0000000000755768

AUTHOR

Daniela Caschera

showing 3 related works from this author

How self-assembly of amphiphilic molecules can generate complexity in the nanoscale

2015

Abstract Given the importance of nanomaterials and nanostructures in modern technology, in the past decades much effort has been directed to set up efficient bottom up protocols for the piloted self-assembly of molecules. However, molecules are generally disinclined to adopt the desired structural organization because they behave according to their own specific intermolecular interactions. Thus, only some selected classes of chemical compounds are capable to lead to useful self-assembled structures. Amphiphiles, simultaneously possessing polar and apolar moieties within their molecular architecture, can give a wide scenario of possible intermolecular interactions: polar–polar, polar–apolar,…

Amphiphilic moleculeNanostructureStructural organizationChemistryNanomachinesNanotechnologyTop-down and bottom-up designLiving cellComplexitySelf-assemblyNanodevicesNanomachinesSelf-assemblyComplexityNanotechnologyColloid and Surface ChemistryNanotechnologySelf-assemblyNanodevices
researchProduct

Spectroscopic and structural characterization of pure and FeCl3-containing tri-n-butyl phosphate

2014

The spectroscopic properties and liquid structure of pure tri-n-butyl phosphate (TBP) and FeCl3/TBP solutions have been investigated by Uv–Vis and Raman spectroscopies, X-ray diffraction and conductometry. Uv–Vis and Raman spectra, supported by conductometric measurements, consistently indicate that the solubilized salt is present mostly as TBP n [FeCl3 − n ] n+ and FeCl4 − complex ions due to specific interaction with the TBP phosphate group. Thanks to this interaction, a high amount of salt (up to 13 % w/w) can be dissolved despite the relatively low dielectric constant of TBP. The X-ray diffractogram of pure TBP has been interpreted in terms of three main contributions which can be attri…

chemistry.chemical_classificationPolymers and PlasticsConductometryChemistryInorganic chemistryTri-N-butyl PhosphateFeCl3 . Tri-n-butyl phosphate . Self-assembling . Local structures .Amphiphilic solventsNanoparticleSalt (chemistry)Ionic bondingTri-n-butyl phosphatePhosphatesymbols.namesakechemistry.chemical_compoundColloid and Surface ChemistryFeCl3Materials ChemistrysymbolsMoleculeSelf-assemblingAmphiphilic solventsPhysical and Theoretical ChemistryLocal structuresRaman spectroscopy
researchProduct

Iron and lithium-iron alkyl phosphates as nanostructured material for rechargeable batteries

2018

Abstract Inorganic/organic hybrid materials composed by iron atoms bonded to an alkyl phosphate can be easily synthesized by mixing at 110 °C iron chlorides with tri-alkyl phosphates. Since structural information on these products are lacking and taking into account that lithium/iron organic hybrid materials are important in lithium ion battery technology we report here the physico-chemical characterization of different hybrid lithium/iron butylphosphates. These materials are characterized by the presence of elongated hexagonal crystals stable up to 315 °C. The insertion of lithium does not affect the local structure. Thanks to such structures the material can be electrochemically-cycled an…

Materials scienceHybrid materials; Lithium ion batteries; Tri n-butyl phosphates; Materials Science (all); Condensed Matter Physics; Mechanics of Materials; Mechanical Engineeringchemistry.chemical_element02 engineering and technology010402 general chemistry01 natural sciencesRedoxLithium-ion batteryIonchemistry.chemical_compoundGeneral Materials ScienceTri n-butyl phosphatesAlkylchemistry.chemical_classificationMechanical EngineeringAlkyl phosphate021001 nanoscience & nanotechnologyCondensed Matter Physics0104 chemical sciencesCharacterization (materials science)chemistryChemical engineeringLithium ion batteriesMechanics of MaterialsLithiumMaterials Science (all)Hybrid materials0210 nano-technologyHybrid material
researchProduct