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ENGINEERING ZINC OXIDE NANOPARTICLES TO BE USED AS NANOFERTILIZERSElhaj Baddar, Zeinah 01 January 2018 (has links)
Zinc deficient soils, or soils with low Zn bioavailability, are widespread, which exacerbates Zn deficiency in human as crops grown on these soils have low Zn content. Often crop yields are also compromised. Fertilizers based on soluble Zn salts often have limited efficacy in such soils. In this research, we evaluate the performance of polymer coated and bare ZnO nanoparticles (NPs) in an attempt to overcome limitations of soluble Zn salts in alkaline soils. We first synthesized 20-30 nm bare ZnO NPs with different surface chemistries to impart colloidal stability to the particles. Bare ZnO were treated in phosphate solution under certain conditions leading to the formation of a core made of ZnO NPs that is covered by a shell of amorphous Zn3(PO4)2 (core-shell NPs). This confers a negative charge to the particles over a wide pH range. The addition of nonionic (neutral dextran) and polyelectrolyte (negatively charged dextran sulfate (DEX(SO4)) during the synthesis resulted in the formation of DEX and DEX(SO4) ZnO NPs. Dextran has a minimal effect on the surface charge of ZnO but dextran sulfate confers a net negative charge. Bare and core-shell ZnO NPs were both electrostatically stabilized whereas DEX and DEX(SO4) ZnO NPs were sterically and electrosterically stabilized, respectively. We investigated the effect of treating seeds with ZnO NPs on the growth and accumulation of Zn in wheat (Triticum aestivum) seedlings in comparison to ZnSO4. All ZnO NPs stimulated seedling growth. Seedlings accumulated higher Zn concentrations when treated with ZnO NPs than with ZnSO4. Zinc sulfate was toxic even at the lower exposure concentrations, which was demonstrated by significantly lower germination success and seedling growth. In the second experiment, we investigated the effect of pH on the attachment and dissolution of ZnO NPs in soil, as compared to ZnSO4. Soil pH was adjusted to 6 and 8, then the soil was spiked with 100 mg Zn/kg soil in the form of ZnSO4, bare, DEX, DEX(SO4), and core-shell ZnO NPs. The results showed that DEX and core-shell ZnO NPs had significantly higher total Zn in soil solution compared to ZnSO4 at pH 8, with little dissolution. Dissolved Zn was similar among treatments except ZnSO4 at pH 6, indicating little dissolution of the ZnO NPs at either pH value. We also found that the engineered coatings dictate the behavior of the particles in simple aqueous systems, but their properties are altered in natural soil solutions because of the dominant effect of natural organic matter (NOM) on their surface chemistry. Based on the outcomes of the previous two experiments, we selected DEX and bare ZnO NPs to test the efficacy of ZnO NPs in delivering Zn to the grain of wheat under greenhouse conditions. We performed two independent studies where seeds were either treated with the NPs or grown in a soil spiked with Zn at pH 6 and 8 and spiked with Zn treatments (nano and ionic). We found that treating seeds with bare ZnO NPs significantly enhanced grain Zn concentrations as compared to the control, DEX-ZnO NPs, and ZnSO4. There were no differences in grain Zn concentration of plants treated with ionic or nano Zn treatments regardless of the soil pH. This work has elucidated important principles which will help carry forward efforts at developing effective ZnO NP-based fertilizers. It also suggests that treatment of seeds with ZnO NPs is more effective than amending soil or treating seeds with ZnSO4.
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Optimization of material composition and processing parameters for hybrid organic-inorganic solar cellsSalpeter, Garrett Morgan 16 February 2011 (has links)
The widespread adoption of hybrid organic-inorganic solar cells has been delayed by low performance. Improving performance requires a firm understanding of how to optimize both material composition and processing parameters. In this thesis, we examine processing parameters that include solution composition, annealing temperature, and the rates of spin casting and evaporative coating. We also find that the optimal weight ratio for the active layer of a ZnO:P3HT solar cell is 40 wt. % ZnO. / text
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Graphenated organic nanoparticles immunosensors for the detection of TB biomarkersMgwili, Phelisa Yonela January 2017 (has links)
Magister Scientiae - MSc (Chemistry) / Pulmonary Tuberculosis (TB) a disease second to HIV/AIDS is a global health problem that
arises in two states; as an active state and as a latent state. Diagnosis of active TB is tedious
and requires expensive procedures since there is no recognizable method for the sole detection
of active TB. The current diagnosis consists of chest X-rays and multiple sputum cultures used
for acid-fast bacilli detection. The TB diagnosis of children is particularly difficult which
further complicates the diagnosis. Thus, rapid identification of this pathogen is important for
the treatment and control of this infection to allow effective and timely therapy. In an effort to
solve this issue, this study reports the development of immunosensors constructed with
electroactive layers of amino groups functionalized graphene oxide (GO) doped respectively
with green synthesized zinc oxide (ZnO NPs) nanoparticles and silver (Ag NPs) nanoparticles
on glassy carbon electrodes. The surface morphology of GO, ZnO NPs, Ag NPs and their
composites was revealed by employing High-Resolution Transmission Electron Microscopy
(HR-TEM) and High-Resolution Scanning Electron Microscopy (HR-SEM) while the
composition and structure of these materials were studied using Fourier Transform Infra-Red
Spectroscopy (FTIR). The resultant graphene oxide-metallic composites were covalently
attached with CFP-10 and/or ESAT-6 antibodies to achieve the electrochemical detection. The
immunosensor was then used for the impedimetric and amperometric detection of anti-CFP-10
and/or anti-ESAT-6 antigens in standard solutions.
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Dissolution and aggregation of zinc oxide nanoparticles at circumneutral pH; a study of size effects in the presence and absence of citric acidRupasinghe, R-A-Thilini Perera 01 July 2011 (has links)
Understanding the size dependent dissolution of engineered nanoparticles is one important aspect in addressing the potential environmental and health impacts of these materials as well as their long-term stability. In this study, experimental measurements of size dependent dissolution of well-characterized zinc oxide (ZnO) nanoparticles with particle diameters in the range of 4 to 130 nm have been measured and compared at circumneutral pH (pH 7.5). Enhanced dissolution was found for the smaller particles with the largest enhancement observed in Zn2+(aq) concentrations for 4 nm diameter ZnO nanoparticles compared to larger-sized particles. Interestingly, size dependent dissolution was observed even though the nanoparticles aggregated with hydrodynamic diameters on the order of 1-3 m in diameter. Although these results are found to be in qualitative agreement with theoretical predictions used to predict the dissolution of solids, a linearized form of the Kelvin equation to calculate a bulk dissolution value for ZnO and a surface free energy yielded quantities inconsistent with known literature values. It is therefore concluded that deviations from solubility behavior from classical thermodynamics are due to a lack of the detailed knowledge of the surface free energy as well as its dependence on the details of the surface structure, surface properties, including the presence of different surface crystal facets and adsorbed ligands, as well of aggregation state. The presence of citric acid significantly enhances the extent of ZnO dissolution for all sizes such that no significant differences were observed for total Zn2+(aq) concentrations for nanoparticles between 4 to 130 nm. This can be attributed to ligand enhanced dissolution of ZnO nanoparticles where there is no dependence on size. Adsorption of citrates onto ZnO nanoparticles was observed using ATR-FTIR spectroscopy. A reversal of surface charge of ZnO nanoparticles was observed upon adsorption of citrates. Adsorption of negatively charged Cit3- onto ZnO nanoparticles make the surfaces negatively charged and this result in a repulsion between nanoparticles eventually leading to a lesser extent of aggregation. Formation of a stable suspension was also observed in the presence of citric acid. These trends observed in aggregation pattern are of great environmental and biological importance as citric acid is abandon in the environment as well as in human body.
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An investigation into the mechanism of toxicity of zinc oxide nanoparticlesSharma, Vyom January 2011 (has links)
The wide scale use of ZnO nanoparticles (NPs) in the world consumer market has resulted in likelihood of exposure to human beings. The present study was aimed to assess the in vitro and in vivo interactions of ZnO NPs in the mammalian system and to elucidate the possible mechanism of their toxicity. Our in vitro results using human epidermal cells (A431), primary human epidermal keratinocytes and human liver cells (HepG2) demonstrated that cells exposed to ZnO NPs exhibit a decrease in cell viability which was independent of NP dissolution. ZnO NPs also induced oxidative DNA damage as evidenced by an increase in the Fpg sensitive sites. The reactive oxygen species triggered a decrease in mitochondrial membrane potential and an increase in the ratio of Bax/Bcl2 leading to apoptosis through the intrinsic pathway. In addition, ZnO NPs induced phosphorylation of JNK, P38 and P53ser15. The results from our in vivo studies using a mouse model showed that ZnO NPs induce lipid peroxidation, oxidative DNA damage and apoptosis in liver which further confirmed our in vitro findings. The data from the present study provide valuable insights into the cellular interactions of ZnO NPs and the underlying molecular mechanism of their toxicity. The results also stress the need for a comprehensive environmental health and safety assessment of engineered nanomaterials to ensure safer nanotechnology based products.
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Les effets de revêtements de surface sur la dissolution et la bioaccumulation de nanoparticules d'oxyde de zinc par l'algue unicellulaire, C. reinhardtiiMerdzan, Vladimir 12 1900 (has links)
Au cours de la dernière décennie, les nanoparticules ont connu un essor sans précédent dans plusieurs domaines. On peut retrouver ces nanoparticules dans des secteurs aussi variés tels que la médecine, l’électronique, les écrans solaires, les cosmétiques et les plastiques, pour ne nommer que ceux-là. Cette utilisation massive a eu un effet pervers sur l’environnement, sachant qu’une grande partie de ces produits se sont retrouvés inévitablement dans les milieux naturels. Plusieurs études révèlent qu’autant la présence des nanoparticules que leurs produits de dissolution sont à prendre en considération lorsque des travaux toxicologiques ou le devenir de ces matériaux sont étudiés. Il est désormais clair que les propriétés de surface de ces nanoparticules jouent un rôle central sur leur comportement dans les solutions aqueuses; que ce soit les interactions avec des organismes ou entre les particules elles-mêmes. Afin d’évaluer le devenir de nZnO, une étude sur la dissolution ainsi que la bioaccumulation a été réalisée avec l’algue modèle Chlamydomonas reinhardtii en présence de nanoparticules ayant différents enrobages. Les nanoparticules d’oxyde de zinc suivantes ont été étudiées : (i) nZnO sans enrobage (nZnO); (ii) nZnO avec enrobage d’acide polyacrylique (nZnO-PAA) et (iii) nZnO avec enrobage d’hexamétaphosphate de sodium (nZnO-HMP). La dissolution était mesurée à l’aide de trois techniques : ultrafiltration par centrifugation (CU); technique potentiométrique (scanned stripping chronopotentiometry, SSCP) et spectrométrie de masse – plasma à couplage inductif couplé à une résine échangeuse d’ions (resin-based inductively coupled plasma-mass spectrometry, resin-based ICP-MS). Les résultats obtenus démontrent une grande tendance à la dissolution pour le nZnO (presque totale) tandis que pour le nZnO-PAA et le nZnO-HMP, la dissolution est dépendante de la nature de l’enrobage le composant. Pour la bioaccumulation sur l’algue testée, les données montrent une grande dépendance au zinc libre issu de la dissolution pour nZnO et nZnO-PAA. À l’inverse, le nZnO-HMP démontre une bioaccumulation plus élevée par comparaison aux mêmes concentrations d’expositions du zinc libre, expliquée par la stimulation de l’internalisation du zinc provoqué par la présence de phosphate constituant l’enrobage de nZnO-HMP. / Over the last decade, the use of nanoparticles (NP) has been increasing exponentially in numerous sectors, leading to their massive release into the environment. For example, zinc oxide nanoparticles (nZnO) can be found in areas such as medicine, electronics, sunscreens, cosmetics and plastics. Concerns have therefore been raised about the impacts of the NP on the natural environment, as well as their consequences for humans. Multiple studies reveal that not only the NP but also their dissolution products may have impacts on environmental systems. It is well understood that surface properties of engineered nanoparticles in aqueous solution play a pivotal role in nanoparticle behavior, including their interactions with organisms. Therefore, in order to assess the behavior of nZnO, this study focuses on their dissolution and evaluates the bioaccumulation of 3 nanoparticles with different surface stabilizations by the freshwater algae Chlamydomonas reinhardtii. The following NP were studied: (i) bare nZnO, (ii) polyacrylic acid coated (nZnO-PAA) and (iii) sodium hexametaphosphate coated (nZnO-HMP). Three different techniques were used to quantify dissolution of the nZnO: centrifugal ultrafiltration (CU), scanned stripping chronopotentiometry (SSCP) and resin-based inductively coupled plasma-mass spectrometry (resin-based ICP-MS). The results reveal a high dissolution of the bare nZnO (nearly total) while the dissolution of the polyacrylate coated and hexamataphosphate coated nZnO were highly dependent on the nature of the stabilizer. As a consequence, bioaccumulation in model algae C. reinhardtii was strongly related to the release of free zinc in the bare nZnO and the nZnO-PAA. On the other hand, algae exposed to nZnO-HMP appeared to be stimulated by the phosphate coating, leading to higher bioaccumulation than for the free zinc, once again demonstrating the importance of the nature of the stabilizer.
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Toxicity Of Silver Nanoparticles In Mouse Embryonic Stem Cells And Chemical Based Reprogramming Of Somatic Cells To Sphere CellsRajanahalli Krishnamurthy, Pavan January 2011 (has links)
No description available.
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On the stability of a variety of organic photovoltaic devices by IPCE and in situ IPCE analyses – the ISOS-3 inter-laboratory collaborationTeran-Escobar, Gerardo, Tanenbaum, David M., Voroshazi, Eszter, Hermenau, Martin, Norrman, Kion, Lloyd, Matthew T., Galagan, Yulia, Zimmermann, Birger, Hösel, Markus, Dam, Henrik F., Jørgensen, Mikkel, Gevorgyan, Suren, Kudret, Suleyman, Maes, Wouter, Lutsen, Laurence, Vanderzande, Dirk, Würfel, Uli, Andriessen, Ronn, Rösch, Roland, Hoppe, Harald, Rivaton, Agnès, Uzunoğlu, Gülşah Y., Germack, David, Andreasen, Birgitta, Madsen, Morten V., Bundgaard, Eva, Krebs, Frederik C., Lira-Cantu, Monica January 2012 (has links)
This work is part of the inter-laboratory collaboration to study the stability of seven distinct sets of state-of-the-art organic photovoltaic (OPV) devices prepared by leading research laboratories. All devices have been shipped to and degraded at RISØ-DTU up to 1830 hours in accordance with established ISOS-3 protocols under defined illumination conditions. In this work, we apply the Incident Photon-to-Electron Conversion Efficiency (IPCE) and the in situ IPCE techniques to determine the relation between solar cell performance and solar cell stability. Different ageing conditions were considered: accelerated full sun simulation, low level indoor fluorescent lighting and dark storage. The devices were also monitored under conditions of ambient and inert (N2) atmospheres, which allows for the identification of the solar cell materials more susceptible to degradation by ambient air (oxygen and moisture). The different OPVs configurations permitted the study of the intrinsic stability of the devices depending on: two different ITO-replacement alternatives, two different hole extraction layers (PEDOT:PSS and MoO3), and two different P3HT-based polymers. The response of un-encapsulated devices to ambient atmosphere offered insight into the importance of moisture in solar cell performance. Our results demonstrate that the IPCE and the in situ IPCE techniques are valuable analytical methods to understand device degradation and solar cell lifetime. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.
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