Global ETD Search

1	Polymer Coated Urea in Kentucky Bluegrass Buss, Jessica Chelise 01 March 2016 (has links) (PDF) Nitrogen (N) is the most commonly over-applied nutrient in urban environments because of the large visual and growth increases. This over-application has led to an increase in the loss of N gas in the forms of ammonia and nitrous oxide, as well as an increase in nitrate leaching to surface and groundwater. Furthermore, excess N results in increased maintenance costs and landfill volume due to increased shoot growth from mowed clipping removal. Polymer coated urea (PCU) has proven to be an excellent source to these losses of N to the environment, but rate and timing parameters need study. A two-year field study, on sand and sandy loam soils in Provo, UT, was initiated in April 2014. Seven fertilized treatments included: urea split applied monthly; a single application of PCU (Agrium One Ap) applied in spring, a single PCU application in fall; two evenly split applications in spring and late summer; and three evenly split applications in spring, late summer, and late fall. These were compared to an untreated control. In addition the two application of PCU also had reduced rates of half and three-quarters, in addition to the full rate. Height and verdure measurements were taken on a weekly basis, along with periodic visual and biomass readings. All fertilized treatments resulted in a significant response to N as compared to the control. The single annual application treatments had significantly greater shoot growth during the weeks immediately after application and a significant reduction in verdure months later and, therefore, were unacceptable for consumer recommendation. Two applications of PCU, either at the three-quarter or full rates, were nearly identical in all measurements as compared to the spoon feeding of urea applied monthly. The half rate of two applications showed signs of inadequate N. Three applications of PCU was identical to two and, therefore, not recommended. This study shows two applications of PCU at the three-quarter rate is equally effective as spoon feeding the N. Doing so would result in less labor for fertilization. Further work is needed to evaluate other timing approaches for a single annual application, as well as long term effects of a reduced rate of N. polymer coated urea PCU urea Kentucky bluegrass Poa pratensis nitrogen fertilizer nitrogen timing nitrogen rate Plant Sciences
2	Nitrogen Use Efficiency of Polymer-Coated Urea Ransom, Curtis J. 19 March 2014 (has links) (PDF) Plants require N to complete their life cycle. Without adequate concentration of N, crops will not produce their potential yields. For turfgrass systems, N fertilizer application allows for the maintenance of functional, aesthetic, and recreational properties. However, fertilizer mismanagement is common and leads to N pollution in the environment. Controlled-release and slow-release fertilizers can enhance nitrogen (N)-use efficiency, reduce N pollution, minimize the need for repeated fertilizer applications, and reduce turfgrass shoot growth and associated costs. In order to evaluate the effectiveness of these fertilizers in the Intermountain West, research is needed. The timing of N release was evaluated for seven urea fertilizers: uncoated, sulfur coated (SCU), polymer-sulfur coated (PSCU), and four polymer-coated (PCU) with release timings of 45, 75, 120, and 180 d estimated release. These products were placed on bare soil, a Kentucky bluegrass (Poa pratensis L.) thatch layer, and incorporated into soil. These three placement treatments were replicated to allow for enough samples to be placed in two locations. The first was outside in a field to represent field conditions with diurnal fluctuating temperatures and the second was placed in a storage facility to replicate laboratory conditions with static diurnal temperatures. The PCU prills incorporated into soil under field conditions generally released N over the estimated release period. However, when applied to bare soil or thatch, N from PCU had 80% or greater N release by 35 d after application regardless of expected release time. Fertilizers under laboratory conditions had minimal N release despite having similar average daily temperatures, suggesting that fluctuating temperatures impact N release. The PSCU and SCU treatments were no different from uncoated urea, showing no slow release properties for this particular product. Spring-applied N fertilizer trials were conducted over two years to determine the optimal N rate for Kentucky bluegrass. Similar PCU120 products were applied at 50, 75, and 100% of the recommended full rate, while also being compared to an unfertilized control and urea applied either all at once or split monthly. Spring-applied PCU showed minimal initial N response while urea applied all at once resulted in an initial spike of N uptake. Once PCU began to release N, there was minimal difference for all rates compared to urea split monthly for biomass growth, verdure, and shoot tissue N. Although at the 50% rate, there were a few sampling dates with slower growth and lower verdure. The decrease in verdure at this low rate was slight, and it is recommended that PCU could be applied effectively at a reduced rate between 50 and 75%. Although for better results, additional quick release N is required to compensate for early season lag in N release. polymer-coated urea (PCU) controlled-release fertilizer (CRF) urea turfgrass Kentucky blue grass (KBG) release rate Animal Sciences
3	Variação hídrica e fontes de nitrogênio em cultivares de arroz de terras altas: produção e qualidade fisiológica de sementes / Hydric variation and nitrogen sources in upland rice cultivars: production and physiological quality of seeds Peres, Amanda Ribeiro [UNESP] 24 February 2017 (has links) Submitted by AMANDA RIBEIRO PERES null (amandarperes_agro@yahoo.com.br) on 2017-03-19T14:03:44Z No. of bitstreams: 1 Amanda Ribeiro Peres-TESE-Agronomia.pdf: 4734675 bytes, checksum: 5a4d70ca13fe949ff04fcd755564e8c4 (MD5) / Approved for entry into archive by Juliano Benedito Ferreira (julianoferreira@reitoria.unesp.br) on 2017-03-22T13:06:45Z (GMT) No. of bitstreams: 1 peres_ar_dr_ilha.pdf: 4734675 bytes, checksum: 5a4d70ca13fe949ff04fcd755564e8c4 (MD5) / Made available in DSpace on 2017-03-22T13:06:45Z (GMT). No. of bitstreams: 1 peres_ar_dr_ilha.pdf: 4734675 bytes, checksum: 5a4d70ca13fe949ff04fcd755564e8c4 (MD5) Previous issue date: 2017-02-24 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Dentre os desafios atuais da agricultura, estão a racionalização do uso da água, aumento da produtividade e redução das perdas de nutrientes. Para isso, deve-se avaliar técnicas de otimização ou redução da utilização da água, como o uso de cultivares mais adaptadas a estresses hídricos e, a aplicação de fertilizantes melhor aproveitados pelas plantas. Recentemente foi lançado no mercado o cultivar de arroz BRS Esmeralda que tem como características maior tolerância ao estresse hídrico e elevado potencial produtivo. Diante disso, o objetivo deste trabalho foi avaliar o efeito da variação hídrica e fontes de N em cultivares de arroz de terras altas sobre o teor de N foliar, desempenho agronômico, produtividade, qualidade industrial e qualidade fisiológica de sementes produzidas. O experimento foi desenvolvido na Fazenda de Ensino e Pesquisa da Unesp, campus de Ilha Solteira, localizada no município de Selvíria-MS e no laboratório de sementes em Ilha Solteira-SP, em 2013/14 e 2014/15. O tipo de solo é um LATOSSOLO VERMELHO Distrófico típico argiloso. O experimento foi realizado em duas etapas: produção em campo e avaliação da qualidade fisiológica das sementes produzidas. O delineamento experimental em campo foi o de blocos casualizados em esquema de parcelas sub-subdividas, sendo constituído de três variações hídricas nas parcelas (irrigação com a lâmina recomendada para o arroz + precipitação; irrigação com a lâmina de 75% da recomendada + precipitação; e sem irrigação + precipitação, ou seja, sequeiro), de dois cultivares nas subparcelas (IAC 202 e BRS Esmeralda) e de quatro fontes de nitrogênio nas sub-subparcelas (ureia, sulfato de amônio, ureia + sulfato de amônio e ureia revestida), com quatro repetições. Observou-se que a redução da disponibilidade de água atrasou o florescimento e a maturação, e diminuiu a produção de matéria seca. As fontes de nitrogênio não diferiram quanto ao teor de nitrogênio foliar e na planta, a quantidade de nitrogênio acumulado na planta e a produtividade de grãos de arroz de terras altas cultivado em sequeiro ou sob irrigação por aspersão. Em ano com incidência de veranico no estádio reprodutivo, houve redução da produtividade de grãos do sequeiro em relação a irrigação por aspersão com as lâminas recomendada e 75% da recomendada, sendo maior a redução em cultivar com ciclo mais curto (BRS Esmeralda). Já em ano em que a deficiência hídrica ocorreu na fase vegetativa não houve interferência da variação hídrica sobre a produtividade de grãos, e o cultivar BRS Esmeralda proporcionou maior produtividade. A qualidade fisiológica das sementes do cultivar IAC 202 em ano com período de altas temperaturas na fase reprodutiva foi maior nas condições de sequeiro em comparação as lâminas de irrigação. Já em ano sem ocorrência de altas temperaturas na fase reprodutiva a maior qualidade de sementes ocorreu nos tratamentos irrigados em comparação ao sequeiro para o cultivar IAC 202. O acamamento do cultivar BRS Esmeralda nos tratamentos com irrigação por aspersão resulta em produção de sementes de menor qualidade em comparação ao sequeiro. As fontes de nitrogênio não diferiram em relação a qualidade fisiológica das sementes. / The rationalization of water use, the increase in productivity and the reduction of nutrient losses are among the current challenges of agriculture. For this, it is necessary to evaluate techniques of optimization or reduction of water use, such as the use of cultivars more adapted to water stresses, and the application of fertilizers better utilized by plants. Recently, the upland rice cultivar BRS Esmeralda, more tolerant to drought and with high productive potential, was released in the market. Thus, the objective of this study was to evaluate the effect of the hydric variation and nitrogen sources in topdressing in upland rice cultivars on the leaf nitrogen content, agronomic performance, yield, industrial quality and physiological quality of the seeds produced. The experiment was conducted at the Education and Research Farm of Unesp, Ilha Solteira campus, located in Selvíria-MS and in the seed laboratory in Ilha Solteira-SP, in 2013/14 and 2014/15. The soil of the area is a Dystrophic RED LATOSOL (Oxisol) with a clayey texture. The experiment was performed in two stages: field production and evaluation of the physiological quality of the seeds produced. The experiment conducted in the field consisted of randomized blocks in a split-split plot design, with three hydric variations as plots (irrigation with a recommended water depth for rice + rainfall; irrigation with 75% of the recommended water depth + rainfall; and without irrigation + rainfall – “rainfed”), two cultivars as subplots (IAC 202 and BRS Esmeralda) and four nitrogen sources as sub-subplots (urea, sulfate, urea + sulfate and coated urea), with four replications. The reduction in water availability delayed the flowering and ripening and reduced the production of dry matter. Nitrogen sources did not differ in terms of the leaf and plant nitrogen content, the amount of nitrogen accumulated in the plant, and grains productivity of upland rice grown in the rainfed or under sprinkler irrigation. In the year with dry spell during the reproductive stage, there was a reduction of the grains productivity of the rainfed in relation to sprinkler irrigation with the recommended and 75% of the recommended depths, being greater the reduction in cultivar with shorter cycle (BRS Esmeralda). On the other hand, there was no interference of hydric variation on grain yield in a year with water deficit during the vegetative stage, and the BRS Esmeralda cultivar provided higher productivity. The physiological quality of the seeds of the cultivar IAC 202 was higher in the rainfed conditions compared to the irrigation depths in year with period of high temperatures in the reproductive stage. However, in the year without occurrence of high temperatures in the reproductive stage, the highest seeds quality occurred in the irrigated treatments in comparison to the rainfed for the cultivar IAC 202. The lodging of the BRS Esmeralda cultivar in the treatments with sprinkler irrigation results in the seeds production of lower quality in comparison to the rainfed. Nitrogen sources did not differ in relation to the physiological quality of the seeds. Oryza sativa L. Irrigação por aspersão Adubação nitrogenada Ureia revestida BRS Esmeralda Teor de N foliar Vigor de sementes Sprinkler irrigation Nitrogen fertilization Coated urea Leaf nitrogen content Seeds vigor
4	Evaluating Innovative Nutrient Management Options and Seasonal Groundwater Recharge Dynamics in an Agricultural Source Water Protection Area Brook, Jacqueline Marie 29 August 2012 (has links) This thesis presents two interrelated studies that consider nutrient management and seasonal changes in recharge on agricultural lands within the context of source water protection. The research focuses first on the management of the risk to groundwater quality through the implementation of various nutrient management practices and secondly considers the dynamic nature of the transport pathway to the groundwater system associated with seasonal changes in climate and hydrology. The combined results provide insight into several of the key factors influencing the protection of groundwater sources within the agricultural landscape. Field work was completed between 2009 and 2010 on an agricultural field near the City of Woodstock, Ontario. The site is located within a source water protection area; the two-year travel time zone of the Thornton Well Field which represents the primary water supply for the City of Woodstock and which has experienced chronic increases in nitrate concentrations over the last few decades. The wells are completed in glacial overburden consisting of intermingling sand and gravel till aquifers which overly a limestone bedrock aquifer. Agricultural best or beneficial management practices (BMPs) field have been implemented and monitored since 2004. The BMPs were adopted in order to reduce nitrogen losses to the aquifer, and consisted of a reduction in nitrogen fertilizer application rates over a series of agricultural fields located near the well The first study is a one year experiment designed to compare alternative nutrient management practices for corn. Combinations of fertilizer treatments with or without a legume cover crop (red clover) were assessed. The fertilizer treatments studied were: a polymer coated urea (slow-release fertilizer) applied at planting, a conventional urea applied at planting, side-dress treatment of a solution of urea and ammonium nitrate in water containing 28% nitrogen with two different application rates applied in the early summer, and a control. The legume cover crop was incorporated in the soil in the previous fall, and acts as a slow release fertilizer as nitrogen is made available to the following crop as the plants decompose. Treatments were compared based on crop yield, overall economic return, and the potential for nitrate leaching. The potential for nitrate leaching was evaluated with bi-weekly shallow soil core during the growing season, and deep soil cores taken before planting, after harvest and the following spring. The deep cores allowed changes in nitrate storage below the rooting zone to be assessed. The results of this study highlight the importance of timing of fertilizer applications and rate of fertilizer applications. Treatments which provide a delay in the release or application of fertilizer, the polymer-coated urea, the calculator-rate side-dress and the clover cover crop, were found to be advantageous. The polymer-coated urea treatments and side-dress treatments were found to reduce leaching compared to the conventional urea treatment. Treatments with the clover cover crops were not found to reduce crop yields or increase leaching potential, and lower fertilizer costs associated to this practice were found to have a positive economic effect. Plots treated with the high-rate side-dress fertilizer application lost more nitrate to the subsurface compared to the other treatment options, and an economic disadvantage was observed as yields did not compensate for higher fertilizer costs. The study highlights the advantages of the different treatments under study, which may be used to inform policy makers and farmers in the selection of economically and environmentally sustainable nutrient management BMP options. Groundwater monitoring at the site over the years has indentified interesting recharge dynamics, particularly in the vicinity of an ephemeral stream which develops annually during spring and winter melt events in a low lying area of the study site. It was hypothesized that rapid recharge could occur beneath the stream allowing for surface water to quickly reach groundwater, posing a threat to municipal water wells. The current framework of source water protection does not take into account the potential risk posed by this type recharge event. At this field site, rapid infiltration associated with this type of event may pose a risk to drinking water quality due to the proximity of the stream to the pumping wells and the nature of the aquifer. The second study examines rapid groundwater recharge processes beneath the ephemeral stream during the course of a spring melt in 2010. The goals of the study were to quantify recharge at one location beneath the stream and to assess whether temperature variations above the water table can be used as a tracer to reasonably estimate recharge during a short live recharge event. A novel housing for the temperature sensors was designed in order to deploy and position them into gravelly materials within the vadose zone, which reduced the potential for the formation of preferential pathways and permitted the retrieval of the sensors at a later date. Field data were collected during the course of the spring melt period from a network of groundwater monitoring wells and subsurface temperature sensors. Spatial and temporal changes in groundwater geochemistry, hydraulic head and temperature were were used to characterize recharge dynamics at the field site. Recharge beneath a segment of the ephemeral stream was quantified through the numerical analysis of the field data using Hydrus 1-D, a one-dimensional numerical model designed to simulate soil water flow and heat transport in variably saturated porous media. Site specific data were used to create the model domain, provide estimates of physical parameters, and to define initial and time variable boundary conditions. Model parameters were first calibrated by simulating periods where it was expected that soils would be gravity drained with minimal soil water flow, and then further refined by simulating the period when the ephemeral stream was present. A final set of parameters was determined, and the initial gravity drained conditions were re-simulated. The model was able to reproduce field observations under different flow scenarios using the final set of parameters, suggesting that the conceptual model and final model domain representative of the actual field conditions. The successful simulation of the field data sets under the different flow scenarios also increases confidence in the uniqueness of the model results. The model estimated that 0.15 m of recharge occurred beneath the instrumented site during the period between March 9th and March 22nd of 2010 when the ephemeral stream was present. This represents approximately a third of the expected total annual recharge for this location. Regional changes in hydraulic head, groundwater temperature and groundwater chemistry provided additional insight into the dynamic nature of the recharge process during the spring meld period and further illustrated the spatial variability of the aquifers’ response to the stream. The study found that the use of temperature as a tracer provided useful and quantifiable insight into recharge phenomena. The results of this study suggest that high rates of rapid recharge occur beneath the ephemeral stream, and are spatially variable. This type of focused infiltration that occurs during the spring melt may represent a risk to municipal water quality if the infiltrating waters are carrying contaminants. green manure slow release fertilizer polymer-coated urea nitrate Hydrus 1-D one-dimensional model heat transport ephemeral stream corn groundwater recharge Earth Sciences
5	Evaluating Innovative Nutrient Management Options and Seasonal Groundwater Recharge Dynamics in an Agricultural Source Water Protection Area Brook, Jacqueline Marie 29 August 2012 (has links) This thesis presents two interrelated studies that consider nutrient management and seasonal changes in recharge on agricultural lands within the context of source water protection. The research focuses first on the management of the risk to groundwater quality through the implementation of various nutrient management practices and secondly considers the dynamic nature of the transport pathway to the groundwater system associated with seasonal changes in climate and hydrology. The combined results provide insight into several of the key factors influencing the protection of groundwater sources within the agricultural landscape. Field work was completed between 2009 and 2010 on an agricultural field near the City of Woodstock, Ontario. The site is located within a source water protection area; the two-year travel time zone of the Thornton Well Field which represents the primary water supply for the City of Woodstock and which has experienced chronic increases in nitrate concentrations over the last few decades. The wells are completed in glacial overburden consisting of intermingling sand and gravel till aquifers which overly a limestone bedrock aquifer. Agricultural best or beneficial management practices (BMPs) field have been implemented and monitored since 2004. The BMPs were adopted in order to reduce nitrogen losses to the aquifer, and consisted of a reduction in nitrogen fertilizer application rates over a series of agricultural fields located near the well The first study is a one year experiment designed to compare alternative nutrient management practices for corn. Combinations of fertilizer treatments with or without a legume cover crop (red clover) were assessed. The fertilizer treatments studied were: a polymer coated urea (slow-release fertilizer) applied at planting, a conventional urea applied at planting, side-dress treatment of a solution of urea and ammonium nitrate in water containing 28% nitrogen with two different application rates applied in the early summer, and a control. The legume cover crop was incorporated in the soil in the previous fall, and acts as a slow release fertilizer as nitrogen is made available to the following crop as the plants decompose. Treatments were compared based on crop yield, overall economic return, and the potential for nitrate leaching. The potential for nitrate leaching was evaluated with bi-weekly shallow soil core during the growing season, and deep soil cores taken before planting, after harvest and the following spring. The deep cores allowed changes in nitrate storage below the rooting zone to be assessed. The results of this study highlight the importance of timing of fertilizer applications and rate of fertilizer applications. Treatments which provide a delay in the release or application of fertilizer, the polymer-coated urea, the calculator-rate side-dress and the clover cover crop, were found to be advantageous. The polymer-coated urea treatments and side-dress treatments were found to reduce leaching compared to the conventional urea treatment. Treatments with the clover cover crops were not found to reduce crop yields or increase leaching potential, and lower fertilizer costs associated to this practice were found to have a positive economic effect. Plots treated with the high-rate side-dress fertilizer application lost more nitrate to the subsurface compared to the other treatment options, and an economic disadvantage was observed as yields did not compensate for higher fertilizer costs. The study highlights the advantages of the different treatments under study, which may be used to inform policy makers and farmers in the selection of economically and environmentally sustainable nutrient management BMP options. Groundwater monitoring at the site over the years has indentified interesting recharge dynamics, particularly in the vicinity of an ephemeral stream which develops annually during spring and winter melt events in a low lying area of the study site. It was hypothesized that rapid recharge could occur beneath the stream allowing for surface water to quickly reach groundwater, posing a threat to municipal water wells. The current framework of source water protection does not take into account the potential risk posed by this type recharge event. At this field site, rapid infiltration associated with this type of event may pose a risk to drinking water quality due to the proximity of the stream to the pumping wells and the nature of the aquifer. The second study examines rapid groundwater recharge processes beneath the ephemeral stream during the course of a spring melt in 2010. The goals of the study were to quantify recharge at one location beneath the stream and to assess whether temperature variations above the water table can be used as a tracer to reasonably estimate recharge during a short live recharge event. A novel housing for the temperature sensors was designed in order to deploy and position them into gravelly materials within the vadose zone, which reduced the potential for the formation of preferential pathways and permitted the retrieval of the sensors at a later date. Field data were collected during the course of the spring melt period from a network of groundwater monitoring wells and subsurface temperature sensors. Spatial and temporal changes in groundwater geochemistry, hydraulic head and temperature were were used to characterize recharge dynamics at the field site. Recharge beneath a segment of the ephemeral stream was quantified through the numerical analysis of the field data using Hydrus 1-D, a one-dimensional numerical model designed to simulate soil water flow and heat transport in variably saturated porous media. Site specific data were used to create the model domain, provide estimates of physical parameters, and to define initial and time variable boundary conditions. Model parameters were first calibrated by simulating periods where it was expected that soils would be gravity drained with minimal soil water flow, and then further refined by simulating the period when the ephemeral stream was present. A final set of parameters was determined, and the initial gravity drained conditions were re-simulated. The model was able to reproduce field observations under different flow scenarios using the final set of parameters, suggesting that the conceptual model and final model domain representative of the actual field conditions. The successful simulation of the field data sets under the different flow scenarios also increases confidence in the uniqueness of the model results. The model estimated that 0.15 m of recharge occurred beneath the instrumented site during the period between March 9th and March 22nd of 2010 when the ephemeral stream was present. This represents approximately a third of the expected total annual recharge for this location. Regional changes in hydraulic head, groundwater temperature and groundwater chemistry provided additional insight into the dynamic nature of the recharge process during the spring meld period and further illustrated the spatial variability of the aquifers’ response to the stream. The study found that the use of temperature as a tracer provided useful and quantifiable insight into recharge phenomena. The results of this study suggest that high rates of rapid recharge occur beneath the ephemeral stream, and are spatially variable. This type of focused infiltration that occurs during the spring melt may represent a risk to municipal water quality if the infiltrating waters are carrying contaminants. green manure slow release fertilizer polymer-coated urea nitrate Hydrus 1-D one-dimensional model heat transport ephemeral stream corn groundwater recharge Earth Sciences
6	Variação hídrica e fontes de nitrogênio em cultivares de arroz de terras altas : produção e qualidade fisiológica de sementes / Peres, Amanda Ribeiro. January 2017 (has links) Orientador: Ricardo Antonio Ferreira Rodrigues / Resumo: Dentre os desafios atuais da agricultura, estão a racionalização do uso da água, aumento da produtividade e redução das perdas de nutrientes. Para isso, deve-se avaliar técnicas de otimização ou redução da utilização da água, como o uso de cultivares mais adaptadas a estresses hídricos e, a aplicação de fertilizantes melhor aproveitados pelas plantas. Recentemente foi lançado no mercado o cultivar de arroz BRS Esmeralda que tem como características maior tolerância ao estresse hídrico e elevado potencial produtivo. Diante disso, o objetivo deste trabalho foi avaliar o efeito da variação hídrica e fontes de N em cultivares de arroz de terras altas sobre o teor de N foliar, desempenho agronômico, produtividade, qualidade industrial e qualidade fisiológica de sementes produzidas. O experimento foi desenvolvido na Fazenda de Ensino e Pesquisa da Unesp, campus de Ilha Solteira, localizada no município de Selvíria-MS e no laboratório de sementes em Ilha Solteira-SP, em 2013/14 e 2014/15. O tipo de solo é um LATOSSOLO VERMELHO Distrófico típico argiloso. O experimento foi realizado em duas etapas: produção em campo e avaliação da qualidade fisiológica das sementes produzidas. O delineamento experimental em campo foi o de blocos casualizados em esquema de parcelas sub-subdividas, sendo constituído de três variações hídricas nas parcelas (irrigação com a lâmina recomendada para o arroz + precipitação; irrigação com a lâmina de 75% da recomendada + precipitação; e sem irrigação + preci... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: The rationalization of water use, the increase in productivity and the reduction of nutrient losses are among the current challenges of agriculture. For this, it is necessary to evaluate techniques of optimization or reduction of water use, such as the use of cultivars more adapted to water stresses, and the application of fertilizers better utilized by plants. Recently, the upland rice cultivar BRS Esmeralda, more tolerant to drought and with high productive potential, was released in the market. Thus, the objective of this study was to evaluate the effect of the hydric variation and nitrogen sources in topdressing in upland rice cultivars on the leaf nitrogen content, agronomic performance, yield, industrial quality and physiological quality of the seeds produced. The experiment was conducted at the Education and Research Farm of Unesp, Ilha Solteira campus, located in Selvíria-MS and in the seed laboratory in Ilha Solteira-SP, in 2013/14 and 2014/15. The soil of the area is a Dystrophic RED LATOSOL (Oxisol) with a clayey texture. The experiment was performed in two stages: field production and evaluation of the physiological quality of the seeds produced. The experiment conducted in the field consisted of randomized blocks in a split-split plot design, with three hydric variations as plots (irrigation with a recommended water depth for rice + rainfall; irrigation with 75% of the recommended water depth + rainfall; and without irrigation + rainfall – “rainfed”), two cultiv... (Complete abstract click electronic access below) / Doutor Oryza sativa L. Irrigação por aspersão Adubação nitrogenada Ureia revestida BRS Esmeralda Teor de N foliar Vigor de sementes Sprinkler irrigation Nitrogen fertilization Coated urea Leaf nitrogen content Seeds vigor
7	Soybean Yield and Biomass Response to Supplemental Nitrogen Fertilization McCoy, Justin Michael 12 August 2016 (has links) Soybean (Glycine max [L.] Merr.) has become one of the main agricultural grain crops produced in the United States. Soybean production continues to increase in high-yield environments throughout the U.S. New innovations are required to sustain gains in soybean yield potential. Field experiments were conducted at the Delta Research and Extension Center in Stoneville, MS in 2014 and 2015 to evaluate soybean aboveground biomass and grain yield response to supplemental N fertilization in a high-yielding environment on two soil textures commonly cropped to soybean in Mississippi. Greenhouse studies were conducted in 2016 at the Delta Research and Extension Center in Stoneville, MS to evaluate the influence of supplemental N fertilization on nodule formation and belowground biomass of soybean on two soil textures commonly cropped to soybean in Mississippi. soybean soybean fertilization soybean nitrogen soybean root growth nitrogen nodule inhibition soybean nodulation polymer coated urea late season nitrogen fertilizer
8	Environmental Implications of Polymer Coated Urea LeMonte, Joshua James 19 April 2011 (has links) (PDF) Nitrogen is an essential plant nutrient in the biosphere. Although N is necessary and beneficial for life, it is also a common pollutant in the atmosphere and hydrosphere as it may be lost to the atmosphere as ammonia (NH3) or nitrous oxide (N2O) gases or to groundwater as nitrate (NO3-) following fertilization. Polymer coated urea (PCU) is one type of N fertilizer which uses temperature-controlled diffusion to control N release to better match plant demand and mitigate environmental losses of N. The objectives of this project were to simultaneously compare the effects of PCU on gaseous (as N2O and NH3) and aqueous (as NO3-) N losses to the environment as compared to uncoated urea in grass systems over the entire PCU N-release period and to investigate the viability of photoacoustic infrared spectroscopy as a method to ascertain N2O and NH3 losses following fertilization. Two field studies were conducted on established turfgrass sites with a mixture of Kentucky bluegrass (KBG; Poa pratensis L.) and perennial ryegrass (PRG; Lolium perenne L.) in sand (Site 1) and loam (Site 2) soils. Each study compared an untreated control to 200 kg N ha-1 applied as either uncoated urea or PCU (Duration 45 CR®). In these studies PCU reduced NH3 emissions by 41-49% and N2O emissions by 16-54%, while improving growth and verdure. Leachate NO3- observations were inconclusive at each site. Glasshouse studies were conducted to compare N2O and NH3 emissions from PCU and uncoated urea to an untreated control utilizing a non-static, non-flow-through chamber in conjunction with photoacoustic infrared spectroscopy (PAIRS) for gas collection and analysis. Three short-term studies (17-21 d) were done with sand, sandy loam, and loam soils and a full-term (45 d) study with the loam soil. Each study was done in maize (Zea mays L.). Volatilization of ammonia was reduced by 72% and 22% in the sandy loam and loam soils, respectively, in 2008-2009 and by 14% in the loam in 2010. Evolution of N2O was reduced by 42% and 63% in the sandy loam and loam soils in 2008-2009 and by 99% in the loam in 2010. Overall, PCU decreased gaseous losses of N following fertilization while providing a steady supply of N to the plant. The utilization of PAIRS is a viable analysis method which gives higher temporal resolution analysis than is typically reported. These considerable decreases in environmental losses of N are major steps toward conserving natural resources and mitigating the negative environmental impacts associated with N fertilization in grass systems. polymer coated urea PCU urea nitrous oxide N2O ammonia NH3 nitrate NO3- turfgrass Kentucky blue grass KBG maize volatilization greenhouse gas Animal Sciences

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