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Halloysite nanotubes with fluorinated cavity: an innovative consolidant for paper treatment

Published online by Cambridge University Press:  02 January 2018

Giuseppe Cavallaro ,
Giuseppe Lazzara ,
Stefana Milioto  and
Filippo Parisi
Giuseppe Cavallaro
Affiliation:
Department of Physics and Chemistry, Università degli Studi di Palermo, Viale delle Scienze, pad. 17, Palermo 90128, Italy
Giuseppe Lazzara*
Affiliation:
Department of Physics and Chemistry, Università degli Studi di Palermo, Viale delle Scienze, pad. 17, Palermo 90128, Italy
Stefana Milioto
Affiliation:
Department of Physics and Chemistry, Università degli Studi di Palermo, Viale delle Scienze, pad. 17, Palermo 90128, Italy
Filippo Parisi
Affiliation:
Department of Physics and Chemistry, Università degli Studi di Palermo, Viale delle Scienze, pad. 17, Palermo 90128, Italy
*
*E-mail: giuseppe.lazzara@unipa.it
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Abstract

Hybrid material based on halloysite nanotubes (HNTs) and sodium perfluorooctanoate (NaPF8) was used as a consolidant for paper treatment. The consolidation efficiency was determined by thermogravimetry as well as by paper grammage determination. Morphological analysis of the treated paper was performed by means of scanning electron microscopy while the effect of modified HNTs on the thermal behaviour of the cellulose fibres was investigated by differential scanning calorimetry which determined the combustion enthalpy of the paper.Water contact angle measurements were performed to study the paper wettability. The physico-chemical properties investigated (mesoscopic structure, thermal stability and wettability) of the treated paper were correlated successfully with the consolidation loading and, consequently, to the affinity between the fluorinated modified HNTs and the fibrous cellulose structure. This study proposes a new green protocol for paper consolidation based on natural tubular nanoparticles with a flame retardant effect.

Keywords

thermogravimetrydifferential scanning calorimetryhalloysitewettabilitypaper
Type
Research Article
Information
Clay Minerals , Volume 51 , Issue 3 , June 2016 , pp. 445 - 455
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 2016

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References

Aulin, C., Shchukarev, A., Lindqvist, J., Malmström, E., Wågberg, L. & Lindström, T. (2008) Wetting kinetics of oil mixtures on fluorinated model cellulose surfaces. Journal of Colloid and Interface Science, 317, 556567.Google Scholar
Badea, E., Della Gatta, G. & Budrugeac, P. (2011) Characterisation and evaluation of the environmental impact on historical parchments by differential scanning calorimetry. Journal of Thermal Analysis and Calorimetry, 104, 495506.Google Scholar
Blanco, I., Abate, L., Bottino, F.A. & Bottino, P. (2012) Thermal degradation of hepta cyclopentyl, mono phenyl-polyhedral oligomeric silsesquioxane (hcp-POSS)/polystyrene (PS) nanocomposites. Polymer Degradation and Stability, 97, 849855.CrossRefGoogle Scholar
Cavallaro, G., Lazzara, G. & Milioto, S. (2011a) Dispersions of nanoclays of different shapes into aqueous and solid biopolymeric matrices. Extended physicochemical study. Langmuir, 27, 11581167.CrossRefGoogle ScholarPubMed
Cavallaro, G., Donato, D.I., Lazzara, G. & Milioto, S. (2011b) Films of halloysite nanotubes sandwiched between two layers of biopolymer: from the morphology to the dielectric, thermal, transparency, and wettability properties. The Journal of Physical Chemistry C, 115, 2049120498.10.1021/jp207261rGoogle Scholar
Cavallaro, G., Lisi, R., Lazzara, G. & Milioto, S. (2013a) Polyethylene glycol/clay nanotubes composites. Journal of Thermal Analysis and Calorimetry, 112, 383389.Google Scholar
Cavallaro, G., Lazzara, G. & Milioto, S. (2013b) Sustainable nanocomposites based on halloysite nanotubes and pectin/polyethylene glycol blend. Polymer Degradation and Stability, 98, 25292536.10.1016/j.polymdegradstab.2013.09.012Google Scholar
Cavallaro, G., Lazzara, G., Milioto, S. & Parisi, F. (2014a) Halloysite nanotubes as sustainable nanofiller for paper consolidation and protection. Journal of Thermal Analysis and Calorimetry, 117, 12931298.Google Scholar
Cavallaro, G., Lazzara, G., Milioto, S., Palmisano, G. & Parisi, F. (2014b) Halloysite nanotube with fluorinated lumen: Non-foaming nanocontainer for storage and controlled release of oxygen in aqueous media. JournalofColloid and Interface Science, 417, 6671.10.1016/j.jcis.2013.11.026Google Scholar
Cavallaro, G., Lazzara, G., Milioto, S., Parisi, F. & Sanzillo, Y. (2014c) Modified halloysite nanotubes: nanoarch- itectures for enhancing the capture of oils from vapor and liquid phases. ACS Applied Materials & Interfaces, 6, 606612.10.1021/am404693rGoogle Scholar
Cavallaro, G., Lazzara, G., Milioto, S., Parisi, F. & Sparacino, Y. (2015) Thermal and dynamic mechanical properties of beeswax-halloysite nanocomposites for consolidating waterlogged archaeological woods. Polymer Degradation and Stability, 120, 220225.Google Scholar
Du, M., Guo, B. & Jia, D. (2006) Thermal stability and flame retardant effects of halloysite nanotubes on poly (propylene). European Polymer Journal, 42, 13621369.10.1016/j.eurpolymj.2005.12.006Google Scholar
Duce, C., Ghezzi, L., Onor, M., Bonaduce, I., Colombini, M., Tine’, M. & Bramanti, E. (2012) Physico-chemical characterization of protein-pigment interactions in tempera paint reconstructions: casein/cinnabar and albumin/cinnabar. Analytical and Bioanalytical Chemistry, 402, 21832193.Google Scholar
Duce, C., Vecchio Ciprioti, S., Ghezzi, L., lerardi, Y. & Tine, M. (2015a) Thermal behavior study of pristine and modified halloysite nanotubes. Journal of Thermal Analysis and Calorimetry, 121, 10111019.10.1007/s10973-015-4741-7Google Scholar
Duce, C., Orsini, S., Spepi, A., Colombini, M.P., Tiné, M.R. & Ribechini, E. (2015b) Thermal degradation chemistry of archaeological pine pitch containing beeswax as an additive. Journal of Analytical and Applied Pyrolysis, 111, 254264.CrossRefGoogle Scholar
Fakhrullina, G.I., Akhatova, F.S., Lvov, Y.M. & Fakhrullin, R.F. (2015) Toxicity of halloysite clay nanotubes in vivo: a Caenorhabditis elegans study. Environmental Science: Nano, 2, 5459.Google Scholar
Farris, S., Introzzi, L., Biagioni, P., Holz, T., Schiraldi, A. & Piergiovanni, L. (2011) Wetting of biopolymer coatings: contact angle kinetics and image analysis investigation. Langmuir, 27, 75637574.10.1021/la2017006Google Scholar
Fix, D., Andreeva, D.V., Lvov, Y.M., Shchukin, D.G. & Möhwald, H. (2009) Application of inhibitor-loaded halloysite nanotubes in active anti-corrosive coatings. Advanced Functional Materials, 19, 17201727.Google Scholar
Gorrasi, G., Pantani, R., Murariu, M. & Dubois, P. (2014) PLA/Halloysite nanocomposite films: water vapor barrier properties and specific key characteristics. Macromolecular Materials and Engineering, 299, 104115.10.1002/mame.201200424Google Scholar
Hanid, N.A., Wahit, M.U., Guo, Q., Mahmoodian, S. & Soheilmoghaddam, M. (2014) Development of regenerated cellulose/halloysites nanocomposites via ionic liquids. Carbohydrate Polymers, 99, 9197.10.1016/j.carbpol.2013.07.080Google Scholar
Havlínová, B., Katuščák, S., Petrovičová, M., Maková, A. & Brezova, Y. (2009) A study of mechanical properties of papers exposed to various methods of accelerated ageing. Part I. The effect of heat and humidity on original wood-pulp papers. Journal of Cultural Heritage, 10, 222231.10.1016/j.culher.2008.07.009Google Scholar
Jana, K. (2009) Mechanism of autoxidative degradation of cellulose. Restaurator, 18, 163176.Google Scholar
Jin, C., Yan, R. & Huang, J. (2011) Cellulose substance with reversible photo-responsive wettability by surface modification. Journal of Materials Chemistry, 21, 1751917525.10.1039/c1jm13399cGoogle Scholar
Joshi, A., Abdullayev, E., Vasiliev, A., Volkova, O. & Lvov, Y. (2013) Interfacial modification of clay nanotubes for the sustained release of corrosion inhibitors. Langmuir, 29, 74397448.Google Scholar
Joussein, E., Petit, S., Churchman, G.J., Theng, B., Righi, D. & Delvaux, B. (2005) Halloysite clay minerals - a review. Clay Minerals, 40, 383426.Google Scholar
Liu, M., Jia, Z., Liu, F., Jia, D. & Guo, B. (2010) Tailoring the wettability of polypropylene surfaces with halloysite nanotubes. Journal of Colloid and Interface Science, 350, 186193.10.1016/j.jcis.2010.06.047Google Scholar
Liu, M., Wu, C., Jiao, Y., Xiong, S. & Zhou, C. (2013) Chitosan-halloysite nanotubes nanocomposite scaf-folds for tissue engineering. Journal of Materials Chemistry B, 1, 20782089.Google Scholar
Luo, Z., Song, H., Feng, X., Run, M., Cui, H., Wu, L., Gao, J. & Wang, Z. (2013) Liquid crystalline phase behavior and sol-gel transition in aqueous halloysite nanotube dispersions. Langmuir, 29, 1235812366.Google Scholar
Lvov, Y. & Abdullayev, E. (2013) Functional polymer-clay nanotube composites with sustained release of chemical agents. Progress in Polymer Science, 38, 16901719.10.1016/j.progpolymsci.2013.05.009CrossRefGoogle Scholar
Lvov, Y.M., Shchukin, D.G., Mohwald, H. & Price, R.R. (2008) Halloysite clay nanotubes for controlled release of protective agents. ACS Nano, 2, 814820.Google Scholar
Makaremi, M., De Silva, R.T. & Pasbakhsh, P. (2015) Electrospun nanofibrous membranes of polyacryloni-trile/halloysite with superior water filtration ability. The Journal of Physical Chemistry C, 119, 79497958.Google Scholar
Marmur, A. (2008) From hygrophilic to superhygropho-bic: theoretical conditions for making high-contact-angle surfaces from low-contact-angle materials. Langmuir, 24, 75737579.10.1021/la800304rGoogle Scholar
Pasbakhsh, P., Churchman, G.J. & Keeling, J.L. (2013) Characterisation of properties of various halloysites relevant to their use as nanotubes and microfibre fillers. Applied Clay Science, 74, 4757.10.1016/j.clay.2012.06.014Google Scholar
Priegert, A.M., Siu, P.W., Hu, T.Q. & Gates, D.P. (2015) Flammability properties of paper coated with poly (methylenephosphine), an organophosphorus polymer. Fire and Materials, 39, 647657.10.1002/fam.2264Google Scholar
Qiao, J., Adams, J. & Johannsmann, D. (2012) Addition of halloysite nanotubes prevents cracking in drying latex films. Langmuir, 28, 86748680.10.1021/la3011597Google Scholar
Rotaru, A., Nicolaescu, I., Rotaru, P. & Neaga, C. (2008) Thermal characterization of humic acids and other components of raw coal. Journal of Thermal Analysis and Calorimetry, 92, 297300.Google Scholar
Shen, J., Song, Z., Qian, X. & Ni, Y. (2010) A review on use of fillers in cellulosic paper for functional applications. Industrial and Engineering Chemistry Research, 50, 661666.10.1021/ie1021078Google Scholar
Shutava, T.G., Fakhrullin, R.F. & Lvov, Y.M. (2014) Spherical and tubule nanocarriers for sustained drug release. Current Opinion in Pharmacology, 18, 141148.Google Scholar
Soares, N.F.F., Moreira, F.K.V., Fialho, T.L. & Melo, N.R. (2012) Triclosan-based antibacterial paper reinforced with nano-montmorillonite: a model nanocomposite for the development of new active packaging. Polymers for Advanced Technologies, 23, 901908.10.1002/pat.1986CrossRefGoogle Scholar
Soheilmoghaddam, M., Wahit, M.U., Mahmoudian, S. & Hanid, N.A. (2013) Regenerated cellulose/halloysite nanotube nanocomposite films prepared with an ionic liquid. Materials Chemistry and Physics, 141, 936943.Google Scholar
Tankhiwale, R. & Bajpai, S.K. (2009) Graft copolymer-ization onto cellulose-based filter paper and its further development as silver nanoparticles loaded antibacterial food-packaging material. Colloids and Surfaces B: Biointerfaces, 69, 164168.Google Scholar
Vergaro, V., Lvov, Y.M. & Leporatti, S. (2012) Halloysite clay nanotubes for resveratrol delivery to cancer cells. Macromolecular Bioscience, 12, 12651271.Google Scholar
Wei, W., Minullina, R., Abdullayev, E., Fakhrullin, R., Mills, D. & Lvov, Y. (2014) Enhanced efficiency of antiseptics with sustained release from clay nanotubes. RSCAdvances, 4, 488494.Google Scholar
Whitmore, M.P. & Bogaard, J. (2009) Determination of the cellulose scission route in the hydrolytic and oxidative degradation of paper. Restaurator, 15, 2615.Google Scholar
Zhao, Y., Abdullayev, E., Vasiliev, A. & Lvov, Y. (2013) Halloysite nanotubule clay for efficient water purification. Journal of Colloid and Interface Science, 406, 121129.10.1016/j.jcis.2013.05.072Google Scholar
Zhao, Y., Cavallaro, G. & Lvov, Y. (2015) Orientation of charged clay nanotubes in evaporating droplet meniscus. Journal of Colloid and Interface Science, 440, 6877.10.1016/j.jcis.2014.10.050Google Scholar