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Since the mid-1970s, the tropical savanna, known as Cerrado, has been transformed into one of the world's largest grain-growing regions. This book explores how and by what Brazil achieved inclusive and sustainable growth in the Cerrado.
Since the mid-1970s, the tropical savanna, known as Cerrado, has been transformed into one of the world's largest grain-growing regions. This book explores how and by what Brazil achieved inclusive and sustainable growth in the Cerrado.
The massive grasslands of Brazil -- known as the cerrados -- which cover roughly a quarter of its land surface and are among the most threatened regions in South America, have received little media attention. This book brings together leading researchers on the area to produce the first detailed account in English of the natural history and ecology of the cerrado/savanna ecosystem. Given their extent and threatened status, the richness of their flora and fauna, and the lack of familiarity with their unique ecology at the international level, the cerrados are badly in need of this important and timely work.
The book offers a rich toolkit of relevant, adoptable ecosystem-based practices that can help the world's 500 million smallholder farm families achieve higher productivity, profitability and resource-use efficiency while enhancing natural capital.
This book is unique and original, constituting a pioneering study in the use of spatial economics and related analytical approaches to Brazil’s Cerrado agricultural development and the formation of agro-industrial value chains. This methodology is appropriate because Cerrado agriculture has been developed from scratch in a vast, previously barren area (204.7 million ha.) in which a spatial transformation has taken place. Until 40 years ago, this region, with its huge expanse of tropical savanna was believed to be unsuited to agriculture. Now, however, it has been transformed into an immense breadbasket, contributing to the mitigation of global food shortages. It also has contributed to the inland development of Brazil, promoting urbanization with a higher living standard and modern production techniques. This book identifies critical factors that enabled the transformation of the Cerrado. To understand the process of agricultural development and the formation of agro-industrial value chains, spatial economics and related approaches are essential because the process involves spatial interactions such as transportation, supply chains, knowledge spillovers, environmental constraints, migration, and urbanization. The book demonstrates that the initial development of Cerrado agriculture was a genuine spatial transformation with contributions from pioneering producers, agribusinesses, and central and local governments, as well as through international cooperation. It also discusses agriculture and agro-industrial value chains focusing on inclusive and sustainable development, a major concern of the international community particularly in terms of the Sustainable Development Goals.
Conservation agriculture in the Brazilian tropics; Background; The Cerrado biome; The Amazon biome; History of zero tillage in the tropical zones of Brazil; Conservation agriculture; How does conservation agriculture work?; Integrated crop-livestock systems with zero tillage; Dissemination of ICLZT technology; Livestock and annual crop production in wet-dry and humid-tropical Brazil; Livestock type; Herd size and performance; Background for ICLZT; The process of pasture degradation; Principal integrated zero tillage crop-livestock systems; General considerations; Systems typology; Common rotations; Crop successions used as building blocks for rotations; Summaries of the ten main ICLZT technologies; Crop establishment in degraded pastures; Establishing pasture in annual crops; Sowing pasture after early harvest; Grass oversown in soybeans or maize; Grass regenerating during the first crop after ZT planting of a crop in old pasture; Planting forages on crop land for silage, green chop, dry season grazing or as a cover crop; Pasture renovation with forages sown jointly with grasses, for early grazing;Pigeon pea sown into existing pasture to improve winter grazing quality; Sowing perenniallegumes into maize; Sowing soybeans in a permanent grass sward; Opportunistic grazing of stubble in the dry season; Pigeon pea undersown in maize for stubble grazing; Grazing stubble in the dry season; Pasture grasses; Cover crops for grazing; Cut forage and silage CTOpS; Pasture and grazing management; Legumes in pastures; Mechanized operations in zero tillage and soil fertility management 49 Residue management; Spraying desiccants and other chemicals; Planting and drilling; Soil fertility considerations; Technical and financial analysis of integrated crop-livestock zero tillage rotations; Case Study 1 - A farm history of the adoption of CA with Z; Wihout project;With ICLZT; lrrigated crop management - with and without project; Analysis of the Model Results; Case studies of other ICLZT technologies; Sustainable agriculture and policy considerations; Farm-based economic benefits of CA, ZT and ICLZT; Farm-based environmental benefits of CA, ZT and ICLZT; Social benefits of ICLZT and increased land use intensity; Social support for conversion investments in ICLZT; Addressing the conversion needs of small farmers.
Sustainability is an essential part of our modern food production system. Carrying out food research that considers environmental, social, and economic factors, is a major objective for food producers and researchers. Strategic development and use of technology can greatly assist in the progression toward a more sustainable food system. Sustainable Production Technology in Food explores important scientific and practical aspects related to sustainable technologies used in all aspects of the food system. This book is organized into 13 chapters, that cover the main concepts related to sustainability and technology. Coverage includes current technology in the industry, technological developments to improve sustainability of food production (biopreservation, pulsed electric fields, high pressure processing, ultrasound, cold plasma, and nanotechnology), regulatory aspects, and future perspectives. - Presents a comprehensive discussion around the technological advances of sustainable food production - Addresses the current relationship between food production and sustainability - Focuses on how technology can impact the sustainability of the food production system
This book is a collection of chapters concerning the use of biomass for the sustainable production of energy and chemicals–an important goal that will help decrease the production of greenhouse gases to help mitigate global warming, provide energy security in the face of dwindling petroleum reserves, improve balance of payment problems and spur local economic development. Clearly there are ways to save energy that need to be encouraged more. These include more use of energy sources such as, among others, manure in anaerobic digesters, waste wood in forests as fuel or feedstock for cellulosic ethanol, and conservation reserve program (CRP) land crops that are presently unused in the US. The use of biofuels is not new; Rudolf Diesel used peanut oil as fuel in the ?rst engines he developed (Chap. 8), and ethanol was used in the early 1900s in the US as automobile fuel [Songstad et al. (2009) Historical perspective of biofuels: learning from the past to rediscover the future. In Vitro Cell Dev Biol Plant 45:189–192). Brazil now produces enough sugar cane ethanol to make up about 50% of its transportation fuel needs (Chap. 4). The next big thing will be cellulosic ethanol. At present, there is also the use of Miscanthus x giganteous as fuel for power plants in the UK (Chap. 2), bagasse (sugar cane waste) to power sugar cane mills (Chap. 4), and waste wood and sawdust to power sawmills (Chap. 7).
The study "Valuing, restoring and managing presumed drylands: Cerrado, Miombo–Mopane woodlands and the Qinghai–Tibetan Plateau" confirms the existence of 1 075 million hectares of presumed drylands that are under threat from unsustainable use and climate change. This is in addition to the 6.1 billion hectares of official drylands that already cover 41 percent of the planet’s land surface and are home to 2 billion people. All these areas contain high levels of biodiversity and are home to a large number of people reliant on agriculture to sustain their livelihoods, this is why it's so important to research, analyse and work to protect them. The report contains concrete information on the environmental and ecological value of these dryland areas, and key recommendations for actions to limit land degradation, sustain biodiversity and mitigate climate change.