Forest [FAR1]

Legacy FAR1 strategy/approaches.

Taxonomy Machine Name
niacs_strategy
Taxonomy Alias
far1

Many invasive species, insect pests, and pathogens in northern Minnesota forests will increase or become more damaging by the end of the century.

Submitted by sdhandler on

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 Minnesota may lose some of the protection offered by a traditionally cold climate and short growing season.

Climate conditions will increase fire risks in northern Minnesota by the end of the century.

Submitted by sdhandler on

At a global scale, the scientific consensus is that fire risk will increase by 10 to 30 percent due to higher summer temperatures. For the early part of the 21st century, there is low agreement in this trend across climate models. By the end of the century, however, most models project an increase in wildfire probability, particularly for boreal forests, temperate coniferous forests, and temperate broadleaf forests. Studies from southern Canada also project more active wildfire regimes in the future.

Northern Minnesota soil moisture patterns will change, with drier soil conditions later in the growing season.

Submitted by sdhandler on

Large variation exists for projected changes in precipitation for Minnesota and the Upper Midwest. Although individual model projections may differ, there is general agreement that annual precipitation is expected to increase slightly (2 to 4 inches) during the 21st century. Models also tend to agree that precipitation patterns between seasons may shift substantially. Averages across multiple climate models indicate that winter and spring may experience 20-30% more precipitation by the end of the century, while summer precipitation is projected to decrease by less than 10%.

Intense precipitation events will continue to become more frequent in northern Minnesota.

Submitted by sdhandler on

Heavy precipitation events have been increasing in number and severity in the upper Midwest in general and for Minnesota in particular, and many models agree that this trend will continue over the next century. For example, storms in the 99th-percentile category incrased by 42% from 1958 to 2016 across the Midwest. Large storms are also expected to deliver more rainfall as well. In the Midwest, 20-year return storms are projected to deliver 11 to 20% more rainfall by the end of the century. Most heavy precipitation events occur during summer in Minnesota.

Northern Minnesota's growing season will increase by 20 to 60 days by the end of the century.

Submitted by sdhandler on

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.

Northern Minnesota will have 20-40 fewer days of frozen ground during the winter by the end of the century.

Submitted by sdhandler on

In the Upper Midwest, the duration of frozen ground conditions suitable for winter harvest operations has already shortened by 2 to 3 weeks in the past 70 years. Cold-season soil temperatures are projected to increase between 1.8 and 5.4 °F by the end of the century, and total frost depth is projected to deline by 40 percent across northern Minnesota by the end of the century. These conditions could increase water infiltration into the soil and reduce runoff, but they may also lead to greater soil water losses through increased evapotranspiration.

Northern Minnesota's winter snowpack will be reduced from 40-80% by the end of the century.

Submitted by sdhandler on

A variety of models project that across the Upper Midwest, more winter precipitation will be delivered as rain, more snow will melt between snowfall events, and the snowpack will not be as deep or consistent. Lake-effect snowfall may increase in the short-term, but these events may convert to rain as temperatures increase.

Northern Minnesota temperatures will increase between 4 °F and 10 °F by the end of the century, with more warming during winter.

Submitted by sdhandler on

Northern Minnesota has already warmed more than 1.5 degrees since the first half of the 20th century, which is one of the fastest rates of warming across the country. All global climate models project that temperatures will increase with continued increases in atmospheric greenhouse gas concentrations. More warming is projected under a high climate scenario (RCP 8.5) and more moderate warming is projected under a moderate climate scenario (RCP 4.5).

Managed Red Pine

Submitted by sdhandler on

Managed Red Pine typically exists as single-species plantations that are managed as even-aged stands with rotation ages from 60 to 120 years. Red pine is typically planted on sandier, relatively nutrient-poor soils.

Managed Aspen

Submitted by sdhandler on

Managed aspen stands are found on a wide range of soil types and landforms, and they are conventionally managed as even-aged stands with rotation ages between 35 to 60 years.