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At a global scale, the scientific consensus is that fire risk will increase by 10 to 30 percent due to higher summer temperatures and occasional increased periods of droughts. Projections for the central United States show low agreement among climate models on changes in fire probability in the near term, but the majority of models project an increase in wildfire probability by the end of the century . Fire seasons in the southeastern United States could nearly double in length and increase in severity.

Evidence at both global and local scales indicates that growing seasons have been getting longer, and this trend is projected to become even more pronounced over the next century. As seasons shift so that spring arrives earlier and fall extends later into the year, phenology may shift for plant species that rely on temperature as a cue for the timing of leaf-out, reproductive maturation, and other developmental processes. Longer growing seasons could also result in greater growth and productivity of trees and other vegetation, but only if balanced by available water and nutrients.

The Central Hardwoods Region is already experiencing a decline in snowfall, depth, and cover. Decreased snowfall and increased snowmelt from higher temperatures are projected to decrease the amount of snow on the ground in the region, and may make some locations snow-free in some years. In recent years, this reduction in snow cover has led to an increase in soil frost from decreased snow insulation.

Hydrologic modeling based on a range of climate models and scenarios suggests an increase in soil moisture, runoff, and streamflow thoughout the next century. The magnitude or frequency of flooding could potentially increase in the winter and spring due to increases in total runoff and peak streamflow during those time periods.

The vast majority of model projections for the Central Hardwoods Region are in agreement that there will be an increase in precipitation in winter and spring.

All global climate models project that temperatures will increase with continued increases in atmospheric greenhouse gas concentrations.

Impact models agree that many temperate species will experience increasing suitable habitat and biomass across the assessment area, and that longer growing seasons and warmer temperatures will lead to productivity increases for temperate forest types. The list of species projected to increase includes American basswood, black cherry, white oak, and a variety of minor southern species. Models also indicate that deciduous forest types have the potential for large productivity increases across northern Michigan.

mpact models agree that boreal or northern species will experience reduced suitable habitat and biomass across the assessment area, and that they may be less able to take advantage of longer growing seasons and warmer temperatures than temperate forest communities. Across northern latitudes, it is generally expected that warmer temperatures will be more favorable to species that are located at the northern extent of their range and less favorable to those at the southern extent.

Evidence indicates that an increase in temperature and greater moisture stress will lead to increases in these kinds of stressors, but research to date has examined only a few species. Invasive species are already a persistent and growing challenge across much of the United States. Changes may exacerbate this problem, as warmer temperatures may allow some invasive plant species, insect pests, and pathogens to expand their ranges farther north. Northern Michigan may lose some of the protection offered by a traditionally cold climate and short growing season.

Evidence at both global and local scales indicates that growing seasons have been getting longer, and this trend is projected to become even more pronounced over the next century. As seasons shift so that spring arrives earlier and fall extends later into the year, phenology may shift for plant species that rely on temperature as a cue for the timing of leaf-out, reproductive maturation, and other developmental processes. Longer growing seasons could also result in greater growth and productivity of trees and other vegetation, but only if balanced by available water and nutrients.