Search results for " Materials Science"

showing 10 items of 7414 documents

Antifouling Mortars for Underwater Restoration

2022

This research has focused on the assessment of the compositional features and mechanical and antifouling performances of two different mortars formulated for an underwater setting, and which contain Mg(OH)2 as an antifouling agent. Regarding the mechanical characterization, the uniaxial compressive strength and flexural strength were measured. The composition of the materials was explored by differential thermal/thermogravimetric analysis (DTA-TG), X-ray diffraction analysis (XRPD), and scanning electronic microscopy (SEM) coupled with EDS microanalysis. The assessment of the biological colonization was evaluated with colorimetric analysis and image analysis. The results suggest that both m…

restorationgeomaterialsbiofouling geomaterials magnesium hydroxide mortars nanoparticles restoration submerged sitesGeneral Chemical Engineeringbiofoulingsubmerged sitesPetrologíananoparticlesGeneral Materials Sciencemortarsmagnesium hydroxide; mortars; submerged sites; biofouling; geomaterials; restoration; nanoparticlesSettore GEO/09 -Georis. Miner.e Appl.Mineral.-Petrogr. per l'Ambi.ed i B.Cult.magnesium hydroxideNanomaterials

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Physicochemical investigation of surfactant-coated gold nanoparticles synthesized in the confined space of dry reversed micelles

2006

Abstract Gold nanoparticle/surfactant composites have been synthesized by a novel reduction reaction in the confined space of dry sodium bis(2- ethylhexyl)sulfosuccinate (AOT) or lecithin reversed micelles dispersed in n-heptane and cyclohexane, respectively. The reaction was carried out by adding an opportune amount of anhydrous hydrazine/tetrahydrofuran solution to a suspension of HAuCl4-containing dry reversed micelles dispersed in organic solvent. UV–vis investigation ascertained the formation of stable metal gold nanoparticles and the analysis of FT-IR spectra highlighted the formation of an oriented surfactant monolayer at the nanoparticle surface. Simple evaporation under vacuum of t…

reversed micellesNanocompositeMaterials scienceCyclohexaneInorganic chemistryNanoparticleCondensed Matter PhysicsMicelleNanomaterialschemistry.chemical_compoundlecithinChemical engineeringchemistryPulmonary surfactantColloidal goldMonolayerconfinement effectAOTGeneral Materials Sciencegold nanoparticlesurfactant adsorptionMaterials Chemistry and Physics

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Investigation of a Gravel-Bed River’s Pattern Changes: Insights from Satellite Images

2021

Changes in river pattern have been documented in the literature. The recognition of islands and vegetated patches, which is indicative of the evolution processes, requires simultaneous information at different points and at different times and field studies are still difficult and scarce. The present work, focusing the attention on a gravel-bed river, explores the possibility to conduct a first-step pattern changes analysis by identifying the evolution of the morphological features and taking information of islands and vegetated patches from satellite images easily available from Google Earth. The study is conducted by combining the information taken from both the satellite images and the f…

river pattern010504 meteorology & atmospheric sciencesriverFlow (psychology)Flux010502 geochemistry & geophysicslcsh:Technology01 natural sciencesDeposition (geology)Settore ICAR/01 - Idraulicalcsh:ChemistryGeneral Materials Sciencelcsh:QH301-705.5Instrumentation0105 earth and related environmental sciencesFluid Flow and Transfer Processeslcsh:TProcess Chemistry and TechnologyGeneral EngineeringSedimentvegetated patcheVegetationpredictionlcsh:QC1-999Field (geography)Computer Science Applicationsimagesmonitoringlcsh:Biology (General)lcsh:QD1-999lcsh:TA1-2040morphological evolutionSatellitePhysical geographylcsh:Engineering (General). Civil engineering (General)Sediment transportlcsh:PhysicsGeologyApplied Sciences

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The Influence of Nanoparticle Shape on Protein Corona Formation

2020

Nanoparticles have become an important utility in many areas of medical treatment such as targeted drug and treatment delivery as well as imaging and diagnostics. These advances require a complete understanding of nanoparticles' fate once placed in the body. Upon exposure to blood, proteins adsorb onto the nanoparticles surface and form a protein corona, which determines the particles' biological fate. This study reports on the protein corona formation from blood serum and plasma on spherical and rod‐shaped nanoparticles. These two types of mesoporous silica nanoparticles have identical chemistry, porosity, surface potential, and size in the y ‐dimension, one being a sphere and the other a …

rod shapeSurface Propertiesnanoparticle shapeNanoparticleProtein Corona02 engineering and technology010402 general chemistry01 natural sciencesBiomaterialsCorona (optical phenomenon)protein coronaAdsorptionBlood serumDrug Delivery SystemsGeneral Materials ScienceChemistryAlbuminsphere shapeGeneral ChemistryMesoporous silica021001 nanoscience & nanotechnologySilicon Dioxideprotein adsorption0104 chemical sciences3. Good healthBiophysicsbio-nanoparticle interactionsNanoparticlesProtein Corona0210 nano-technologymesoporous nanoparticlesBiotechnologyProtein adsorption

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Packing incentives and a reliable N–H⋯N–pyridine synthon in co-crystallization of bipyridines with two agrochemical actives

2011

The co-crystallization of agrochemical actives thiophanate-methyl and thiophanate-ethyl with 2,2′-bipyridine, 4,4′-bipyridine and 1,2-bis(4-pyridyl)ethane was investigated with conventional crystallization, the slurry method and liquid-assisted grinding. Co-crystals of both thiophanates with all bipyridines were found and the structures solved with single crystal X-ray diffraction. Whereas the 2,2′-bipyridine co-crystals seem to form because of a combination of weak interactions, and in the case of the thiophanate-methyl, partly because of close packing incentives, the 4,4′-bipyridine and 1,2-bis(4-pyridyl)ethane co-crystals form mainly because of a favourable N–H···N–pyridine hydrogen bond…

röntgen diffraktioyhteiskideChemistryHydrogen bondSynthonClose-packing of equal spheressupramolecular synthonGeneral ChemistryCondensed Matter Physicsco-crystalsupramolekyyliX-ray diffractionlaw.inventionGrindingchemistry.chemical_compoundlawPyridineSlurryOrganic chemistryGeneral Materials ScienceCrystallizationcocrystalta116Single crystalCrystEngComm

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N,N-Dimethyl-N-propylpropan-1-aminium chloride monohydrate

2008

The title compound, C8H20N+·Cl−·H2O, has been prepared by a simple one-pot synthesis route followed by anion exchange using resin. In the crystal structure, the cations are packed in such a way that channels exist parallel to the b axis. These channels are filled by the anions and water molecules, which interact via O—H...Cl hydrogen bonds [O...Cl = 3.285 (3) and 3.239 (3) Å] to form helical chains. The cations are involved in weak intermolecular C—H...Cl and C—H...O hydrogen bonds. The title compound is not isomorphous with the bromo or iodo analogues.

röntgendiffraktioCrystallographyIon exchangeChemistryHydrogen bondGeneral ChemistryCrystal structurekvaternäärinen ammoniumkloridiCondensed Matter Physicscomputer.software_genreChlorideOrganic PapersCrystallographyQD901-999medicineGeneral Materials ScienceData miningquaternary ammonium chloridecomputersingle crystal diffractionmedicine.drug

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3,4,5-Trimethoxy-4'-methylbiphenyl

2013

In the title compound, C16H18O3, the dihedral angle between the benzene rings is 33.4 (2)°. In the crystal, molecules are packed in a zigzag arrangement along the b-axis and are interconnected via weak C—H⋯O hydrogen bonds, and C—H⋯π interactions involving the methoxy groups and the benzene rings of neighbouring molecules.

röntgendiffraktiocrystal structure010405 organic chemistryHydrogen bonddendrimeeri prekursoriGeneral ChemistrykiderakenneDihedral angle010402 general chemistryCondensed Matter Physics01 natural sciencesOrganic Papers3. Good health0104 chemical sciencesX-ray diffractionCrystalchemistry.chemical_compoundCrystallographychemistryZigzagdendrimer precursorMoleculeGeneral Materials ScienceBenzeneta116Acta Crystallographica Section E-Structure Reports Online

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3,5-Dimethoxy-4'-methylbiphenyl

2013

The title compound, C15H16O2, crystallizes with three independent molecules in the asymmetric unit. The intramolecular torsion angle between the aromatic rings of each molecule are −36.4 (3), 41.3 (3) and −37.8 (3)°. In the crystal, the complicated packing of the molecules forms wave-like layers along the b and c axes. The molecules are connected via extensive methoxy–phenyl C—H…π interactions. A weak C—H…O hydrogen-bonding network also exists between methoxy O atoms and aromatic or methoxy H atoms.

röntgendiffraktiocrystal structuredendrimeeri prekursori010405 organic chemistryChemistryX-ray DiffractionAromaticitykiderakenneGeneral ChemistryDihedral angle010402 general chemistryCondensed Matter PhysicsBioinformaticsOrganic Papers01 natural sciences0104 chemical sciences3. Good healthCrystalCrystallographydendrimer precursorGeneral Materials Scienceta116

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3,4-Dimethoxy-4'-methylbiphenyl

2013

In the title compound, C15H16O2, the dihedral angle between the planes of the aromatic rings is 30.5 (2). In the crystal, molecules are linked via C—HO hydrogen bonds and C— H interactions, forming a two-dimensional network lying parallel to (100). peerReviewed

röntgendiffraktiocrystal structuredendrimeeri prekursori010405 organic chemistryHydrogen bondChemistryAromaticitykiderakenneGeneral ChemistryDihedral angle010402 general chemistryCondensed Matter Physics01 natural sciencesOrganic PapersX-ray diffraction0104 chemical sciences3. Good healthCrystalCrystallographydendrimer precursorGeneral Materials Scienceta116Acta Crystallographica Section E-Structure Reports Online

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Methyl 3',5'-dimethoxybiphenyl-4-carboxylate

2013

In the title compound, C16H16O4, the dihedral angle between the benzene rings is 28.9 (2)°. In the crystal, molecules are packed in layers parallel to the b axis in which they are connected via weak intermolecular C-H...O contacts. Face-to-face π-π interactions also exist between the benzene rings of adjacent molecules, with centroid-centroid and plane-to-plane shift distances of 3.8597 (14) and 1.843 (2) Å, respectively.

röntgendiffraktiocrystal structuredendrimeeri prekursorikiderakenneDihedral angle010402 general chemistryBioinformatics01 natural sciencesOrganic PapersCrystalchemistry.chemical_compoundGeneral Materials ScienceBenzeneta116Biphenyl010405 organic chemistryHydrogen bondGeneral ChemistryMeth-Condensed Matter PhysicsX-ray diffraction0104 chemical sciences3. Good healthCrystallographychemistrydendrimer precursorLayer (electronics)

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