Please use this identifier to cite or link to this item: http://repositorio.lnec.pt:8080/jspui/handle/123456789/1009650
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dc.contributor.authorBorsoi, G.pt_BR
dc.contributor.authorLubelli, B.pt_BR
dc.contributor.authorvan Hees, R.pt_BR
dc.contributor.authorVeiga, M. R.pt_BR
dc.contributor.authorSantos Silva, A.pt_BR
dc.contributor.authorColla, L.pt_BR
dc.contributor.authorFedele, L.pt_BR
dc.contributor.authorTomasin, P.pt_BR
dc.date.accessioned2017-07-06T08:10:14Zpt_BR
dc.date.accessioned2017-08-08T14:26:40Z-
dc.date.available2017-07-06T08:10:14Zpt_BR
dc.date.available2017-08-08T14:26:40Z-
dc.date.issued2016-05pt_BR
dc.identifier.citationhttp://dx.doi.org/10.1016/j.colsurfa.2016.03.007pt_BR
dc.identifier.urihttps://repositorio.lnec.pt/jspui/handle/123456789/1009650-
dc.description.abstractConsolidation treatment is a common practice in the field of conservation. However, when considering calcareous materials, there is a lack of efficient and durable consolidants. Colloidal dispersions of Ca(OH)2 nanoparticles, commonly known as nanolimes, can effectively recover the superficial loss of cohesion. However, they do not always guarantee in-depth mass consolidation. The aim of this paper is to give directions for improving in-depth deposition of nanolime dispersions when applied on limestone. A conceptual model, correlating the drying rate and the kinetic stability of nanolimes dispersed in different solvents, to the porosity of the limestone to be treated, is conceived. This model can help to select a suitable nanolime solvent depending on the substrate. *Manuscript Click here to view linked References Nanolimes were synthetized and dispersed in different solvents (ethanol, isopropanol, butanol and water). The morphology and size of the lime nanoparticles were studied by dynamic light scattering (DLS) and scanning electron microscopy (SEM-EDS). The kinetic stability of the nanolime was assessed by Uv-Vis spectroscopy. The porosity of the limestones were determined by mercury intrusion porosimetry (MIP), measuring as well their moisture transport properties. The model was validated by applying the different nanolimes to two limestones with very coarse (Maastricht limestone) and very fine porosity (Migné limestone). The absorption and drying kinetics and the deposition of the nanolimes within the treated limestones were investigated by phenolphthalein test, optical microscopy and SEM-EDS analysis. The results show that, as suggested by the model, less stable dispersions (as obtained by higher boiling point solvents e.g. butanol) are more suitable for coarse-pore limestones, while for fine limestones, more stable nanolime dispersions (as obtained by low boiling point solvents e.g. ethanol) should be preferred. Suggestions are given for further improvement and fine tuning of the nanolimes.pt_BR
dc.language.isoengpt_BR
dc.publisherElsevierpt_BR
dc.rightsrestrictedAccesspt_BR
dc.subjectNanolimept_BR
dc.subjectConsolidation productspt_BR
dc.subjectSolvent modificationpt_BR
dc.subjectIn-depth depositionpt_BR
dc.titleEffect of solvent on nanolime transport within limestone: How to improve in-depth depositionpt_BR
dc.typeworkingPaperpt_BR
dc.description.pages171-181pp.pt_BR
dc.description.volumeVolume 497pt_BR
dc.description.sectorDM/NMMpt_BR
dc.identifier.proc0204/112/19715pt_BR
dc.identifier.proc0803/112/1946002pt_BR
dc.description.magazineColloids and Surfaces A: Physicochemical and Engineering Aspectspt_BR
dc.contributor.peer-reviewedSIMpt_BR
dc.contributor.academicresearchersSIMpt_BR
dc.contributor.arquivoNAOpt_BR
Appears in Collections:DM/NMM - Comunicações a congressos e artigos de revista

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