Global ETD Search

41	Nanostructuring noble metals as unsupported electrocatalysts for polymer electrolyte fuel cells Cai, Bin, Henning, Sebastian, Herranz, Juan, Schmidt, Thomas J., Eychmüller, Alexander 28 December 2018 (has links) Two major challenges that impede fuel cell technology breakthrough are the insufficient activity of the electrocatalysts for the oxygen reduction reaction and their degradation during operation, caused by the potential-induced corrosion of their carbon-support upon fuel cell operation. Unsupported electrocatalysts derived from tailored noble-metal nanostructures are superior to the conventional carbon-supported Pt nanoparticle catalysts and address these barriers by fine-tuning the surface composition and eliminating the support. Herein, recent efforts and achievements in the design, synthesis and characterization of unsupported electrocatalysts are reviewed, paying special attention to noble-metal aerogels, nano/meso-structured thin films and template-derived metal nanoarchitectures. Their electrocatalytic performances for oxygen reduction are compared and discussed, and examples of successful catalyst transfer to polymer electrolyte fuel cells are highlighted. This report aims to demonstrate the potential and challenges of implementing unsupported catalysts in fuel cells, thereby providing a perspective on the further development of these materials. info:eu-repo/classification/ddc/600 ddc:600
42	Synthese, Charakterisierung und elektrochemische Eigenschaften nanostrukturierter, perowskitischer Elektrodenmaterialien Franke, Daniela 30 November 2012 (has links) La0.6Ca0.4Mn0.8Ni0.2O3-, La0.6Ca0.4Mn0.8Fe0.2O3- und La0.75Ca0.25Mn0.5Fe0.5O3-Volumenmaterialien wurden im potentiometrischen Messaufbau bereits erfolgreich auf ihre NO-Sensitivität getestet. Keramischen Nanomaterialien werden generell eine Reihe neuer oder verbesserter Eigenschaften (verbessertes Sinterverhalten, erhöhte NOx-Sensitivität, höhere Leitfähigkeit) zugesprochen. La0.6Ca0.4Mn0.8Ni0.2O3, La0.6Ca0.4Mn0.8Fe0.2O3 und La0.75Ca0.25Mn0.5Fe0.5O3 wurden mittels PVA/Sucrose-Methode, Aktivkohlemethode und Fällungssynthese als Nanomaterialien sowie mit Festkörperreaktion als Volumenmaterialien dargestellt und mit typischen Charakterisierungsmethoden untersucht. Die Materialien wurden in verschiedenen Schichtdicken auf YSZ-Substrate aufgetragen und potentiometrisch sowie impedanzspektroskopisch auf ihre NO-Sensitivität und die Querempfindlichkeit gegenüber NO2 und Propylen geprüft. Potentiometrische Messungen im NO-Gasstrom ergeben eine Abhängigkeit der NO-Sensitivität von der Partikelgröße, der Schichtdicke und der Beschichtungsmethode. Impedanzspektroskopische Messungen an beidseitig beschichteten YSZ-Substraten zeigen ebenfalls eine Abhängigkeit des Zellwiderstands von der NO-Konzentration und der Partikelgröße. Die Nanomaterialien zeigen bei unterschiedlichen Sauerstoffpartialdrücken im untersuchten Temperaturbereich (300°C bis 850°C) höhere Leitfähigkeiten als die Volumenmaterialien gleicher Zusammensetzung. Dieses Verhalten wird mit dem höheren Sauerstoffaustausch der Nanomaterialien in Verbindung gebracht, der zur Erzeugung zusätzlicher Defekte in der Kristallstruktur führt. Die Nanostruktur und somit eine entsprechend hohe Leitfähigkeit bleiben bei hohen Sintertemperaturen (T > 1000°C), die der Herstellung gasdichter Presslinge dienen, erhalten. XANES- und Photoelektronenspektroskopie wurden verwendet, um die Punktdefekte zu definieren. info:eu-repo/classification/ddc/540 ddc:540
43	Nanostructured Bulk Thermoelectrics : Scalable Fabrication Routes, Processing and Evaluation Yakhshi Tafti, Mohsen January 2016 (has links) Current fossil fuel based energy sources have a huge shortcoming when one discusses their efficiency. The conversion efficiency of fossil fuel-based technologies is less than 40% in best cases. Therefore, until the renewable energy section is mature enough to handle all the energy demand one has to research and develop the technologies available to harvest the energy from the waste heat generated in fossil fuel-based supply sources. One of these emerging technologies is the use of thermoelectric (TE) devices to achieve this goal, which are solid-state devices capable of directly interconverting between heat and electrical energy. In the past decade there has been a significant scientific and financial investment within the field to enhance their properties and result in time/energy efficient fabrication processes of TE materials and devices for a more sustainable environment. In this thesis with use of chemical synthesis routes for nanostructured bulk thermoelectric materials iron antimonide (FeSb2), skutterudites (based on general formula of RzMxCo1-xSb3-yNy) and copper selenide (Cu2Se) are developed. These materials are promising candidates for use in thermoelectric generators (TEG) or for sensing applications. Using chemical synthesis routes such as chemical co-precipitation, salt melting in marginal solvents and thermolysis, fabrication of these TE materials with good performance can be performed with high degree of reproducibility, in a much shorter time, and easily scalable manner for industrial processes. The TE figure of merit ZT of these materials is comparable to, or better than their conventional method counterparts to ensure the applicability of these processes in industrial scale. Finally, through thorough investigation, optimized consolidation parameters were generated for compaction of each family of materials using Spark Plasma Sintering technique (SPS). As each family of TE nanomaterial investigated in this thesis had little to no prior consolidation literature available, specific parameters had to be studied and generated. The aim of studies on compaction parameters were to focus on preservation of the nanostructured features of the powder while reaching a high compaction density to have positive effects on the materials TE figure of merit. / Dagens fossilbränslebaserade energikällor har en enorm brist gällande effektivitet. Effektiviteten av fossilbränslebaserade teknologiers omvandling är mindre än 40 % i bästa fall. Därför tills förnybar energi är mogen nog att hantera alla energibehov, måste man forska och utveckla teknik för att skörda energi från spillvärme i fossilbränslebaserade försörjningskällor. En av dessa nya tekniker är tillämpning av termoelektriska (TE) material för att uppnå målet. Nämnde material är Soldi-State materialer som kan transformera mellan värme och elektrisk energi. Under det senaste decenniet har det pågått en stor vetenskaplig och ekonomisk investering inom området för att förbättra termoelektriska materials egenskaper. Dessutom ville man ta fram tid/energieffektiva TE material och komponenter för en mer hållbar miljö. I denna avhandling utvecklades och producerades termoelektriska material såsom järn antimonid (FeSb2), skutterudit (baserat på allmänna formeln RzMxCo1-xSb3-YNY) och koppar selenid (Cu2Se) med hjälp av kemiska syntesmetoder. Genom att Använda kemiska syntesmetoder som kemisk samutfällning, salt smältning i marginella lösningsmedel och termolys, kan material med hög grad av reproducerbarhet och ställbar för industriella processer tillverkas. Termoelektrisk omvandling effektivitet hos uppnådde material är betydligt högre än resultat av andra studier. I och med detta kan man säga att materialet kan användas inom industri. Slutligen, genom en grundlig undersökning optimerades packningsparametrar som genererades för packning av varje materialgrupp med hjälp av Spark Plasma Sintring teknik (SPS). Eftersom ingen relevant studie finns för varje grupp av termoelektriska nanomaterial som undersökts i denna avhandling, studerades och genererades dessa specifika parametrar. Syftet med studien är att fokusera på bevarande av nanostrukturerade egenskaperna hos pulvret och att samtidigt nå en hög packningstäthet för att ha positiva effekter på materialens termoelektriska omvandlingseffektivitet. / <p>QC 20160503</p> / NEXTEC / SCALTEG Thermoelectric Iron antimonide (FeSb2) Skutterudite Copper Selenide (Cu2Se) Spark Plasma Sintering (SPS) nanomaterial
44	THE EFFECTS OF MANUFACTURED NANOMATERIAL TRANSFORMATIONS ON BIOAVAILABILITY, TOXICITY AND TRANSCRIPTOMIC RESPONSES OF <em>CAENORHABDITIS ELEGANS</em> Starnes, Daniel L. 01 January 2016 (has links) In recent decades, there has been a rapid expansion in the use of manufactured nanoparticles (MNPs). Experimental evidence and material flow models predict that MNPs enter wastewater treatment plants and partition to sewage sludge and majority of that sludge is land applied as biosolids. During wastewater treatment and after land application, MNPs undergo biogeochemical transformations (aging). The primary transformation process for silver MNPs (Ag-MNPs) is sulfidation, while zinc oxide MNPs (ZnO-MNPs) most likely undergo phosphatation and sulfidation. Our overall goal was to assess bioavailability and toxicogenomic impacts of both pristine, defined as-synthesized, and aged Ag- and ZnO-MNPs, as well as their respective ions, to a model organism, the soil nematode Caenorhabditis elegans. We first investigated the toxicity of pristine Ag-MNPs, sulfidized Ag-MNPs (sAg-MNPs), and AgNO3 to identify the most sensitive ecologically relevant endpoint in C. elegans. We identified reproduction as the most sensitive endpoint for all treatments with sAg-MNPs being about 10-fold less toxic than pristine Ag-MNPs. Using synchrotron x-ray microspectroscopy we demonstrated that AgNO3 and pristine Ag-MNPs had similar bioavailability while aged sAg-MNPs caused toxicity without being taken up by C. elegans. Comparisons of the genomic impacts of both MNPs revealed that Ag-MNPs and sAg-MNPs have transcriptomic profiles distinct from each other and from AgNO3. The toxicity mechanisms of sAg-MNPs are possibly associated with damaging effects to cuticle. We also investigated the effects pristine zinc oxide MNPs (ZnO-MNPs) and aged ZnO-MNPs, including phosphatated (pZnO-MNPs) and sulfidized (sZnO-MNPs), as well as ZnSO4 have on C. elegans using a toxicogenomic approach. Aging of ZnO-MNPs reduced toxicity nearly 10-fold. Toxicity of pristine ZnO-MNPs was similar to the toxicity caused by ZnSO4 but less than 30% of responding genes was shared between these two treatments. This suggests that some of the effects of pristine ZnO-MNPs are also particle-specific. The genomic results showed that based on Gene Ontology and induced biological pathways all MNP treatments shared more similarities than any MNP treatment did with ZnSO4. This dissertation demonstrates that the toxicity of Ag- and ZnO-MNPs to C. elegans is reduced and operates through different mechanisms after transformation during the wastewater treatment process. Silver Nanomaterials Zinc oxide nanomaterials Bioaccumulation Nanomaterial transformations Wastewater treatment Agriculture Agricultural Science Agriculture Genomics Toxicology
45	INVESTIGATIONS OF OXIDATIVE STRESS EFFECTS AND THEIR MECHANISMS IN RAT BRAIN AFTER SYSTEMIC ADMINISTRATION OF CERIA ENGINEERED NANOMATERIALS Hardas, Sarita S. 01 January 2012 (has links) Advancing applications of engineered nanomaterials (ENM) in various fields create the opportunity for intended (e.g. drug and gene delivery) or unintended (e.g. occupational and environmental) exposure to ENM. However, the knowledge of ENM-toxicity is lagging behind their application development. Understanding the ENM hazard can help us to avoid potential human health problems associated with ENM applications as well as to increase their public acceptance. Ceria (cerium [Ce] oxide) ENM have many current and potential commercial applications. Beyond the traditional use of ceria as an abrasive, the scope of ceria ENM applications now extends into fuel cell manufacturing, diesel fuel additives and for therapeutic intervention as a putative antioxidant. However, the biological effects of ceria ENM exposure have yet to be fully defined. Both pro-and anti-oxidative effects of ceria ENM exposure are repeatedly reported in literature. EPA, NIEHS and OECD organizations have nominated ceria for its toxicological evaluation. All these together gave us the impetus to examine the oxidative stress effects of ceria ENM after systemic administration. Induction of oxidative stress is one of the primary mechanisms of ENM toxicity. Oxidative stress plays an important role in maintaining the redox homeostasis in the biological system. Increased oxidative stress, due to depletion of antioxidant enzymes or molecules and / or due to increased production of reactive oxygen (ROS) or nitrogen (RNS) species may lead to protein oxidation, lipid peroxidation and/or DNA damage. Increased protein oxidation or lipid peroxidation together with antioxidant protein levels and activity can serve as markers of oxidative stress. To investigate the oxidative stress effects and the mechanisms of ceria-ENM toxicity, fully characterized ceria ENM of different sizes (~ 5nm, 15nm, 30nm, 55nm and nanorods) were systematically injected into rats intravenously in separate experiments. Three brain regions (hippocampus, cortex and cerebellum) were harvested from control and ceria treated rats after various exposure periods for oxidative stress assessment. The levels of oxidative stress markers viz. protein carbonyl (PC), 3-nitrotyrosine (3NT), and protein bound 4-hydroxy-2-trans-nonenal (HNE) were evaluated for each treatment in each control and treated rat organ. Further, the levels and activities of antioxidant proteins, such as catalase, glutathione peroxidase (GPx), glutathione reductase (GR), super oxide dismutase (SOD), were measured together with levels of heat shock proteins heme oxygenase -1 and 70 (HO-1 and Hsp-70). In addition, the levels of pro-inflammatory cytokines IL-1β, TNF-α, pro-caspase-3, and autophagy marker LC-3A/B were measured by Western blot technique. In agreement with the literature-proposed model of oxidative stress hierarchy mechanism of ENM-toxicity, the statistical analysis of all the results revealed that the ceria ENM-induced oxidative stress mediated biological response strongly depends on the exposure period and to some extent on the size of ceria ENM. More specifically, a single intravenous injection of ceria ENM induced tier-1 (phase-II antioxidant) response after shorter exposure periods (1 h and 20 h) in rat brain. Upon failure of tier-1 response after longer exposure periods (1 d to 30 d), escalated oxidative stress consequently induced tier-2 and tier-3 oxidative stress responses. Based on our observations made at chronic exposure period (90 d) after the single i.v. injection of ceria ENM, we could extend the model of oxidative stress hierarchy mechanisms for ceria-ENM-induced toxicity. Considering the evaluation of all the oxidative stress indices measured in 3-brain regions, oxidative stress effects were more prominent in hippocampus and the least in cerebellum, but no specific pattern or any significant difference was deduced. Ceria cerium oxide nanomaterial nanoparticles nanotoxicity oxidative stress phase-II enzymes Chemistry Nanoscience and Nanotechnology Toxicology
46	Green Organic Solar Cells from a Water Soluble Polymer and Nancrystalline TiO2 Qiao, Qiquan 01 January 2006 (has links) The cost of the present generation of inorganic silicon solar cells is very high and further breakthroughs in cost and efficiency using traditional materials are becoming less and less likely after over 50 years of development. Next generation organic solar cells offer a solution to the limitations of silicon through the vision of low-cost, liquid-based, large area fabrication technology based on polymer and nanomaterials at room temperature. However, most polymers used in solar cells are dissolved in organic solvents such as xylene, toluene, chloroform, and chlorobenzene. Such solvents are harmful to people and environments, leading to higher costs due to complicated waste disposal processing. This is in conflict with the low cost, green, and renewable energy for which we are aiming. To realize a green organic solar cell, a novel solar cell has been created using an environmentally friendly water-soluble thiophene polymer [(Sodium poly[2-(3-thienyl)-ethoxy-4-butylsulfonate])] (PTEBS) and nanocrystalline TiO2. This novel system has shown great potential in photovoltaics the work has garnered the attention of the international community.In our innovative solar cells, the water-soluble polythiophene (PTEBS) is used as electron donor. Nanoparticle TiO2 acts as electron acceptor. PTEBS/TiO2 solar cells with various structures including bilayer heterojunctions, bulk heterojunctions and a hybrid of bilayer and bulk heterojunctions have been developed and explored. These results are comparable to the best polymer/metal-oxide solar cells reported by other groups using organic solvents.In summary, this is the first time that green solar cells have been fabricated from environmentally friendly water-soluble polymers. By using water as the solvent and utilizing liquid-based processing, the cost of the energy generated by this type of solar cell will be further lowered. In addition, the flexible polymer offers the ease of fabrication and integration into different devices. polymer nanomaterial solar energy organic solar cell water soluble photovoltaic Electrical and Computer Engineering Engineering
47	A Multi-Method Approach for the Quantification of Surface Amine Groups on Silica Nanoparticles Sun, Ying 29 July 2019 (has links) As nanomaterials continue to garner interest in a wide range of industries and scientific fields, commercial suppliers have met growing consumer demand by readily offering custom particles with size, shape and surface functionality made-to-order. By circumventing the challenging and complex synthesis of functionalized nanoparticles, these businesses seek to provide greater access for the experimentation and application of these nanoscale platforms. In many cases, amine functional groups are covalently attached as a surface coating on a nanoparticle to provide a starting point for chemical derivatization and commonly, conjugation of biomolecules in medical science applications. Successful conjugation can improve the compatibility, interfacing and activity of therapeutic and diagnostic nanomedicines. Amines are amongst the most popular reactive groups used in bioconjugation pathways owing to the many high-yield alkylation and acylation reaction are involved in. For the design of functionalized nanomaterials with precisely tuned surface chemical properties, it is important to develop techniques and methods which can accurately and reproducibly characterize these materials. Quantification of surface functional groups is crucial, as these groups not only allow for conjugation of chemical species, but they also influence the surface charge and therefore aggregation behavior of nanomaterials. The loss of colloidal stability of functionalized nanomaterials can often correspond to a significant if not complete loss of functionality. Thus, we sought to develop multiple characterization approaches for the quantification of surface amine groups. Silica nanoparticles were selected as a model nanomaterial as they are widely used, commercially available, and their surface chemistry has been investigated and studied for decades. Various commercial batches of silica nanoparticles were procured with sizes ranging from 20 – 120 nm. Two colorimetric assays were developed and adapted for their ease-of-use, sensitivity, and convenience. In addition, a fluorine labelling technique was developed which enabled analysis by quantitative solid-state 19F NMR and X-ray photoelectron spectroscopy (XPS). XPS provided data on surface chemical composition at a depth of ≈ 10 nm, which allowed us to determine coupling efficiencies of the fluorine labelling technique and evaluate the reactivity of the two assays. The ensemble of surface-specific quantification techniques was used to evaluate multiple commercial batches of aminated silica and investigate batch-to-batch variability and the influence of particle size with degree of functionalization. In addition, resulting measurements of surface amine content were compared and validated by an independent method based on quantitative solution 1H NMR, which was developed for total functional group content determination. This allowed for us to assess the role of accessibility and reactivity of the amine groups present in our silica particles. Overall, the objective of this study was to develop a multi-method approach for the quantification of amine functional groups on silica nanoparticles. At the same time, we hoped to set a precedent for the development and application of multiple characterization techniques with an emphasis of comparing them on the basis of reproducibility, sensitivity, and mutual validation. Nanotechnology Analytical Chemistry Silica Nanoparticles Amine Functional Groups Quantification Surface Chemistry Functionalized Materials Nanomaterial Characterization
48	Zero-Group-Velocity Propagation Of Electromagnetic Wave Through Nanomaterial Fan, Taian 01 January 2016 (has links) This research will investigate the problem on the propagation of electromagnetic wave through a specific nanomaterial. The nanomaterial analyzed is a material consisting of a field of Pt nanorods. This field of Pt nanorods are deposited on a substrate which consists of a RuO2 nano structure. When the nanorod is exposed to an electron beam emitted by a TEM (Transmission electron microscopy). A wave disturbance has been observed. A video taken within the chamber shows a wave with a speed in the scale of um/s (Á?10Á?^(-6) m/s), which is 14 orders of magnitude lower than speed of light in free space (approximate 3ÁÁ?10Á?^8 m/s ). A physical and mathematical model is developed to explain this phenomenon. Due to the process of fabrication, the geometry of the decorated Pt nanorod field is assumed to be approximately periodic. The nanomaterials possess properties similar to a photonic crystal. Pt, as a noble metal, shows dispersive behaviours that is different from those ones of a perfect or good conductors. A FDTD algorithm is implemented to calculate the band diagram of the nanomaterials. To explore the dispersive properties of the Pt nanorod field, the FDTD algorithm is corrected with a Drude Model. The analysis of the corrected band diagram illustrates that the group velocity of the wave packet propagating through the nanomaterial can be positive, negative or zero. The possible zero-group velocity is therefore used to explain the extremely low velocity of wave (wave envelope) detected in the TEM. band diagram dispersion Drude model FDTD nanomaterial zero group velocity Electrical and Electronics Electromagnetics and Photonics Engineering
49	Numerical and Experimental Investigation of Inorganic Nanomaterials for Thermal Energy Storage (TES) and Concentrated Solar Power (CSP) Applications Jung, Seunghwan 2012 May 1900 (has links) The objective of this study is to synthesize nanomaterials by mixing molten salt (alkali nitrate salt eutectics) with inorganic nanoparticles. The thermo-physical properties of the synthesized nanomaterials were characterized experimentally. Experimental results allude to the existence of a distinct compressed phase even for the solid phase (i.e., in the nanocomposite samples). For example, the specific heat capacity of the nanocomposites was observed to be enhanced after melting and re-solidification - immediately after their synthesis; than those of the nanocomposites that were not subjected to melting and re-solidification. This shows that melting and re-solidification induced molecular reordering (i.e., formation of a compressed phase on the nanoparticle surface) even in the solid phase - leading to enhancement in the specific heat capacity. Numerical models (using analytical and computational approaches) were developed to simulate the fundamental transport mechanisms and the energy storage mechanisms responsible for the observed enhancements in the thermo-physical properties. In this study, a simple analytical model was proposed for predicting the specific heat capacity of nanoparticle suspensions in a solvent. The model explores the effect of the compressed phase – that is induced from the solvent molecules - at the interface with individual nanoparticles in the mixture. The results from the numerical simulations indicate that depending on the properties and morphology of the compressed phase – it can cause significant enhancement in the specific heat capacity of nanofluids and nanocomposites. The interfacial thermal resistance (also known as Kapitza resistance, or “Rk”) between a nanoparticle and the surrounding solvent molecules (for these molten salt based nanomaterials) is estimated using Molecular Dynamics (MD) simulations. This exercise is relevant for the design optimization of nanomaterials (nanoparticle size, shape, material, concentration, etc.). The design trade-off is between maximizing the thermal conductivity of the nanomaterial (which typically occurs for nanoparticle size varying between ~ 20-30nm) and maximizing the specific heat capacity (which typically occurs for nanoparticle size less than 5nm), while simultaneously minimizing the viscosity of the nanofluid. The specific heat capacity of nitrate salt-based nanomaterials was measured both for the nanocomposites (solid phase) and nanofluids (liquid phase). The neat salt sample was composed of a mixture of KNO3: NaNO3 (60:40 molar ratio). The enhancement of specific heat capacity of the nanomaterials obtained from the salt samples was found to be very sensitive to minor variations in the synthesis protocol. The measurements for the variation of the specific heat capacity with the mass concentration of nanoparticles were compared to the predictions from the analytical model. Materials characterization was performed using electron microscopy techniques (SEM and TEM). The rheological behavior of nanofluids can be non-Newtonian (e.g., shear thinning) even at very low mass concentrations of nanoparticles, while (in contrast) the pure undoped (neat) molten salt may be a Newtonian fluid. Such viscosity enhancements and change in rheological properties of nanofluids can be detrimental to the operational efficiencies for thermal management as well as energy storage applications (which can effectively lead to higher costs for energy conversion). Hence, the rheological behavior of the nanofluid samples was measured experimentally and compared to that of the neat solvent (pure molten salt eutectic). The viscosity measurements were performed for the nitrate based molten salt samples as a function of temperature, shear rate and the mass concentration of the nanoparticles. The experimental measurements for the rheological behavior were compared with analytical models proposed in the literature. The results from the analytical and computational investigations as well as the experimental measurements performed in this proposed study – were used to formulate the design rules for maximizing the enhancement in the thermo-physical properties (particularly the specific heat capacity) of various molten salt based inorganic nanomaterials. The results from these studies are summarized and the future directions are identified as a conclusion from this study. nanomaterial specific heat capacity interfacial thermal resistance viscosity molten salt thermal energy storage
50	Rock Salt vs. Wurtzite Phases of Co1-xMnxO: Control of Crystal Lattice and Morphology at the Nanoscale Walsh, Sean 24 July 2013 (has links) Diamond cuboid-, rhombohedron- and hexagon-shaped nanocrystals as well as branched rods of the solid solution Co1-xMnxO have been synthesized via a solvothermal synthetic route from manganese formate and cobalt acetate at elevated temperature. Rhombohedra and hexagons have dimensions no larger than 50 nm on the longest axis, rods have branches up to 150 nm long and cuboids grow up to 250 nm on a side. X-ray and electron diffraction and transmission electron microscopy analyses show that these nanoparticles are single crystals of wurtzite-type and rock salt-type Co1-xMnxO. Varying the surfactant, water and precursor ratios allows control of particle size, morphology and stoichiometry. Extending growth time at high temperatures (>370°C) leads to the disappearance of the wurtzite phase due to Ostwald ripening. Longer reaction times at temperatures between 345-365°C lead to more crystalline wurtzite-lattice particles. These results show that nanoparticle morphologies and crystal lattices arise from crystal growth and Ostwald ripening at different rates selecting for either small, smooth-surfaced wurtzite lattice particles or large, dendritically-grown rock salt lattice particles.

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