Abstract
AbstractGlobal mean temperature may increase up to 6°C by the end of this century and together with precipitation change may steepen regional aridity gradients. The hydrology, productivity, and ecosystem services from freshwater wetlands depend on their future water balance. We simulated the hydrology and vegetation dynamics of wetland complexes in the North American Prairie Pothole Region with the WETLANDSCAPE model. Simulations for 63 precipitation × temperature combinations spanning 6°C warming and −20% to +20% annual precipitation change at 19 locations along a mid‐continental aridity gradient showed that aridity explained up to 99% of the variation in wetland stage and hydroperiod for all wetland permanence types, and in vegetation cycling for semipermanent wetlands. The magnitude and direction of hydrologic responses depended on whether climate changes increased or decreased water deficits. Warming to 6°C and 20% less precipitation increased wetland water deficits and more strongly decreased wetland stage and hydroperiod from historic levels at low aridity, especially in semipermanent wetlands, where peak vegetation cycling (Cover Cycle Index, CCI) also shifted to lower aridity. In contrast, 20% more precipitation decreased water deficits, increasing wetland stage and hydroperiod most strongly in shallow wetlands at high aridity, but filling semipermanent wetlands and reducing CCI at low aridity. All climate changes narrowed the range of aridity favorable to high productivity. Climate changes that reduce water deficits may help maintain wetlands at high aridity at the expense of those at low aridity, but with warming certain, increased deficits are more likely and will help maintain wetlands at lower aridity but exacerbate loss of wetlands at high aridity. Thus, there is likely not a universally applicable approach to mitigating climate change impacts on freshwater wetlands across regional aridity gradients. Conservation strategies need to account for aridity‐specific effects of climate change on freshwater wetland ecosystems.
Highlights
Continuing accumulation of CO2 and other greenhouse gases in the atmosphere is predicted to increase global mean temperature up to 6°C by the end of this century (IPCC 2013)
We focused on warming and precipitation sensitivities at the extremes of precipitation change (−20% and +20% precipitation) and precipitation sensitivity at maximum warming (6°C) to reveal potential boundary conditions on wetland hydrology and function under increased and decreased water deficits
They show that changes in the warming and precipitation sensitivity of wetland stage and hydroperiod along the Prairie Pothole Region (PPR) aridity gradient increased where climate changes increased the depth of historically dry wetlands or decreased the depth of historically deep wetlands
Summary
Continuing accumulation of CO2 and other greenhouse gases in the atmosphere is predicted to increase global mean temperature up to 6°C by the end of this century (IPCC 2013). Future precipitation change is less certain, but contrasts in mean annual precipitation between wet and dry regions may increase, which may steepen regional gradients in precipitation, temperature and evaporative demand, and aridity (Bonan 2002, IPCC 2013). A steeper aridity gradient will increase differences across regions in ecosystem water balances and their responses to warming v www.esajournals.org. Increased responses to warming or precipitation change may push ecosystem water balance past functional and structural thresholds, at the extremes of regional aridity gradients. Future regional biodiversity and ecosystem goods and services provision from wetlands hinge on the effects of future warming and precipitation change on their water balance and its variation along regional aridity gradients (Johnson et al 2010)
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