Potential greenhouse gas reductions from Natural Climate Solutions in Oregon, USA

Graves, Rose A.; Haugo, Ryan D.; Holz, Andrés; Jones, Aaron M.; Kellogg, Bryce; MacDonald, Cathy; Popper, Kenneth J.; Schindel, Michael

doi:10.1371/journal.pone.0230424

Cited by 29 publications

(24 citation statements)

References 134 publications

(209 reference statements)

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“…These include the creation of green space, the mitigation of the urban heat island effect, cooling the environment, and the removal of air pollutants such as ozone and nitrogen dioxide (Alexandri and Jones 2008;Yang et al 2008;Bowler et al 2010;Baik et al 2012;Gago et al 2013;Berardi et al 2014;Feng and Hewage 2014;Nowak et al 2018;Sicard et al 2018;Gourdji 2018;Anderson and Gough 2020). The application of green infrastructure has proven effective in reducing GHG emissions and reducing ambient carbon dioxide concentrations (Berardi et al 2014;Alexandri and Jones 2008;Li et al, 2010;Marchi et al 2014;Bowler et al 2010;Hall et al 2012;Velasco et al, 2016;Fargione et al 2018;Graves et al 2020;Anderson and Gough 2020). For example, green roofing and green wall technologies reduce air pollutant concentrations resulting in urban cooling (Speak et al 2012;Kessler 2013;Anderson and Gough 2020).…”

Section: Literature Reviewmentioning

confidence: 99%

Nature-based cooling potential: a multi-type green infrastructure evaluation in Toronto, Ontario, Canada

Anderson

Gough

2021

Int J Biometeorol

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The application of green infrastructure presents an opportunity to mitigate rising temperatures using a multi-faceted ecosystems-based approach. A controlled field study in Toronto, Ontario, Canada, evaluates the impact of nature-based solutions on near surface air temperature regulation focusing on different applications of green infrastructure. A field campaign was undertaken over the course of two summers to measure the impact of green roofs, green walls, urban vegetation and forestry systems, and urban agriculture systems on near surface air temperature. This study demonstrates that multiple types of green infrastructure applications are beneficial in regulating near surface air temperature and are not limited to specific treatments. Widespread usage of green infrastructure could be a viable strategy to cool cities and improve urban climate.

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Section: Literature Reviewmentioning

confidence: 99%

Nature-based cooling potential: a multi-type green infrastructure evaluation in Toronto, Ontario, Canada

Anderson

Gough

2021

Int J Biometeorol

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“…A study on natural climate solutions in Oregon reports that practices associated with woody biomass generally have the greatest potential for increased sequestration and avoided emissions [ 5 ], which is consistent with CALAND. Forest restoration potential in Oregon (on average about -2.5 to -6 Mg CO 2 eq ha -1 yr -1 ) is on par with CALAND (-2.04 to -5.21 Mg CO 2 eq ha -1 yr -1 ), while deferred harvest has less potential than CALAND’s less intensive forest management.…”

Section: Resultsmentioning

confidence: 54%

“…Outside of California, but consistent with CALAND, practices associated with woody vegetation generally provide the greatest potential for reducing landscape carbon emissions, followed by avoided conversion of natural lands, and then either agricultural management or wetland restoration depending on the implementation area. In Oregon, regardless of implementation scenario, deferred timber harvest provides the greatest potential benefits, followed by reforestation and riparian restoration, and then agricultural management [ 5 ]. CALAND’s BAU estimates of these practices show a similar pattern ( Fig 8 ).…”

Section: Resultsmentioning

confidence: 99%

“…While the IPCC scenarios consider interactions and tradeoffs with other land dynamics, their global perspective limits specificity and circumvents regional and local limits to implementing land practices [3]. Studies that address practice-specific GHG benefits sum independent estimates, ignoring interactions and tradeoffs among practices, and rarely address other interactions related to land use and land cover change (LULCC), climate change, wildfire, biodiversity, and food security (e.g., [4][5][6]). While McGlynn and Chitkara [7] also use this type of independent accounting method for land contributions to GHG reductions in the United States, they thoroughly discuss the potential effects of interactions and tradeoffs and consider how unaccounted-for uncertainty decreases robustness of estimates.…”

Section: Introductionmentioning

confidence: 99%

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Quantifying the effects of multiple land management practices, land cover change, and wildfire on the California landscape carbon budget with an empirical model

2021

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The effectiveness of land-based climate mitigation strategies is generally estimated on a case-by-case basis without considering interactions with other strategies or influencing factors. Here we evaluate a new, comprehensive approach that incorporates interactions among multiple management strategies, land use/cover change, wildfire, and climate, although the potential effects of climate change are not evaluated in this study. The California natural and working lands carbon and greenhouse gas model (CALAND) indicates that summing individual practice estimates of greenhouse gas impacts may underestimate emission reduction benefits in comparison with an integrated estimate. Annual per-area estimates of the potential impact of specific management practices on landscape emissions can vary based on the estimation period, which can be problematic for extrapolating such estimates over space and time. Furthermore, the actual area of implementation is a primary factor in determining potential impacts of management on landscape emissions. Nonetheless, less intensive forest management, avoided conversion to urban land, and urban forest expansion generally create the largest annual per-area reductions, while meadow restoration and forest fuel reduction and harvest practices generally create the largest increases with respect to no management. CALAND also shows that data uncertainty is too high to determine whether California land is a source or a sink of carbon emissions, but that estimating effects of management with respect to a baseline provides valid results. Important sources of this uncertainty are initial carbon density, net ecosystem carbon accumulation rates, and land use/cover change data. The appropriate choice of baseline is critical for generating valid results.

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“…Spearheaded by Griscom et al (2017), NCS are intended to “increase carbon storage and avoid greenhouse gas emissions” via enhanced carbon sinks and other means (Fargione et al, 2018, p. 1). NCS have not been cited directly as adaptation tools, although climate resilience has been listed as one of the expected co‐benefits of their development, along with flood control, increased biodiversity, and soil health (Graves et al, 2020; Griscom et al, 2017; Griscom et al, 2020). Examples of NCS are thus concentrated on those actions that are both considered “natural” and that lead to the greatest mitigation effects—Griscom et al (2017) and Fargione et al (2018) have compiled fairly comprehensive lists of approximately 20 examples of NCS, including reforestation, coastal restoration, biochar, and cropland nutrient management (see Table 3).…”

Section: Defining “Natural” Solutionsmentioning

confidence: 99%

Framing “nature‐based” solutions to climate change

Osaka

Bellamy

Castree

2021

WIREs Climate Change

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In recent years, there has been a growth in scholarship on “nature‐based solutions” and “natural climate solutions” to climate change. A variety of actors have argued that these natural solutions—variously involving the protection, conservation, restoration, management, enhancement, or imitation of natural ecosystems—can play a crucial role in both mitigating and adapting to climate change. What is more, by virtue of their label, natural solutions promise to be particularly attractive to the public and policymakers and have received significant media and scholarly attention. But what is natural is also social: people, acting in various social groups, can selectively emphasize or deemphasize certain characteristics of climate solutions to make them seem more or less natural. The framing of particular solutions as “natural” or “unnatural” has far‐reaching implications for climate policy, but has thus far been overlooked. Here, we undertake a critical review of the ways in which natural solutions to climate change have been framed and examine the normative and practical implications of this framing. We review what counts (and what does not count) as a natural solution, and find that those labeled natural are routinely framed under technical and social appraisal criteria as being more beneficial, cost effective, mature, and democratic than ostensibly artificial counterparts. And yet we show that, under greater scrutiny, the natural framing obscures the reality that natural solutions can be just as risky, expensive, immature, and technocratic. We conclude by reflecting on the dangers of narrowing the range of solutions considered natural and indeed, of selecting solutions through recourse to “nature” at all. Rather, climate solutions must be evaluated in terms of their specific qualities, against a far broader range of framings. This article is categorized under: Social Status of Climate Change Knowledge > Knowledge and Practice

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Potential greenhouse gas reductions from Natural Climate Solutions in Oregon, USA

Cited by 29 publications

References 134 publications

Nature-based cooling potential: a multi-type green infrastructure evaluation in Toronto, Ontario, Canada

Nature-based cooling potential: a multi-type green infrastructure evaluation in Toronto, Ontario, Canada

Quantifying the effects of multiple land management practices, land cover change, and wildfire on the California landscape carbon budget with an empirical model

Framing “nature‐based” solutions to climate change

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