International climate change negotiation: the role of Brazil
Marcela Cardoso Guilles da Conceiçãoa Renato Aragão Ribeiro Rodriguesb Fernanda Reis Cordeiroc Fernando Vieira Cesáriod Gracie Verde Selvae Carolinna Mariaf Eduardo da Silva Matosg Renato Campello Cordeiroh Edison Dausacker Bidonei
10.18472/SustDeb.v10n3.2019.27962
The increase of greenhouse gases in the atmosphere raises the average temperature of the planet, triggering problems that threaten the survival of humans. Protecting the global climate from the effects of climate change is an essential condition for sustaining life. For this reason, governments, scientists, and society are joining forces to propose better solutions that could well-rounded environmentally, social and economic development relationships. International climate change negotiations involve many countries in establishing strategies to mitigate the problem. Therefore, understanding international negotiation processes and how ratified agreements impact a country is of fundamental importance. The purpose of this paper is to systematize information about how climate negotiations have progressed, detailing key moments and results, analyzing the role that Brazil played in the course of these negotiations and the country’s future perspectives.
Changes in Soil Carbon Stocks under Integrated Crop-Livestock-Forest System in the Brazilian Amazon Region
Marcela C. G. da Conceição1, Eduardo S. Matos2*, Edison D. Bidone1, Renato de A. R. Rodrigues3, Renato C. Cordeiro1
https://doi.org/10.4236/as.2017.89066
Several studies indicate that the use of integrated production systems, such as integrated crop-livestock-forest systems (ICLF), improves the quality of the soil and consequently the sequestration of organic carbon in the soil. In this way, this work aims to evaluate the carbon stocks in soil under different management systems in the Cerrado/Amazonia transition zone, namely: ICLF, no-tillage, pasture and eucalyptus plantation. For this, two soil sam- plings were done in 2011 and 2014, in the 0 – 5, 5 – 10 and 10 – 30 cm layers. Soil carbon and nitrogen stocks were analyzed. ICLF system was the treatment that obtained the highest percentage of carbon gain (7.8%) after three years of establishment which represents to an increase of 5.5 Mg·ha−1. Management systems, such as ICLF, with minimal soil disturbance combined with crop ro- tations that contribute to the quantity and quality of residues input, increase soil organic matter content. Carbon stock data show the potential of ICLF systems to increase soil carbon stocks.
Climate-related land use policies in Brazil: How much has been achieved with economic incentives in agriculture?
Marcelo Carauta a, Christian Troost a, Ivan Guzman-Bustamante b, Anna Hampf c, Affonso Libera d, Katharina Meurer e, Eric Bo ̈necke f, Uwe Franko g, Renato de Araga ̃o Ribeiro Rodriguesh, Thomas Bergera,*
https://doi.org/10.1016/j.landusepol.2021.105618
Until 2019, the Brazilian federal government employed a number of policy measures to fulfill the pledge of reducing greenhouse gas emissions from land use change and agriculture. While its forest law enforcement strategy was partially successful in combating illegal deforestation, the effectiveness of positive incentive mea- sures in agriculture has been less clear. The reason is that emissions reduction from market-based incentives such as the Brazilian Low-Carbon Agriculture Plan cannot be easily verified with current remote sensing monitoring approaches. Farmers have adopted a large variety of integrated land-use systems of crop, livestock and forestry with highly diverse per-hectare carbon balances. Their responses to policy incentives were largely driven by cost and benefit considerations at the farm level and not necessarily aligned with federal environmental objectives. This article analyzes climate-related land-use policies in the state of Mato Grosso, where highly mechanized soybean–cotton and soybean–maize cropping systems prevail. We employ agent-based bioeconomic simulation together with life-cycle assessment to explicitly capture the heterogeneity of farm-level costs, benefits of adoption, and greenhouse gas emissions. Our analysis confirms previous assessments but suggests a smaller farmer policy response when measured as increase in area of integrated systems. In terms of net carbon balances, our simulation results indicate that mitigation effects at the farm level depended heavily on the exact type of livestock and grazing system. The available data were insufficient to rule out even adverse effects. The Brazilian experience thus offers lessons for other land-rich countries that build their climate mitigation policies on eco- nomic incentives in agriculture.
Soil CO2 emission in ‘Tifton 85’ bermudagrass pasture fertilized with liquid pig slurry
Adilson Amorim Brandão1*, Eduardo Guimarães Couto2, Renato de Aragão Ribeiro Rodrigues3, Oscarlina Lúcia dos Santos Weber2, Osvaldo Borges Pinto Júnior4
10.21475/ajcs.21.15.05.p2959
The application of liquid pig slurry (LPS) to pastures offers potential as a fertilizer but could have a direct influence on soil CO2 emissions. This study evaluated soil carbon dioxide emissions after successive LPS applications to soils under pasture cultivation. The experiment was carried out on ‘Tifton-85’ bermudagrass pasture cultivated in a red-yellow oxisol soil in the municipality of Lucas do Rio Verde-MT, Brazil. Two treatments were evaluated: the control and an application of 20 m3 ha-1 of LPS after each cut of the pasture. The CO2 emissions from the soil were determined using a high-precision infrared gas analyzer. Soil temperature and soil moisture were determined as were micrometeorological variables. The application of LPS had a significant effect on soil C-CO2 flow. The average flow of C-CO2 from the soil for the control treatment and with the application of LPS was 0.236 g C-CO2 m-2 h-1 and 0.291 g C-CO2 m-2 h-1, respectively. The application of LPS increased the accumulated CO2 emissions from the soil by 23.2%. Soil temperature and moisture are the main factors regulating the process of soil CO2 emission. These factors therefore need to be considered when evaluating the impact of LPS application on greenhouse gas emissions.
Greenhouse gas emission from the soils fertilized with liquid pig slurry (LPS) in Tifton 85 bermudagrass pasture in tropical savanna
Adilson Amorim Brandão1*, Eduardo Guimarães Couto2, Renato de Aragão Ribeiro Rodrigues3, Oscarlina Lúcia Santos Weber2, Osvaldo Borges Pinto Júnior4
10.21475/ajcs.20.14.06.p2582
Abstract
Soils have important roles in the global budgets of the greenhouse gases. The liquid pig slurry (LPS) in pastures has high potential as a fertilizer but could have a direct influence on emission of greenhouse gasses. This study evaluated the effects of the application of LPS and inorganic mineral fertilization during the rainy and dry seasons on the emissions of CO2, CH4 and N2O in pastures planted with Tifton-85. The following treatments were tested: Control – no fertilization; LPS30 – 30 m3 ha-1; LPS60 – 60 m3 ha-1; LPS90 – 90 m3 ha-1 and inorganic mineral fertilization. Gasses were sampled using static chambers first during the months of March and April, then in June and July. Fertilization with LPS caused an increase in the flux of CO2 and CH4 during the first hours after its application, and CO2 emissions are greater during the rainy than in the dry season. However, the application of LPS in Tifton-85 pasture during rainy periods did not show high potential for emission of CO2, in contrast to application during the dry season. Fertilization with LPS increases the emission of N2O, and this varies as a function of the volume of LPS applied and the experimental conditions experimental conditions. The application of LPS in Tifton-85 pasture has a high potential for N2O emission during the rainy season, but the magnitude is similar to that resulting from inorganic mineral fertilization.
Simulation of soil carbon changes due to conventional systems in the semi-arid region of Brazil: adaptation and validation of the century model
Renato Américo de Araújo Neto, Stoécio Malta Ferreira Maia, Tiago Diniz Althoff, Carlos Eduardo Pellegrino Cerri, Andre Luiz de Carvalho & Romulo Simões Cezar Menezes
https://doi.org/10.1080/17583004.2021.1962978
Soils play an important role on the global carbon cycle, but conventional land use practices generate negative impact by reducing soil organic carbon (SOC) content. Studies regarding the use of mathematical models on the magnitude of such impacts are scarce in semi-arid regions, but they are essential to broaden the understanding of the effects of cropping systems and help in proposing more rational land use alternatives. However, mathematical models (e.g. Century) must be previously calibrated and validated to present satisfactory results. Therefore, the aim of the present study was to validate the Century model for simulating SOC dynamics in areas of native vegetation and estimating SOC stocks on the adoption of agricultural systems in the semi-arid region of Brazil with a previous calibrated model. The study was carried out in three soil types (Quartzipsamments, Psamments and Ultisol), located in the state of Alagoas, north-eastern Brazil, adopting conventional (with minimal use of machinery) agricultural land-use practices under rainfed conditions. Simulations consisted of validating the model with previously calibrated parameters from another area of the Brazilian semi-arid region. The results showed that the model proved to be effective in simulating SOC dynamics in areas of native vegetation in the semi-arid region of Alagoas (PBIAS ranging from 20 to −9%); however, it needs further adjustment for satisfactory SOC simulation in agricultural/pasture systems. The results showed that conventional systems of agricultural crops and pasture in the semi-arid region of Brazil lead to losses (2673 g C m−2 in native vegetation to 1960 g C m−2 in conventional systems) between 22% and 35%, (PBIAS variating −9 to 49%) and that SOC stocks reach a new steady state between 30 and 40 years after conversion from native vegetation into agriculture (ranging from 24 to 42% in different soil types).
Losses and gains of soil organic carbon in grasslands in the Brazilian semi-arid region
Aldair de Souza Medeiros1* , Stoécio Malta Ferreira Maia2 , Thiago Cândido dos Santos1 , Tâmara Cláudia de Araújo Gomes3
http://dx.doi.org/10.1590/1678-992X-2019-0076
ABSTRACT: Studies show that soil organic carbon (SOC) decreases between 3 % and 9 % in degraded grasslands in tropical regions, mainly due to the absence of techniques to enhance carbon contribution to soils. This study assessed SOC stock change factors for grassland management, specific to the semi-arid region of Brazil. These factors may contribute to a better understanding of SOC dynamics and could be used to improve inventories on GHG emissions. In addition, they could be used for updating default factors used by the Intergovernmental Panel on Climate Change. This study considers both soil sampling and a literature review, and comprises 27 paired comparisons, where the dataset was analyzed using a mixed linear model. For the grassland in the Brazilian semi-arid region, the SOC stock is reduced by between 12 % and 27 % due to inadequate management, overgrazing, and edaphoclimatic conditions of the Brazilian semiarid. However, this depends on aspects, such as land use and soil layer, which represents substantially more severe losses than in other regions of the country. We also found that losses occur during the first five years after conversion of native vegetation. The results also indicated a trend for SOC stocks to recover over time, reaching 4 % after 30 years of use as grassland, probably related to the long period without soil tillage and the role of gramineas root system. Keywords: Caatinga, soil organic matter, management factors, degraded grasslands
2021_Medeiros et al. 2021 (Pastagem)
Soil carbon losses in conventional farming systems due to land-use change in T the Brazilian semi-arid region
Aldair de Souza Medeiros, Stoécio Malta Ferreira Maia,⁎, Thiago Cândido dos Santos, Tâmara Cláudia de Araújo Gomes
Agriculture, Ecosystems and Environment
https://doi.org/10.1016/j.agee.2019.106690
Soil carbon losses in conventional farming systems due to land-use change in T the Brazilian semi-arid region
Conventional farming systems reduce soil organic carbon (SOC) stocks in tropical regions, predisposing these soils to emit CO2 to the atmosphere. However, studies conducted worldwide have shown that the magnitude of these losses depends on the management practices adopted as well as climate and soil conditions; thus, accu- rately quantifying these SOC changes can be a major challenge. In this regard, the aim of this study was to derive specific SOC stock change factors for conventional farming systems in the semi-arid region of Brazil and to evaluate the impacts caused by the conventional systems of annual crops throughout time and soil profile on SOC stocks in this region. A total of 66 pairs of comparisons were used, and datasets were analyzed through a mixed linear model. Conventional systems with annual crops reduced the SOC stocks by 17, 13 and 4% for the 0–30, 0–50 and 0–100 cm soil layers, respectively, and for the period of 20 years of land use change. The SOC losses increased with the crop period, since the land-use change factors derived for 40 years showed a decrease of 26, 22 and 13% for the 0–30, 0–50, and 0–100 cm soil layers, respectively, when compared to the SOC stocks in native vegetation.
Can forests buffer negative impacts of land-use and climate changes on water ecosystem services? The case of a Brazilian megalopolis
Desagregação setorial do balanço energético nacional a partir dos dados da matriz insumo-produto: uma avaliação metodológica
MONTOYA, M. A.; LOPES, R. L.; GUILHOTO, J. J. M.
Economia Aplicada (Impresso), v. 18, p. 379-419, 2014
http://dx.doi.org/10.1590/1413-8050/ea463
Brasil, Insumo-Produto, Matriz Energética,
O artigo propõe e avalia três metodologias para estimar matrizes energéticas nacionais mais desagregadas a partir dos dados da matriz insumo-produto (MIP). Para avaliar os resultados, foram construídas três matrizes insumo-produto híbridas. As análises de correlação e de acuidade dos multiplicadores, índices de ligação setoriais, requerimentos de energia e emissões de CO2 mostraram convergência de resultados nos métodos Base BEN e Base MIP Ajustada. Conclui-se, portanto, que o uso de coeficientes insumo-produto, como ponderadores de expansão do consumo setorial de energia, permite estimar matrizes energéticas consistentes e que são válidas as análises estruturais da economia realizadas com base nelas.