Climate change in Michigan

Climate change in Michigan encompasses the effects of climate change, attributed to man-made increases in atmospheric carbon dioxide, in the U.S. state of Michigan.

Köppen climate types in Michigan, showing most of the state to be warm-summer humid continental, with some hot-summer humid continental portions.

The United States Environmental Protection Agency states that "Michigan's climate is changing. Most of the state has warmed two to three degrees (F) in the last century. Severe thunderstorms and tornadoes are becoming more frequent, and ice cover on the Great Lakes is forming later or melting sooner. In the coming decades, the state will have more extremely hot days, which may harm public health in urban areas and corn harvests in rural areas".[1]

The overall effects are expected to be widespread, mixed, and net-negative. A January 2013 'National Climate Assessment' study on the Great Lakes region, led by University of Michigan scholars, stated that climate change would have mixed but net-negative effects in the region by 2050. Specifically, longer growing seasons as well as higher carbon dioxide levels were predicted to increase crop yield but heat waves, droughts, and floods were also forecast to rise. The report predicted declines in ice cover on the Great Lakes that would lengthen commercial shipping season although the regions would also suffer from invasive species as well as damaging algae blooms. The negative scenario described in the study used modeling with a 3.8 to 4.9 °F (2.1 to 2.7 °C) range for 2000 to 2050 warming versus the 1 °F (0.56 °C) of historical warming for 1950 to 2000.[2]

Heavy precipitation and flooding

In the state of Michigan there are over 11,000 lakes that are 5 acres or larger. With this much water in the state, Michigan is more susceptible to flooding. "Changing the climate is likely to increase the frequency of floods in Michigan. Over the last half century, average annual precipitation in most of the Midwest has increased by 5 to 10 percent. But rainfall during the four wettest days of the year has increased about 35 percent. During the next century, spring rainfall and annual precipitation are likely to increase, and severe rainstorms are likely to intensify. Each of these factors will tend to further increase the risk of flooding". [3] Michigan recorded an annual average of two or more inches of rain during a period of just over one day. This is significant as it is more rain days per year than when record-keeping began in 1900. [4] Climate change could potentially increase the occurrence of 100-year floods. This is significant because 100-year floods are major floods that have a 1 percent chance of occurring in any given year. Michigan’s Upper and Lower Peninsula could see an increase of 25 to 500 present increase of 100- year floods from 2040 to 2060 compared to those seen from 1950 to 2000.[5]

2.6 million people in Michigan get their drinking water from private wells located at their household. These types of wells are not regulated to maximum standards. Extreme rainfall can affect these private wells, which threatens the safety of many individuals’ drinking water.[1] When private wells experience heavy rain, they can trigger extensive runoff. Extensive runoff can lead to bacterial contamination which aren’t normally treated.[6] It is generally the responsibility of the home owner to be aware of contamination. With the potential of more floods, it is posing a threat to Michigan’s agricultural industry resulting in loss of crop production and delaying when farmers can plant their fields.[7]

Great Lakes

"Changing the climate is likely to harm water quality in Lake Erie and Lake Michigan. Warmer water tends to cause more algal blooms, which can be unsightly, harm fish, and degrade water quality. During August 2014, an algal bloom in Lake Erie prompted the Monroe County Health Department to advise residents in four townships to avoid using tap water for cooking and drinking. Severe storms increase the amount of pollutants that run off from land to water, so the risk of algal blooms will be greater if storms become more severe. Severe rainstorms can also cause sewers to overflow into lakes and rivers, which can threaten beach safety and drinking water supplies. For example, heavy rains in August 2014 led to nearly 10 billion gallons of sewer overflows in southeastern Michigan, much of which ended up in Lake St. Clair and eventually Lake Erie. More severe rainstorms could also cause sewers in Milwaukee and Chicago to overflow into Lake Michigan more often, which could pollute beaches in Michigan".[3]

"One advantage of climate change is that warmer winters reduce the number of days that ice prevents navigation. Between 1994 and 2011, the decline in ice cover lengthened the shipping season on the Great Lakes by eight days. The lakes are likely to warm another 3° to 7°F in the next 70 years, which will further extend the shipping season".[3]

Winter recreation

"Warmer winters are likely to shorten the season for recreational activities like ice fishing, snowmobiling, snowboarding, and skiing, which could harm the local economies that depend on them. Small lakes are freezing later and thawing earlier than a century ago, which shortens the season for ice fishing and ice skating and can cause those to become impossible or unsafe due to thin and unreliable ice coverage upon lakes especially in the extreme south of the state. Since the early 1970s, winter ice coverage in the Great Lakes has decreased by 63 percent. Warmer temperatures are likely to shorten the season when the ground is covered by snow, and thereby shorten the season for activities that take place on snow. Nevertheless, annual snowfall has increased in much of the Great Lakes region, which could benefit winter recreation at certain times and locations".[3]

Ecosystems

"The ranges of plants and animals are likely to as the climate changes. For example, warmer weather could change the composition of Michigan’s forests. As the climate warms, the population of paper birch, quaking aspen, balsam fir, and black spruce may decline in the Upper Peninsula and northern Lower Peninsula, while oak, hickory, and pine trees may become more numerous. Climate change will also transform fish habitat. Rising water temperatures will increase the available habitat for warmwater fish such as bass, while shrinking the available habitat for coldwater fish such as trout. Declining ice cover and increasingly severe storms would harm both types of fish habitat through erosion and flooding. Warming could also harm ecosystems by changing the timing of natural processes such as migration, reproduction, and flower blooming".[3]

"Migratory birds are arriving in the Midwest earlier in spring today than 40 years ago. Along with range shifts, changes in timing can disrupt the intricate web of relationships between animals and their food sources and between plants and pollinators. Because not all species adjust to climate change in the same way, the food that one species eats may no longer be available when that species needs it (for example, when migrating birds arrive). Some types of animals may no longer be able to find enough food".[3]

Agriculture

"Changing the climate will have both beneficial and harmful effects on farming. Higher concentrations of atmospheric carbon dioxide and longer frost-free growing seasons would increase yields of wheat during an average year. But increasingly hot summers are likely to reduce yields of corn and possibly soybeans. Seventy years from now, Michigan’s Lower Peninsula is likely to have 5 to 15 more days per year with temperatures above 95°F than it has today. More severe droughts or floods would also hurt crop yields".[3]

References
  1. "GROUNDWATER STATISTICS" (PDF). Department of Environmental Quality.
  2. "Heat Waves, Storms, Flooding: Climate Change to Profoundly Affect U.S. Midwest in Coming Decades". Science Daily. January 18, 2013. Retrieved August 26, 2013.
  3. "What Climate Change Means for Michigan" (PDF). United States Environmental Protection Agency. August 2016.
  4. "Michigan - State Summaries 2019". statesummaries.ncics.org. Retrieved 2020-04-28.
  5. Wobus, Cameron; Gutmann, Ethan; Jones, Russell; Rissing, Matthew; Mizukami, Naoki; Lorie, Mark; Mahoney, Hardee; Wood, Andrew W.; Mills, David; Martinich, Jeremy (2017-12-08). "Climate change impacts on flood risk and asset damages within mapped 100-year floodplains of the contiguous United States". Natural Hazards and Earth System Sciences. 17 (12): 2199–2211. doi:10.5194/nhess-17-2199-2017. ISSN 1561-8633.
  6. US EPA, OW (2015-05-06). "Potential Well Water Contaminants and Their Impacts". US EPA. Retrieved 2020-04-28.
  7. "Michigan - State Summaries 2019". statesummaries.ncics.org. Retrieved 2020-04-28.

Further reading

Angel, J.; C. Swanston; B.M. Boustead; K.C. Conlon; K.R. Hall; J.L. Jorns; K.E. Kunkel; M.C. Lemos; B. Lofgren; T.A. Ontl; J. Posey; K. Stone; G. Tackle; D. Todey (2018). "Midwest". In Reidmiller, D.R.; C.W. Avery; D.R. Easterling; K.E. Kunkel; K.L.M. Lewis; T.K. Maycock; B.C. Stewart (eds.). Impacts, Risks, and Adaptation in the United States: Fourth National Climate Assessment, Volume II (Report). Washington, DC, USA: U.S. Global Change Research Program. pp. 872–940. doi:10.7930/NCA4.2018.CH21. -- this chapter of the National Climate Assessment covers Midwest states (Illinois, Indiana, Iowa, Michigan, Minnesota, Missouri, Ohio, and Wisconsin).

This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.