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101	Implementação e validação de metodologia para determinação simultânea de Glifosato e Ampa (ácido Aminometilfosfônico/0 em águas naturais por IC/Condutometria Ribeiro, Anézia Lima Chaves 17 March 2017 (has links) Submitted by Biblioteca da Faculdade de Farmácia (bff@ndc.uff.br) on 2017-03-17T19:14:35Z No. of bitstreams: 1 Ribeiro, Anézia Lima Chaves [Dissertação, 2011].pdf: 3144917 bytes, checksum: 028a1b168bde80a2bfe9b881b9c28b08 (MD5) / Made available in DSpace on 2017-03-17T19:14:35Z (GMT). No. of bitstreams: 1 Ribeiro, Anézia Lima Chaves [Dissertação, 2011].pdf: 3144917 bytes, checksum: 028a1b168bde80a2bfe9b881b9c28b08 (MD5) / O glifosato é um herbicida organofosforado amplamente utilizado que constitui um poluente potencial do meio ambiente; ácido aminometilfosfônico (AMPA) é o seu principal metabólito. O objetivo deste estudo foi desenvolver um método direto rápido e sensível para a quantificação dos herbicidas, a fim de monitorar seus resíduos na água de diferentes fontes. Além disso, este estudo teve como objetivo elaborar um procedimento para a determinação simultânea de glifosato, AMPA e F-, Cl-, Br-, NO3 -, SO4 2- e PO4 3- na água. Em ambos os casos, foram usados a cromatografia de troca iônica com detecção condutométrica. A determinação de glifosato pode ser realizada em modo isocrático (6,0 mmol L-1 Na2CO3 e 2,0 mmol L-1 NaHCO3), enquanto a separação simultânea de glifosato, AMPA e ânions foi realizada por gradiente com as seguintes fases móveis: A: 15,0 mmol L-1 NaOH + 1,0 mmol L-1 Na2CO3 e B : Na2CO3 - 15,0 mmol L-1. A confirmação de espécies AMPA (m / z = 110) e glifosato (m / z = 168) foi realizada pelo IC-MS. A determinação do isótopo 31P por ICPMS permitiu a determinação indireta destas espécies e um teste de recuperação resultou em cerca de 105%. O método foi validado utilizando matrizes de agua ultrapura, agua superficial, mineral e água subterrânea. Por eluição isocrática, os limites de detecção (LODs) encontrados para o glifosato foram: 10 μgL-1 em água ultrapura , 54 μgL-1 em água subterrânea. Para a determinação simultânea de glifosato e AMPA, os LODs foram: 9,6 μgL-1 , 9,8 μgL-1 (água ultrapura), 9,5 μgL-1 , 60 μgL-1 (água mineral), 12,4 , 29,7 μgL-1 (agua superficial) respectivamente para glifosato e AMPA. A determinação de glifosato por IC/Condutimetria mostrou-se adequada à aplicação em águas naturais, alcançando valores de LD muito abaixo dos permitidos pela legislação vigente (500 μgL-1; Portaria MS 518 de 25/03/2004 e Resolução CONAMA 396 de 03/04/2008) e, também outros órgão internacionais como EPA, sem necessidade de preparação prévia da amostra como extração, pré-concentração e derivatização / Glyphosate is a widely used organophosphorated herbicide, which constitutes a potential pollutant of the environment; aminomethylphosphonic acid (AMPA) is its main metabolite. The purpose of this study was to develop a direct, rapid and sensitive method for quantification of the herbicide in order to monitor its residues in water from different sources. Furthermore, this study aimed to draw up a procedure for the simultaneous determination of glyphosate, AMPA and F-, Cl-, Br-, NO3 -, SO4 2- and PO4 3- in water. In both cases, ion-exchange chromatography with conductimetric detection were used. The determination of glyphosate could be performed in isocratic mode (6.0 mmol L-1 Na2CO3 and 2.0 mmol L-1 NaHCO3), while the simultaneous separation of glyphosate, AMPA and anions was performed by gradient elution with the following mobile phases: A - 15.0 mmol L-1 NaOH + 1.0 mmol L-1 Na2CO3 and B - 15.0 mmol L-1 Na2CO3. Confirmation of species AMPA (m/z = 110) and glyphosate (m/z = 168) were carried out by IC-MS. The determination of the isotope 31P by ICPMS allowed the indirect determination of these species and a recovery test resulted in about 105%. The method was validated using ultrapure, river, mineral and groundwater. With isocratic elution, limits of detection (LODs) of 10 μg L-1 in ultrapure water and 54 μg L-1 in groundwater were found for glyphosate. For the simultaneous determination of glyphosate and AMPA, LODs were, respectively, 9.6 μg L-1, 9.8 μg L-1 (ultrapure water), 9.5 μg L-1, 60 μg L-1 (mineral water), 12.4 μg L-1, 29.7 μg L-1 (river water). The determination of glyphosate IC / Conductimetry proved to be suitable for application in natural waters, reaching LD values far below those allowed by legislation (500 μg L-1), MS portaria 518 of 25/03/2004 and CONAMA Resolution 396 of 03 / 04/2008), and also other international bodies such as EPA, without previous sample preparation and extraction, pre-concentration and derivatization Glifosato Ácido aminometilfônico (AMPA) Cromatografia de íons Glyphosate Ion chromatography
102	Dibutyl Amine Detection, Quantification, and Removal with Iron(II)tetrasulfophthalocyanine (FeTSPc) Bittner, Kyle 01 August 2022 (has links) Pesticide testing is of practical interest in various areas of today’s world due to their prevalence and toxicity. These areas include agriculture, environmental, chemical plants, and many others. Herbicides, like Roundup, contain secondary amines such as glyphosate. The ability to detect secondary amines could offer a method for glyphosate detection in agricultural and environmental samples. Secondary amines can interact with metal complexes through electron charge transfer. Such interactions can cause a change in the metal’s electron configuration and energy state and can be seen in the UV-Vis spectrum. Metal phthalocyanines (MPc’s) and other organometallic complexes have been of interest for these reasons and may be applicable to glyphosate detection without extensive laboratory tests. UV-Vis absorption can further provide quantitative measurements. An evaluation of FeTSPc’s ability to aid in remediation via adsorption supports was also examined. Amines Phthalocyanines UV-Vis Dibutylamine FeTSPc Glyphosate Environmental Health
103	Testing the effects of glyphosate and a possible tradeoff with immunity on native and non-native species of crickets Mullins, Lydia R. 06 October 2020 (has links) No description available. Biology Ecology crickets herbicides tradeoff invasive species glyphosate
104	Postemergence Control of Palmer Amaranth with Mesotrione-Based Herbicide Mixtures and the Impact of Lactofen and Planting Date on the Growth, Development, and Yield of Indeterminate Soybean Mangialardi, Joseph Paul 14 August 2015 (has links) Research was conducted in 2013 and 2014 to evaluate the postemergence control of Palmer amaranth [Amaranthus palmeri (S.) Wats.] with mesotrione alone and in mixtures with fomesafen and/or glyphosate and to evaluate the impact of lactofen and planting date on growth, development, and yield of indeterminate soybean [Glycine max (L.) Merr.]. Studies included a greenhouse evaluation of different rates of mesotrione on the control of 5- and 10-cm Palmer amaranth and field studies evaluating the control of 5- to 10-cm Palmer amaranth with three rates of mesotrione applied alone and in mixtures with fomesafen and/or glyphosate. Lactofen studies include a planting date study evaluating one rate of lactofen applied at V2 soybean stage with planting dates of April 15, May 1, May 15, and June 1 and a lactofen timing study where one rate of lactofen was applied at soybean growth stages ranging from V1 to R5. Glyphosate resistant Application timing Treatments Planting date Growth stage
105	Development of Herbicide Tolerant Tomato Sharma, Gourav 08 December 2017 (has links) Tomato is a major horticulture crop grown across the globe. Unfortunately, its yield is reduced by 25% because of auxin herbicides and glyphosate drift. In this present study, wild germplasm of tomato was screened for herbicide tolerance. From the greenhouse study nine accessions for glyphosate and 2,4-D, eleven accessions for dicamba, five accessions for quinclorac, eight accessions for aminocyclopyrachlor, and two accessions for picloram and aminopyralid were identified to be tolerant. A few accessions were selected from each herbicide tolerant group for field trials at two locations in Mississippi in 2016 and 2017. Results indicated that TOM18 was most tolerant to dicamba herbicide, while TOM87 and TOM129 to glyphosate and quinclorac herbicide, respectively, on the basis of yield and injury. Molecular experiments were conducted to measure the genetic diversity among diverse germplasm. Genetic diversity analysis showed wild accessions to be highly diverse as compared to cultivated tomato. Herbicide tolerant Wild tomaotes Auxin herbicides Herbicide drift Glyphosate
106	The effects of glyphosate salts and volatility-reducing agents (VRA) on dicamba volatility Glenn, Nicole 09 December 2022 (has links) (PDF) Dicamba is often tank mixed with glyphosate to increase herbicidal efficacy but may contribute to off-target movement (OTM). In recent years, volatilization has become problematic for dicamba-containing herbicides, resulting in increased regulatory requirements necessitating the use of volatility-reducing agents (VRA) for application. Research was conducted in 2021 and 2022 using low tunnels in a field environment and humidomes in a greenhouse environment to further assess how glyphosate salts and VRAs affect dicamba volatility. Our data indicate that the inclusion of glyphosate to dicamba can increase dicamba volatility, depending on the glyphosate salt used. The inclusion of the evaluated VRAs will decrease dicamba volatility when applied to a tank mixture of dicamba plus potassium salt of glyphosate. dicamba volatility glyphosate volatility-reducing agent (VRA) herbicides soybeans Agriculture
107	Seasonal comparison on the effectiveness of control methods for Microstegium vimineum in the North Carolina Piedmont Beam, Casey 09 December 2022 (has links) Microstegium vimineum, or Japanese stilt grass, is an invasive species that readily outcompetes native vegetation and is of poor forage quality for wildlife. This species is widespread throughout the southeastern United States, including North Carolina. Much of this region is privately owned and there is a gap in the literature providing succinct information about the best methods of treatment, timing of treatment, and effects of treatment on native herbaceous plants in this region. In two parts, this study seeks to address this gap by employing treatments that are easily accessible to landowners at different times during the growing season and assessing the effects on the herbaceous plant community post-treatment. Results of this study found that application of glyphosate was the most effective treatment at M. vimineum removal, application of household vinegar was the most effective at increasing post-treatment species richness and diversity, and that seasonality did not play a role in the effectiveness of treatment options. This study will increase landowner knowledge on treating this invasive successfully and choosing a treatment that fosters an understory that meets their management goals. North Carolina invasive species Japanese Stilt grass vinegar glyphosate
108	Rice (Oryza sativa) response to sub-lethal concentrations of crop desiccants McCoy, Justin M 13 December 2019 (has links) Research was conducted at the Mississippi State University Delta Research and Extension Center from 2016 to 2018 to determine the effects of sub-lethal concentrations of paraquat, glyphosate, saflufenacil, and sodium chlorate exposure to rice at late-season growth stages, determine the effects of exposure to sub-lethal concentrations of glyphosate or paraquat on multiple rice cultivars, and characterize the effects of paraquat exposure and Oebalus pugnax feeding on rice grain quality. In the current research, rough rice grain yields were reduced by exposure to sub-lethal concentrations of soybean desiccants 0 to 28 DAH. Rice injury was determined to not be an accurate predictor of rough rice grain yield loss as injury did not exceed 20% with any desiccant, and no injury was observed from glyphosate applications. Rough rice grain yield reductions were reflected in yield component reductions following desiccant exposure. Applications of sub-lethal concentrations of glyphosate or paraquat to rice at 50% heading caused rough rice grain yield decreases ranging from 0 to 20 and 9 to 21 % respectively. Hybrid cultivars were unaffected following glyphosate exposure at 50% heading. In the current research, observations of paraquat exposure or O. pugnax infestation of rice at the soft dough growth stage suggest rice may exhibit severe sensitivity to both events in the form of reduced kernel weight and reductions in rice milling quality. Rough rice grain yield reductions coupled with milling quality reductions and driven by the proximity of rice to corn, cotton, soybean, and sorghum in Mississippi creates the need to exercise caution when applying desiccants. Rice off-target movement drift desiccant paraquat glyphosate sub-lethal
109	Photopolymerizable “Roundup” Synthesis, Herbicidal Activity and Coating Formulation Piunova, Victoria A. 27 June 2006 (has links) No description available. Chemistry, Polymer acrylated glyphosate acrylic N-Acryloyl-N NMR phosphonomethyl
110	Synthèse et caractérisation des matériaux nanostructurés et leur mise en oeuvre comme photocatalyseurs pour la dégradation du glyphosate en milieux aqueux Feriani, Mabrouk 24 April 2018 (has links) L’utilisation des pesticides n’a cessé d’augmenter en particulier le glyphosate, herbicide utilisé principalement dans l’agriculture. Ses effets ont été démontrés néfastes sur l’environnement et sur la santé humaine. Bien que la plupart du glyphosate résiduel soit adsorbé par les constituants du sol, une partie peut être désorbée ou atteindre les eaux de surface par érosion. Le renforcement des normes de qualité de l'eau en milieu agricole et urbain entraîne le développement de nouveaux procédés. Les photocatalyseurs à base de TiO2 peuvent procurer une solution attrayante pour l’élimination de cet herbicide. Actif uniquement dans le domaine de l’UV qui représente 4% du rayonnement solaire, étendre cette réactivité photocatalytique dans le domaine du visible est un enjeu majeur. Le dopage du TiO2 à l’azote et au graphène a permis une élimination totale du glyphosate au bout de 30 minutes. Après sa synthèse, le photocatalyseur GR-N/TiO2 a été caractérisé par différentes techniques à savoir la diffraction des rayons X (DRX), l’infrarouge à transformée de Fourier (FTIR), la spectroscopie de photoélectrons X (XPS) et la microscopie électronique par transmission (TEM). L'activité photocatalytique est testée sur la dégradation du glyphosate sous irradiation de la lumière visible. Les résultats montrent que le composite GR-N/TiO2 peut effectivement photodégrader le glyphosate grâce à une amélioration impressionnante de l’activité photocatalytique due à une grande adsorption du glyphosate sur le nanomatériau synthétisé et à l’extension de l'absorption au domaine du visible. / Pesticide use has been increasing especially for glyphosate an herbicide used mainly in agriculture. Its effects have been proven harmful to the environment and human health. Although most of the residual glyphosate can be adsorbed by the soil constituents, a part may be desorbed or reach surface waters by erosion. Strengthening the quality standards of water in agricultural and urban areas leads to the development of new processes. TiO2- based photocatalysts can provide an attractive solution for the elimination of this herbicide. Active under UV light which represents only 4% of solar radiation, extending this photocatalytic activity to the visible range is a major issue. Doping TiO2 with nitrogen and graphene shows a total elimination of glyphosate within 30 minutes of reaction. The photocatalyst GR-N/TiO2 was characterized by various techniques namely X-ray diffraction (XRD), infrared Fourier transform (FTIR), X-ray photoelectron spectroscopy (XPS) and transmission electron microscopy (TEM). The photocatalytic activity was tested under visible light irradiation to glyphosate degradation. Results showed that the GRN/ TiO2 composite can effectively photodegrade glyphosate with an impressive improvement of the photocatalytic activity due to a large adsorption of glyphosate on the synthesized nanomaterial and the extension of the absorption to the visible light region conferred to photocatalyst. S 405 UL 2016 Glyphosate -- Biodégradation Photocatalyse Nanomatériaux

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