ORIGINAL_ARTICLE
Decolorization of Malachite Green Dye Solution by Bacterial Biodegradation
Malachite green dye is widely used in food and textile industries for various purposes and also used as biocide in the aquaculture industry to control fungal attacks and protozoan infections. Surface and ground water is contaminated by dyes due to discharge of untreated wastewater from industries. The presence of malachite green in water causes serious health effects such as mutagenesis, respiratory toxicity and carcinogenesis. Therefore, removal of malachite green from water by using various techniques is an essential concern for living beings as well as environment. In this study, the ability of isolated bacteria (from oil contaminated soil) for biodegradation of MG dye was investigated. The bacterium was able to grow in temperature range of 25 to 45°C and pH range of 5 to 9. Optimum temperature and pH for bacterial growth were determined as 37 °C and 7, respectively. Effect of temperature, initial concentration of dye and shaking condition on decolorization of dye solution was also tested. 20 ppm MG dye was efficiently degraded by bacteria in less than 2 h, and biodegradation of MB dye followed first-order kinetics model. These properties make the bacteria suitable for industrial wastewater treatment.
https://pccc.icrc.ac.ir/article_81670_8051dc05206ed9b9a99c3bb27c9a3125.pdf
2021-05-01
79
87
10.30509/pccc.2021.81670
Malachite Green
Decolorization
Wastewater
Biodegradation
Bacteria
S. M.
Etezad
etezad-ma@icrc.ac.ir
1
Department of Environmental Research, Institute for Color Science and Technology, Tehran, Iran
LEAD_AUTHOR
M.
Sadeghi-Kiakhani
sadeghi-mo@icrc.ac.ir
2
Department of Organic Colorants, Institute for Color Science and Technology, Tehran, Iran
AUTHOR
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ORIGINAL_ARTICLE
Removal of Methylene Blue from Water by Polyacrylonitrile Co Sodium Methallylsulfonate Copolymer (AN69) and Polysulfone (PSf) Synthetic Membranes
Polyacrylonitrile-co-sodium methallylsulfonate copolymer (AN69) and polysulfone (PSf) synthetic membranes were prepared and used for the removal of methylene blue (MB) from water. Atomic Force Microscopy (AFM), Ionic exchange capacity (IEC), and Swelling ratio (Sr) were employed to determine the membrane characteristics. pH, membrane composition and initial dye concentration were used for the evaluation of the efficiency of MB adsorption on AN69/PSf membranes. Isotherms and kinetic models were applied to determine the adsorption mechanism and to calculate the values of adsorption parameters. The various methods reveal that with the increase of PSf percentage, the membrane surface becomes rougher and the average values of ionic exchange capacity and the swelling ratio reach 0.6 meq/g and 7%, respectively. The adsorption of MB is more efficient at higher pH (92%) and the maximum adsorption capacity reaches 75.75 mg/g. The mechanism of adsorption is perfectly fitted by pseudo-second order (R2 = 0.984) whereas the isotherm adsorption follows better the Freundlich isotherm (n = 1.49 and R2 = 0.96).
https://pccc.icrc.ac.ir/article_81690_51deff630188c781370a87755c9023aa.pdf
2021-05-01
89
100
10.30509/pccc.2021.81690
Methylene blue
Dye removal
AN69
Adsorption
Water treatment
E.
Cheikh S&#;Id
cheikhatti@gmail.com
1
Research Team: Energy, Materials and Environment (E.M.E.), FS, University of Chouaib Doukkali, El-Jadida, Morocco.
LEAD_AUTHOR
A.
Kheribech
kheribech@yahoo.fr
2
Research Team: Energy, Materials and Environment (E.M.E.), FS, University of Chouaib Doukkali, El-Jadida, Morocco.
AUTHOR
M.
Degu
djegue@una.mr
3
Research unit: Polymer, Processes and Aquatic Medium (2PMA), FST, University of Nouakchott Al-Aasriya, Nouakchott, Mauritania.
AUTHOR
Z.
Hatim
zineb.hatim@yahoo.fr
4
Research Team: Energy, Materials and Environment (E.M.E.), FS, University of Chouaib Doukkali, El-Jadida, Morocco.
AUTHOR
R
Chourak
chourak.rajaa@gmail.com
5
Research Team: Energy, Materials and Environment (E.M.E.), FS, University of Chouaib Doukkali, El-Jadida, Morocco.
AUTHOR
C.
M&#;Bareck
chamec10@yahoo.com
6
Research unit: Polymer, Processes and Aquatic Medium (2PMA), FST, University of Nouakchott Al-Aasriya, Nouakchott, Mauritania.
AUTHOR
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ORIGINAL_ARTICLE
Investigating the Effects of Thickness on the Performance of ZnO-Based DSSC
Zinc oxide nanostructures exhibit unique properties which make them suitable for dye-sensitized solar cell applications. Their specific properties such as appropriate optical properties, proper energy band gap and high electron transfer characteristics have motivated researchers to use them in the fabrication of dye-sensitized solar cell photo-anodes. In the present study, the effect of thickness on the performance of a new ZnO photo-anode has been studied. All the photovoltaic parameters of the cells fabricated using N719 ruthenium dye were measured. SEM technique was utilized to determine the thickness and the UV-Visible method was used to study the transparent properties of the photo-anodes. Electrochemical impedance spectroscopy technique was employed to determine the appropriate equivalent circuit for studying the electron transfer mechanisms in all the fabricated cells. The results demonstrated that the ZnO thickness is a critical parameter for providing either sufficient resistance to suppress the charge recombination process or appropriate electron transferring properties. The optimized ZnO photo-anode was obtained at a thickness of 19 µm, which resulted in an efficiency of 3.22%.
https://pccc.icrc.ac.ir/article_81685_e3625b622de5fd5dbfadc4b039e88f82.pdf
2021-05-01
101
112
10.30509/pccc.2021.81685
Dye-sensitized solar cell
electrochemical impedance spectroscopy
Photo-anode thickness
Thickness effect
ZnO nanoparticles
E.
Kouhestanian
elhamkouhestanian@gmail.com
1
Thin Layer and Nanotechnology Laboratory, Department of Chemical Technology, Iranian Research Organization for Science and Technology (IROST), Tehran, Iran.
AUTHOR
M.
Ranjbar
marandjbar@irost.ir
2
Thin Layer and Nanotechnology Laboratory, Department of Chemical Technology, Iranian Research Organization for Science and Technology (IROST), Tehran, Iran.
LEAD_AUTHOR
S. A.
Mozaffari
mozaffari@irost.ir
3
Thin Layer and Nanotechnology Laboratory, Department of Chemical Technology, Iranian Research Organization for Science and Technology (IROST), Tehran, Iran.
AUTHOR
H.
Salaramoli
salar@irost.ir
4
Thin Layer and Nanotechnology Laboratory, Department of Chemical Technology, Iranian Research Organization for Science and Technology (IROST), Tehran, Iran.
AUTHOR
J. Khan, M. H. Arsalan, Solar power technologies for sustainable electricity generation-A review, Renew. Sustain. Energy Rev., 55(2016), 414-425.
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4
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5
M. U. Rahman, M. Wei, F. Xie, M. Khan, Efficient dye-sensitized solar cells composed of nanostructural ZnO doped with Ti, Catalysts, 9(2019), 273-284.
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Q. Zhang, C. Li, TiO2 coated ZnO nanorods by mist chemical vapor deposition for application as photoanodes for dye-sensitized solar cells, Nanomaterials, 9(2019), 1339-1352.
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Y. He, J. Hu, Y. Xie, High-efficiency dye-sensitized solar cells of up to 8.03% by air plasma treatment of ZnO nanostructures, Chem. Commun., 51(2015), 16229-16232.
10
M. Ye, X. Wen, M. Wang, J. Locozzia, N. Zhang, C. Lin, Z. Lin, Recent advances in dye-sensitized solar cells: from photoanodes, sensitizers and electrolytes to counter electrodes, Mater. Today, 18(2015), 155-162.
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13
S. S. Khadtare and H. M. Pathan, Rose bengal sensitized ZnO photoelectrode for dye sensitized solar cell: optimizingthe performance, J. Renew. Sustain. Energy, 6(2014), 053131-053138.
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K. Premaratne, G. R. A. Kumara, R. M. G. Rajapakse, and M. L. Karunarathne, Highly efficient, optically semi-transparent, ZnO-based dye-sensitized solar cells with indoline D -358 as the dye, J. Photochem. Photobiol. A: chem., 229(2012), 29-32.
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A. B. F. Martinson, T. W. Hamann, M. J. Pellin, J. T. Hupp, New architectures for dye-sensitized solar cells, Chem. Eur. J., 14(2008), 4458-4467.
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C. C. Raj, R. Prasanth, A critical review of recent developments in nanomaterials for photoelectrodes in dye sensitized solar cells. J. Power Sources, 317(2016), 120–132.
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J. Han, F. Fan, C. Xu, S. Lin, M. Wei, X. Duan, Z. L. Wang, ZnO nanotube-based dye-sensitized solar cell and its application in self-powered devices, Nanotechnology, 21(2010), 405203-405209.
18
K. Keis, C. Bauer, G. Boschloo, A. Hagfeldt, K. Westermark, H. Rensmo, H. Siegbahn, Nanostructured ZnO electrodes for dye-sensitized solar cell applications, J. Photochem. Photobiol. A: chem., 148(2002), 57-64.
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G. S. Selopal, H. P. Wu, J. Lu, Y. Chang, M. Wang, A. Vomiero, I. Concina, E. W. G. Diau, Metal-free organic dyes for TiO2 and ZnO dye-sensitized solar cells, Scientific Reports, 6(2016), 18756- 18767.
20
J. Patwari, S. Shyamal, T. Khan, H. Ghadi, C. Bhattacharya, S. Chakrabarti, S. K. Pal, Inversion of activity in DSSC for TiO2 and ZnO photo-anodes depending on the choice of sensitizer and carrier dynamics, J. Lumin., 207(2019), 169-176.
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Z. S. Wang, H. Kawauchi, T. Kashima, H. Arakawa, Significant influence of TiO2 photoelectrode morphology on the energy conversion efficiency of N719 dye-sensitized solar cell, Coord. Chem. Rev., 248(2004), 1381-1389.
22
S. H. Kang, J. Y. Kim, H. S, Kim, H. D. Koh, J. S. Lee, Y. E Sung, Influence of light scattering particles in the TiO2 photoelectrode for solid-state dye-sensitized solar cell, J Photochem. Photobiol. A: chem., 200(2008), 294-300.
23
S. Ito, M. Nazeeruddin, P. Liska, P. Comte,R. Charvet, P,Péchy, M, Jirousek, A. Kay, S. Zakeeruddin, M. Grätzel, Fabrication of screen-printing pastes from TiO2 powders for dye-sensitised solar cells, Prog. Photovolt. Res. Appl., 14(2006), 589-601.
24
Y, Qiu, W. Chen, S. Yang, Double-layered photoanodes from variable-size anatase TiO2 nanospindles: A candidate for high-efficiency dye-sensitized solar cells, Angew Chem. Int. Ed., 49(2010), 3675-3679.
25
M. Ranjbar, S. A. Mozaffari, E. Kouhestanian, H. Salar Amoli, Sonochemical synthesis and characterization of a Zn(II) supramolecule, bis(2,6 diaminopyridinium)bis(pyridine-2,6-dicarboxylato)zincate(II), as a novel precursor for the ZnO-based dye sensitizer solar cell, J. Photochem. Photobiol. A: Chem., 321(2016), 110–121.
26
B. O’Regan. M. Grätzel, A low-coat, high-efficiency solar cell based on dye-sensitized colloidal TiO2 film. Nature, 353(1991), 737-739.
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W. C. Chang, C. H. Lee, W. C. Yu, C. M. Lin, Optimization of dye adsorption time and film thickness for efficient ZnO dye-sensitized solar cells with high at-rest stability, Nanoscale Research Letters, 7(2012), 688-697.
28
S. Ito, T. Murakami, P. Comte, P. Liska, C. Grätzel, M. Nazeeruddin, M. Grätzel, Fabrication of thin film dye sensitized solar cells with solar to electric power conversion efficiency over 10%, Thin Solid Films, 516(2008), 4613-4619.
29
N. Tounsi, M. M. Habchi, Z. Chine, A. Rebey, B. E. Jani, Optical properties study of In.08Ga.92As/GaAs using spectral reflectance, photoreflectance and near-infrared Photoluminescence, Superlattice. Microstruct., 59(2013), 133-143.
30
Q. Zhang, G. Cao, Hierarchically structured photoelectrodes for dye-sensitized solar cells, J. Mater. Chem., 21(2011), 6769-6774.
31
S. A. Mozaffari, M. Ranjbar, E. Kouhestanian, H. Salar Amoli, M. H. Armanmehr, An investigation on the effect of electrodeposited nanostructured ZnO on the electron transfer process efficiency of TiO2 based DSSC, Mater. Sci. Semicon. Proc., 40(2015), 285-292.
32
B. Tan, Y.Y. Wu, Dye-sensitized solar cells based on anatase TiO2 nanoparticle/nanowire composites, J. Phys. Chem. B, 110(2006), 15932-15938.
33
B. Lee, D. K. Hwang, P. Guo, S. T. Ho, D. B. Buchholtz, C. Y. Wang, R. P. H. Chang, Materials, interfaces, and photon confinement in dye-sensitized solar cells, J. Phys. Chem. B, 114(2010), 14582-14591.
34
S. Khadtarea, A. S. Ansari, H. M. Pathan, S. H. Hana, K. M. Mahadevan, S. D. Mane, C. Bathula Silver nanoparticles loaded ZnO photoelectrode with Rose Bengal as a sensitizer for dye sensitized solar cells, Inorg. Chem. commun., 104(2019), 155-159.
35
S. Khadtare, A. S. Bansode, V. L. Mathe, N. K. Shrestha, C. Bathula, S. H. Han, H. M. Pathan, Effect of oxygen plasma treatment on performance of ZnO based dye sensitized solar cells, J. Alloys and Compd., 72415(2017), 348-352.
36
S. Khadtare, A. Ware, S. A. S. Gawali, S. R. Jadkar, H. M. Pathan, S. S. Pingale, Dye sensitized solar cell with lawsone dye using ZnO photoanode: experimental and TD-DFT study, RSC Adv., 5(2015), 17647-17652.
37
P. Du, L. Songa, J. Xiong, N. Li, Z. Xi, L. Wang, D. Jin, S. Guob, Y. Yuan, Coaxial electrospun TiO2/ZnO core–sheath nanofibers film: Novel structure for photoanode of dye-sensitized solar cells, Electrochim. Acta, 78(2012), 392-397.
38
S. H. Kang, J. Y. Kim, Y. Y. Kim, H. S. Kim, Y. E. Sung, Surface modification of stretched TiO2 nanotubes for solid-state dye-sensitized solar cells, J. Phys. Chem. C, 111(2007), 9614-9623.
39
S. A. Mozaffari, R. Rahmanian, M. Abedi, H. Salar Amoli, Urea impedimetric biosensor based on reactive RF magnetron sputtered zinc oxide nanoporous transducer,Electrochim. Acta, 146(2014), 538-547.
40
S. A. Mozaffari, H. Salar Amoli, S. Simorgh, R. Rahmanian, Impedimetric thiourea sensing in copper electrorefining bath based on DC magnetron sputtered nanosilver as highly uniform transducer, Electrochim. Acta, 184 (2015) 475-482.
41
R. Rahmanian, S. A. Mozaffari, Electrochemical fabrication of ZnO-polyvinyl alcohol nanostructured hybrid film for application to urea biosensor, Sensor Actuator B: chem., 207(2015), 772-787.
42
F. F. Santiago, J. Bisquert, E. Palomares, L. Otero, D. Kuang, S. M. Zakeeruddin, M. Grätzel, Correlation between photovoltaic performance and impedance spectroscopy of dye-sensitized solar cells based on ionic liquids, J. Phys. Chem. C, 111(2007), 6550-6560.
43
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44
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45
Q. Wang, S. Ito, M. Grätzel, F. F. Santiago, I. M. Sero, J. Bisquert, T. Bessho, H. Imai, Characteristics of high efficiency dye-sensitized solar cells, J. Phys. Chem. B, 110(2006), 25210-25221.
46
P. T. Hsiao, Y. L. Tung, H. Teng, Electron transport patterns in TiO2 nanocrystalline films of dye-sensitized solar cells, J. Phys. Chem. C, 114(2010), 6762-6769.
47
ORIGINAL_ARTICLE
Producing Ceramic Toner Via Emulsion Aggregation Method Based on ZrSiO4: Pr Ceramic Pigment
Toner is a powder mainly composed of polymer and colorant that are used as ink in electrophotographic printing. Several methods have been employed for producing toner and one of is emulsion aggregation (EA) method. The purpose of this study is to produce ceramic toner based on ZrSiO4: Pr uses emulsion aggregation method and investigate the effect of ceramic pigment synthesis method on the final properties of the toner. For synthesis of zirconium silicate pigment with Praseodymium dopant, two combustion and combinational methods were studied. Ceramic Toner characteristics were analyzed using a spectrophotometer, X-ray diffraction, scanning electron microscopy, particle size analyzer and differential scanning calorimetry. Structural studies show that the pure phase of zirconium silicate can be identified as a pure phase in the toner and toner particle size and particle size distribution is in the appropriate (4-7 µm) range for printing. Thermal analyzes show an appropriate glass transition temperature at around 77 °C. Color specification shows that in spite of a decrees in color characteristics of the ceramic pigment at the manufacturing process of the toner, after application and baking at a temperature of 1000 °C, the color is converted to a suitable yellow intensity range.
https://pccc.icrc.ac.ir/article_81703_8982839620a829408c55f56253e63af6.pdf
2021-05-01
113
120
10.30509/pccc.2021.81703
ceramic toner
Electrophotographic printing
Ceramic pigment
Praseodymium Oxide (Pr6O11)
M.
Ataeefard
ataeefard-m@icrc.ac.ir
1
Department of Printing Science and Technology, Institute for Color Science and Technology, Tehran, Iran
LEAD_AUTHOR
A. M.
Aarabi
aarabi@icrc.ac.ir
2
Department of Nanoscience and Naotechnology, Institute for Color Science and Technology,Tehran, Iran
AUTHOR
A. Dinsdale, Pottery Science. Ellis Horwood Limited, New York, pp.83-86 (1986).
1
Z. Pana, Y. Wang, H. Huang, Z. Ling, Y. Dai, Sh. Kea, Recent development on preparation of ceramic inks in ink-jet printing, Ceramics Inter. 41(2015), 12515-12528
2
M. Montorsi, C. Mugonia, A. Passalacqua, A. Annovi, F. Maranic,L. Fossac, R. Capitanid, T. Manfredin, improvement of color quality and reduction of defects in the inkjet-printing technology for ceramic tiles production: A Design of Experiments study, Ceramics Inter. 42(2016), 1459-1469
3
A. Soleimani-Gorgania, , M. Ghahari, M. Peymanniaa, In situ production of nano-CoAl2O4on a ceramic surface by ink-jet printing, J. European Ceram. Soc., 35(2015), 779–786.
4
G. L.Güngör , A.Karaa, M. Blosi, D.Gardini, G. Guarini,C. Zanelli, M. Dondi, Micronizing ceramic pigments for ink jet printing: Part I. Grind ability and particle size distribution, Ceram. Inter., 41(2015), 6498–6506.
5
V. Sanz, Y. Bautista, and C. Ribes, Preparation of Ceramic Toner by Suspension Polymerization, J. Imag. Sci. Technol. 56(2012), 605-610
6
Y. Zhang, K. Zhang, M. Ye, A. Han, C. Ding, J. Yang, L. Yao, Preparation and characterization of poly (styrene-co-butyl acrylate) encapsulated, C.I. Pigment Yellow 53, charge control agents and paraffin wax composite particles for yellow ceramic toner via suspension polymerization, Prog. Org. Coat.117(2018), 69-75.
7
Y. de Hazan, M. Thänert, M. Trunec, J. Misak, Robotic deposition of 3d nanocomposite and ceramic fiber architectures via UV curable colloidal inks, J. Euro. Ceram. Soc., 32(2012), 1187–1198
8
M. Ataeefard, Y. Mohammadi, M.R. Saeb, Intelligently Synthesized In Situ Suspension Carbon Black/Styrene/Butylacrylate Composites: Using Artificial Neural Networks towards Printing Inks with Well-Controlled Properties, Poly. Sci. Seri. 61(2019), 667-680
9
M. M. Salehi, M. Ataeefard, Micro powder poly lactic acid/carbon black composite as a bio printing ink, J. Composite Mater. 53(2017), 2407-2414
10
S. Akdemir, E.zeln, E.Suvac, Stability of zircon pigments in water and diethylene glycol media: The case of turquoise V–ZrSiO, Ceram. Inter. 39(2013), 1909–1915.
11
M. Trojan. Synthesis of a pink zircon pigment, Dyes Pig. 9(1988), 329-342.
12
M Ataeefard, SMS Tilebon, MR Saeb, Intelligent modeling and optimization of emulsion aggregation method for producing green printing ink, Green Proc. Synth. 8(2019), 703-718
13
M Ataeefard, Preparing nanosilver/styrene–butyl acrylate core–shell composite via eco-friendly emulsion aggregation method as a printing ink, Colloid Poly. Sci. 296(2014), 819-827
14
G. Marshall, Recent progress in toner technology. society for imaging science and technology, 1997.
15
N. Ohta, M. Rosen Color desktop printer technology. Taylor & Francis Group, NY, 2006. .
16
ORIGINAL_ARTICLE
Cleaner Production of Dyed and Functional Polyester Using Natural Dyes vis-a-vis Exploration of Secondary Shades
atural dyes are known for their added benefits over synthetic dyes in terms of health and ecology. They are considered to present a limited range of shades, which limits their use in high-end value-added products. Thus, to explore natural dyes on large scales, it is essential to generate a wide range of shades like synthetic dyes. Therefore, it is important to explore the secondary shades of natural dyes especially those which can act as primary colors in the recipe (red, yellow and blue). In the present work, three natural dyes, namely indigo, pomegranate peels and kumkum were used to dye the polyester fabric. Along with color strength at different dye concentrations, functional properties such as antioxidant, antibacterial, and UV protection were also evaluated. The dyed polyester showed good color values (K/S>1.7) and also displayed satisfactory color fastness to light, washing and rubbing. The polyester fabric dyed with pomegranate and kumkum in self-shades displayed a variety of functional properties including a bacterial reduction of more than 90%, radical scavenging activity of greater than 90% and also displayed excellent UPF values (UPF > 270). Indigo-dyed samples displayed antibacterial activity and UV-protection; however, their antioxidant activity was poor. The secondary shades of these dyes were produced on polyester fabric.
https://pccc.icrc.ac.ir/article_81700_a919bc9b38db4803ec5268a4187d867e.pdf
2021-05-01
121
128
10.30509/pccc.2021.81700
polyester
Natural dyeing
Functional properties
Secondary shades
S.
Tambi
shubham.tambi.tt115@textile.iitd.ac.in
1
Deptartment of Textile and Fibre Engineering, Indian Institute of Technology, Hauz Khas, New Delhi, India
AUTHOR
A.
Mangal
tt1150874@iitd.ac.in
2
Deptartment of Textile and Fibre Engineering, Indian Institute of Technology, Hauz Khas, New Delhi, India
AUTHOR
N.
Singh
jangra.nagender@gmail.com
3
Deptartment of Textile and Fibre Engineering, Indian Institute of Technology, Hauz Khas, New Delhi, India
AUTHOR
J.
Sheikh
jnsheikh@textile.iitd.ac.in
4
Deptartment of Textile and Fibre Engineering, Indian Institute of Technology, Hauz Khas, New Delhi, India
LEAD_AUTHOR
F. Rehman, N. Sanbhal, T. Naveed, A. Farooq, Y. Wang, W. Wei, Antibacterial performance of tencel fabric dyed with pomegranate peel extracted via ultrasonic method, Cellulose. 25(2018), 4251–4260.
1
B. Patel, P. Kanade, Sustainable dyeing and printing with natural colours vis-à-vis preparation of hygienic viscose rayon fabric, Sustain. Mater. Technol. 22(2019), e00116.
2
Y. Zhou, J. Zhang, R. C. Tang, J. Zhang, Simultaneous dyeing and functionalization of silk with three natural yellow dyes, Ind. Crops Prod. 64(2015), 224–232.
3
X. Hou, F. Fang, X. Guo, J. Wizi, B. Ma, Y. Tao, Y. Yang, Potential of sorghum husk extracts as a natural functional dye for wool fabrics, ACS Sustain. Chem. Eng. 5(2017), 4589–4597.
4
M. Shabbir, L. J. Rather, F. Mohammad, Economically viable UV-protective and antioxidant finishing of wool fabric dyed with Tagetes erecta flower extract: Valorization of marigold, Ind. Crops Prod. 119(2018), 277–282.
5
J. Sheikh, N. Singh, D. Pinjari, Sustainable functional coloration of linen fabric using kigelia africana flower colorant, J. Nat. Fibers. (2019), 1–10.
6
J. Sheikh, N. Singh, M. Srivastava, Functional dyeing of cellulose-based (Linen) fabric using bombax ceiba (Kapok) flower extract, Fibers Polym. 20(2019), 312–319.
7
J. Sheikh, A. Agrawal, H. Garg, A. Agarwal, P. Mathur, Functionalization of wool fabric using pineapple peel extract (PPE) as a natural dye, AATCC J. Res. 6(2019), 16–20.
8
A. Sharma, S. Kadam, P. Mathur, Shahid-ul-Islam, J. Sheikh, Re-using henna natural dyeing wastewater for coloration and multifunctional finishing of linen fabric, Sustain. Chem. Pharm. 11(2019), 17–22.
9
M. Hosseinnezhad, K. Gharanjig, R. Jafari, H. Imani, Green dyeing of woolen yarns with weld and Madder natural dyes in the presences of biomordant, Prog. Color Colorant Coat. 14(2021), 35–45.
10
J. G. Choi, O. H. Kang, Y. S. Lee, H. S. Chae, Y. C. Oh, O. O. Brice, M. S. Kim, D. H. Sohn, H. S. Kim, H. Park, D. W. Shin, J. R. Rho, D. Y. Kwon, In vitro and in nivo antibacterial activity of punica granatum peel ethanol extract against salmonella., Evid. Based. Complement. Alternat. Med. 2011(2011), 690518.
11
R. P. Singh, K. N. Chidambara Murthy, G. K. Jayaprakasha, Studies on the antioxidant activity of pomegranate (Punica granatum) peel and seed extracts using in vitro models, J. Agric. Food Chem., 50(2002), 81–86.
12
E. P. Lansky, R. A. Newman, Punica granatum (pomegranate) and its potential for prevention and treatment of inflammation and cancer, J. Ethnopharmacol. 109(2007), 177–206.
13
L. C. Braga, J. W. Shupp, C. Cummings, M. Jett, J. A. Takahashi, L.S. Carmo, E. Chartone-Souza, A.M.A. Nascimento, Pomegranate extract inhibits staphylococcus aureus growth and subsequent enterotoxin production, J. Ethnopharmacol. 96(2005), 335–339.
14
D. Heber, N. P. Seeram, H. Wyatt, S. M. Henning, Y. Zhang, L. G. Ogden, M. Dreher, J. O. Hill, Safety and antioxidant activity of a pomegranate ellagitannin-enriched polyphenol dietary supplement in overweight individuals with increased waist size, J. Agric. Food Chem. 55(2007), 10050–10054.
15
M. Gangwar, R. K. Goel, G. Nath, Mallotus philippinensis muell. arg (euphorbiaceae): ethnopharmacology and phytochemistry review., Biomed Res. Int. 2014(2014), 213973.
16
V. P. Kumar, N. S. Chauhan, H. Padh, M. Rajani, Search for antibacterial and antifungal agents from selected Indian medicinal plants, J. Ethnopharmacol. 107(2006), 182–188.
17
A. A. Mostafa, A. A. Al-Askar, K. S. Almaary, T. M. Dawoud, E. N. Sholkamy, M. M. Bakri, Antimicrobial activity of some plant extracts against bacterial strains causing food poisoning diseases, Saudi J. Biol. Sci. 25(2018), 361–366.
18
W. O. Oduro, F. Addo-Yobo, Enhancing the value of indigo-blue dyes from lonchocarpus cyanescens leaves, Inter. J. Appl. Sci. Technol. 3(2013), 78-86.
19
S. Wahyuningsih, A. H. Ramelan, D. K. Wardani, F. N. Aini, P. L. Sari, B. P. N. Tamtama, Y. R. Kristiawan, Indigo dye derived from indigofera tinctoria as natural food colorant, IOP Conf. Ser. Mater. Sci. Eng. 193(2017), 012048.
20
A. Sen, A. Bhowal, S. Datta, Comparison of dyeing of polyester fibers with natural dye and bio-Mordant, Prog. Color Colorant Coat. 11(2018), 165–172.
21
K. Elnagar, T. Abou Elmaaty, S. Raouf, Dyeing of polyester and polyamide synthetic fabrics with natural dyes using ecofriendly technique, J. Text. 2014(2014), 1–8.
22
M. A. Rahman Bhuiyan, A. Ali, A. Islam, M. A. Hannan, S. M. Fijul Kabir, M. N. Islam, Coloration of polyester fiber with natural dye henna (Lawsonia inermis L.) without using mordant: a new approach towards a cleaner production, Fash. Text. 5(2018), 2-11.
23
R.A. Arain, F. Ahmad, Z. khatri, M.H. Peerzada, Microwave assisted henna organic dyeing of polyester fabric: a green, economical and energy proficient substitute, Nat. Prod. Res. (2019), 1–4.
24
M. T. Abate, A. Ferri, J. Guan, G. Chen, V. Nierstrasz, Colouration and bio-activation of polyester fabric with curcumin in supercritical CO2: Part I - Investigating colouration properties, J. Supercrit. Fluids. 152(2019), 104548.
25
S. Shahidi, M. Ghoranneviss, J. Wiener, Improving synthetic and natural dyeability of polyester fabrics by dielectric barrier discharge, J. Plast. Film Sheeting. 31(2015), 286–308.
26
M. H. Zohdy, Cationization and gamma irradiation effects on the dyeability of polyester fabric towards disperse dyes, Radiat. Phys. Chem. 73(2005), 101–110.
27
A. Haji, Dyeing of cotton fabric with natural dyes improved by mordants and plasma treatment, Prog. Color Colorant Coat. 12(2019), 191–201.
28
M. Sadeghi-Kiakhani, S. Safapour, Y. Golpazir-Sorkheh, Impact of chitosan-poly(amidoamine) dendreimer hybrid treatment on dyeing and color fastness properties of wool yarn with madder natural dye, Prog. Color Colorant Coat. 12(2019), 241–250.
29
A. Kerkeni, D. Gupta, A. Perwuelz, N. Behary, Chemical grafting of curcumin at polyethylene terephthalate woven fabric surface using a prior surface activation with ultraviolet excimer lamp, J. Appl. Polym. Sci. 120(2011), 1583–1590.
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S. Adeel, S. Shahid, S. G. Khan, F. Rehman, M. Muneer, M. Zuber, N. Akhtar, Eco-Friendly disperse dyeing of ultraviolet-treated polyester fabric using disperse yellow 211, Polish J. Environ. Stud. 27(2018), 1935–1939.
31
S. Adeel, T. Gulzar, M. Azeem, Fazal-ur-Rehman, M. Saeed, I. Hanif, N. Iqbal, Appraisal of marigold flower based lutein as natural colourant for textile dyeing under the influence of gamma radiations, Radiat. Phys. Chem. 130(2017), 35–39.
32
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33
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36
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37
S. Naz, R. Siddiqi, S. Ahmad, S.A. Rasool, S.A. Sayeed, Antibacterial activity directed isolation of compounds from punica granatum, J. Food Sci. 72(2007), M341–M345.
38
ORIGINAL_ARTICLE
Direct Sublimation Inkjet Printing as a New Environmentally Friendly Approach for Printing on Polyester Textiles
Polyester is one of the most important synthetic fibers extensively used in textile industry. Inkjet printing on polyester textile is performed either by direct or transfer approaches. The first method needs chemical surface treatment, while the latter uses transfer paper. In this article, direct sublimation inkjet printing (DSIP) on polyester textile has been studied to overcome the natural resource limitations and environmental problems by eliminating the need for transfer paper and chemical surface treatment. Polyester textile was surface treated using atmospheric-pressure plasma under air atmosphere. The effects of different factors including plasma speed, plasma power, and the number of treatments on the contact angle and K/S value have been investigated via experimental design method. Scanning electron microscopy (SEM), attenuated total reflection-fourier transform infrared (ATR-FTIR), and bleeding test showed that plasma power has the least effect on both K/S value and contact angle. The K/S values increased while the contact angle decreased by increasing the number of treatments and decreasing the plasma speed. Optical and scanning electron microscopy images also revealed that the treated textile using constant plasma power of 350 W, 60 plasma treatments and the plasma speed of 3 m/min showed the most printing thickness and the highest image resolution.
https://pccc.icrc.ac.ir/article_81699_606a07d1c8c1a859e1291491614fec03.pdf
2021-05-01
129
138
10.30509/pccc.2021.81699
Direct sublimation printing
inkjet
atmospheric-pressure plasma
polyester
K/S value
M. R.
Alihoseini
m.alihoseini@mail.sbu.ac.ir
1
Laser and Plasma Research Institute, Shahid Beheshti University, Tehran, Iran
AUTHOR
M. R.
Khani
m_khani@sbu.ac.ir
2
Laser and Plasma Research Institute, Shahid Beheshti University, Tehran, Iran
AUTHOR
M.
Jalili
jalili@icrc.ac.ir
3
Department of Printing Ink, Institute for Color Science and Technology, Tehran, Iran
LEAD_AUTHOR
B.
Shokri
b-shokri@sbu.ac.ir
4
Department of Physics, Shahid Beheshti University, Tehran, Iran
AUTHOR
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ORIGINAL_ARTICLE
Sol–Gel Based Liquid-Mix Method for the Synthesis of Znfe2O4 Spinel
The superparamagnetic ZnFe2O4 (ZFO) powder with spinel structure was synthesized by a sol–gel based liquid-mix method using deionized water, citric acid, iron nitrate, zinc nitrate, and propylene glycol. Based on the principles of the Pechini method, the obtained solutions were treated under reflux at 95 °C followed by drying to obtain the desired powder. Simultaneous thermal analysis (STA) showed that there are three main thermal events at 165, 300, and 800 °C, which are related to the evaporation of water and/or volatile chemicals, combustion of organic materials, and chemical reactions to form ZFO phase, respectively. Among different calcination temperatures, thermal treatment at 900 °C led to the formation of a powder which its XRD pattern is well-matched with the ZFO standard peaks. Scanning electron microscopy (SEM) showed that calcination at 400-600 °C led to some agglomerated sediment particles in the range of 50-100 nm, whereas the morphologies of the samples calcined at 700-900 °C consisted of some fused particles with larger size (~1 μm). The vibrating sample magnetometer (VSM) results approved that although magnetization saturation (Ms) values were negligible in the samples calcined at lower temperatures (low–temperature samples), Ms value of the sample calcined at 900 °C was about ±7.5 emu/g. On the other hand, the S-shaped hysteresis curves of the high-temperature samples (calcined at 700-900 °C) and consequently zero/near-zero value for the coercivity (Hc) and remanence (Mr) parameters confirmed the superparamagnetic behavior of the as-synthesized ZFO compound.
https://pccc.icrc.ac.ir/article_81689_08a96fe7e58d8ffb7dfbdb7b57a5ef33.pdf
2021-05-01
139
147
10.30509/pccc.2021.81689
ZnFe2O4 spinel
superparamagnetic behavior
sol–gel based liquid-mix method
XRD
VSM
M.
Gharagozlou
gharagozlou@icrc.ac.ir
1
Department of Nanomaterials and Nanocoatings, Institute for Color Science and Technology, Tehran, Iran
LEAD_AUTHOR
S.
Naghibi
sanaz.naghibi@flinders.edu.au
2
Medical Device Research Institute, College of Science and Engineering, Flinders University, South Australia, Australia
AUTHOR
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