Source: The Heritage Foundation | VIEW ORIGINAL POST ==>
The benefits we derive from healthy and productive ecosystems are critical to economic prosperity. Important ecological goods and services include the market commodities that originate from forest habitats, such as food, fuel, timber, and fresh water, but they also include the food from croplands and rangelands as well as the recreational and esthetic value that undeveloped landscapes provide. Any and all threats to these ecological goods and services, including those that may come from future increases in global temperature caused by our use of fossil fuels, must therefore be taken seriously.<span class="annotation__highlight" data-annotation="
Government of Manitoba, Department of Agriculture, “Ecological Goods and Services and Natural Capital,” https://www.gov.mb.ca/agriculture/environment/ecological-goods-and-services/index.html (accessed August 23, 2024); “Ecosystems Goods and Services,” Chapter 4, Section 4.1.1. in Intergovernmental Panel on Climate Change, Climate Change 2007: Impacts, Adaptation and Vulnerability, Working Group II Contribution to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change, ed. Martin Parry et al. (Cambridge, UK: Cambridge University Press, 2007), p. 215, https://www.ipcc.ch/site/assets/uploads/2018/03/ar4_wg2_full_report.pdf (accessed August 23, 2024); Wei Zhang et al., “Ecosystem Services and Dis-services to Agriculture,” Ecological Economics, Vol. 64, No. 2 (December 15, 2007), pp. 253–260, https://uvm.edu/giee/pubpdfs/Zhang_2007_Ecological_Economics.pdf (accessed August 23, 2024); John Westra, “Ecosystem Goods and Services and Environmental Markets,” University of Nebraska–Lincoln, Institute of Agriculture and Natural Resources, Center for Agricultural Profitability, June 14, 2021, https://cap.unl.edu/management/ecosystem-goods-and-services-and-environmental-markets (accessed August 23, 2024).
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In forest, cropland, and rangeland ecosystems, increased risk to plant species of all kinds is perceived to come from predicted increases in summer heat waves and associated drought conditions. While it is known that increased carbon dioxide (CO2) levels have already caused better growth rates and improved water management in virtually all plant types (including trees, food crops, and rangeland grasses), some models predict that these benefits will be overwhelmed in the future by drought conditions of unprecedented severity.<span class="annotation__highlight" data-annotation="
For forecasts of agricultural and ecological drought, see “North America,” Chapter 14 in Intergovernmental Panel on Climate Change, Climate Change 2022: Impacts, Adaptation and Vulnerability: Working Group II Contribution to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change, ed. Hans-Otto Pörtner et al., (Cambridge, UK, and New York: Cambridge University Press, 2022), pp. 1929–2042, https://www.ipcc.ch/report/ar6/wg2/ (accessed September 11, 2024), and “Summary for Policymakers” in Intergovernmental Panel on Climate Change, Climate Change 2023: Synthesis Report, ed. Core Writing Team, Hoesung Lee, and José Romero (Geneva, Switzerland: IPCC, 2023), pp. 12–18, https://www.ipcc.ch/report/ar6/syr/downloads/report/IPCC_AR6_SYR_FullVolume.pdf (accessed August 23, 2024).
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Predictions of increased risk of forest fires due to climate change have also been advanced. An abundance of drought-killed and pest-killed trees is often blamed for causing larger and more intense fires in recent years, and computer models predict that these events could get worse over time as global temperatures increase.<span class="annotation__highlight" data-annotation="
Patrick T. Brown, “I Left out the Full Truth to Get My Climate Change Paper Published,” The Free Press, September 5, 2023, https://www.thefp.com/p/i-overhyped-climate-change-to-get-published (accessed August 23, 2024); Patrick T. Brown et al., “Climate Warming Increases Extreme Daily Wildfire Growth Risk in California,” Nature, Vol. 621, No. 7980 (September 28, 2023), pp. 760–766, https://www.nature.com/articles/s41586-023-06444-3.epdf?sharing_token=I86PZp3gGAfxhF70ZEyVp9RgN0jAjWel9jnR3ZoTv0OVfAHVtT4T_lgbAhs5GRzz91ftcZ-DYELeFxz2Fa6405YYs8htFGrdwdx2NnAjlcN5I8el9Yh8Eet0d2wmX04G2fnvwXAaBvK6Oja_dK5sxa7TBPR_ecRWd8Uj23z5WiCyNL1Rl41ealGTzbJD9e1PccnEV–1yhOexzkQ_uFGHqiVBMA31pt57_smHL-8xp0%3D&tracking_referrer=www.latimes.com (accessed August 23, 2024); Ronnie Abolafia-Rosenzweig, Cenlin He, and Fei Chen, “For Western Wildfires, the Immediate Past Is Prologue,” Eos, July 13, 2022, https://www.researchgate.net/publication/361971779_For_Western_Wildfires_the_Immediate_Past_Is_Prologue https://doi.org/10.1029/2022EO220319 (accessed August 23, 2024); U.S. Department of Commerce, National Oceanic and Atmospheric Administration, NOAA and Wildfire, “Wildfire Climate Connection,” last updated July 24, 2023, https://www.noaa.gov/noaa-wildfire/wildfire-climate-connection (accessed August 23, 2024).
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This Special Report examines the evidence surrounding these claims. Historical context is critical here as are the often-ignored potential for other human causes and the beneficial effects of human innovation. Extreme weather conditions with devastating effects—driven in part by completely natural, long-term climate cycles, short-term El Niño Southern Oscillation events, and decadal-level cycles in solar radiation—are nothing new to U.S. ecosystems. At issue is whether a slight rise in global temperature caused by greenhouse gas emissions might worsen such natural events and, if so, whether the most adverse effects can be alleviated.<span class="annotation__highlight" data-annotation="
Erik Hofmeister et al., “Climate Change and Wildlife Health: Direct and Indirect Effects,” U.S. Department of the Interior, U.S. Geological Survey, Fact Sheet No. 10-3017, revised 2012, https://pubs.usgs.gov/fs/2010/3017/pdf/fs2010-3017_rev2012.pdf (accessed August 23, 2024); John K. Dagsvik and Sigmund H. Moen, “To What Extent Are Temperature Levels Changing Due to Greenhouse Gas Emissions?” Statistics Norway Discussion Paper No. 1007, September 25, 2023, https://www.ssb.no/natur-og-miljo/forurensning-og-klima/artikler/i-hvilken-grad-endrer-temperaturnivaet-seg-pa-grunn-av-klimagassutslipp/_/attachment/inline/5a3f4a9b-3bc3-4988-9579-9fea82944264:f63064594b9225f9d7dc458b0b70a646baec3339/DP1007.pdf (accessed August 23, 2024).
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Farms and Croplands
Croplands in the southern Great Plains (Kansas, Oklahoma and Texas) are expected to be most at risk of the worst adverse effects of high temperatures and drought conditions caused by future increases in CO2 emissions from the burning of fossil fuels. However, historic records and proxy data indicate that droughts are nothing new to U.S. ecosystems. Moreover, the natural responses of plants as well as human innovation—including improved irrigation methods and regulations, strategic use of fertilizers, and the never-ending development of resilient crop varieties—will likely continue to offset any potentially harmful effects of climate change on crop yield and quality as they have since the 1930s.<span class="annotation__highlight" data-annotation="
Seung Min Kim and Robert Mendelsohn, “Climate Change to Increase Crop Failure in U.S.,” Environmental Research Letters, Vol. 18, No. 1 (January 2023), https://iopscience.iop.org/article/10.1088/1748-9326/acac41/pdf (accessed August 23, 2024); Hannah Hickey, “Warmer Climate Will Dramatically Increase the Volatility of Global Corn Crops,” University of Washington News, June 11, 2018, https://www.washington.edu/news/2018/06/11/warmer-climate-will-dramatically-increase-the-volatility-of-global-corn-crops/ (accessed August 23, 2024).
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Drought and Water Management. Droughts that adversely affect ecosystems are periods with abnormally low soil moisture due to increased evaporation and decreased precipitation, which the Intergovernmental Panel on Climate Change (IPCC) calls “agricultural and ecological drought.”<span class="annotation__highlight" data-annotation="
See, for example, “Summary for Policymakers” in Intergovernmental Panel on Climate Change, Climate Change 2021: The Physical Science Basis, Working Group I Contribution to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change, ed. Valérie Masson-Delmotte et al. (Cambridge, UK, and New York: Cambridge University Press, 2021), p. 19, https://www.ipcc.ch/report/ar6/wg1/downloads/report/IPCC_AR6_WGI_FullReport_small.pdf (accessed September 11, 2024). The IPPC is self-described as “the United Nations body for assessing the science related to climate change.” Intergovernmental Panel on Climate Change, “About the IPPC,” https://www.ipcc.ch/about/ (accessed August 25, 2024).
“>REF Proxy evidence from tree rings over the past 2,000 years compared to historical records indicates that drought conditions much more severe than those that plagued parts of the contiguous U.S. in the 1930s, 1950s, and early 2000s—lasting three decades or more—occurred in the late 1200s and late 1500s as a result of natural climatic variation and that 1930s-like drought conditions have occurred repeatedly over the past 400 years.<span class="annotation__highlight" data-annotation="
Sonia I. Seneviratne et al., “Weather and Climate Extreme Events in a Changing Climate,” Chapter 11 in Intergovernmental Panel on Climate Change, Climate Change 2021: The Physical Science Basis, pp. 1513–1765; Richard R. Heim Jr., “A Comparison of the Early Twenty-First Century Drought in the United States to the 1930s and 1950s Drought Episodes,” Bulletin of the American Meteorological Society, Vol. 98, No. 12 (December 2017), pp. 2579–2592, https://doi.org/10.1175/BAMS-D-16-0080.1 (accessed August 24, 2024); Connie A. Woodhouse and Jonathan T. Overpeck, “2000 Years of Drought Variability in the Central United States,” Bulletin of the American Meteorological Society, Vol. 79, No. 12 (December 1998), pp. 2693–2714, https://journals.ametsoc.org/view/journals/bams/79/12/1520-0477_1998_079_2693_yodvit_2_0_co_2.xml?tab_body=pdf (accessed August 24, 2024); Matthew Wills, “Why Did They Leave the Pueblos?” JStor Daily, November 16, 2022, https://daily.jstor.org/why-did-they-leave-the-pueblos/ (accessed August 24, 2024).
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The IPCC expects with “medium to high confidence” that extreme heat and severe droughts will occur more frequently over the next seven decades and that demand for limited water supplies in the western U.S. in particular could adversely impact agricultural operations. Irrigation of crops, especially the hay and corn used to feed cattle and pigs, puts the heaviest demand on water supplies, while domestic and commercial users draw significantly less. In the western U.S., from Wyoming to California, water from the Colorado River drainage is the most fought-over because it is critical to so many stakeholders; shortages in 2022 drove tempers especially high. However, future innovations in irrigation systems and the availability of more drought-tolerant and heat-tolerant crop varieties could reduce this usage considerably.<span class="annotation__highlight" data-annotation="
Intergovernmental Panel on Climate Change, Sixth Assessment Report, Working Group II—Impacts, Adaptation and Vulnerability, “Fact Sheet—North America,” December 2022, https://www.ipcc.ch/report/ar6/wg2/downloads/outreach/IPCC_AR6_WGII_FactSheet_NorthAmerica.pdf (accessed August 24, 2024); Michael F. Wehner et al., “Droughts, Floods, and Wildfires,” Chapter 8 in U.S. Global Change Research Program, Climate Science Special Report: Fourth National Climate Assessment, Volume I, ed. Donald J. Wuebbles et al., 2017, pp. 231–256, https://science2017.globalchange.gov/downloads/CSSR2017_FullReport.pdf (accessed August 24, 2024); Brian D. Richter et al., “Water Scarcity and Fish Imperilment Driven by Beef Production,” Nature Sustainability, Vol. 3, No. 4 (April 2020), pp. 319–328, https://digitalcommons.unl.edu/cgi/viewcontent.cgi?article=1064&context=wffdocs (accessed August 24, 2024); Kansas State University, Beef Cattle Institute, “Does Beef Production Really Use That Much Water?” November 16, 2020, https://ksubci.org/2020/11/16/does-beef-production-really-use-that-much-water/ (accessed August 24, 2024).
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While it remains to be seen whether more frequent and severe droughts will put even more pressure on water supplies in the western U.S. than has been seen historically, it has been pointed out that state-imposed and federally imposed water laws often hinder conservation measures and limit the ability to move water to where it is most needed. Effective water management has been an issue in the western U.S. at least since the early 1900s, and the fact that the numbers of people and domestic livestock on the landscape have increased markedly over the past 100 years is almost certainly a bigger part of the problem than is human-caused climate change. However, at least twice over the past 400–1,000 years, wild bison herds in the tens of millions and perhaps as many Native Americans vied for dwindling water supplies when catastrophic drought events occurred—a reminder that such competition is nothing new. Thoughtful water policy has considerable potential to offset future scarcities, whether naturally caused or human-caused.<span class="annotation__highlight" data-annotation="
Jim Geraghty, “The Biden Administration’s Brewing Battle with the Western States,” National Review, January 27, 2023, https://www.nationalreview.com/the-morning-jolt/the-biden-administrations-brewing-battle-with-the-western-states/ (accessed August 24, 2024); Joe Gelt, “Sharing Colorado River Water: History, Public Policy and the Colorado River Compact,” Arroyo, Vol. 10, No. 1 (August 1997), https://wrrc.arizona.edu/publication/sharing-colorado-river-water-history-public-policy-and-colorado-river-compact (accessed August 24, 2024); James H. Shaw, “How Many Bison Originally Populated Western Rangelands?” Rangelands, Vol. 17, No. 5 (October 1995), pp. 148–150, https://repository.arizona.edu/bitstream/handle/10150/639069/11258-10800-1-PB.pdf?sequence=1&isAllowed=y (accessed August 24, 2024); Statista Research Department, “Estimated Pre-Colonization Population of the Americas~1492,” January 1, 1983, https://www.statista.com/statistics/1171896/pre-colonization-population-americas/ (accessed August 24, 2024).
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Range Shifts and Crop Yields. The IPCC predicts with “high confidence” that future human-caused climate change will shift the ranges in North America where crucial food crops can be grown, which it says may intensify some harvest losses.<span class="annotation__highlight" data-annotation="
Intergovernmental Panel on Climate Change, Sixth Assessment Report, Working Group II—Impacts, Adaptation and Vulnerability, “Fact Sheet—North America.”
“>REF Such range shifts have already been documented in Canada where a growing season that is two to five weeks longer relative to 1950 is already benefitting Alberta and Saskatchewan farmers, enabling them to grow fast-maturing varieties of corn and soybeans profitably where they could not have done so in the past.<span class="annotation__highlight" data-annotation="
Jacob Bunge, “A Warming Climate Brings New Crops to Frigid Zones,” The Wall Street Journal, November 25, 2018, https://web.archive.org/web/20210217021704/https://www.wsj.com/articles/a-warming-climate-brings-new-crops-to-frigid-zones-1543168786 (accessed August 23, 2024).
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In the U.S., drought and heat waves rather than range shifts are the main climate-associated concerns: It is predicted that lack of soil moisture and daytime temperatures that are much higher than usual could stress even heat-loving crops like corn, potentially reducing their yield at harvest.<span class="annotation__highlight" data-annotation="
Peter Thomison, “Hot, Dry Conditions Stressing Corn,” C.O.R.N. [Crop Observation and Recommendation Network] Newsletter: 2016-22, July 26–August 1, 2016, https://agcrops.osu.edu/newsletter/corn-newsletter/hot-dry-conditions-stressing-corn (accessed August 24, 2024); Michelle Tigchelaar et al., “Future Warming Increases Probability of Globally Synchronized Maize Production Shocks,” Proceedings of the National Academy of Sciences of the United States of America, Vol. 115, No. 26 (June 26, 2018), pp. 6644–6649, https://www.pnas.org/doi/epdf/10.1073/pnas.1718031115 (accessed August 23, 2024).
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So far, however, the warming experienced in recent decades either has improved harvest yields because of higher minimum temperatures (warmer nights) or has had no overall effect. In the Midwest, the severe drought of 2012 reduced yields for corn by only 13 percent compared to 2011 and soybeans by 3 percent. By contrast, in the southeastern U.S., an increased average temperature of 1 degree Celsius between 1980 and 2020 significantly improved corn and rice yields and had no effect on wheat. Altogether, across the U.S., major crop yields have continued to increase since the 1960s despite continually increasing CO2 emissions and recent drought conditions.<span class="annotation__highlight" data-annotation="
News release, “Crop Production Down in 2012 Due to Drought, USDA Reports: Winter Wheat Seedlings and Grain Stocks Are Also Reported,” U.S. Department of Agriculture, National Agricultural Statistics Service, January 11, 2013, https://www.nass.usda.gov/Newsroom/archive/2013/01_11_2013.php (accessed August 23, 2024); Ramandeep Kumar Sharma et al., “Impact of Recent Climate Change on Corn, Rice, and Wheat in Southeastern USA,” Scientific Reports, Vol. 12 (2022), article no. 16928, https://doi.org/10.1038/s41598-022-21454-3 (accessed August 24, 2024); Hannah Ritchie, Pablo Rosado, and Max Roser, “Crop Yields 1960–2021: Rice” and “Crop Yields 1866–2021: Corn /Maize,” Our World in Data, https://ourworldindata.org/crop-yields (accessed August 24, 2024); Robert L. Nielsen, “Historical Corn Grain Yields in the U.S.,” Corny News Network, updated February 2023, http://www.kingcorn.org/news/timeless/YieldTrends.html (accessed August 24, 2024).
“>REF (See Chart 1 and Chart 2.)
In another example, a study published in October 2023 used computer models to predict that by 2050, drought and high temperatures could somewhat reduce crop yields for European hops used in the fast-growing beer market. Media outlets promoted this as a threat to future beer drinking, but the largest producers of hops worldwide are in the U.S., where yields have been increasing steadily since 2012 despite (and perhaps because of) steadily increasing global CO2 levels. Virtually all U.S. hops are grown in the Pacific Northwest, and 2021 was a bumper year. Yields in 2022 were slightly lower because of cold spring weather unrelated to climate change.<span class="annotation__highlight" data-annotation="
Maggie Penman, “How Climate Change Is Threatening Your Beer,” The Washington Post, October 20, 2023, https://www.washingtonpost.com/climate-solutions/2023/10/10/climate-change-beer-hops/ (accessed August 24, 2024); Martin Mozny et al., “Climate-Induced Decline in the Quality and Quantity of European Hops Calls for Immediate Adaptation Measures,” Nature Communications, Vol. 14 (2023), article no. 6028, https://doi.org/10.1038/s41467-023-41474-5 (accessed August 24, 2024); Chris [last name unknown], “The Top 15 Hop Producing Countries in 2023,” Beer Maverick, updated January 11, 2023, https://beermaverick.com/between-the-35th-and-55th-parallels-worlds-hop-production/ (accessed August 24, 2024); Hop Growers of America, 2022 Statistical Report, released January 2023, https://www.usahops.org/img/blog_pdf/436.pdf (accessed August 24, 2024).
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In contrast to the pessimistic predictions offered by academics, the people who actually grow hops have forecasted a modest boost in U.S. hops production over the next decade and a significant increase in European production. Such forecasts make sense because modern farmers do not sit around waiting for adverse conditions to decimate their yields: Since the 1930s, farmers increasingly have turned to innovations in irrigation, fertilizers, crop rotation, and especially genetics, which produce all kinds of crops that are resistant to disease, drought, and high temperatures. (See Chart 2.) Climate-based models do not take future agricultural innovations like these into account. The reality is that increased crop resilience due to human innovation is likely to intensify in future decades because hundreds of years of experience have taught farmers everywhere that unforeseen adverse weather and disease can be expected at any time, and they had better take what steps they can beforehand to mitigate the damage.<span class="annotation__highlight" data-annotation="
Mike Snider, “Could a Beer Shortage Be Looming? Changing Weather Could Hit Hops Needed in Brews,” USA Today, October 10, 2023, https://www.usatoday.com/story/money/2023/10/10/beer-shortage-weather-hops-threatened-climate/71132739007/ (accessed August 23, 2024); Globe Newswire, “Hops Market Expected to Experience Robust Growth with a Projected CAGR of 4.2% During the Forecast Period,” March 30, 2023, https://www.globenewswire.com/news-release/2023/03/30/2637349/0/en/Hops-Market-Expected-to-Experience-Robust-Growth-with-a-Projected-CAGR-of-4-20-during-the-Forecast-Period.html (accessed August 23, 2024); U.S. Department of Agriculture, Agricultural Research Service, Tellus, “Barley and Hops: Beer’s Top Crops,” March 6, 2019, https://tellus.ars.usda.gov/stories/articles/barley-and-hops-beer-s-top-crops (accessed August 23, 2024); Dave McIntyre, “Climate Change Wreaks More Havoc on Wine Growers with Spring Frost,” The Washington Post, July 6, 2023, https://www.washingtonpost.com/food/2023/07/06/climate-change-wine-frost-finger-lakes/ (accessed August 23, 2024).
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Another aspect of crop futures that is seldom taken into account in predictive models is the fertilizing effect of CO2, which is literally food for plants. Higher atmospheric concentration of CO2 makes plants grow faster and boosts their efficient use of available water. In the future, this will at least partially offset the adverse effects of higher than usual daytime temperatures and drought conditions that might occur, especially when accompanied by innovative crop management measures and the use of genetically improved crop varieties.<span class="annotation__highlight" data-annotation="
Zaichun Zhu et al., “Greening of the Earth and Its Drivers,” Nature Climate Change, Vol. 6, No. 8 (August 2016), pp. 791–795, https://escholarship.org/uc/item/8mc6q011 (accessed August 24, 2024); Marie-Anne De Graaff et al., “Interactions Between Plant Growth and Soil Nutrient Cycling Under Elevated CO2: A Meta-Analysis,” Global Change Biology, Vol. 12, No. 11 (November 2006), pp. 2077–2091, https://ecoss.nau.edu/wp-content/uploads/2016/04/09e4150c217e14cbad000000.pdf (accessed August 24, 2024); Kevin D. Dayaratna, Ross McKitrick, and Patrick J. Michaels, “Climate Sensitivity, Agricultural Productivity and the Social Cost of Carbon in FUND,” Environmental Economics and Policy Studies, Vol. 22, No. 3 (July 2020), pp. 433–448, https://doi.org/10.1007/s10018-020-00263-w (accessed August 24, 2024); Yitao Li. et al., “Biophysical Impacts of Earth Greening Can Substantially Mitigate Regional Land Surface Temperature Warming,” Nature Communications, Vol. 14 (2023), article no. 121, https://doi.org/10.1038/s41467-023-35799-4 (accessed August 24, 2024); Lewis H. Ziska, Dana M. Blumenthal, and Steven J. Franks, “Understanding the Nexus of Rising CO2, Climate Change, and Evolution in Weed Biology,” Invasive Plant Science and Management, Vol. 12, No. 2 (April 2019), pp. 79–88, https://www.cambridge.org/core/services/aop-cambridge-core/content/view/FBF2BA52A5A18B5E3F2105AECE705D5A/S1939729119000129a.pdf/div-class-title-understanding-the-nexus-of-rising-co-span-class-sub-2-span-climate-change-and-evolution-in-weed-biology-div.pdf (accessed August 24, 2024).
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Rangelands
Rangelands are grasslands, shrublands, and woodlands that are used for grazing domestic livestock, whether on private or public land, and currently represent about 42 percent of the total area of the U.S. Rangelands are also used by a variety of wild species including economically important stocks of elk (Cervus elaphus canadensis); moose (Alces alces); and deer (Odocoileus spp).<span class="annotation__highlight" data-annotation="
Joseph M. DiTomaso, “Invasive Weeds in Rangelands: Species, Impacts, and Management,” Weed Science, Vol. 48, No. 2 (March 2000), pp. 255–265, https://library.ndsu.edu/ir/bitstream/handle/10365/3250/1491di00.pdf (accessed August 24, 2024).
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In the contiguous U.S., ecologically distinct rangelands are found east of the Rocky Mountains on the Great Plains and west of the Rockies in the dry Southwest, including the shrublands of California. Different effects of human-caused climate change are predicted depending on the region, although much uncertainty is involved. In the Southwest, the possibility of adverse effects from more intense or frequent drought events in the future is a big worry; in the northern Great Plains, predictions of longer and warmer growing seasons are good news because this should result in increased habitat and forage for wild and domestic species.<span class="annotation__highlight" data-annotation="
Prasanta C. Bhowmik, “Invasive Weeds and Climate Change: Past, Present, and Future,” Journal of Crop and Weed, Vol. 10, No. 2 (January 2014), pp. 345–349, https://www.researchgate.net/publication/273121149_Invasive_weeds_and_climate_change_past_present_and_future (accessed August 24, 2024); Daniel W. McCollum et al., “Climate Change Effects on Rangelands and Rangeland Management: Affirming the Need for Monitoring,” Ecosystem Health and Sustainability, Vol. 3, No. 3 (March 2017), article no. e01264, https://esajournals.onlinelibrary.wiley.com/doi/full/10.1002/ehs2.1264 (accessed August 24, 2024).
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In other words, greater future CO2 emissions could affect the quality and aerial extent of wildlife habitat and forage on rangeland as well as the economic viability of these ecosystems for raising domestic livestock. Because both directly positive and negative consequences of global warming are anticipated, a few examples of more indirect repercussions—from invasive weeds and soil erosion—may help to explain why the perceived adverse effects on ecosystem goods and services from rangelands are not likely to be realized in future decades.<span class="annotation__highlight" data-annotation="
Dennis S. Ojima et al., “A Climate Change Indicator Framework for Rangelands and Pastures of the USA,” Climatic Change, Vol. 163, No. 4 (December 2020), pp. 1733–1750, https://www.researchgate.net/publication/346057990_A_climate_change_indicator_framework_for_rangelands_and_pastures_of_the_USA (accessed August 24, 2024); Linda A. Joyce et al., “Climate Change and North American Rangelands: Assessment of Mitigation and Adaptation Strategies,” Rangeland Ecology & Management, Vol. 66, No. 5 (September 2013), pp. 512–528, https://www.researchgate.net/publication/270167715_Climate_Change_and_North_American_Rangelands_Assessment_of_Mitigation_and_Adaptation_Strategies (accessed August 24, 2024).
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Invasive Plant Species (Weeds). An increase in the abundance of invasive weeds and grasses is forecasted to become a critical problem in future decades for rangelands across the contiguous U.S. Most invasive weeds and grasses are not native to North America: Some weed species were introduced by early settlers, and others were brought in either accidentally or intentionally.<span class="annotation__highlight" data-annotation="
DiTomaso, “Invasive Weeds in Rangelands: Species, Impacts, and Management.”
“>REF As a consequence, most weeds have no natural enemies that would normally keep their abundance within bounds.
Invasive grasses and weeds are resilient species almost by definition. They are often less drought-tolerant and more fire-prone with very effective strategies for rapid growth and reproduction that may include deep or expansive roots systems, massive seed production, and self-pollination. In addition, the fertilizing effect of recent increases in global CO2 emissions that has made trees and crops grow better unfortunately has done the same for weeds, and this situation is predicted to get worse over time as emissions increase.<span class="annotation__highlight" data-annotation="
David R. Clements and Vanessa L. Jones, “Rapid Evolution of Invasive Weeds Under Climate Change: Present Evidence and Future Research Needs,” Frontiers in Agronomy, Vol. 3 (April 2021), article no. 664034, https://www.researchgate.net/publication/350696462_Rapid_Evolution_of_Invasive_Weeds_Under_Climate_Change_Present_Evidence_and_Future_Research_Needs (accessed August 24, 2024).
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The superior productivity of weeds makes it difficult for native species to compete, which means that weeds can expand quickly. Drought-killed or fire-killed rangelands or those subjected to overgrazing are often subsequently invaded by weedy plants. Some of these species are poisonous, but even weeds that are simply unpalatable reduce the yield and quality of nutritious forage on rangelands. Weeds may also interfere with effective grazing when domestic livestock and wildlife avoid weed-infested areas. For these reasons, future increases in the prevalence of weeds on rangelands due to increased CO2 emissions could have serious economic and ecological repercussions.<span class="annotation__highlight" data-annotation="
DiTomaso, “Invasive Weeds in Rangelands: Species, Impacts, and Management.”
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However, invasive weeds are currently managed with a combination of mowing, selective and timely grazing, native grass reseeding, controlled burns, and the strategic application of herbicides and natural enemies (including species-specific insect and mite pests, collectively known as biocontrol agents). Most weeds can never be truly eradicated, but the expanded use of biocontrol agents and herbicides especially shows much promise for future management of weeds in the face of increased fossil fuel emissions.<span class="annotation__highlight" data-annotation="
Hariet L. Hinz, “Invasive Weeds in America’s Western States: Restoring Balance Using Biological Control,” CABI [CAB International], Invasives Blog, August 10, 2020, https://blog.invasive-species.org/2020/08/10/invasive-weeds-in-americas-western-states-restoring-balance-using-biological-control/ (accessed August 24, 2024); Ramanathan Kathiresan and Gbehounou Gualbert, “Impact of Climate Change on the Invasive Traits of Weeds,” Weed Biology and Management, Vol. 16, No. 2 (June 2016), pp. 59–66, https://doi.org/10.1111/wbm.12096 (accessed August 24, 2024); Ziska et al., “Understanding the Nexus of rising CO2, Climate Change, and Evolution in Weed Biology.”
“>REF
Soil Erosion. Soil erosion is the natural loss of soil on landscapes due to the effects of wind and water. Bare, dry soil can lose nutrients and is easily transported by strong winds; surface runoff from intensive downpours, such as occur during thunderstorms, can lead to destructive flash floods that scour landscapes and precipitate devastating landslides. Much of the damage to U.S. soils since the 1970s has come from the overgrazing of domestic livestock on rangelands, not the intensive cultivation of croplands, exacerbated by drought, that led to extreme erosion during the 1930s.<span class="annotation__highlight" data-annotation="
Mark A. Weltz and Gary Frasier, eds., Rangeland Hydrology and Soil Erosion Processes, U.S. Department of Agriculture, Natural Resources Conservation Service, Handbook No. 646, 2017, https://directives.nrcs.usda.gov/sites/default/files2/1719429486/Part%20646%20-%20Rangeland%20Processes%20Handbook%20Hydrology%20and%20Soil%20Erosion.pdf (accessed August 25, 2024); Library of Congress, “The Dust Bowl,” U.S. History Primary Source Timeline, https://www.loc.gov/classroom-materials/united-states-history-primary-source-timeline/great-depression-and-world-war-ii-1929-1945/dust-bowl/ (accessed August 25, 2024).
“>REF
In the U.S. Southwest, which is a naturally semi-arid landscape, human-caused climate change is predicted primarily to cause catastrophic flooding as a result of more frequent extreme precipitation events. Such adverse effects have the potential to destroy portions of rangeland ecosystems and their wildlife inhabitants. However, extreme weather events are locality-specific and notoriously difficult to predict accurately: The IPCC has only low confidence in the likelihood of any increased incidence of heavy precipitation.<span class="annotation__highlight" data-annotation="
Y. Zhang et al., “Modeling Climate Change Effects on Runoff and Soil Erosion in Southeastern Arizona Rangelands and Implications for Mitigation with Conservation Practices,” Journal of Soil and Water Conservation, Vol. 67, No. 5 (September/October 2012), pp. 390–405, https://www.jswconline.org/content/jswc/67/5/390.full.pdf (accessed August 25, 2024); Roger Pielke Jr., “What the IPCC Actually Says About Extreme Weather,” The Honest Broker, July 19, 2023, https://rogerpielkejr.substack.com/p/what-the-ipcc-actually-says-about (accessed August 25, 2024).
“>REF
The failure to restore overgrazed rangelands with deliberate planting seems to be the primary cause of recent soil erosion and flooding events. Fortunately, the solution is relatively simple: reduced grazing intensity coupled with purposeful restoration of overgrazed habitats.<span class="annotation__highlight" data-annotation="
Alexander P.E. van Oudenhoven et al., “Effects of Different Management Regimes on Soil Erosion and Surface Runoff in Semi-Arid to Sub-Humid Rangelands,” Journal of Arid Environments, Vol. 121 (October 2015), pp. 100–111, https://www.pbl.nl/sites/default/files/downloads/PBL_2015_Effects_of_different_management_regimes_on_soil_erosion_and_surface_runoff_in_semi-arid_to_sub-humid_rangelands_1835.pdf (accessed August 25, 2024).
“>REF
Forests and Wildfire Risk
Extended periods of hot weather and drought create ideal conditions for hard-to-fight forest fires. Although climate models predict that such weather conditions generated by human-caused global warming will increase the incidence of wildfires, recent wildfires cannot be blamed exclusively (or even primarily) on global warming: Weather-driven conditions conducive to forest fires have existed for millennia as a result of naturally occurring climate cycles. For example, studies have shown that over the past 3,000 years, severe fires in the western U.S. occurred during the 1800s and the Medieval Warm Period (950–1250 AD), and some of the least destructive happened in the mid-20th century and during the Little Ice Age (1400–1700 AD).<span class="annotation__highlight" data-annotation="
Jennifer R. Marlon et al., “Long-Term Perspective on Wildfires in the Western USA,” Proceedings of the National Academy of Sciences of the United States of America, Vol. 109, No. 9 (February 14, 2012), pp. E535–E543, https://www.pnas.org/doi/epdf/10.1073/pnas.1112839109 (accessed August 23, 2024).
“>REF
Natural climate variability clearly modified historical fire severity, but landscape changes and similar human influences—including logging and farming practices, firefighting practices, the building of railroad lines and electrical grids, domestic livestock grazing, clearing forests for farmland and settlements (including modern suburbs), deliberate agricultural burning, increased recreational use of back-country landscapes, and the intentional or accidental introduction of weedy, non-native grasses and shrubs—have affected wildlife behavior as they have changed over time, especially since the 1800s.<span class="annotation__highlight" data-annotation="
Daniel L. Swain, “A Shorter, Sharper Rainy Season Amplifies California Wildfire Risk,” Geophysical Research Letters, Vol. 48, No. 5 (March 2021), article no. e2021GL092843, https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2021GL092843 (accessed August 25, 2024); Iman Palm, “Humans to Blame for About 90% of Wildfire Ignitions, Report Finds,” KTLA [Los Angeles], July 23, 2023, https://ktla.com/news/california/humans-to-blame-for-about-90-of-wildfire-ignitions-report-finds/ (accessed August 25, 2024).
“>REF
The strongest data for assessing modern forest fire severity over time in the contiguous U.S. come from the western states (Arizona, California, Colorado, Idaho, Montana, Oregon, New Mexico, Nevada, Utah, Washington, and Wyoming), where comparable records go back to 1916. (See Chart 3.) These records show that on federal and federally protected lands, fires from 1916 to the mid-1940s (excluding those caused by arson) were similar in scale to fires in the early 2000s. The most acres burned in a given year burned in 2012, but the second highest number burned in 1919, and some huge fires occurred before 1932 that were equal in size to more recent events. Overall, there is no obvious trend over time.<span class="annotation__highlight" data-annotation="
Data exclude intentional fires and count only burns on federal or federally protected land. Updated to 2020 by Jeremy Littell from data published in Jeremy S. Littell et al., “Climate and Wildfire Area Burned in Western U.S. Ecoprovinces, 1916–2003,” Ecological Applications, Vol. 19, No. 4 (June 2009), pp. 1003–1021, https://www.researchgate.net/publication/26309358_Climate_and_wildfire_area_burned _western_US_ecoprovinces_1916-2003 (accessed August 25, 2024), and Jon Greenberg, “No, Fires Weren’t Bigger in the 1920s and ’30s than Today,” PolitiFact, October 15, 2021, https://www.politifact.com/factchecks/2021/oct/15/heartland-institute/no-wildfires-werent-bigger-1920s-and-30s-today/ (accessed August 25, 2024). See also National Wildfire Coordinating Group, “The Great Fires of 1910 (The Big Blowup)—August 20th,” This Day in History, https://www.nwcg.gov/6mfs/day-in-history/great-fires-of-1910-big-blowup-august-20th (accessed August 25, 2024); Abolafia-Rosenzweig et al., “For Western Wildfires, the Immediate Past Is Prologue;” and Caitlin Dempsey, “2023 Wildfires in the Western United States,” Geography Realm, updated August 6, 2023, https://www.geographyrealm.com/2023-wildfire-western-united-states/ (accessed August 25, 2024). “The National Wildfire Coordinating Group (NWCG) was established in 1976 through a Memorandum of Understanding between the Department of Agriculture and the Department of the Interior.” National Wildfire Coordinating Group, “About Us: NWCG History,” https://www.nwcg.gov/about-us (accessed August 25, 2024).
“>REF
Records show that most forest fires (including arson, unattended camp fires, discarded cigarettes, sparks from power lines or machinery, etc.) are started by people, whether intentionally or accidentally, and this has largely been true for hundreds of years in North America.<span class="annotation__highlight" data-annotation="
Glen MacDonald et al., “Drivers of California’s Changing Wildfires: A State-of-the-Knowledge Synthesis,” International Journal of Wildland Fire, Vol. 32, No. 7 (2023), pp. 1039–1058, https://www.researchgate.net/publication/370990037_Drivers_of_California%27s_changing_wildfires_a_state-of-the-knowledge_synthesis (accessed August 23, 2024); U.S. Department of Homeland Security, Federal Emergency Management Agency, U.S. Fire Administration, “Wildland Fires: A Historical Perspective,” Topical Fire Research Series, Vol. 1, No. 3 (October 2000; revised December 2001), pp. 8–12, https://www.govinfo.gov/content/pkg/GOVPUB-HS5-PURL-LPS124512/pdf/GOVPUB-HS5-PURL-LPS124512.pdf (accessed August 23, 2024); Marlon et al., “Long-Term Perspective on Wildfires in the Western USA.”
“>REF For example, a huge forest fire that blazed through Maine in the fall of 1825 was variously blamed on loggers burning slash piles, settlers using fire to clear farmland, and federal agents setting fire to the hay cut by illegal loggers as fodder for their draft animals, in part because such activities were known causes of forest fires at the time.<span class="annotation__highlight" data-annotation="
Alan MacEachern, “Firebreak: How the Maine–New Brunswick Border Defined the 1825 Miramichi Fire,” Forest History Today, Spring/Fall 2020, pp. 18–25, https://foresthistory.org/periodicals/spring-fall-2020/ (accessed August 25, 2024).
“>REF By 2021, 75 percent of wildfires in Oregon and Washington State were determined to be human-caused, up from the previous 10-year average of 64 percent.<span class="annotation__highlight" data-annotation="
U.S. Department of Agriculture, Forest Service, Pacific Northwest Region, “2021 Wildfire Summary,” May 2022, https://www.fs.usda.gov/Internet/FSE_DOCUMENTS/fseprd1103226.pdf (accessed August 25, 2024).
“>REF
Arson is a disturbing subset of human-caused wildland fires, and the deliberate intent that defines these fires can be difficult to detect and hard to prove. However, records show that arson was a serious issue in several southern U.S. states as early as the 1950s when 35 percent–50 percent of forest fires were judged to have been started deliberately.<span class="annotation__highlight" data-annotation="
Jeffrey P. Prestemon and David T. Butry, “Wildland Arson: A Research Assessment,” in Advances in Threat Assessment and Their Application to Forest and Rangeland Management, Volume 2, ed. John M. Pye et al., U.S. Department of Agriculture, Forest Service, Pacific Northwest Research Station, General Technical Report PNW-GTR-802, September 2010, pp. 271–283, https://www.fs.usda.gov/pnw/pubs/gtr802/Vol2/pnw_gtr802vol2.pdf (accessed August 25, 2024); Ed Kerr, “Southerners Who Set the Woods on Fire,” Harper’s Magazine, July 1958, pp. 28–33, https://harpers.org/archive/1958/07/southerners-who-set-the-woods-on-fire/ (accessed August 25, 2024); Macdonald et al., “Drivers of California’s Changing Wildfires: A State-of-the-Knowledge Synthesis;” Gemma Clark, “A Short History of Arson,” The Conversation, December 5, 2014, https://phys.org/news/2014-12-short-history-arson.html (accessed August 25, 2024).
“>REF More recently, one study has determined that about 86 percent of all fires in California since the 1990s have been caused by human activity; other studies put that number as high as 95 percent with perhaps 21 percent of these due to arson.<span class="annotation__highlight" data-annotation="
Sarah Gibbens, “Humans Cause over 95 Percent of California Wildfires,” National Geographic, August 10, 2018, https://www.nationalgeographic.com/environment/article/news-california-wildfire-arson-human-cause (accessed August 25, 2024); Kate Murphy and Erin Davis, “People Caused Most of California’s Wildfires over the Last 30 Years,” Axios, August 24, 2023, https://www.axios.com/local/san-diego/2023/08/24/california-wildfires-human-caused (accessed August 25, 2024). For fires set in 2019 and 2021, see Jessica Skropanic, “California Man Who Set 11 Fires in National Forest Sentenced to Two and [a] Half Years in Prison,” USA Today, February 14, 2023, https://www.usatoday.com/story/news/nation/2023/02/14/california-man-sentenced-arson-forest-fires/11256469002/ (accessed August 25, 2024); for a fire set in 2022, see Associated Press, “Man Arrested on Suspicion of Starting Northern California Fire that Burned More than 100 Homes,” June 16, 2023, https://apnews.com/article/california-deadly-forest-fire-arson-arrest-a134175f355c70edf906d5ec3209f58c (accessed August 25, 2024); for a fire set in 2021, see Rachel Treisman, “A Father and Son Were Arrested in Connection with California’s Massive Caldor Fire,” NPR, December 9, 2021, https://www.npr.org/2021/12/09/1062717505/father-son-arrested-reckless-arson-caldor-fire-northern-california (accessed August 25, 2024).
“>REF Because it takes so long for the judicial system to sort accidental fires from intentional ones, it will be years before we have any reliable data on whether arson fires have increased over the past decade. Nevertheless, research has shown that fires started by people are more ecologically destructive than naturally caused fires triggered by lightning because they are more likely to start on open, less-forested landscapes and on very dry days with gusty winds, which increase a fire’s intensity and ability to spread quickly.<span class="annotation__highlight" data-annotation="
Tess Joosse, “Human-Sparked Wildfires Are More Destructive than Those Caused by Nature,” Science, December 8, 2020, https://www.science.org/content/article/human-sparked-wildfires-are-more-destructive-those-caused-nature (accessed August 25, 2024); Stijn Hantson et al., “Human-Ignited Fires Result in More Extreme Fire Behavior and Ecosystem Impacts,” Nature Communications, Vol. 13 (2022), article no. 2717, https://doi.org/10.1038/s41467-022-30030-2 (accessed August 25, 2024).
“>REF
Some advocates have claimed that increased numbers of pest-killed trees caused by human-caused global warming have intensified recent fires, but it appears (as explained below) that purposeful changes in human behavior have been largely responsible for worsening infestations. Recent epidemics of forest pests—including the mountain pine beetle (Dendroctonus ponderosae); western pine beetle (Dendroctonus brevicomis); spruce beetle (Dendroctonus rufipennis); and western spruce budworm (Choristoneura feemani)—have devastated large woodland tracts across the contiguous U.S. over the past 40 years, but all of the evidence points to intentional shifts in forestry and wildfire-suppression practices as primary causal factors and reduced timber harvests and increased fire suppression as having had the greatest impact on wildfire behavior since 1980.
Tree Pest Infestations. The tree pests responsible for the recent loss of forest trees in the U.S. are largely native species gone rogue. Most are host-specific, which makes them ecosystem-specific: Mountain pine beetles attack lodgepole and ponderosa pines that are widespread across western North America, and spruce beetles go after Engelmann spruce that live in more isolated, high-elevation habitats across the western U.S. The southern pine beetle (Dendroctonus frontalis) is native to the southeastern U.S. and attacks pitch pines and red pines.<span class="annotation__highlight" data-annotation="
Brady Self, “Southern Pine Beetle in Mississippi: An Overview,” Mississippi State University Extension Service Publication 2748, 2022, http://extension.msstate.edu/publications/southern-pine-beetle-mississippi-overview (accessed August 25, 2024); D.A. Leatherman, I. Aguayo, and T.M. Mehall, “Mountain Pine Beetle,” Colorado State University Extension Insect Series Fact Sheet No. 5.528, revised September 2011, https://csfs.colostate.edu/wp-content/uploads/2024/01/Mountain-Pine-Beetle-Fact-Sheet-5.528.pdf (accessed August 25, 2024); Colorado State Forest Service, “Western Spruce Budworm,” Quick Guide Series No. FM 2016-2, 2016, https://csfs.colostate.edu/wp-content/uploads/2014/02/Western_Spruce_Budworm_QG_10May2016.pdf (accessed August 25, 2024).
“>REF
These destructive forest pests have been present in North America for millennia: Infestations are not a new phenomenon. Records show that epidemics of bark beetle infestations tend to occur every three to 15 years or so. In the past, severely cold winters capable of killing these pests have partly controlled severe infestations, which is why warmer winters due to human-caused climate change are often blamed for recent outbreaks, especially at higher altitudes and more northerly latitudes. While pest-killed trees do provide fuel for wildfires and are often said to be a major contributor to recent increases in forest fires, at least one study in the western U.S. has shown little overlap between these patches of dead trees and major, destructive fires.<span class="annotation__highlight" data-annotation="
Cheryl Katz, “Small Pests, Big Problems: The Global Spread of Bark Beetles,” Yale Environment 360, September 21, 2017, https://e360.yale.edu/features/small-pests-big-problems-the-global-spread-of-bark-beetles (accessed August 25, 2024); Corey Lesk et al., “Threats to North American Forests from Southern Pine Beetle with Warming Winters,” Nature Climate Change, Vol. 7, No. 10 (August 2017), pp. 713–717, https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7398402/ (accessed August 25, 2024); Christopher J. Fettig et al., “Trends in Bark Beetle Impacts in North America During a Period (2000–2020) of Rapid Environmental Change,” Journal of Forestry, Vol. 120, No. 6 (November 2022), pp. 693–713, https://doi.org/10.1093/jofore/fvac021 (accessed August 25, 2024); Sarah J. Hart et al., “Area Burned in the Western United States Is Unaffected by Recent Mountain Pine Beetle Outbreaks,” Proceedings of the National Academy of Sciences of the United States of America, Vol. 112, No. 14 (April 7, 2015), pp. 4375–4380, https://www.pnas.org/doi/epdf/10.1073/pnas.1424037112 (accessed August 23, 2024).
“>REF
The evidence shows that the trees most at risk for insect infestations are slow-growing individuals living in densely packed, mature timber stands, primarily because older trees produce less of the resins that help to rebuff pests in faster-growing young trees. Because these pests thrive on old trees and in forests where trees grow close to one another, reduced or abolished logging and increased fire suppression are considered primarily responsible for the recent phenomenon of bark beetles spreading farther, more rapidly, and more destructively than they did in the past.<span class="annotation__highlight" data-annotation="
Government of Canada, Environment and Climate Change Canada, Parks Canada, “Why Are There So Many Beetles Right Now?” last modified May 27, 2024, https://parks.canada.ca/docs/v-g/dpp-mpb/sec1/dpp-mpb1a (accessed August 23, 2024).
“>REF
Tree Diseases. Increases in infectious disease that afflict trees most often damage or weaken them, making them more susceptible to lethal insect infestation. While warmer winters and the stresses induced by heat and drought due to human-caused climate change have been blamed for an apparent increase in the incidence and spread of tree diseases in the U.S. in recent decades, some of the same causes of pest infestation discussed above also apply to the spread of disease. As discussed below, changes in forestry and fire-suppression practices since the 1980s almost certainly have increased the ability of tree diseases to spread more easily. And while drought can certainly make trees more susceptible to infection, most diseases need a certain level of humidity for survival and effective spread, which challenges the plausibility of predictions that we will see more adverse effects from tree diseases because of climate change over the coming decades.<span class="annotation__highlight" data-annotation="
CBC [Canadian Broadcasting Corporation] News, “Emerging Tree Diseases Are on the Rise, Threatening the Planet’s Largest Plants,” last updated October 12, 2023, https://www.cbc.ca/news/science/what-on-earth-tree-diseases-1.6993883 (accessed August 25, 2024); Andrew V. Gougherty, “Emerging Tree Diseases Are Accumulating Rapidly in the Native and Non-Native Ranges of Holarctic Trees,” NeoBiota, Vol. 87 (2023), pp. 143–160, https://www.fs.usda.gov/nrs/pubs/jrnl/2023/nrs_2023_gougherty_001.pdf (accessed August 25, 2024); Joan Dudney et al., “Nonlinear Shifts in Infectious Rust Disease Due to Climate Change,” Nature Communications, Vol. 12 (2021), article no. 5102, https://www.nature.com/articles/s41467-021-25182-6 (accessed August 25, 2024).
“>REF
Changes in Forestry Practices and Wildfire Suppression. Western U.S. forests live in close association with fire. They are dominated by trees in the family Pinaceae, which includes many commercially important species of pines, cedars, firs, hemlocks, larches, and spruces, as well as the giant redwoods and sequoias of California in the family Taxodiaceae. Their normal life cycle is for portions of the forest to burn down periodically, perhaps every 100 years or so, with regrowth afterwards. This effectively eliminates the old-growth forests that are so susceptible to catastrophic pest infestations.<span class="annotation__highlight" data-annotation="
Christopher J. Fettig et al., “Fire and Insect Interactions in North American Forests,” Current Forestry Reports, Vol. 8, No. 4 (August 2022), pp. 301–316, https://www.fs.usda.gov/psw/publications/fettig/psw_2022_fettig005.pdf (accessed August 25, 2024); “Summary for Policymakers” in Intergovernmental Panel on Climate Change, Climate Change 2022: Impacts, Adaptation and Vulnerability: Working Group II Contribution to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change, p. 27; Shuang Liang and Matthew D. Hurteau, “Novel Climate–Fire–Vegetation Interactions and Their Influence on Forest Ecosystems in the Western USA,” Functional Ecology, Vol. 37, No. 8 (August 2023), pp. 2126–2142, https://doi.org/10.1111/1365-2435.14263 (accessed August 23, 2024).
“>REF
Since the 1980s, the modern practice of suppressing low-intensity to moderate-intensity fires in such naturally fire-adapted ecosystems has been called “maladaptive actions” by the IPCC because they have unintentionally caused an increase in large-scale, high-intensity fires that adversely affect those ecosystems.<span class="annotation__highlight" data-annotation="
Intergovernmental Panel on Climate Change, Sixth Assessment Report, Working Group II—Impacts, Adaptation and Vulnerability, “Fact Sheet—North America.” See also Wehner et al., “Droughts, Floods, and Wildfires.”
“>REF When left to burn naturally, small to medium-sized wildfires generate a “patchwork forest” with trees of various ages and densities, making them much more resistant to heavy pest infestation and intense firestorms. Selective logging and burning of remnant fuel left after harvest (called “slash”), where it can be done and is permitted, has much the same effect.<span class="annotation__highlight" data-annotation="
Erin Blakemore, “Large Trees Fueled Massive Calif. Wildfire that Killed Giant Sequoias,” The Washington Post, October 1, 2023, https://www.washingtonpost.com/science/2023/10/01/old-large-trees-knp-wildfire-fuel (accessed August 23, 2024).
“>REF
Although the widespread suppression of low-intensity to moderate-intensity fires since the 1980s, together with severe restrictions on logging and slash burning, has been largely responsible for the recent increase in large-acreage, high-intensity fires in the western U.S., it has become apparent that better forest management would go a long way toward ameliorating this pattern.<span class="annotation__highlight" data-annotation="
MacDonald et al., “Drivers of California’s Changing Wildfires: A State-of-the-Knowledge Synthesis;” Audrey Odwuor et al., “Evidence for Multi-Decadal Fuel Buildup in a Large California Wildfire from Smoke Radiocarbon Measurements,” Environmental Research Letters, Vol. 18, No. 9 (September 2023), article no. 094030, https://iopscience.iop.org/article/10.1088/1748-9326/aced17/pdf (accessed August 23, 2024); Paul Driessen, “‘Climate Arson’ and Other Wildfire Nonsense,” Frontier Centre for Public Policy, October 27, 2020, https://fcpp.org/2020/10/27/climate-arson-and-other-wildfire-nonsense/ (accessed August 23, 2024); Nicolas Loris and Chandler Hubbard, “Look to Native Americans’ Forest Management for Better Wildfire Abatement,” Heritage Foundation Commentary, November 16, 2020, https://www.heritage.org/environment/commentary/look-native-americans-forest-management-better-wildfire-abatement.
“>REF
Hot, dry weather over the past two decades has been a contributing factor for increased wildfires in some regions and perhaps the primary factor in others, particularly in southern California shrublands and some steep, subalpine areas of the Rocky Mountains (Colorado and Wyoming) that have never been logged or exposed to fire-suppression activities. However, the increased incidence of accidental or deliberate human-caused ignition must also be factored in, including for remote back-country locations that may have been inaccessible in the past.<span class="annotation__highlight" data-annotation="
Philip E. Higuera, Bryan N. Shuman, and Kyra D. Wolf, “Rocky Mountain Subalpine Forests Now Burning More than Any Time in Recent Millennia,” Proceedings of the National Academy of Sciences of the United States of America, Vol. 118, No. 25 (June 14, 2021), article no. e2103135118, https://www.pnas.org/doi/epub/10.1073/pnas.2103135118 (accessed August 23, 2024); Jon E. Keeley, “Fire Management of California Shrubland Landscapes,” Environmental Management, Vol. 29, No. 3 (March 2002), pp. 395–408, https://doi.org/10.1007/s00267-001-0034-Y (accessed August 23, 2024).
“>REF
Conclusion
More frequent and severe droughts generated by human-caused increases in greenhouse gases are the primary concern for future U.S. forests, croplands, and rangelands, but drought is nothing new for these ecosystems: Drought conditions more severe than the catastrophe of the 1930s have occurred at least twice in the past 1,000 years and both times were due entirely to natural climatic variation. Any future droughts predicted based on increasing CO2 emissions seem unlikely to exceed these devastating conditions, and innovations in genetics and water management, as well as the fertilizing effects of CO2 itself, have effectively mitigated recent drought events associated with warmer temperatures and reduced rainfall. Yields of essential food crops like corn, rice, and wheat—considered to be the most at risk of calamitous failure—have increased since the 1960s despite continued increases in CO2. Similarly, because of improved management and biological innovation, soil erosion and invasive weeds on rangelands and croplands have been less of a problem than predicted as global temperatures have risen.
The extensive history of forest fires in the western U.S. shows that they have always increased in range and intensity when climatic conditions generated drought conditions: Recent severe fire incidents are nothing new. However, compared to the early 1900s when large tracts of forests last burned extensively, the early 21st century presents many more potential ignition triggers during times of drought. Despite this, careful analysis indicates that the apparent increase in fire severity since the 1980s is due primarily to recent restrictions on timber harvests and increased suppression of low-intensity and moderate-intensity fires rather than to increased global temperatures.
While almost all recent forest fires are ultimately human-caused, arson fires are a category apart. Blaming recent forest fires on climate change comes with a specific, unique risk. Sentiments conveyed through news and social media that recent forest fires are a frightening sign of climate change could motivate emotionally unstable activists to set fires deliberately as a way to garner media attention and send a stronger message to policymakers. Wildfires are exceptional in this regard: One individual could start several huge, destructive wildland fires without detection but cannot, for example, cause sea ice to decline or sea levels to rise.
Because a demonstrable link between recent fires and rising CO2 levels is tenuous at best, as the evidence presented in this Special Report shows, climate scientists and their supporters in the media should perhaps avoid labeling forest fires as a clear signal of human-caused climate change until the evidence supporting such a position is more convincing.
Susan J. Crockford, PhD, is a zoologist and evolutionary biologist for the private consulting company Pacific Identifications Inc.
