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667.3 : Teinture et impression des tissus 667.1 Nettoyage
667.2 Colorants et pigments 667.4 Encres 667.5 Encres d'imprimerie 667.6 Peintures 667.7 Cires, laques, vernis 667.9 Revêtements et enduits |
Ouvrages de la bibliothèque en indexation 667.3
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Dyeing of leather with microencapsulated acid dye / Nasanjargal Purev in COLORATION TECHNOLOGY, Vol. 129, N° 6 (12/2013)
[article]
Titre : Dyeing of leather with microencapsulated acid dye Type de document : texte imprimé Auteurs : Nasanjargal Purev, Auteur ; Ladislav Burgert, Auteur ; Petr Prichystal, Auteur ; Radim Hrdina, Auteur ; Jiri Kühn, Auteur ; Michal Cerny, Auteur ; Jamyan Oyuntulkhuur, Auteur Année de publication : 2013 Article en page(s) : p. 412-417 Note générale : Bibliogr. Langues : Anglais (eng) Catégories : Colorants acides
Cuirs et peaux -- Teinture
Encapsulation
LiposomesIndex. décimale : 667.3 Teinture et impression des tissus Résumé : CI Acid Black 210 was microencapsulated into liposomic systems, and the effects of the microencapsulation on dyebath exhaustion, depth of shade, colour fastness properties and through-dyeing of chrome-tanned leather were studied. In comparison with the original dyestuff form, the microencapsulated dye showed a deeper shade and a greater depth of through-dyeing. Exhaustion and colour fastness values were the same. Note de contenu : - EXPERIMENTAL : Materials and equipment - Equipment and analyses - Preparation of the microencapsulated form of acid dyes
- EXPERIMENTAL PROCEDURE : Dyeing procedure ofleather with liquoring - Dyeing procedure of leather without liquoring
- RESULTS AND DISCUSSION : Physicochemical parameters of liposomic systems - Effect of microencapsulation of final dyebath exhaustion - Effect of microencapsulation on through-dyeing of leather - Effect of microencapsulation on depth of shade - Effect of microencapsulation on colour fastness propertiesDOI : 10.1111/cote.12054 En ligne : http://onlinelibrary.wiley.com/doi/10.1111/cote.12054/pdf Format de la ressource électronique : Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=19740
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Code-barres Cote Support Localisation Section Disponibilité 15730 - Périodique Bibliothèque principale Documentaires Disponible Dyeing of nylon 6 fabric with a bifunctional sulphatoethylsulphone reactive disperse dye / Yehya A. Youssef in COLORATION TECHNOLOGY, Vol. 123, N° 5 (2007)
[article]
Titre : Dyeing of nylon 6 fabric with a bifunctional sulphatoethylsulphone reactive disperse dye Type de document : texte imprimé Auteurs : Yehya A. Youssef, Auteur ; Aballa A. Mousa, Auteur ; Reham Farouk, Auteur ; E. E. Allam, Auteur ; E. A. El-Kharadly, Auteur Année de publication : 2007 Article en page(s) : p. 312-316 Note générale : Bibliogr. Langues : Anglais (eng) Index. décimale : 667.3 Teinture et impression des tissus Résumé : A bifunctional reactive disperse dye containing two temporarily anionic sulphatoethylsulphone groups was synthesised and applied to nylon 6 fabric by exhaust dyeing at a variety of pH levels and temperatures. A monofunctional reactive disperse dye containing one temporarily anionic sulphatoethylsulphone group was also synthesised, and its dyeing behaviour was compared with the bifunctional dye. The bifunctional reactive disperse dye exhibited high exhaustion and total fixation yield under alkaline conditions. The results also indicate that the introduction of two temporarily anionic sulphatoethylsulphone groups of the bifunctional dye gave an enhancement in dyeing performance compared with that of the monofunctional dye. The dyes also showed very good levelling and fastness properties on nylon 6 fabric. DOI : 10.1111/j.1478-4408.2007.00100.x En ligne : http://onlinelibrary.wiley.com/doi/10.1111/j.1478-4408.2007.00100.x/pdf Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=3224
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Code-barres Cote Support Localisation Section Disponibilité 009868 - Périodique Bibliothèque principale Documentaires Disponible Dyeing of poly(lactic acid) fibres with synthesised novel heterocyclic disazo disperse dyes / Ozan Avinc in COLORATION TECHNOLOGY, Vol. 136, N° 4 (08/2020)
[article]
Titre : Dyeing of poly(lactic acid) fibres with synthesised novel heterocyclic disazo disperse dyes Type de document : texte imprimé Auteurs : Ozan Avinc, Auteur ; Emine Bakan, Auteur ; Aykut Demirçali, Auteur ; Görkem Gedik, Auteur ; Fikret Karci, Auteur Année de publication : 2020 Article en page(s) : p. 356-369 Note générale : Bibliogr. Langues : Anglais (eng) Catégories : Colorants azoïques
Colorants dispersésCatégorie de colorants très peu solubles dans l'eau, utilisés à l'origine comme colorants pour l'acétate, et qui généralement sont appliqués sous forme de suspensions aqueuses de faible concentration.Les colorants dispersés sont largement utilisés dans la teinture de la plupart des fibres manufacturées, surtout le polyester.
Colorimétrie
Décapage
Polyéthylène téréphtalate
Polylactique, AcideL'acide polylactique (anglais : polylactic acid, abrégé en PLA) est un polymère entièrement biodégradable utilisé dans l'alimentation pour l'emballage des œufs et plus récemment pour remplacer les sacs et cabas en plastiques jusqu'ici distribués dans les commerces. Il est utilisé également en chirurgie où les sutures sont réalisées avec des polymères biodégradables qui sont décomposés par réaction avec l’eau ou sous l’action d’enzymes. Il est également utilisé pour les nouveaux essais de stent biodégradable.
Le PLA peut-être obtenu à partir d'amidon de maïs, ce qui en fait la première alternative naturelle au polyéthylène (le terme de bioplastique est utilisé). En effet, l'acide polylactique est un produit résultant de la fermentation des sucres ou de l'amidon sous l'effet de bactéries synthétisant l'acide lactique. Dans un second temps, l'acide lactique est polymérisé par un nouveau procédé de fermentation, pour devenir de l'acide polylactique.
Ce procédé conduit à des polymères avec des masses molaires relativement basses. Afin de produire un acide polylactique avec des masses molaires plus élevées, l'acide polylactique produit par condensation de l'acide lactique est dépolymérisé, produisant du lactide, qui est à son tour polymérisé par ouverture de cycle.
Le PLA est donc l’un de ces polymères, dans lequel les longues molécules filiformes sont construites par la réaction d’un groupement acide et d’une molécule d’acide lactique sur le groupement hydroxyle d’une autre pour donner une jonction ester. Dans le corps, la réaction se fait en sens inverse et l’acide lactique ainsi libéré est incorporé dans le processus métabolique normal. On obtient un polymère plus résistant en utilisant l'acide glycolique, soit seul, soit combiné à l’acide lactique.
Solidité de la couleur
Solubilité
Teinture -- Fibres textiles synthétiquesIndex. décimale : 667.3 Teinture et impression des tissus Résumé : Poly(lactic acid) (PLA) is the first melt‐processable, renewable, sustainable and biodegradable natural‐based synthetic fibre. It has a broad range of uses and combines ecological advantages with outstanding performance in textiles. PLA fibre, as an aliphatic polyester, can be dyed with disperse dyes. Apart from the limited number of commercial disperse dyes, disperse dye exhaustion on PLA is generally lower than that on poly(ethylene terephthalate) (PET). In this study, new heterocyclic disazo disperse dyes, substituted with methyl, nitro and chloro groups at their ortho‐, meta‐ and para‐ positions, synthesised in our previous study, were applied to PLA and PET fibres to examine their dyeing performance, and colour fastness and dye exhaustion properties. Different shades of yellow, orange, reddish brown and brown were obtained. Most of the synthesised novel heterocyclic disazo disperse dyes exhibited good build‐up properties with high K/S levels on both fibres. Para‐ bonding substituent provided higher K/S values than meta‐ and ortho‐ positions for –NO2 and –Cl substituents for both fibres. Overall, the most synthesised novel heterocyclic disazo disperse dyes in this study exhibited good build‐up properties with high K/S, exhaustion and wet fastness levels on both PLA and PET fibres. Note de contenu : - EXPERIMENTAL : Materials - Methods - Solubility parameter determination - Scouring and dyeing - Determination of colour properties - Determination of exhaustion yield - Assessment of fastness properties
- RESULTS AND DISCUSSION : Colorimetric characteristics of PLA and PET fabrics dyed with novel synthesised dyes (4a-4j)DOI : https://doi.org/10.1111/cote.12472 En ligne : https://onlinelibrary.wiley.com/doi/epdf/10.1111/cote.12472 Format de la ressource électronique : Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=34353
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Code-barres Cote Support Localisation Section Disponibilité 21876 - Périodique Bibliothèque principale Documentaires Disponible Dyeing of polyamide fabrics with a reverse micellar system using soybean oil as a solvent / Leticia Fantinati Guimaraes in COLORATION TECHNOLOGY, Vol. 140, N° 1 (02/2024)
[article]
Titre : Dyeing of polyamide fabrics with a reverse micellar system using soybean oil as a solvent Type de document : texte imprimé Auteurs : Leticia Fantinati Guimaraes, Auteur ; Angelo Granato Granato, Auteur Année de publication : 2024 Article en page(s) : p. 103-113 Note générale : Bibliogr. Langues : Anglais (eng) Catégories : Caractérisation
Colorants acides
Colorimétrie
Emulsions
Micelles
PolyamidesUn polyamide est un polymère contenant des fonctions amides -C(=O)-NH- résultant d'une réaction de polycondensation entre les fonctions acide carboxylique et amine.
Selon la composition de leur chaîne squelettique, les polyamides sont classés en aliphatiques, semi-aromatiques et aromatiques. Selon le type d'unités répétitives, les polyamides peuvent être des homopolymères ou des copolymères.
Surfactants
Teinture -- Fibres textiles synthétiquesIndex. décimale : 667.3 Teinture et impression des tissus Résumé : The current study reports the results of non-aqueous dyeing on polyamide fabrics based on a reverse micellar system composed of a stable emulsion of soybean oil, a co-surfactant, a nonionic surfactant and acid dyes. The system does not make use of water or electrolytes and significantly reduces the dyebath volume. The influence of the hydrophilic lipophilic balance of the surfactants was evaluated, and it was found that the more hydrophilic the surfactant, the better the interaction of the reverse micellar emulsion with the substrate and, consequently, the greater the resulting colour strength. The co-surfactant plays an important role in the system, as its proportion to the surfactant/oil mixture is directly related to better exhaustion of the dyebath. The results were compared with those from a conventional water-based dyeing system. Colour matching was performed using the CIELab colour difference formula (ΔE) measured by a reflectance spectrophotometer. Note de contenu : - EXPERIMENTAL : Materials - Micellar emulsion preparation - Characterisation of reverse micelles - Scanning electron microscopy - Reverse micellar dyeing - Conventional aqueous dyeing - Colour measurements
- RESULTS AND DISCUSSION : TEM - Influence of the bath ratio - Influence of the surfactant to co-surfactant ratio - Influence of the HLB of the surfactant - Scanning electron microscopy - Colour fastness to rubbing/crocking and to washing
- Table 1 : Hydrophilic–lipophilic balance (HLB) values of the surfactants
- Table 2 : Colour difference (ΔE) values for micellar dyeing with different surfactants
- Table 3 : Tinctorial power related to conventional aqueous dyeing with C.I. Acid Blue 260
- Table 4 : Tinctorial power related to conventional aqueous dyeing with C.I. Acid Yellow 127
- Table 5 : Tinctorial power related to conventional aqueous dyeing with Acid Red G
- Table 6 : Colour fastness to rubbing/crocking
- Table 7 : Colour fastness to rubbing/crocking
- Table 8 : Colour fastness to rubbing/crocking
- Table 9 : Colour fastness to washing
- Table 10 : Colour fastness to washing
- Table 11 : Colour fastness to washingDOI : https://doi.org/10.1111/cote.12702 En ligne : https://onlinelibrary.wiley.com/doi/epdf/10.1111/cote.12702 Format de la ressource électronique : Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=40394
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Code-barres Cote Support Localisation Section Disponibilité 24413 - Périodique Bibliothèque principale Documentaires Disponible Dyeing of silk fabric with natural dye from camphor (Cinnamomum camphora) plant leaf extract / Asfandyar Khan in COLORATION TECHNOLOGY, Vol. 134, N° 4 (08/2018)
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Titre : Dyeing of silk fabric with natural dye from camphor (Cinnamomum camphora) plant leaf extract Type de document : texte imprimé Auteurs : Asfandyar Khan, Auteur ; Muhammad Tahir Hussain, Auteur ; Huiyu Jiang Année de publication : 2018 Article en page(s) : p. 266-270 Note générale : Bibliogr. Langues : Anglais (eng) Catégories : Colorants végétaux
Essais (technologie)
Extraction (chimie)
Mordançage (teinture)
pH
Soie et constituants
Solidité de la couleur
Teinture -- Fibres textiles
Textiles et tissus -- Propriétés mécaniquesIndex. décimale : 667.3 Teinture et impression des tissus Résumé : Natural dye extracted from the leaves of camphor (Cinnamomum camphora) was applied to silk fabric, with and without metallic salt mordants, using the exhaust dyeing method. Three techniques, meta‐mordanting, post‐mordanting and pre‐mordanting, were employed, using potash alum, ferrous sulphate and zinc sulphate as mordants. Dyed silk fabric was analysed for K/S, CIE L*a*b* values, and colourfastness performance to washing, light and crocking. Optimal results were obtained for dyeing at 90 °C for 60 min at pH 4. A yellowish shade was observed when silk fabric was dyed without mordants, and a variety of pale to dark reddish colour shades were achieved with the trio of mordants; ferrous sulphate produced the dullest and darkest shades. Colourfastness to washing was fair to good, colourfastness to light was poor to fair, and colourfastness to crocking was good to excellent. Note de contenu : - EXPERIMENTAL : Materials - Instruments - Extraction, dyeing and mordanting - Testing
- RESULTS AND DISCUSSION : Effect of dyeing conditions and mordanting techniques on KS/ and CIE L*a*b* values - Effect of dyeing conditions and mordanting techniques on colourfastness and tensile strength
- Tables : 1. Effect of dyeing pH on colourfastness and tensile strength - 2. Effect of dyeing temperature on colourfastness - 3. Effect of mordanting techniquesDOI : 10.1111/cote.12338 En ligne : https://onlinelibrary.wiley.com/doi/epdf/10.1111/cote.12338 Format de la ressource électronique : Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=30920
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Code-barres Cote Support Localisation Section Disponibilité 20089 - Périodique Bibliothèque principale Documentaires Disponible Dyeing of silk fabric with phenazine from Pseudomonas species / Rajasekar Saranya in COLORATION TECHNOLOGY, Vol. 128, N° 6 (2012)
PermalinkDyeing of woven polyester fabric with curcumin : effect of dye concentrations and surface pre-activation using air atmospheric plasma and ultraviolet excimer treatment in COLORATION TECHNOLOGY, Vol. 128, N° 3 (2012)
PermalinkDyeing properties of CI acid blue 193 and the non-equivalent properties of CI acid black 194 produced by different manufacturers / Krzysztof Wojciechowski in COLORATION TECHNOLOGY, Vol. 130, N° 3 (06/2014)
PermalinkDyeing properties of novel electrolyte-free reactive dyes on cotton fibre / Zheng Chunllin in COLORATION TECHNOLOGY, Vol. 128, N° 3 (2012)
PermalinkDyeing properties of polylactic acid fabric with disperse dyes of different structures using decamethylcyclopentasiloxane as non-aqueous media / Yinchun Fang in COLORATION TECHNOLOGY, Vol. 140, N° 1 (02/2024)
PermalinkDyeing properties of textiles by Turkish hazelnut (Corylus colurna) : leaves, coat, shell and dice / Mustafa Tutak in COLORATION TECHNOLOGY, Vol. 128, N° 6 (2012)
PermalinkDyeing properties on polyurethane fibres of novel azo disperse dyes prepared from a four-component Ugi reaction / Huanhuan Li in COLORATION TECHNOLOGY, Vol. 136, N° 6 (12/2020)
PermalinkDyeing recipe prediction of cotton fabric based on hyperspectral colour measurement and an improved recurrent neural network / Jianxin Zhang in COLORATION TECHNOLOGY, Vol. 137, N° 2 (04/2021)
PermalinkDyeing treatments for protecting colour and colour fastness of green bamboo culms / Min-Jay Chung in COLORATION TECHNOLOGY, Vol. 133, N° 4 (08/2017)
PermalinkDyeing wool with a sulphur black dye using a sodium borohydride /sodium bisulphite reducing system / Jackie Y. Cai in COLORATION TECHNOLOGY, Vol. 128, N° 1 (2012)
PermalinkDyes based on a 1,4-naphthoquinone skeleton as new type II photoinitiators for radical polymerisation / Agnieszka M. Szymczak in COLORATION TECHNOLOGY, Vol. 129, N° 4 (08/2013)
PermalinkDyes based on the 6,7-dichloro-5,8-quinolinedione skeleton as new type II photoinitiators for radical polymerisation / Agnieszka Orzel in COLORATION TECHNOLOGY, Vol. 130, N° 3 (06/2014)
PermalinkDyes based on the azo-1H-pyrrole moiety – synthesis, spectroscopic and electrochemical properties, and adsorption on TiO2 / Anna Maruszewska in COLORATION TECHNOLOGY, Vol. 132, N° 1 (02/2016)
PermalinkDyes derived from 1,4-naphthoquinone as initiators for radical and cationic photopolymerisation / Agnieszka Szymczak in COLORATION TECHNOLOGY, Vol. 128, N° 5 (2012)
PermalinkDyes derived from 3-formyl-2(1H)-quinolone – synthesis, spectroscopic characterisation, and their behaviour in the presence of sulfhydryl and non-sulfhydryl amino acids / Aleksandra Kowalska in COLORATION TECHNOLOGY, Vol. 131, N° 2 (04/2015)
PermalinkDyes from the leaves of deciduous plants with a high tannin content for wool / A. S. M. Raja in COLORATION TECHNOLOGY, Vol. 124, N° 5 (2008)
PermalinkDynamic colorimetric properties of mixed thermochromic printing inks / Rahela Kulčar in COLORATION TECHNOLOGY, Vol. 127, N° 6 (2011)
PermalinkEco-friendly approach on wool pretreatment and effect on the wool structure and dyeability / Gizem Ceylan Türkoglu in COLORATION TECHNOLOGY, Vol. 139, N° 2 (04/2023)
PermalinkEco-friendly dyeing of cotton using waste-derived natural dyes and mordants / Faiza Nazir in COLORATION TECHNOLOGY, Vol. 138, N° 6 (12/2022)
PermalinkEco-friendly pretreatment of silk fabric for dyeing with Delonix regia extract / Padma Shree Vankar in COLORATION TECHNOLOGY, Vol. 125, N° 3 (2009)
PermalinkEffect of atmospheric pressure plasma treatment on the desizing and subsequent colour fading process of cotton denim fabric / C. W. Kan in COLORATION TECHNOLOGY, Vol. 128, N° 5 (2012)
PermalinkEffect of a cationising agent on the conventional reactive dyeing of cotton / M. Javaid Mughal in COLORATION TECHNOLOGY, Vol. 124, N° 1 (2008)
PermalinkEffect of coloration with various metal oxides on zirconia / Jianfeng Chen in COLORATION TECHNOLOGY, Vol. 131, N° 1 (02/2015)
PermalinkEffect of colourants on the optical characteristics and structure of Y2O3 stabilised tetragonal zirconia ceramic / Jianfeng Chen in COLORATION TECHNOLOGY, Vol. 137, N° 5 (10/2021)
PermalinkEffect of corona discharge treatment on indigo dyed cotton fabric / Shirin Nourbakhsh in COLORATION TECHNOLOGY, Vol. 124, N° 1 (2008)
PermalinkEffect of cotton fabric pretreatment on drop spreading and colour performance of reactive dye inks / Zundong Liu in COLORATION TECHNOLOGY, Vol. 132, N° 5 (10/2016)
PermalinkEffect of different softeners and sanforising treatment on pilling performance of polyester/viscose blended fabrics / Tanveer Hussain in COLORATION TECHNOLOGY, Vol. 124, N° 6 (2008)
PermalinkEffect of enzyme treatment and dyeing on the mechanical properties of linen / C. W. Kan in COLORATION TECHNOLOGY, Vol. 125, N° 5 (2009)
PermalinkEffect of inorganic anions on the photocatalytic decolorisation of an azo dye in the aqueous phase by cadmium sulphide/polymer nanocomposite films under visible light irradiation / Ru Jiang in COLORATION TECHNOLOGY, Vol. 127, N° 6 (2011)
PermalinkEffect of inorganic salts on ferric oxalate-induced decomposition of CI Acid Black 234 under different weather conditions / Yongchun Dong in COLORATION TECHNOLOGY, Vol. 124, N° 1 (2008)
PermalinkEffect of microwave pretreatment on the dyeing behaviour of polyester fabric / Manik J. Kale in COLORATION TECHNOLOGY, Vol. 127, N° 6 (2011)
PermalinkEffect of N,N-diethyl-m-toluamide on the structure and dyeing properties of meta-aramid and para-aramid fibre / Le-Yan Lei in COLORATION TECHNOLOGY, Vol. 130, N° 5 (10/2014)
PermalinkEffect of nanoclays on the dyeability of polypropylene nanocomposite fibres / Lova Razafimahefa in COLORATION TECHNOLOGY, Vol. 124, N° 2 (2008)
PermalinkEffect of process conditions on the properties of surface-modified organic pigments encapsulated by UV-curable resins / Osama Abdel Hakeim in COLORATION TECHNOLOGY, Vol. 134, N° 1 (02/2018)
PermalinkEffect of reactive dyeing on the UV protection affected by knitted fabric made from different types of cotton fibre / C. W. Kan in COLORATION TECHNOLOGY, Vol. 132, N° 2 (04/2016)
PermalinkEffect of silica based sols on the optical properties and colour fastness of synthetic indigo dyed denim fabrics / Sabiha Sezgin Bozok in COLORATION TECHNOLOGY, Vol. 137, N° 3 (06/2021)
PermalinkEffect of silver on cellulose fibre colour / Emilia Smiechowicz in COLORATION TECHNOLOGY, Vol. 130, N° 6 (12/2014)
PermalinkEffect of a standard colorimetric observer on the reconstruction of reflectance spectra of coloured fabrics / Ali Shams Nateri in COLORATION TECHNOLOGY, Vol. 124, N° 1 (2008)
PermalinkEffect of tartrazine dye on micellisation of cationic surfactants : conductometric, spectrophotometric, and tensiometric studies / Anwar Ali in COLORATION TECHNOLOGY, Vol. 132, N° 5 (10/2016)
PermalinkEffect of the addition of a modifier in the supercritical dyeing of polyester / Mauro Banchero in COLORATION TECHNOLOGY, Vol. 126, N° 3 (2010)
PermalinkEffect of the ozonation process on the dyeability of mohair fibres / Riza Atav in COLORATION TECHNOLOGY, Vol. 127, N° 3 (2011)
PermalinkEffect of the rubbing force on dry rubbing fastness with various white cloths / Keiko Suganuma in COLORATION TECHNOLOGY, Vol. 129, N° 6 (12/2013)
PermalinkEffect of the water content of padded cotton fabrics on reactive dye fixation in the pad-steam process / Jianfei Zhang in COLORATION TECHNOLOGY, Vol. 133, N° 1 (02/2017)
PermalinkEffective models for correlating spectral reflectance between spectrophotometers / Yang Xu in COLORATION TECHNOLOGY, Vol. 129, N° 4 (08/2013)
PermalinkEffects of additives on the dyeing of cotton yarn with the aqueous extract of combretum latifolium blume stems / Montra Chairat in COLORATION TECHNOLOGY, Vol. 131, N° 4 (08/2015)
PermalinkEffects of alkali and ultraviolet treatment on colour strength and mechanical properties of jute yarn / Ali A. Zolriasatein in COLORATION TECHNOLOGY, Vol. 128, N° 5 (2012)
PermalinkEffects of atmospheric plasma treatment on the dyeability of cotton fabrics by acid dyes / H. A. Karahan in COLORATION TECHNOLOGY, Vol. 124, N° 2 (2008)
PermalinkEffects of biowashing and liquid ammonia treatment on the physical characteristics and hand of denim fabric / In Yeol Lee in COLORATION TECHNOLOGY, Vol. 131, N° 3 (06/2015)
PermalinkEffects of a cationic diblock copolymer derived from [2-(methacryloyloxy)-ethyl]trimethylammonium chloride in the dyeing of cotton with reactive dye / Shin Young Han in COLORATION TECHNOLOGY, Vol. 124, N° 4 (2008)
PermalinkEffects of cationic fixing agents on the direct dyeing properties of cotton fabrics / Saima Sharif in COLORATION TECHNOLOGY, Vol. 124, N° 3 (2008)
PermalinkEffects of molecular structure on dyeing performance and colour fastness of yellow dyestuffs applied to polypropylene fibres in supercritical carbon dioxide / Keisuke Miyazaki in COLORATION TECHNOLOGY, Vol. 128, N° 1 (2012)
PermalinkEffects of ozone treatment on denim garment properties / Abir Ben Fraj in COLORATION TECHNOLOGY, Vol. 137, N° 6 (12/2021)
PermalinkEffects of starch addition on the characteristics of CoAl2O4 nano pigments / Leila Torkian in COLORATION TECHNOLOGY, Vol. 130, N° 5 (10/2014)
PermalinkEffects on print quality of varying acrylic binder types in water-based flexographic ink formulations / Sinan Sonmez in COLORATION TECHNOLOGY, Vol. 139, N° 3 (06/2023)
PermalinkEfficient adsorption of dyes from aqueous solution by poly(vinyl alcohol-co-ethylene) nanofibre membranes modified with B-cyclodextrin / Wen Wang in COLORATION TECHNOLOGY, Vol. 135, N° 3 (06/2019)
PermalinkElectrochemical method for quantitative determination of trace amounts of disperse dye in wastewater / Daniela P. Santos in COLORATION TECHNOLOGY, Vol. 130, N° 1 (02/2014)
PermalinkElectrochemical treatment of Methyl Orange dye wastewater by rotating disc electrode : optimisation using response surface methodology / Palani Ramasamy in COLORATION TECHNOLOGY, Vol. 128, N° 6 (2012)
PermalinkElectrocoagulation of azo dye production wastewater with iron electrodes : process evaluation by multi-response central composite design / Idil Arslan-Alaton in COLORATION TECHNOLOGY, Vol. 125, N° 4 (2009)
PermalinkElectrostatic self-assembly dyeing of cotton fabrics / Sule S. Ugur in COLORATION TECHNOLOGY, Vol. 127, N° 6 (2011)
PermalinkEliminating material dependency in spectra measurement via non-neighbouring band regression / Hui-Liang Shen in COLORATION TECHNOLOGY, Vol. 132, N° 2 (04/2016)
PermalinkEncapsulation of textile dyes and textile auxiliary agents into liposome systems and their use for polyamide dyeing / Petr Prichystal in COLORATION TECHNOLOGY, Vol. 129, N° 1 (02/2013)
PermalinkEnergy-efficient dyeing of nylon 6 using indigo powder dyestuff after atmospheric plasma treatment at ambient pressure / Fei Fan in COLORATION TECHNOLOGY, Vol. 135, N° 4 (08/2019)
PermalinkPermalinkEnhanced dyeability of poly(ethylene terephthalate)/organoclay nanocomposite filaments / Ilhan Özen in COLORATION TECHNOLOGY, Vol. 131, N° 6 (12/2015)
PermalinkEnhanced model for the diffusivity of a dye molecule into human hair fibre based on molecular modelling techniques / Olivier Morel in COLORATION TECHNOLOGY, Vol. 124, N° 5 (2008)
PermalinkEnhanced PAA bleaching of cotton by incorporating a cationic bleach activator / Pavla Krizman Lavric in COLORATION TECHNOLOGY, Vol. 123, N° 4 (2007)
PermalinkEnhancement of the advanced Fenton process by ultrasound for decolorisation of real textile wastewater / Chih-Huang Weng in COLORATION TECHNOLOGY, Vol. 130, N° 2 (04/2014)
PermalinkEnhancement of the Mie scattering effect using floatstone-like TiO2 spherical micropigment / Tomohiro Shirosaki in COLORATION TECHNOLOGY, Vol. 133, N° 3 (06/2017)
PermalinkEnhancing dye adsorption of wool by controlled and facile surface modification using sodium bisulphite / Zhe Jiang in COLORATION TECHNOLOGY, Vol. 138, N° 1 (02/2022)
PermalinkEnhancing textile ink-jet printing with chitosan / C. W. M. Yuen in COLORATION TECHNOLOGY, Vol. 123, N° 4 (2007)
PermalinkEnhancing the wash fastness of disperse dyes on wool with oxidants / Steven J. McNeil in COLORATION TECHNOLOGY, Vol. 136, N° 3 (06/2020)
PermalinkEnvironmentally friendly aspects in coloration / Chi-Wai Kan in COLORATION TECHNOLOGY, Vol. 132, N° 1 (02/2016)
PermalinkEnvironmentally friendly coloration of cotton by the UV-induced photografting of a-bromoacrylamido dyes / Yuanyuan Dong in COLORATION TECHNOLOGY, Vol. 130, N° 4 (08/2014)
PermalinkEnvironmentally friendly coloured materials : cellulose/titanium dioxide/inorganic pigment composite spherical microbeads prepared by viscose phase-separation method / Shoji Nagaoka in COLORATION TECHNOLOGY, Vol. 123, N° 6 (2007)
PermalinkEnzymatic improvement of guar-based thickener for better-quality silk screen printing / Eva Baldaro in COLORATION TECHNOLOGY, Vol. 128, N° 4 (2012)
PermalinkEnzymatic synthesis of sodium alginate-g-poly (acrylic acid) grafting copolymers as a novel printing thickener / Nan Zhang in COLORATION TECHNOLOGY, Vol. 138, N° 3 (06/2022)
PermalinkEpaississants synthétiques / Alex Zogu in L'INDUSTRIE TEXTILE, N° 1329 (03/2001)
PermalinkEquilibrium and kinetic studies of the cationic dye removal capability of a novel biosorbent Tamarindus indica from textile wastewater / Shooka Khorramfar in COLORATION TECHNOLOGY, Vol. 126, N° 5 (2011)
PermalinkErratum : Progress towards a greener textile industry / Tim Dawson in COLORATION TECHNOLOGY, Vol. 128, N° 4 (2012)
PermalinkEthylene glycol diglycidyl ether applied to crosslinking dyeing of cotton fabric with madder dye / Xiaoyu Cai in COLORATION TECHNOLOGY, Vol. 138, N° 4 (08/2022)
PermalinkEvaluating colour image difference metrics for gamut-mapped images / Jon Yngve Hardeberg in COLORATION TECHNOLOGY, Vol. 124, N° 4 (2008)
PermalinkEvaluation of colour fastness and thermal migration in softened polylactic acid fabrics dyed with disperse dyes of differing hydrophobicity / Ozan Avinc in COLORATION TECHNOLOGY, Vol. 126, N° 6 (2010)
PermalinkEvaluation of the homogenization properties of masterbatches / László Zsíros in COLORATION TECHNOLOGY, Vol. 133, N° 5 (10/2017)
PermalinkEvolution of right-first-time dyeing production / James Park in COLORATION TECHNOLOGY, Vol. 125, N° 3 (2009)
PermalinkExamination, conservation and restoration of painted art / Timothy L. Dawson in COLORATION TECHNOLOGY, Vol. 123, N° 5 (2007)
PermalinkExhaust dyeing of meta-aramid yarn at low temperature and time / Komal Kukreja in COLORATION TECHNOLOGY, Vol. 139, N° 5 (10/2023)
PermalinkExperimental and theoretical insight into the electronic properties of 4-aryl-5-arylazo-3-cyano-6-hydroxy-2-pyridone dyes / Vesna D. Vitnik in COLORATION TECHNOLOGY, Vol. 133, N° 3 (06/2017)
PermalinkExperimental study on supercritical water oxidation of CI Reactive Orange 7 dye wastewater using response surface methodology / Jie Zhang in COLORATION TECHNOLOGY, Vol. 128, N° 4 (2012)
PermalinkExtraction and characterisation of non-scourable chromophores from discoloured fleece wool / Jolon M. Dyer in COLORATION TECHNOLOGY, Vol. 123, N° 1 (2007)
PermalinkExtraction of juglone from Pterocarya fraxinifolia leaves for dyeing, anti-fungal finishing, and solar UV protection of wool / Izadyar Ebrahimi in COLORATION TECHNOLOGY, Vol. 131, N° 6 (12/2015)
PermalinkExtraction of natural dyes from Alpinia blepharocalyx K. Schum. for dyeing of silk fabric / Chunxia Wang in COLORATION TECHNOLOGY, Vol. 129, N° 1 (02/2013)
PermalinkExtraction of polyphenolic dyes from henna, pomegranate rind, and Pterocarya fraxinifolia for nylon 6 dyeing / Izadyar Ebrahimi in COLORATION TECHNOLOGY, Vol. 132, N° 2 (04/2016)
PermalinkExtraction of polyphenolic substances from bark as natural colorants for wool dyeing / Christa Fitz-Binder in COLORATION TECHNOLOGY, Vol. 135, N° 1 (02/2019)
PermalinkExtraction of reactive dyes from aqueous solutions by halogen-free ionic liquids / Jazmin Narcedalia Castillo-Cervantes in COLORATION TECHNOLOGY, Vol. 135, N° 6 (12/2019)
PermalinkFabric defect detection based on golden image subtraction / Jun-Feng Jing in COLORATION TECHNOLOGY, Vol. 133, N° 1 (02/2017)
PermalinkFabric dyeing with colorimetric pH-responsive colours / Roberta Peila in COLORATION TECHNOLOGY, Vol. 137, N° 2 (04/2021)
PermalinkFabrication of high-quality silica photonic crystals on polyester fabrics by gravitational sedimentation self-assembly / Lan Zhou in COLORATION TECHNOLOGY, Vol. 131, N° 6 (12/2015)
PermalinkA facile synthesis and tautomeric structure of novel 4-arylhydrazono-3-(2-hydroxyphenyl)-2-pyrazolin-5-ones and their application as disperse dyes in COLORATION TECHNOLOGY, Vol. 129, N° 6 (12/2013)
PermalinkFacile synthesis of a cardanol-based levelling agent as a biodegradable alternative to tristyrylphenol ethoxylates for the dyeing of polyester fabric / Kun Chen in COLORATION TECHNOLOGY, Vol. 138, N° 3 (06/2022)
PermalinkFading of reactive dyes on cellulose under light and perspiration / Dehua Zhuang in COLORATION TECHNOLOGY, Vol. 123, N° 2 (2007)
PermalinkFenton and Fenton-like oxidation of CI Basic Yellow 51 : a comparative study / Nilsun H. Ince in COLORATION TECHNOLOGY, Vol. 126, N° 6 (2010)
PermalinkFenton and photo-Fenton oxidation of a model mixture of dyes – overall kinetic analysis / Francesc Torrades in COLORATION TECHNOLOGY, Vol. 124, N° 6 (2008)
PermalinkFoam properties and application in dyeing cotton fabrics with reactive dyes / Hong Yu in COLORATION TECHNOLOGY, Vol. 130, N° 4 (08/2014)
PermalinkFragrant finishing of cotton with microcapsules : comparison between printing and impregnation / Barbara Golja in COLORATION TECHNOLOGY, Vol. 129, N° 5 (10/2013)
PermalinkFunctional finishing and coloration of textiles with nanomaterials / Shagufta Riaz in COLORATION TECHNOLOGY, Vol. 134, N° 5 (10/2018)
PermalinkFunctionalisation of lyocell. Part 2 : Synthesis of 6-p-aminoanilino-4-p- (B-sulphatoethylsulphonyl)anilino- 1,3,5-triazin-2(1H)-one / A. H. M. Renfrew in COLORATION TECHNOLOGY, Vol. 124, N° 1 (2008)
PermalinkFungal colorants in applications - focus on Cortinarius species / Riikka Räisänen in COLORATION TECHNOLOGY, Vol. 135, N° 1 (02/2019)
PermalinkDe la garance au pastel / Michel Garcia / Saint-Remy-de-Provence : Edisud Nature (1996)
PermalinkA general metric for the magnitude of observer metamerism / Boris Sluban in COLORATION TECHNOLOGY, Vol. 130, N° 5 (10/2014)
PermalinkGeneration of virtual illuminants for a balanced colorimetric match / Farnaz Agahian in COLORATION TECHNOLOGY, Vol. 125, N° 1 (2009)
PermalinkGreen fire retardant finishing and combined dyeing of proteinous wool fabric / Santanu Basak in COLORATION TECHNOLOGY, Vol. 132, N° 2 (04/2016)
PermalinkGreen synthesis of reactive dye for ink-jet printing in COLORATION TECHNOLOGY, Vol. 136, N° 2 (04/2020)
PermalinkGuanidine derivatives used as peroxide activators for bleaching cellulosic textiles / Jackie Y. Cai in COLORATION TECHNOLOGY, Vol. 123, N° 2 (2007)
PermalinkA hemicyanine fluorescent reactive cationic dye : synthesis and applications on wool fabrics / Wei Zhang in COLORATION TECHNOLOGY, Vol. 131, N° 4 (08/2015)
PermalinkHigh-binding-fastness dye from functional extracts of Keemun black tea waste for dyeing flax fabric / Peng Wang in COLORATION TECHNOLOGY, Vol. 138, N° 3 (06/2022)
PermalinkHigh-performance liquid chromatography of some natural dyes : analysis of plant extracts and dyed textiles / Ozan Deveoglu in COLORATION TECHNOLOGY, Vol. 128, N° 2 (2012)
PermalinkA highly selective and sensitive benzothiazole-based 'turn-on' fluorescent sensor for Hg2+ ion / Serkan Erdemir in COLORATION TECHNOLOGY, Vol. 131, N° 1 (02/2015)
PermalinkA highly selective ratiometric fluorescent sensor for Hg2+ based on 1,8-naphthalimide / Xiangzhi Li in COLORATION TECHNOLOGY, Vol. 130, N° 3 (06/2014)
PermalinkHorseradish peroxidase-mediated polyethylene glycol-templated polymerisation of gallic acid and pyrrole to improve the functionalisation and dyeing properties of silk fabrics / Na-won Baek in COLORATION TECHNOLOGY, Vol. 139, N° 1 (02/2023)
PermalinkHow to turn black to cool / Lutz Frischmann in POLYMERS PAINT COLOUR JOURNAL - PPCJ, Vol. 197, N° 4517 (10/2007)
PermalinkHue-shifting for accurate and precise quantification of biochemical substances using diagnostic test strips / Ryoichi Doi in COLORATION TECHNOLOGY, Vol. 137, N° 5 (10/2021)
PermalinkIdentification and quantification of CI Reactive Blue 19 dye degradation product in soil / Chengcheng Fen in COLORATION TECHNOLOGY, Vol. 137, N° 3 (06/2021)
PermalinkIdentification of early synthetic dyes in historical Chinese textiles of the late nineteenth century by high-performance liquid chromatography coupled with diode array detection and mass spectrometry / Jian Liu in COLORATION TECHNOLOGY, Vol. 132, N° 2 (04/2016)
PermalinkIlluminant metamerism potentiality of metameric pairs / Seyed Hossein Amirshahi in COLORATION TECHNOLOGY, Vol. 128, N° 5 (2012)
PermalinkIllumination compensation in textile colour constancy, based on an improved least-squares support vector regression and an improved GM(1,1) model of grey theory / Jian-xin Zhang in COLORATION TECHNOLOGY, Vol. 133, N° 2 (04/2017)
PermalinkImpression du polyester par jet d'encre / Bernd Siegel in L'INDUSTRIE TEXTILE, N° 1306 (02/1999)
PermalinkPermalinkImproved mechanism of polyester dyeing with disperse dyes in finite dyebath / Bingnan Mu in COLORATION TECHNOLOGY, Vol. 133, N° 5 (10/2017)
PermalinkImproved reactive dyeing of wool with novel trifunctional reactive dyes / H. J. Cho in COLORATION TECHNOLOGY, Vol. 123, N° 2 (2007)
PermalinkImprovement in the dyeability of viscose / D. P. Chattopadhyay in COLORATION TECHNOLOGY, Vol. 125, N° 5 (2009)
PermalinkImprovement in the light fastness of dyed meta-aramid fabric using titanium dioxide nanoparticles / Ravindra D. Kale in COLORATION TECHNOLOGY, Vol. 134, N° 6 (12/2018)
PermalinkImprovement of light fastness of natural dye : effect of ultraviolet absorbers containing benzotriazolyl moiety on the photofading of red carthamin / Hironori Oda in COLORATION TECHNOLOGY, Vol. 128, N° 2 (2012)
PermalinkImprovement of light fastness of water-based printing inks with addition of glycerol derivative containing thiol groups in COLORATION TECHNOLOGY, Vol. 134, N° 2 (04/2018)
PermalinkImprovement of the dyeing and fastness properties of a naphthalimide fluorescent dye using poly(amidoamine) dendrimer / Mousa Sadeghi-Kiakhani in COLORATION TECHNOLOGY, Vol. 131, N° 2 (04/2015)
PermalinkImprovement of the standard method for assessing colour fastness to wet rubbing / Keiko Suganuma in COLORATION TECHNOLOGY, Vol. 131, N° 5 (10/2015)
PermalinkImproving light fastness of natural dye : photostabilisation of gardenia blue / Hironori Oda in COLORATION TECHNOLOGY, Vol. 128, N° 1 (2012)
PermalinkImproving the colour fastness of dyed nylon-6 fabric by graft copolymerisation and curing of acrylic acid / Farzad Mohaddes in COLORATION TECHNOLOGY, Vol. 132, N° 3 (06/2016)
PermalinkImproving the dyeability of polyimide by pretreatment with alkali / Zehong Wang in COLORATION TECHNOLOGY, Vol. 132, N° 6 (12/2016)
PermalinkImproving the photostability of bleached silk without reducing its whiteness / Wang Zongqian in COLORATION TECHNOLOGY, Vol. 131, N° 6 (12/2015)
PermalinkImproving the photostability of bleached wool without increasing its yellowness / Keith R. Millington in COLORATION TECHNOLOGY, Vol. 130, N° 6 (12/2014)
PermalinkImproving transfer printing and ultraviolet-blocking properties of polyester-based textiles using MCT-β-CD, chitosan and ethylenediamine / Heba M. Khalil in COLORATION TECHNOLOGY, Vol. 126, N° 6 (2010)
PermalinkIn situ fabric coloration with indigo synthesised in flow / Michael P. Haaf in COLORATION TECHNOLOGY, Vol. 135, N° 2 (04/2019)
PermalinkIndustrial organic photochromic dyes / S. Nigel Corns in COLORATION TECHNOLOGY, Vol. 125, N° 5 (2009)
PermalinkInfluence of aminopropylvinylsilsesquioxane post-treatment on the colour performance of pigment-based inks on ink-jet-printed polyester fabrics / Osama Abdel Hakeim in COLORATION TECHNOLOGY, Vol. 137, N° 6 (12/2021)
PermalinkInfluence of carbon black with different polar groups on the solvent N-methylmorpholine N-oxide / Hong Jin in COLORATION TECHNOLOGY, Vol. 137, N° 5 (10/2021)
PermalinkInfluence of dichloro-s-triazinyl reactive dyes on the fibrillation propensity of lyocell fibres / Duncan A. S. Phillips in COLORATION TECHNOLOGY, Vol. 124, N° 3 (2008)
PermalinkInfluence of different finishing conditions on the wet fastness of selected disperse dyes on polylactic acid fabrics / Ozan Avinc in COLORATION TECHNOLOGY, Vol. 125, N° 5 (2009)
PermalinkInfluence of Eri silk fibre on the physical characteristics and dyeing properties of Eri silk/cotton blended yarn / Rungsima Chollakup in COLORATION TECHNOLOGY, Vol. 126, N° 1 (2010)
PermalinkInfluence of liquor ratio and amount of dyestuff in producing ultradeep black dyeing using mercerised and cationised cotton / Sha Fu in COLORATION TECHNOLOGY, Vol. 132, N° 3 (06/2016)
PermalinkInfluence of melt spinning conditions on dye uptake of poly(ethylene terephthalate) fibres / Kenan Yildirim in COLORATION TECHNOLOGY, Vol. 125, N° 3 (2009)
PermalinkInfluence of nano-coated pigment ink formulation on ink-jet printability and printing accuracy / Min Li in COLORATION TECHNOLOGY, Vol. 133, N° 6 (12/2017)
PermalinkInfluence of sublimation transfer printing on alterations in the structural and physical properties of knitted fabrics / Sandra Stojanovic in COLORATION TECHNOLOGY, Vol. 137, N° 2 (04/2021)
PermalinkInk-jet printing of cotton with natural dyes / Georgios Savvidis in COLORATION TECHNOLOGY, Vol. 130, N° 3 (06/2014)
PermalinkInk-jet printing of nylon fabric using reactive dyestuff in COLORATION TECHNOLOGY, Vol. 127, N° 6 (2011)
PermalinkInk-jet printing process for lyocell and cotton fibres. Part 2 : The relationship of colour strength and dye fixation to ink penetration / Robert M. Christie in COLORATION TECHNOLOGY, Vol. 126, N° 6 (2010)
PermalinkInk jet textile printing / Christina Cie / Cambridge [United Kingdom] : Woodhead Publishing Ltd (2015)
PermalinkInnovative technologies for high performance textiles / Ian Holme in COLORATION TECHNOLOGY, Vol. 123, N° 2 (2007)
PermalinkInsights into the dyeing using natural indigo (Indigofera tinctoria) : Toward an environmentally friendly garment / Luciana M. C. Silva in COLORATION TECHNOLOGY, Vol. 140, N° 1 (02/2024)
PermalinkInstrumental shade sorting of coloured fabrics using genetic algorithm and particle swarm optimisation / Elham Hasanlou in COLORATION TECHNOLOGY, Vol. 139, N° 4 (08/2023)
PermalinkInteraction of N-methylformanilide with high-performance polyimide fibre and its effect on dyeing / Dongyan Shao in COLORATION TECHNOLOGY, Vol. 138, N° 4 (08/2022)
PermalinkInteraction of phenol red with cetyltrimethylammonium bromide in aqueous solution in COLORATION TECHNOLOGY, Vol. 131, N° 6 (12/2015)
PermalinkIntroducing variations in colour of cotton fabric–reactive dye systems through irradiation with a carbon dioxide laser / On Na Hung in COLORATION TECHNOLOGY, Vol. 132, N° 1 (02/2016)
PermalinkInvestigating the in-solution photodegradation pathway of diamond green G by chromatography and mass spectrometry / Francesca Sabatini in COLORATION TECHNOLOGY, Vol. 137, N° 5 (10/2021)
PermalinkInvestigation and feed-forward neural network-based estimation of dyeing properties of air plasma treated wool fabric dyed with natural dye obtained from Hibiscus sabdariffa / Zeynep Omerogullari Basyigit in COLORATION TECHNOLOGY, Vol. 139, N° 4 (08/2023)
PermalinkInvestigation into photocatalytic decolorisation of CI Reactive Black 5 using titanium dioxide nanopowder / Fiona Chai Foong Low in COLORATION TECHNOLOGY, Vol. 128, N° 1 (2012)
PermalinkInvestigation into the development of novel lanthanide-based luminescent colorants for application to textiles and paper materials / David M. Lewis in COLORATION TECHNOLOGY, Vol. 139, N° 5 (10/2023)
PermalinkInvestigation into the dyeing of wool with Lanasol and Remazol reactive dyes in seawater / Peter J. Broadbent in COLORATION TECHNOLOGY, Vol. 134, N° 2 (04/2018)
PermalinkInvestigation into the effect of a plant-derived stabiliser on the light and wash fastness of sulphur-dyed cotton and nylon fabrics / Peter J. Broadbent in COLORATION TECHNOLOGY, Vol. 136, N° 3 (06/2020)
PermalinkInvestigation into the reaction of reactive dyes with carboxylate salts and the application of carboxylate-modified reactive dyes to cotton / David M. Lewis in COLORATION TECHNOLOGY, Vol. 138, N° 1 (02/2022)
PermalinkInvestigation into the removal of pigment, sulphur and vat colourants from cotton textiles and implications for waste cellulosic recycling / Pendo Bigambo in COLORATION TECHNOLOGY, Vol. 137, N° 6 (12/2021)
PermalinkInvestigation into the sequential application of cationic/anionic fixing agents to improve the oxidative washing resistance of CI Leuco Sulphur Black 1-dyed cotton fabric / Quratulain Mohtashim in COLORATION TECHNOLOGY, Vol. 136, N° 3 (06/2020)
PermalinkInvestigation of alkaline hydrolysis of phthalimide-based azo dye and its application to after-treatment optimisation for high-fasntess dyeing of polyesters in COLORATION TECHNOLOGY, Vol. 134, N° 3 (06/2018)
PermalinkInvestigation of a homogeneous activating ozonation method in the rinsing procedure of cotton fabric dyed with reactive dye / Ya-Hong Mao in COLORATION TECHNOLOGY, Vol. 127, N° 4 (2011)
PermalinkInvestigation of the effect of laser technology on the colouring and patterning possibilities in polyacrylonitrile socks / Riza Atav in COLORATION TECHNOLOGY, Vol. 138, N° 4 (08/2022)
PermalinkInvestigation on colour, fastness properties and HPLC-DAD analysis of silk fibres dyed with Rubia tinctorium L. and Quercus ithaburensis Decaisne / Ozan Deveoglu in COLORATION TECHNOLOGY, Vol. 128, N° 5 (2012)
PermalinkIonic-liquid-assisted mixed alkali system for reactive dye fixation in a batch process – optimisation through response surface methodology / Umesh B. Kore in COLORATION TECHNOLOGY, Vol. 133, N° 4 (08/2017)
PermalinkIonic liquids as performance additives for water-based printing inks / Zuzanna Zolek-Tryznowska in COLORATION TECHNOLOGY, Vol. 130, N° 4 (08/2014)
PermalinkIsolation of colour components from flowers of Tabebuia argentea: kinetic and adsorption studies on silk yarn / Konaghatta Narayanachar Vinod in COLORATION TECHNOLOGY, Vol. 127, N° 3 (2011)
PermalinkIt must be green : meeting society's environmental concerns / Timothy L. Dawson in COLORATION TECHNOLOGY, Vol. 124, N° 2 (2008)
PermalinkJohn Mercer FRS, FCS, MPhS, JP : the Father of Textile Chemistry / Ian Holme in COLORATION TECHNOLOGY, Vol. 135, N° 3 (06/2019)
PermalinkA kinetic and thermodynamic study of lac dye adsorption on silk yarn coated with microcrystalline chitosan / Aunlika Chimprasit in COLORATION TECHNOLOGY, Vol. 135, N° 3 (06/2019)
PermalinkKnowledge distillation for unsupervised defect detection of yarn-dyed fabric using the system DAERD : Dual attention embedded reconstruction distillation / Hongwei Zhang in COLORATION TECHNOLOGY, Vol. 140, N° 1 (02/2024)
PermalinkLaccase-catalysed coloration of wool and nylon / Chetna D. Prajapati in COLORATION TECHNOLOGY, Vol. 134, N° 6 (12/2018)
PermalinkLiants et fixateurs / Alex Zogu in L'INDUSTRIE TEXTILE, N° 1324 (10/2000)
PermalinkLight-harvesting and light-protecting pigments in simple life forms / Timothy L. Dawson in COLORATION TECHNOLOGY, Vol. 123, N° 3 (2007)
PermalinkLimitations in predicting dyebath exhaustion using optical spectroscopy / Melih Günay in COLORATION TECHNOLOGY, Vol. 126, N° 3 (2010)
PermalinkLiposomes of phosphatidylcholine : a biological natural surfactant as a dispersing agent / M. Marti in COLORATION TECHNOLOGY, Vol. 123, N° 4 (2007)
PermalinkLooking into special surface effects : diffuse coarseness and glint impression / Zihao Winston Wang in COLORATION TECHNOLOGY, Vol. 132, N° 2 (04/2016)
PermalinkLow-temperature bleaching of cotton fabric using a copper-based catalyst for hydrogen peroxide / Chong Yin in COLORATION TECHNOLOGY, Vol. 131, N° 1 (02/2015)
PermalinkLow-temperature bleaching of cotton fabric with a binuclear manganese complex of 1,4,7-trimethyl-1,4,7-triazacyclononane as catalyst for hydrogen peroxide / Xinbo Qin in COLORATION TECHNOLOGY, Vol. 128, N° 5 (2012)
PermalinkLow-temperature dyeing of meta-aramid fabrics pretreated with 2-phenoxyethanol / Dan Sheng in COLORATION TECHNOLOGY, Vol. 133, N° 4 (08/2017)
PermalinkMathematical models for water vapour resistance prediction of printed garments / Mladen Stancic in COLORATION TECHNOLOGY, Vol. 134, N° 1 (02/2018)
PermalinkMeasurements of dye absorption by cellulose triacetate using matching index of refraction absorption spectroscopy / Patricia Anne Annis in COLORATION TECHNOLOGY, Vol. 123, N° 4 (2007)
PermalinkMechanism and application of ozone fading: Oxidative decolorisation of disperse dyes and waste-dyed polyester fabrics / Jiangfei Lou in COLORATION TECHNOLOGY, Vol. 139, N° 3 (06/2023)
PermalinkMechanism and properties of coloured nanoscale SiO2 prepared from silica and reactive dyes / Liping Zhang in COLORATION TECHNOLOGY, Vol. 132, N° 5 (10/2016)
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