Public-private partnerships in renewable energy in Latin America and the Caribbean

Incluye Bibliografía

Proposta de metodologia para análise de eficiência hidro-energética e ambiental: estudo de caso da agroindústria

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)

Pervasive transition of the Brazilian land-use system

Agriculture, deforestation, greenhouse gas emissions and local/regional climate change have been closely intertwined in Brazil. Recent studies show that this relationship has been changing since the mid 2000s, with the burgeoning intensification and commoditization of Brazilian agriculture. On one hand, this accrues considerable environmental dividends including a pronounced reduction in deforestation (which is becoming decoupled from agricultural production), resulting in a decrease of similar to 40% in nationwide greenhouse gas emissions since 2005, and a potential cooling of the climate at the local scale. On the other hand, these changes in the land-use system further reinforce the long-established inequality in land ownership, contributing to rural-urban migration that ultimately fuels haphazard expansion of urban areas. We argue that strong enforcement of sector-oriented policies and solving long-standing land tenure problems, rather than simply waiting for market self-regulation, are key steps to buffer the detrimental effects of agricultural intensification at the forefront of a sustainable pathway for land use in Brazil.

Modelling energy utilization in poultry

Models of daily energy requirement can help to establish better and more profitable feeding programs for poultry. Studies have been conducted at UNESP-Jaboticabal-Brazil with the aim of studying energy utilization in broiler breeders, laying hens, and broilers, and to establish metabolisable energy requirement models. The factorial approach was used to partition the energy requirements into maintenance, growth, and production components. The resulting models consider body weight, weight gain, egg production, and environmental temperature for the determination of the energy requirements of poultry. These models were evaluated in performance trials and provided good estimates. Therefore, they can be used to establish nutritional programs. The aim of this chapter is to describe the development of these models and to outline the results of our studies at UNESP.

Life cycle assessment of biofuels produced by the new integrated hydropyrolysis-hydroconversion (IH2) process

Biofuels are alternative fuels that have the promise of reducing reliance on imported fossil fuels and decreasing emission of greenhouse gases from energy consumption. This thesis analyses the environmental impacts focusing on the greenhouse gas (GHG) emissions associated with the production and delivery of biofuel using the new Integrated Hydropyrolysis and Hydroconversion (IH2) process. The IH2 process is an innovative process for the conversion of woody biomass into hydrocarbon liquid transportation fuels in the range of gasoline and diesel. A cradle-to-grave life cycle assessment (LCA) was used to calculate the greenhouse gas emissions associated with diverse feedstocks production systems and delivery to the IH2 facility plus producing and using these new renewable liquid fuels. The biomass feedstocks analyzed include algae (microalgae), bagasse from a sugar cane-producing locations such as Brazil or extreme southern US, corn stover from Midwest US locations, and forest feedstocks from a northern Wisconsin location. The life cycle greenhouse gas (GHG) emissions savings of 58%–98% were calculated for IH2 gasoline and diesel production and combustion use in vehicles compared to fossil fuels. The range of savings is due to different biomass feedstocks and transportation modes and distances. Different scenarios were conducted to understand the uncertainties in certain input data to the LCA model, particularly in the feedstock production section, the IH2 biofuel production section, and transportation sections.

Leakage of nitrous oxide emissions within the Spanish agro-food system in 1961-2009

Abstract In this paper we examine the trends of nitrous oxide (N2O) emissions of the Spanish agricultural sector related to national production and consumption in the 1961?2009 period.The comparison between production- and consumption-based emissions at the national level provides a complete overview of the actual impact resulting from the dietary choices of a given country and allows the evaluation of potential emission leakages. On average, 1.5 % of the new reactive nitrogen that enters Spain every year is emitted as N2O. Production- and consumption-based emissions have both significantly increased in the period studied and nowadays consumption-based emissions are 45 % higher than production-based emissions. A large proportion of the net N2O emissions associated with imported agricultural godos comes from countries that are not committers for the United Nations Framework Convention on Climate Change Kyoto Protocol Annex I. An increase in feed consumption is the main driver of the changes observed, leading to a arkable emission leakage in the Spanish agricultural sector. The complementary approach used here is essential to achieve an effective mitigation of Spanish greenhouse gas emissions.

Sostenibilidad en el sector de la construcción. Sostenibilidad en estructuras y puentes ferroviarios

La escasez de recursos, el cambio climático, la pobreza y el subdesarrollo, los desastres naturales, son solo algunos de los grandes retos a que se enfrenta la humanidad y a los que la economía verde y el desarrollo sostenible tienen que dar respuesta. El concepto sostenible surge a raíz de la necesidad de lograr en todas las actividades humanas un nuevo equilibrio con el medioambiente, la sociedad y la economía, es decir un desarrollo más sostenible. La construcción supone en este nuevo concepto un sector básico, con grandes impactos en los recursos, los residuos, las emisiones, la biodiversidad, el paisaje, las necesidades sociales, la integración, el desarrollo económico del entorno, etc. Es por ello, que la construcción sostenible tiene una importancia esencial como demuestra su amplia aplicación teórica y práctica ya en proyectos de planificación urbana y de edificación. En la ingeniería civil estas aproximaciones son todavía mínimas, aunque ya se están considerando ciertos criterios de sostenibilidad en proyectos de construcción. La construcción consume muchos recursos naturales, económicos y tiene gran incidencia social. En la actualidad su actividad consume un 30% de los recursos extraídos de la tierra y la energía, y en consecuencia genera el 30% de los gases de efecto invernadero y residuos sólidos del mundo (EEA, 2014). Este impacto debería suponer una gran responsabilidad para los profesionales y gobiernos que toman cada día las decisiones de diseño e inversión en la construcción, y su máxima eficiencia debería estar muy presente entre los objetivos. En esta tesis doctoral se plantea un nuevo modelo para la evaluación de la sostenibilidad en los proyectos mediante un sistema de indicadores, basados en las áreas de estudio de las certificaciones de sostenibilidad existentes y en un análisis multi-criterio de cada uno de los axiomas de la sostenibilidad. Como reto principal se marca la propuesta de una metodología que permita identificar, priorizar y seleccionar los indicadores y las variables más importantes de lo que es considerado como una construcción sostenible en el caso de infraestructuras ferroviarias, más concretamente en puentes ferroviarios, y que además sirva para priorizar nuevos proyectos que se adapten a los nuevos objetivos del desarrollo sostenible: el respeto al medioambiente, la integración social y la económica. El objetivo es la aplicación de estos indicadores desde las etapas más tempranas del proyecto: planificación, diseño de alternativas y selección de alternativas. Para ello, en primer lugar, se ha realizado un análisis en profundidad de los distintas organizaciones de certificación de la sostenibilidad mundiales y se ha desarrollado una comparativa entre ellas, detallando el funcionamiento de las más extendidas (BREEAM, LEED, VERDE, DGNB). Tras esto, se ha analizado la herramienta matemática MIVES de análisis multi-criterio para su aplicación, en la tesis, a las infraestructuras ferroviarias. En la segunda parte se desarrolla para las estructuras ferroviarias un nuevo modelo de indicadores, un sistema de ayuda a la decisión multi-criterio basado en los tres axiomas de las sostenibilidad (sociedad, medioambiente y economía), articulados en un árbol de requerimientos inspirado en el método MIVES, que propone una metodología para el caso de las infraestructuras ferroviarias. La metodología MIVES estructura el proceso de decisión en tres ramas: Requisitos, componentes y ciclo de vida. Estas ramas definen los límites de los sistemas. El eje de los requisitos del árbol de los requisitos o se estructura en tres niveles que corresponden al requisito específico: criterios e indicadores. Además, es necesario definen la función del valor para cada indicador, definen el peso de importancia de cada elemento del árbol y finalmente con el calcular el valor de cada alternativa selecciona el mejor de él. La generación de este árbol de requerimientos en estructuras ferroviarias y la medición de los parámetro es original para este tipo de estructuras. Por último, tras el desarrollo de la metodología, se ha aplicado la propuesta metodológica mediante la implementación práctica, utilizando el método propuesto con 2 puentes ferroviarios existentes. Los resultados han mostrado que la herramienta es capaz de establecer una ordenación de las actuaciones coherente y suficientemente discriminante como para que el decisor no tenga dudas cuando deba tomar la decisión. Esta fase, es una de las grandes aportaciones de la tesis, ya que permite diferenciar los pesos obtenidos en cada una de las áreas de estudio y donde la toma de decisión puede variar dependiendo de las necesidades del decisor, la ubicación del puente de estudio etc. ABSTRACT Scarce resources, climate change, poverty and underdevelopment, natural disasters are just some of the great challenges facing humanity and to which the green economy will have to respond. The sustainable concept arises from the need for all human activities in a new equilibrium with the environment, society and the economy, which is known as sustainable development. The construction industry is part of this concept, because of its major impacts on resources, waste, emissions, biodiversity, landscape, social needs, integration, economical development, environment, etc. Therefore, sustainable construction has a critical importance as already demonstrated by its wide application and theoretical practice in urban planning and building projects. In civil engineering, these approaches are still minimal, although some criteria are already taken into account for sustainability in infrastructure projects. The construction industry requires a lot of natural resources, has a real economic relevance and a huge social impact. Currently, it consumes 40% of produced power as well as natural resources extracted from the earth and thus leads to an environmental impact of 40% regarding greenhouse gas emissions and solid wastes (EEA 2014). These repercussions should highly concern our governments and professional of this industry on the decisions they take regarding investments and designs. They must be inflexible in order to ensure that the main concern has to be a maximum efficiency. Major events like the COP21 held in Paris in December 2015 are a concrete signal of the worldwide awareness of the huge impact of each industry on climate. In this doctoral thesis a new model for the evaluation of the sustainability in the projects by means of a system of indicators, based on the areas of study of the existing certifications of sustainability and on an analysis considers multi-criterion of each one of the axioms of the sustainability. The primary aim of this thesis is to study the mode of application of sustainability in projects through a system of indicators. . The main challenge consists of create a methodology suitable to identify, prioritize and select the most important indicators which define if a building is sustainable in the specific case of railway infrastructures. The methodology will help to adapt future projects to the new goals of sustainable development which are respect of nature, social integration and economic relevance. A crucial point is the consideration of these indicators from the very beginning steps of the projects: planning, design and alternatives reflections. First of all, a complete inventory of all world energy certification organizations has been made in order to compare the most representative ones regarding their way of functioning (BREEAM, LEED, VERDE, DGNB). After this, mathematical tool MIVES of analysis has been analyzed multi-criterion for its application, in the thesis, to railway infrastructures. The second part of the thesis is aimed to develop a new model of indicators, inspired by the MIVES method, consisting in a decision-making system based on the 3 foundations of sustainability: nature impact, social concerns, and economic relevance. The methodology MIVES structures the decision process in three axes: Requirements, components and life cycle. These axes define the boundaries of the systems. The axis of requirements o tree requirements is structured in three levels corresponding to specific requirement: criteria and indicators. In addition, is necessary define the value function for each indicator, define the weight of importance of each element of the tree and finally with the calculate the value of each alternative select the best of them. The generation of this tree requirements in railway structures and measuring the parameter is original for this type of structures. Finally, after the development of the methodology, it has validated the methodology through practical implementation, applying the proposed method 2 existing railway bridges. The results showed that the tool is able to establish a coherent management of performances and discriminating enough so that the decision maker should not have doubts when making the decision. This phase, is one of the great contributions of the thesis, since it allows to differentiate the weights obtained in each one from the study areas and where the decision making can vary depending on the necessities of the decisor, the location of the bridge of study etc.

Impactos de regulações ambientais sobre o transporte de cargas no Brasil: uma análise para o transporte de soja

O aumento da concentração de gases de efeito estufa na atmosfera levou a uma preocupação de como se reduzir as emissões destes gases. Desta preocupação surgiram instrumentos de regulação a fim de reduzir ou controlar os níveis de poluição. Dentro deste contexto, esta pesquisa analisou o setor de transportes de cargas, com ênfase no transporte de soja. No Brasil, o setor de transportes é um dos principais responsáveis pelas emissões de gases de efeito estufa provenientes da queima de combustíveis fósseis. No setor de transportes, as emissões diferem entre os modais, sendo que as ferrovias e hidrovias poluem menos que as rodovias. Desta forma, simulou-se por meio de um modelo de programação linear se a adoção de medidas regulatórias sobre as emissões de CO2 traria uma alteração no uso das ferrovias e hidrovias. Uma das constatações, ao se utilizar o modelo de Minimização de Fluxo de Custo Mínimo para o transporte de soja em 2013, foi que a capacidade de embarque nos terminais ferroviários e hidroviários desempenha um papel fundamental na redução das emissões de CO2. Se não houver capacidade suficiente, a adoção de uma taxa pode não provocar a redução das emissões. No caso do sistema de compra e crédito de carbono, seria necessária a compra de créditos de carbono, numa situação em que a capacidade de embarque nos terminais intermodais seja limitada. Verificou-se, ainda, que melhorias na infraestrutura podem desempenhar um papel mitigador das emissões. Um aumento da capacidade dos terminais ferroviários e hidroviários existentes, bem como o aumento da capacidade dos portos, pode provocar a redução das emissões de CO2. Se os projetos de expansão das ferrovias e hidrovias desenvolvidos por órgãos governamentais saírem do papel, pode-se chegar a uma redução de pouco mais de 50% das emissões de CO2. Consideraram-se ainda quais seriam os efeitos do aumento do uso de biodiesel como combustível e percebeu-se que seria possível obter reduções tanto das emissões quanto do custo de transporte. Efeitos semelhantes foram encontrados quando se simulou um aumento da eficiência energética. Por fim, percebeu-se nesta pesquisa que a adoção de uma taxa não traria tantos benefícios, econômicos e ambientais, quanto a melhoria da infraestrutura logística do país.

A Comparison of the Impacts of Lithium Extraction and Lithium Recycling Processes

Lithium is used in the cathode and electrolyte of rechargeable batteries in many portable electronics and electric vehicles, and is thus seen as a critical component of modern technology (Gruber et al., 2011). Electric vehicles are promoted as a way to reduce carbon emissions associated with the transportation sector, which accounts for 14.3% of anthropogenic greenhouse gas emissions (OECD International Transport Forum, 2010). However, the sustainability of lithium procurement will influence the overall environmental impact of this proposed “green” solution. It is estimated that 66% of the world’s lithium resource is contained in natural brines, 24% in pegmatites, and 8% in sedimentary rocks such as hectorite clays (Gruber et al., 2011). It has been shown that “[r]ecycling of lithium from Li-ion batteries may be a critical factor in balancing the supply of lithium with future demand” (Gruber et al., 2011). In an attempt to quantify energy and materials consumption associated with production of a unit of useful lithium compounds, industry reports and peer-reviewed scientific literature concerning lithium mining and lithium recycling were reviewed and compared. Other aspects of sustainability, such as waste or by-products produced in the production of a unit of useful lithium, were also explored. Thus, this paper will serve to further the evaluation of the comparative environmental consequences associated with lithium production via extraction versus recycling. Efficiencies must be made in both processes to maximize productivity while minimizing ecological harm.

The EU regime on biofuels in transport: Still in search of sustainability. Egmont Paper No. 68, July 2014

Like other regions of the world, the EU is developing biofuels in the transport sector to reduce oil consumption and mitigate climate change. To promote them, it has adopted favourable legislation since the 2000s. In 2009 it even decided to oblige each Member State to ensure that by 2020 the share of energy coming from renewable sources reached at least 10% of their final consumption of energy in the transport sector. Biofuels are considered the main instrument to reach that percentage since the development of other alternatives (such as hydrogen and electricity) will take much longer than expected. Meanwhile, these various legislative initiatives have driven the production and consumption of biofuels in the EU. Biofuels accounted for 4.7% of EU transport fuel consumption in 2011. They have also led to trade and investment in biofuels on a global scale. This large-scale expansion of biofuels has, however, revealed numerous negative impacts. These stem from the fact that first-generation biofuels (i.e., those produced from food crops), of which the most important types are biodiesel and bioethanol, are used almost exclusively to meet the EU’s renewable 10% target in transport. Their negative impacts are: socioeconomic (food price rises), legal (land-grabbing), environmental (for instance, water stress and water pollution; soil erosion; reduction of biodiversity), climatic (direct and indirect land-use effects resulting in more greenhouse gas emissions) and public finance issues (subsidies and tax relief). The extent of such negative impacts depends on how biofuel feedstocks are produced and processed, the scale of production, and in particular, how they influence direct land use change (DLUC) and indirect land use change (ILUC) and the international trade. These negative impacts have thus provoked mounting debates in recent years, with a particular focus on ILUC. They have forced the EU to re-examine how it deals with biofuels and submit amendments to update its legislation. So far, the EU legislation foresees that only sustainable biofuels (produced in the EU or imported) can be used to meet the 10% target and receive public support; and to that end, mandatory sustainability criteria have been defined. Yet they have a huge flaw. Their measurement of greenhouse gas savings from biofuels does not take into account greenhouse gas emissions resulting from ILUC, which represent a major problem. The Energy Council of June 2014 agreed to set a limit on the extent to which firstgeneration biofuels can count towards the 10% target. But this limit appears to be less stringent than the ones made previously by the European Commission and the European Parliament. It also agreed to introduce incentives for the use of advanced (second- and third-generation) biofuels which would be allowed to count double towards the 10% target. But this again appears extremely modest by comparison with what was previously proposed. Finally, the approach chosen to take into account the greenhouse gas emissions due to ILUC appears more than cautious. The Energy Council agreed that the European Commission will carry out a reporting of ILUC emissions by using provisional estimated factors. A review clause will permit the later adjustment of these ILUC factors. With such legislative orientations made by the Energy Council, one cannot consider yet that there is a major shift in the EU biofuels policy. Bolder changes would have probably meant risking the collapse of the high-emission conventional biodiesel industry which currently makes up the majority of Europe’s biofuel production. The interests of EU farmers would have also been affected. There is nevertheless a tension between these legislative orientations and the new Commission’s proposals beyond 2020. In any case, many uncertainties remain on this issue. As long as solutions have not been found to minimize the important collateral damages provoked by the first generation biofuels, more scientific studies and caution are needed. Meanwhile, it would be wise to improve alternative paths towards a sustainable transport sector, i.e., stringent emission and energy standards for all vehicles, better public transport systems, automobiles that run on renewable energy other than biofuels, or other alternatives beyond the present imagination.

Electric vehicles: limited range and high costs hamper commercialization. Report by the Comptroller General of the United States.

Mode of access: Internet.

Fossil fuels : pace and focus of the Clean Coal Technology Program need to be assessed : report to the Honorable Philip R. Sharp, Chairman, Subcommittee on Energy and Power, Committee on Energy and Commerce, House of Representatives /

"B-230504"--P. [1].

Industrial electric vehicles and trucks.

Mode of access: Internet.