00857nam0-22002651i-450-99000624044040332119980601000624044FED01000624044(Aleph)000624044FED0100062404419980601d1987----km-y0itay50------ba----m---00-yyBesitzbegriff und Besitzesschutz im Zurcher privatrechtlichen Gestzbuch Johann Caspar BluntschilsMarkus Affentrager.ZurichSchulthess pol.1987346Affentranger,Markus236134ITUNINARICAUNIMARCBK990006240440403321DISSERT. A 132427525*FGBCFGBCBesitzbegriff und Besitzesschutz im Zurcher privatrechtlichen Gestzbuch Johann Caspar Bluntschils636745UNINAGIU0103975nam 2200973z- 450 991055711790332120210501(CKB)5400000000040867(oapen)https://directory.doabooks.org/handle/20.500.12854/68350(oapen)doab68350(EXLCZ)99540000000004086720202105d2021 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierIon-Substituted Calcium Phosphates CoatingsBasel, SwitzerlandMDPI - Multidisciplinary Digital Publishing Institute20211 online resource (182 p.)3-03943-543-4 3-03943-544-2 Coatings based on hydroxyapatite and calcium phosphates have a significant relevance in several research fields, such as biomaterials, cultural heritage, and water treatment, due to their characteristic properties. Hydroxyapatite can easily accommodate foreign ions, which can either be incorporated into the lattice, thanks to its specific lattice characteristics, or be adsorbed onto its surface. All these substitutions significantly alter the morphology, lattice parameters, and crystallinity of hydroxyapatite so they influence its main properties. These ion substitutions can be sought or can derive from substrate contaminations, which is an important aspect to be evaluated. Finally, this capability can be used to obtain hydroxyapatites with specific properties, such as antibacterial characteristics, among others. For these reasons, the aim of this Special Issue is to document current advances in the field of ion-substituted hydroxyapatites and highlight possible future perspectives regarding their use. Contributions in the form of original articles and review articles are presented, covering different areas of application.History of engineering and technologybicsscacid attackallograftammonium phosphateautograftbiocompatibilitybonebone regenerationC. albicanscalcitecalcium phosphatecalcium phosphatescarbonated hydroxyapatitecave paintingcoatingscompositionconsolidating treatmentcrystallinitycultural heritagecurrentdissolutiondolomiteelectrodepositionethyl silicateGLADhydroxyapatiteinhibition of microbial biofilms developmentinorganic consolidantion-substituted apatitesion-substituted calcium phosphateslayerslithium-doped hydroxyapatite coatingsmagnesium phosphatemarblenanomaterialsnanostructured coatingsnon-thermal plasmaplasma-assisted depositionpotentialprotective coatingspulsed laser depositionrenewable resources for implant coatingsRF magnetron sputteringS. aureussol-gel spin coatingsolubilitystruviteTEOSultrasound measurementwettabilityxenograftzincHistory of engineering and technologyGraziani Gabrielaedt1283236Sassoni EnricoedtGraziani GabrielaothSassoni EnricoothBOOK9910557117903321Ion-Substituted Calcium Phosphates Coatings3019005UNINA