The Scope for Reducing Emissions from Forestry and Agriculture in the Brazilian Amazon
Abstract
:1. Introduction
- (1) Come with high biophysical potential for emission reductions;
- (2) Be adoptable at low opportunity costs and low risk of economic failure;
- (3) Be carried out at low implementation costs;
- (4) And disseminated with low risk of negative spillover effects, e.g., leakage.
2. Study Area, Methods and Data
3. Results
3.1. Biophysical Mitigation Potential
Status quo | REF | REF | BAU | BAU | BAU | BAU | BAU | ||
---|---|---|---|---|---|---|---|---|---|
Land use type | Primary forest | Secondary forest | Degraded logged forest | Fallow-based annual cropping under S&B | Extensive pasture | Till continuous annual monoculture | Non-tree perennial cropping systems* | ||
Category | F | F | F | AG | AG | AG | AG | ||
Above ground C (Δ against forest)1 | 160 | (−56%) | (−48%) | (−94%) | (−98%) | (−98%) | (−97%) | ||
Below-ground C (Δ against forest) | 197 | (~) | (~) | (~) | (+/−) | (−) | (−) | ||
Other GHG emissions | - | - | Decay + post-harvest | Fire use, decay, post-harvest | Fire use, enteric fermentation, post-cull | Fossil fuel use, nitrification, post-harvest | Nitrification, post-harvest | ||
ALT | Primary forest conservation | F | - | - | +AC+BC−OE | +AC+BC−OE | +AC+BC−OE | +AC+BC−OE | +AC+BC−OE |
ALT | Set-aside land for forest restoration | F | - | - | +AC+BC−OE | +AC+BC−OE | +AC+BC−OE | +AC+BC−OE | +AC+BC−OE |
TREND | No-till continuous annual monoculture | AG | −AC−BC+OE | −AC−BC+OE | −AC−BC+OE | −AC−BC−OE | −AC−BC~OE | +AC+BC−OE | −AC−BC~OE |
TREND | Integrated crop-pasture systems | AG | −AC−BC+OE | −AC−BC+OE | −AC−BC+OE | −AC−BC−OE | ~AC−BC~OE | +AC+BC−OE | −AC−BC~OE |
ALT | Fire-free fallow-based annual cropping | AG | −AC−BC+OE | −AC−BC+OE | −AC−BC+OE | +AC~BC−OE | +AC+BC~OE | +AC+BC−OE | +AC+BC~OE |
ALT | Intensified pastures | AG | −AC−BC+OE | −AC−BC+OE | −AC−BC+OE | −AC~BC−OE | +AC+BC−OE | +AC+BC−OE | −AC−BC~OE |
ALT | No-till continuous Multi-crop systems | AG | −AC−BC+OE | −AC−BC+OE | −AC−BC+OE | −AC~BC−OE | ~AC−BC~OE | +AC+BC~OE | −AC−BC~OE |
ALT | Agro-forestry | AG/F | −AC−BC+OE | ~AC~BC+OE | −AC−BC+OE | +AC~BC−OE | +AC+BC−OE | +AC+BC−OE | +AC+BC~OE |
ALT/TREND | Tree/Fruit tree systems | F | −AC−BC+OE | ~AC~BC+OE | −AC−BC+OE | +AC~BC−OE | +AC+BC~OE | +AC+BC−OE | +AC+BC~OE |
ALT | Sustainable forest management | F | −AC−BC+OE | ~AC~BC+OE | +AC+BC−OE | - | - | - | - |
Alt/TREND | Afforestation/Reforestation for timber | F | ~AC−BC+OE | ~AC~BC+OE | +AC+BC−OE | +AC+BC−OE | +AC+BC−OE | +AC+BC−OE |
3.2. Opportunity Costs and Other Adoption Barriers
3.2.1. Opportunity Costs
Status quo | BAU | BAU | BAU | BAU | |
---|---|---|---|---|---|
Land-use type | Degraded logged forest | Fallow-based annual cropping under S&B | Extensive pasture | Till continuous annual monoculture | |
US$ NPV/ha | - | 206 | 39–59 | 171 | |
ALT | Primary forest conservation | - | - | - | - |
ALT | Set-aside land for forest restoration | - | - | - | - |
TREND | No-till continuous annual monoculture | - | - | - | TC |
TREND | Integrated crop-pasture systems | - | - | - | TC++ |
ALT | Fire-free fallow-based annual cropping | - | TC | - | - |
ALT | Intensified pastures | - | - | TC+ | TC++ |
ALT | No-till continuous Multi-crop systems | - | - | - | TC+ |
ALT | Agro-forestry | - | TC++ | TC++ | TC++ |
ALT/TREND | Tree/Fruit tree-based systems | - | TC++ | TC++ | TC++ |
ALT | Sustainable forest management | TC | - | - | - |
TREND | Afforestation/Reforestation for timber | - | TC++ | TC++ | TC++ |
3.2.2. Other Adoption Obstacles
3.3. Policy Implementation Costs
3.3.1. Intervention Context
3.3.2. Technological Complexity
3.4. Economic and Environmental Spillover Risks
4. Discussion and Conclusions
Mitigation option | Bio-physical mitigation potential per ha (BP) | Opportunity costs (OC) | Implementation cost (IC) | Leakage and spillover effects (L) |
---|---|---|---|---|
Primary forest conservation | Very high at most forest frontiers | Many low cost options | Low technological complexity, but high operational costs at new frontiers | High leakage risk |
Retiring extensive pastures | High | Low cost options, especially where pastures are degraded | Low technological complexity and low operational costs in old frontiers | High leakage risk |
Sustainable forest management | Medium to high depending on BAU | Medium under currently low prices for certified timber | High technological complexity and high operational costs at new frontiers | Low |
Reforesting extensive pastures | High | Low or negative depending on species choice and risk profile | Medium to high technological complexity and low operational costs in old frontier areas | Medium |
Intensifying extensive pastures | Medium | Low to medium depending on state of existing pastures | Low to medium technological complexity and low operational costs in old frontiers areas | Low |
Integrating trees in crops and pastures | Medium to high depending on tree density | Low or negative depending on tree species and market access | Medium to high technological complexity and low operational costs in old frontier areas | Low |
Avoiding fire use in annual crop production | Medium to high | Medium depending on crop types and risk profiles | Low to medium technological complexity and low operational costs in old frontiers areas | Low |
Acknowledgments
Conflict of Interest
References and Notes
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Börner, J.; Wunder, S. The Scope for Reducing Emissions from Forestry and Agriculture in the Brazilian Amazon. Forests 2012, 3, 546-572. https://doi.org/10.3390/f3030546
Börner J, Wunder S. The Scope for Reducing Emissions from Forestry and Agriculture in the Brazilian Amazon. Forests. 2012; 3(3):546-572. https://doi.org/10.3390/f3030546
Chicago/Turabian StyleBörner, Jan, and Sven Wunder. 2012. "The Scope for Reducing Emissions from Forestry and Agriculture in the Brazilian Amazon" Forests 3, no. 3: 546-572. https://doi.org/10.3390/f3030546