climate models that provide boundary conditions under two different future greenhouse gas (GHG) concentration trajectories. The results from two decadal‐length time slices (2045–2054 and 2085–2094) are compared with a historical decade (1995–2004). Probability density functions of daily maximum/minimum temperatures are analyzed over seven climatologically cohesive regions of the CONUS. The impacts of different boundary conditions as well as future GHG concentrations on extreme events such as heat waves and days with temperature higher than 95°F are also investigated. The results show that the intensity of extreme warm temperature in future summer is significantly increased, while the frequency of extreme cold temperature in future winter decreases. The distribution of summer daily maximum temperature experiences a significant warm‐side shift and increased variability, while the distribution of winter daily minimum temperature is projected to have a less significant warm‐side shift with decreased variability. Using “business‐as‐usual” scenario, 5‐day heat waves are projected to occur at least 5–10 times per year in most CONUS and ≥95°F days will increase by 1–2 months by the end of the century.

show abstract

High‐resolution dynamically downscaled projections of precipitation in the mid and late 21st century over North America

Cited by 107 publications

References 85 publications

An Earth's Future Special Collection: Impacts of the coastal dynamics of sea level rise on low‐gradient coastal landscapes

An Earth's Future Special Collection: Impacts of the coastal dynamics of sea level rise on low‐gradient coastal landscapes

Vegetation Responses to 2012–2016 Drought in Northern and Southern California

High‐Resolution Dynamical Downscaling Ensemble Projections of Future Extreme Temperature Distributions for the United States

Contact Info

Product

Resources

About