Theoretical analysis of light scattering properties of encapsulated rutile titanium dioxide pigments in dependent light scattering regime

•Air/TiO2 pigments have better backscattering coefficient than standard TiO2.•Air/TiO2 pigments show better spatial distribution than standard TiO2.•Air/TiO2 pigments exhibit lower dependency on crowding than standard TiO2.•Air/TiO2 pigments only more effective than standard TiO2 at low PVC.•Air/TiO...

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Veröffentlicht in:	Progress in organic coatings 2014-11, Vol.77 (11), p.1619-1628
Hauptverfasser:	Auger, J.-C., McLoughlin, Daragh
Format:	Artikel
Sprache:	eng
Schlagworte:	Dependent scattering Encapsulation Hiding power Light scattering Mathematical models Multiple scattering Opacity Paints Pigments Rutile titanium dioxide Shells Titanium dioxide White coating
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creator	Auger, J.-C. McLoughlin, Daragh
description	•Air/TiO2 pigments have better backscattering coefficient than standard TiO2.•Air/TiO2 pigments show better spatial distribution than standard TiO2.•Air/TiO2 pigments exhibit lower dependency on crowding than standard TiO2.•Air/TiO2 pigments only more effective than standard TiO2 at low PVC.•Air/TiO2 cannot substitute standard TiO2 pigment. Using numerical simulation, we study and compare the optical properties of model systems representing three types of scatterer: (a) standard TiO2 pigments, (b) standard TiO2 pigments encapsulated by a hard polymer shell and (c) standard TiO2 pigments encapsulated by a layer of air and a polymer shell. Calculations are performed taking into account multiple and dependent light scattering regimes. Assuming an equivalent amount of TiO2 in each system, results show that a standard TiO2 pigment particle encapsulated by air could be a better opacifier than a standard un-encapsulated TiO2 pigment because the presence of air could provide: (a) additional volume to the existing particle to scatter light; (b) better redistribution of the scattered field in the backward hemisphere; (c) a scattering cross-section less affected by crowding and (d) spacing effects due to the presence of the thin hard polymer shell which is required to encapsulate the air layer. Nonetheless, results also suggest that such benefits could probably not be exploited in real paint systems as encapsulated TiO2 would only be more efficient than standard TiO2 in a range of pigment volume filling fractions (PVC) that would not generate enough scattering efficiency to yield complete hiding as required by international standards.
doi_str_mv	10.1016/j.porgcoat.2014.05.005
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Using numerical simulation, we study and compare the optical properties of model systems representing three types of scatterer: (a) standard TiO2 pigments, (b) standard TiO2 pigments encapsulated by a hard polymer shell and (c) standard TiO2 pigments encapsulated by a layer of air and a polymer shell. Calculations are performed taking into account multiple and dependent light scattering regimes. Assuming an equivalent amount of TiO2 in each system, results show that a standard TiO2 pigment particle encapsulated by air could be a better opacifier than a standard un-encapsulated TiO2 pigment because the presence of air could provide: (a) additional volume to the existing particle to scatter light; (b) better redistribution of the scattered field in the backward hemisphere; (c) a scattering cross-section less affected by crowding and (d) spacing effects due to the presence of the thin hard polymer shell which is required to encapsulate the air layer. 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Using numerical simulation, we study and compare the optical properties of model systems representing three types of scatterer: (a) standard TiO2 pigments, (b) standard TiO2 pigments encapsulated by a hard polymer shell and (c) standard TiO2 pigments encapsulated by a layer of air and a polymer shell. Calculations are performed taking into account multiple and dependent light scattering regimes. Assuming an equivalent amount of TiO2 in each system, results show that a standard TiO2 pigment particle encapsulated by air could be a better opacifier than a standard un-encapsulated TiO2 pigment because the presence of air could provide: (a) additional volume to the existing particle to scatter light; (b) better redistribution of the scattered field in the backward hemisphere; (c) a scattering cross-section less affected by crowding and (d) spacing effects due to the presence of the thin hard polymer shell which is required to encapsulate the air layer. 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Using numerical simulation, we study and compare the optical properties of model systems representing three types of scatterer: (a) standard TiO2 pigments, (b) standard TiO2 pigments encapsulated by a hard polymer shell and (c) standard TiO2 pigments encapsulated by a layer of air and a polymer shell. Calculations are performed taking into account multiple and dependent light scattering regimes. Assuming an equivalent amount of TiO2 in each system, results show that a standard TiO2 pigment particle encapsulated by air could be a better opacifier than a standard un-encapsulated TiO2 pigment because the presence of air could provide: (a) additional volume to the existing particle to scatter light; (b) better redistribution of the scattered field in the backward hemisphere; (c) a scattering cross-section less affected by crowding and (d) spacing effects due to the presence of the thin hard polymer shell which is required to encapsulate the air layer. Nonetheless, results also suggest that such benefits could probably not be exploited in real paint systems as encapsulated TiO2 would only be more efficient than standard TiO2 in a range of pigment volume filling fractions (PVC) that would not generate enough scattering efficiency to yield complete hiding as required by international standards.</abstract><pub>Elsevier B.V</pub><doi>10.1016/j.porgcoat.2014.05.005</doi><tpages>10</tpages></addata></record>
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source	Elsevier ScienceDirect Journals Complete - AutoHoldings
subjects	Dependent scattering Encapsulation Hiding power Light scattering Mathematical models Multiple scattering Opacity Paints Pigments Rutile titanium dioxide Shells Titanium dioxide White coating
title	Theoretical analysis of light scattering properties of encapsulated rutile titanium dioxide pigments in dependent light scattering regime
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