Urea Fertilizer Placement Effects on Soil Greenhouse Gas Emissions and Corn Growth PDF Download
Are you looking for read ebook online? Search for your book and save it on your Kindle device, PC, phones or tablets. Download Urea Fertilizer Placement Effects on Soil Greenhouse Gas Emissions and Corn Growth PDF full book. Access full book title Urea Fertilizer Placement Effects on Soil Greenhouse Gas Emissions and Corn Growth by Frank E. Johnson (II). Download full books in PDF and EPUB format.
Author: Frank E. Johnson (II) Publisher: ISBN: Category : Languages : en Pages : 87
Book Description
Agricultural soils are responsible for a majority of human caused greenhouse gas (GHG) production, such as N2O and carbon dioxide (CO2). Nitrous oxide is a potent GHG that stays in the atmosphere for at least 100 years. It is also an ozone-depleting gas. Carbon dioxide is problematic due to its abundance in the atmosphere. These GHGs, along with methane, have had a significant impact on climate change. Claypan soils are characterized as having a significantly higher clay content deeper in the soil profile compared to the layers directly above it. The goal of this research was to investigate the impact N fertilizer placement has on GHG emissions and corn growth. The specific research objectives were to determine the effects of urea fertilizer placement with and without a nitrification inhibitor (NI) on cumulative soil GHG emissions (N2O and CO2) and to assess the effects of urea fertilizer placement with and without a NI on plant N uptake, N use efficiency (NUE), and corn (Zea mays L.) production, on a poorly drained claypan soil in Northeastern Missouri. A NI helps reduce the amount of nitrous oxide produced. Field studies were conducted in 2014 and 2015. Soil greenhouse gas emissions were measured frequently throughout the growing season to determine flux and cumulative N2O and CO2 emissions. Soil water content and soil temperature were also assessed at each gas sampling event. Rainfall was higher than the 10-year average over the growing season for both 2014 and 2015 and possibly resulted in increased environmental N loss. Soil N2O and CO2 emissions were higher during the 2015 growing season. The UDB treatment produced the greatest amount of cumulative soil N2O emissions during both growth seasons at 100 and 354 g N2O-N ha−1. Deep banded urea without a NI resulted in the highest soil CO2 production in 2014 and UAA had the greatest cumulative CO2 emissions in 2015 at approximately 11 and 17 kg CO2-C ha−1, respectively. Incorporating urea to a depth of 8 cm, deep banding urea, and deep banding urea with a NI all resulted in significantly higher yields of corn by as much as much as 10%. Deep banding urea with a NI provided as high as a 48% increase in grain yield compared to other treatments in 2015. The highest yields occurred in 2014 when there were lower N2O emissions. In 2015, there were higher N2O emissions and lower yields. This research suggests that urea fertilizer placement has an impact on GHG emissions and corn growth and this information should be provided to farmers who are interested in producing more corn and losing less N. The amount of rainfall during the growing season may also influence soil GHG emissions and corn growth. More research should be conducted to understand to what extent climatic variability impacts GHG and crop production.
Author: Frank E. Johnson (II) Publisher: ISBN: Category : Languages : en Pages : 87
Book Description
Agricultural soils are responsible for a majority of human caused greenhouse gas (GHG) production, such as N2O and carbon dioxide (CO2). Nitrous oxide is a potent GHG that stays in the atmosphere for at least 100 years. It is also an ozone-depleting gas. Carbon dioxide is problematic due to its abundance in the atmosphere. These GHGs, along with methane, have had a significant impact on climate change. Claypan soils are characterized as having a significantly higher clay content deeper in the soil profile compared to the layers directly above it. The goal of this research was to investigate the impact N fertilizer placement has on GHG emissions and corn growth. The specific research objectives were to determine the effects of urea fertilizer placement with and without a nitrification inhibitor (NI) on cumulative soil GHG emissions (N2O and CO2) and to assess the effects of urea fertilizer placement with and without a NI on plant N uptake, N use efficiency (NUE), and corn (Zea mays L.) production, on a poorly drained claypan soil in Northeastern Missouri. A NI helps reduce the amount of nitrous oxide produced. Field studies were conducted in 2014 and 2015. Soil greenhouse gas emissions were measured frequently throughout the growing season to determine flux and cumulative N2O and CO2 emissions. Soil water content and soil temperature were also assessed at each gas sampling event. Rainfall was higher than the 10-year average over the growing season for both 2014 and 2015 and possibly resulted in increased environmental N loss. Soil N2O and CO2 emissions were higher during the 2015 growing season. The UDB treatment produced the greatest amount of cumulative soil N2O emissions during both growth seasons at 100 and 354 g N2O-N ha−1. Deep banded urea without a NI resulted in the highest soil CO2 production in 2014 and UAA had the greatest cumulative CO2 emissions in 2015 at approximately 11 and 17 kg CO2-C ha−1, respectively. Incorporating urea to a depth of 8 cm, deep banding urea, and deep banding urea with a NI all resulted in significantly higher yields of corn by as much as much as 10%. Deep banding urea with a NI provided as high as a 48% increase in grain yield compared to other treatments in 2015. The highest yields occurred in 2014 when there were lower N2O emissions. In 2015, there were higher N2O emissions and lower yields. This research suggests that urea fertilizer placement has an impact on GHG emissions and corn growth and this information should be provided to farmers who are interested in producing more corn and losing less N. The amount of rainfall during the growing season may also influence soil GHG emissions and corn growth. More research should be conducted to understand to what extent climatic variability impacts GHG and crop production.
Author: Tyler W. Steusloff Publisher: ISBN: Category : Languages : en Pages : 155
Book Description
Adoption of nitrogen (N) management strategies to minimize gaseous N loss from agriculture while maintaining high yield production is increasingly important for an exponentially growing population. Agricultural management on poorly-drained claypan soils in the Midwestern U.S. make corn (Zea mays L.) production even more challenging due to the subsoil's low permeability, which may result in wetter soil conditions and relatively larger amounts of soil N[subscript 2]O emissions during the growing season. The objective of this study was to determine the effects of urea fertilizer placement with and without the addition of a nitrification inhibitor (NI) on corn yield, N use efficiency (NUE), and cumulative soil N[subscript 2]O emissions on a Northeastern Missouri claypan soil. The fertilizer strategies utilized in this study consisted of deep-banded urea (DB) or urea plus nitrapyrin [2-chloro-6-(trichloromethyl) pyridine] (DB+NI) at a depth of 20 cm compared to urea broadcast surface applied (SA) or incorporated to a depth of 8 cm (IA). The addition of a NI with deep-banded urea resulted in 27% greater apparent N recovery efficiency than all other N treatments. Additionally, DB+NI had 54 and 55% lower cumulative soil N[subscript 2]O emissions than IA and SA treatments in the two combined growing seasons. These results suggest that deep placement of urea with or without nitrapyrin is an effective management strategy for increasing corn yield and reducing N loss on a claypan soil.
Author: R. Nieder Publisher: Springer ISBN: 9789048178803 Category : Science Languages : en Pages : 0
Book Description
Carbon and Nitrogen in the Terrestrial Environment is a comprehensive, interdisciplinary description of C and N fluxes between the atmosphere and the terrestrial biosphere; issues related to C and N management in different ecosystems and their implications for the environment and global climate change; and the approaches to mitigate emission of greenhouse gases. Drawing upon the most up-to-date books, journals, bulletins, reports, symposia proceedings and internet sources documenting interrelationships between different aspects of C and N cycling in the terrestrial environment, Carbon and Nitrogen in the Terrestrial Environment fills the gap left by most of the currently available books on C and N cycling. They either deal with a single element of an ecosystem, or are related to one or a few selected aspects like soil organic matter (SOM) and agricultural or forest management, emission of greenhouse gases, global climate change or modeling of SOM dynamics.
Author: Maria Angeles Munoz Publisher: Academic Press ISBN: 0128121297 Category : Science Languages : en Pages : 398
Book Description
Soil Management and Climate Change: Effects on Organic Carbon, Nitrogen Dynamics, and Greenhouse Gas Emissions provides a state of the art overview of recent findings and future research challenges regarding physical, chemical and biological processes controlling soil carbon, nitrogen dynamic and greenhouse gas emissions from soils. This book is for students and academics in soil science and environmental science, land managers, public administrators and legislators, and will increase understanding of organic matter preservation in soil and mitigation of greenhouse gas emissions. Given the central role soil plays on the global carbon (C) and nitrogen (N) cycles and its impact on greenhouse gas emissions, there is an urgent need to increase our common understanding about sources, mechanisms and processes that regulate organic matter mineralization and stabilization, and to identify those management practices and processes which mitigate greenhouse gas emissions, helping increase organic matter stabilization with suitable supplies of available N. - Provides the latest findings about soil organic matter stabilization and greenhouse gas emissions - Covers the effect of practices and management on soil organic matter stabilization - Includes information for readers to select the most suitable management practices to increase soil organic matter stabilization
Author: Christopher Knowles Publisher: CRC Press ISBN: 1351079956 Category : Science Languages : en Pages : 252
Book Description
It is the aim of this book to present reviews on a wide range of aspects of bacterial respiratory systems. Because the on-going publication elsewhere of reviews on bacterial respiration, ablanket coverage of the field has not been attempted. Rather, a range of topics have been selected, either because they are of special current interest, they have not been reviewed recently, or they have never been reviewed.
Author: Food and Agriculture Organization of the United Nations Publisher: Food & Agriculture Org. ISBN: 9251318948 Category : Technology & Engineering Languages : en Pages : 40
Book Description
This report presents the world nitrogen, phosphorus and potassium fertilizer medium-term supply and demand forecasts for the period 2017-2022. FAO, in collaboration with other members of the Fertilizer Outlook Expert Group dealing with fertilizer production, consumption and trade, provides forecasts of world and regional fertilizer supply, demand and potential balance.
Author: Todd S. Rosenstock Publisher: Springer ISBN: 3319297945 Category : Technology & Engineering Languages : en Pages : 217
Book Description
This book provides standards and guidelines for quantifying greenhouse gas emissions and removals in smallholder agricultural systems and comparing options for climate change mitigation based on emission reductions and livelihood trade-offs. Globally, agriculture is directly responsible for about 11% of annual greenhouse gas (GHG) emissions and induces an additional 17% through land use change, mostly in developing countries. Farms in the developing countries of sub-Saharan Africa and Asia are predominately managed by smallholders, with 80% of land holdings smaller than ten hectares. However, little to no information exists on greenhouse gas emissions and mitigation potentials in smallholder agriculture. Greenhouse gas measurements in agriculture are expensive, time consuming, and error prone, challenges only exacerbated by the heterogeneity of smallholder systems and landscapes. Concerns over methodological rigor, measurement costs, and the diversity of approaches, coupled with the demand for robust information suggest it is germane for the scientific community to establish standards of measurements for quantifying GHG emissions from smallholder agriculture. Standard guidelines for use by scientists, development organizations will help generate reliable data on emissions baselines and allow rigorous comparisons of mitigation options. The guidelines described in this book, developed by the CGIAR Research Program on Climate Change, Agriculture, and Food Security (CCAFS) and partners, are intended to inform anyone conducting field measurements of agricultural greenhouse gas sources and sinks, especially to develop IPCC Tier 2 emission factors or to compare mitigation options in smallholder systems.
Author: Frank E. Johnson (II)
Author: Frank E. Johnson (II)
Author: Tyler W. Steusloff
Author: Amal Roy
Author: R. Nieder
Author: Maria Angeles Munoz
Author: Christopher Knowles
Author: Food and Agriculture Organization of the United Nations
Author: Todd S. Rosenstock
Author: Frederick Burean Smith
Author: James Stuart Schepers