Jayant Sathaye scite author profile

Tropical deforestation is estimated to cause about one-quarter of anthropogenic carbon emissions, loss of biodiversity, and other environmental services. United Nations Framework Convention for Climate Change talks are now considering mechanisms for avoiding deforestation (AD), but the economic potential of AD has yet to be addressed. We use three economic models of global land use and management to analyze the potential contribution of AD activities to reduced greenhouse gas emissions. AD activities are found to be a competitive, low-cost abatement option. A program providing a 10% reduction in deforestation from 2005 to 2030 could provide 0.3-0.6 Gt (1 Gt ‫؍‬ 1 ؋ 10 5 g) CO2⅐yr ؊1 in emission reductions and would require $0.4 billion to $1.7 billion⅐yr ؊1 for 30 years. A 50% reduction in deforestation from 2005 to 2030 could provide 1.5-2.7 Gt CO 2⅐yr ؊1 in emission reductions and would require $17.2 billion to $28.0 billion⅐yr ؊1 . Finally, some caveats to the analysis that could increase costs of AD programs are described.carbon sequestration ͉ climate change ͉ reducing emissions from deforestation and ecosystem degradation (REDD) ͉ marginal cost ͉ tropical forest T ropical deforestation is considered the second largest source of greenhouse gas emissions (1) and is expected to remain a major emission source for the foreseeable future (2). Despite policy attention on reducing deforestation, Ϸ13 million ha⅐yr Ϫ1 of forests continue to be lost (3). Deforestation could have the effect of cooling the atmosphere (4), but it also leads to reductions in biodiversity, disturbed water regulation, and the destruction of livelihoods for many of the world's poorest (5). Slowing down, or even reversing, deforestation is complicated by multiple causal factors, including conversion for agricultural uses, infrastructure extension, wood extraction (6-9), agricultural product prices (10), and a complex set of additional institutional and place-specific factors (11).Avoided deforestation (AD) was included alongside afforestation as a potential mechanism to reduce net global carbon emissions in the Kyoto Protocol (KP), but until recently, climatepolicy discussions have focused on afforestation and forest management. Discussions about new financial mechanisms that include AD provide optimism for more effective synergies between forest conservation and carbon policies (11)(12)(13)(14). In 2005, Papua New Guinea and Costa Rica proposed to the United Nations Framework Convention on Climate Change that carbon credits be provided to protect existing native forests (15). The proposal triggered a flurry of discussion on the topic. SoaresFilho et al. (16), for example, suggest that protecting Ϸ130 million ha of land from deforestation in the Amazon could reduce global carbon emissions by 62 Gt (1 Gt ϭ 1 ϫ 10 15 g) CO 2 over the next 50 years.Although the potential for AD activities to help mitigate climate change is widely acknowledged (16,17), there is little information available on what the costs might be globally. This article uses t...

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Large historical changes of fossil‐fuel black carbon aerosols

Novakov

Ramanathan

Hansen

et al. 2003

Geophysical Research Letters

262

256

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Anthropogenic emissions of fine black carbon (BC) particles, the principal light‐absorbing atmospheric aerosol, have varied during the past century in response to changes of fossil‐fuel utilization, technology developments, and emission controls. We estimate historical trends of fossil‐fuel BC emissions in six regions that represent about two‐thirds of present day emissions and extrapolate these to global emissions from 1875 onward. Qualitative features in these trends show rapid increase in the latter part of the 1800s, the leveling off in the first half of the 1900s, and the re‐acceleration in the past 50 years as China and India developed. We find that historical changes of fuel utilization have caused large temporal change in aerosol absorption, and thus substantial change of aerosol single scatter albedo in some regions, which suggests that BC may have contributed to global temperature changes in the past century. This implies that the BC history needs to be represented realistically in climate change assessments.

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Renewable energy costs, potentials, barriers: Conceptual issues

et al. 2010

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Renewable Energy in the Context of Sustainable Development

Sathaye¹,

Lucon²,

Rahman³

et al. 2011

102

107

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Urban Energy Systems

et al.

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Jayant Sathaye

Global cost estimates of reducing carbon emissions through avoided deforestation

Large historical changes of fossil‐fuel black carbon aerosols

Renewable energy costs, potentials, barriers: Conceptual issues

Renewable Energy in the Context of Sustainable Development

Urban Energy Systems

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