Your search keyword '"Mudryk, Lawrence"' showing total 3 results

1. Quantifying the Uncertainty in Historical and Future Simulations of Northern Hemisphere Spring Snow Cover.

Author

Thackeray, Chad W., Fletcher, Christopher G., Mudryk, Lawrence R., and Derksen, Chris

Subjects

SNOW cover, SPRING, ATMOSPHERIC models, UNCERTAINTY, METEOROLOGICAL precipitation

Abstract

Projections of twenty-first-century Northern Hemisphere (NH) spring snow cover extent (SCE) from two climate model ensembles are analyzed to characterize their uncertainty. Phase 5 of the Coupled Model Intercomparison Project (CMIP5) multimodel ensemble exhibits variability resulting from both model differences and internal climate variability, whereas spread generated from a Canadian Earth System Model-Large Ensemble (CanESM-LE) experiment is solely a result of internal variability. The analysis shows that simulated 1981-2010 spring SCE trends are slightly weaker than observed (using an ensemble of snow products). Spring SCE is projected to decrease by −3.7% ± 1.1% decade−1 within the CMIP5 ensemble over the twenty-first century. SCE loss is projected to accelerate for all spring months over the twenty-first century, with the exception of June (because most snow in this month has melted by the latter half of the twenty-first century). For 30-yr spring SCE trends over the twenty-first century, internal variability estimated from CanESM-LE is substantial, but smaller than intermodel spread from CMIP5. Additionally, internal variability in NH extratropical land warming trends can affect SCE trends in the near future ( R2 = 0.45), while variability in winter precipitation can also have a significant (but lesser) impact on SCE trends. On the other hand, a majority of the intermodel spread is driven by differences in simulated warming (dominant in March-May) and snow cover available for melt (dominant in June). The strong temperature-SCE linkage suggests that model uncertainty in projections of SCE could be potentially reduced through improved simulation of spring season warming over land. [ABSTRACT FROM AUTHOR]

Published

2016

2. Maintenance and Broadening of the Ocean's Salinity Distribution by the Water Cycle.

Author

Zika, Jan D., Skliris, Nikolaos, Nurser, A. J. George, Josey, Simon A., Mudryk, Lawrence, Laliberté, Frédéric, and Marsh, Robert

Subjects

METEOROLOGICAL precipitation, SALINITY, HYDROLOGIC cycle, EVAPORATION (Meteorology), OCEAN temperature

Abstract

The global water cycle leaves an imprint on ocean salinity through evaporation and precipitation. It has been proposed that observed changes in salinity can be used to infer changes in the water cycle. Here salinity is characterized by the distribution of water masses in salinity coordinates. Only mixing and sources and sinks of freshwater and salt can modify this distribution. Mixing acts to collapse the distribution, making saline waters fresher and fresh waters more saline. Hence, in steady state, there must be net precipitation over fresh waters and net evaporation over saline waters. A simple model is developed to describe the relationship between the breadth of the distribution, the water cycle, and mixing-the latter being characterized by an e-folding time scale. In both observations and a state-of-the-art ocean model, the water cycle maintains a salinity distribution in steady state with a mixing time scale of the order of 50 yr. The same simple model predicts the response of the salinity distribution to a change in the water cycle. This study suggests that observations of changes in ocean salinity could be used to infer changes in the hydrological cycle. [ABSTRACT FROM AUTHOR]

Published

2015

3. A statistical model for estimating monthly snow water equivalent anomalies from temperature and precipitation predictors under changing climatic conditions.

Author

Sospedra-Alfonso, Reinel, Mudryk, Lawrence, and Merryfield, William

Subjects

*CLIMATE change, *STATISTICAL models, *SNOW, *METEOROLOGICAL precipitation, *TEMPERATURE

Published

2018