-Akbarifar, Z., 1389. Effect of Surface Oxidation and Clay Nanoparticles as Fillers on the Properties of Layer Boards. M.Sc. Thesis, University of Tehran. Iran.
-Arantes, A.C.C., Almeida, C.D.G., Dauzacker, L.C.L., Bianchi, M.L., Wood, D.F., Williams, T.G., Orts, W.J. and Tonoli, G.H.D., 2017. Renewable hybrid nanocatalyst from magnetite and cellulose for treatment of textile effluents. Carbohydrate Polymers, 163: 101 – 107.
-Asna Ashari Ivari, H. and Arabi, V.H., 2013. Synthesis of iron oxide magnetic nanoparticles by in situ method and evaluation of the effect of concentration ratio of reactive materials on particle size and magnetic properties. Journal of Ceramic Science and Engineering, 2 (1): 77 – 84.
-Azad Fallah, M., Moradian, K., Mousavi Pajouh, H., Hadilam, M. and Amini, A., 2013. Use of non-bleached Bagas fibers in magnetic paper making. Forest and Wood Products, 67 (4): 667 – 675.
-Bani Asadi, M., Tajabadi, M., Nourbakhsh, M. and Kamali, M., 2015. Nuclear-shell synthesis and characterization with superparamagnetic nuclear magnetite and bright polyamide (PAMAM) shell. Journal of Applied Research in Chemistry, 8 (3): 51 – 63.
-Cao, Sh. L., Xu, H., Li, X., Lou, W.Y. and Zong, M., 2015. Novel papain mgnetic nanocrystalline cellulose nano – biocatalyst: a highly efficient biocatalyst for dipeptide biosynthesis in deep eutectic solvents. ACS Sustainable Chemistry Engineering. DOI: 10.1021 /acssuschemeng.
-Carrazana-Garcia, J.A., Lopez-Quintela, M. and Rivas, J., 1995. Ferrimagnetic paper obtained by in situ synthesis of substituted ferrites. IEEE Transactions on Magnetics, 31: 3126 –3130.
-Chia, C. H., Zakaria, S., Nguyen, K.L. and Abdullah, M., 2008. Utilization of unbleached kenaf fibers for preparation of magnetic paper. Industrial Crops and Products, 28: 330 – 339.
-Chin, S.F., Binti Romainor, A.N. and Pang, S.C., 2014. Fabrication of hydrophobic and magnetic cellulose aerogel with high oil absorption capacity. Materials Letter, 115: 241 – 243.
-Faraji, M. and Fadavi, GH. 2013. Applications of Magnetic Nanoparticles in Food Science and Technology. Iranian Journal of Nutrition Sciences and Food Technology, 8 (2): 239 – 252.
-Fragouli, D., Bayer, I., Di Corato, R., Brescia, R., Bertoni, G., Innocenti, C., Gatteschi, D., Pellegrino, T., Cingolani, R. and Athanassiou, A., 2012. Superpapramgnetic cellulose fiber networks via nanocomposite functionalization. Journal of Materials Chemistry, 22: 1662 – 1666.
-Gnanaprakash, G., Mahadevan, S., Jayakumar, T., Kalyanasundaram, P. and Philip, T., 2007. Effect of initial pH and temperature of iron salt solutions on formation of magnetite nanoparticles. Materials Chemistry and Physics, 103: 168 – 175.
-Hubbe, M.A., 2014. Prospects for maintaining strength of paper and paperboard products while using less forest resources: A review. Bioresoures, 9: 1634 – 1763.
-Kaco, H., Waznah, Kh., Jaafar, N. and Gan, Y.S., 2017. Preparation and characterization of Fe3O4 / Regenerated cellulose membrane. Sains malaysiana, 46 (4): 623 – 628.
-Karami, Z. and Soleimani, A., 2013. A review of antibacterial cotton fibers. Journal of Studies in the Color World 3: 43 – 51. -Khalafalla, S.E. and Reimers, G.W., 1980. Preparation of Dilution-Stable Aqueous Magnetic Fluids. IEEE Transactions on Magnetics, 16: 178 – 183.
-Li, Y., Zhu, H., Gu, H., Dai, H., Fong, Zh., Weadock, J.N., Gou, Zh. and Hu, L., 2013. Strong transparent magnetic nanopapper prepared by immobilization of Fe3O4 nanoparticles in a nanofibrillated cellulose network. Journal of Materials Chemistry A, 1: 15278 – 15283.
-Liu, Sh., Zhou, J. and Zhang, L., 2011. In situ synthesis of plate-like Fe2o3 nanoparticles in porous cellulose films with obvious magnetic anisotropy. Cellulose, 18: 663 – 673.
-Long, Z., Li, H.F., Yang, X. and Liang, H.N., 2009. Study on preparation and characterization of magnetic paper with bleached chemical pulp. 2nd international congress on image and signal prcessinng, Tianjin, China, 987(1): 4131 - 4244.
-Mahdieh, A., Mahdavian, A., Farhadnejad, H. and Salehi Mobakheh, H., 2015. Introduction to magnetic nanoparticles, their synthesis methods and their applications. Nanoscience, 41: 25 – 35.
-Mashkor, M., Tajvidi, M. Kimura, T., Kimura, F. and Ebrahmi, Gh., 2011. Fabricating unidirectional magnetic papers using permanent magnets to align magnetic nanoparticles covered natural cellulose fibers. Bioresources, 6(4): 4731 – 4738.
-Marchessault, R. H., Rioux, P. and Louis, R., 1992. Magnetic cellulose fibers and paper: preparation, processing and properties. Polymer, 33(19): 4024 - 4028.
-Marchessult, R.H., Bremner, G. and Chauve, G., 2006. Fishing for proteins with magnetic cellulosic nanocrystals. American chemical society, Acs symposium series, Washington, DC, chapter 1, 15 pp.
Mohamed, A.Z., Zakaria, S., Shamsudin, R. and Abdullah, M., 2010. Cationic starch as a dry strength agent in magnetic papermaking. Sains Malaysiana, 39 (2): 239 – 242.
-Mohammad Alizadeh Hanjani, M., Qasemi, A. and Monshi, A., 2013. Influence of Synthesis Temperature on Properties of Magnetic Iron Oxide Nanoparticles in situ Method. Modern Processes in Materials Engineering, 6 (3): 77 – 83.
-Molai, M., Azad Fallah, M., Hamza, Y. and Gods, C.F., 2015. The effect of chitosan coating on the barrier and resistance properties of wrapping paper. Iranian Journal of Wood and Paper Science Research, 30 (2): 340 – 330.
-Olsson, R.T., Azizi, M. A. S., Salazar, G., Belora, L., Strom, V., Berglund, L. A., Ikkala, O., Nogues, J. and Gedde, U. W., 2010. Making flexible magnetic aerogel and stiff magnetic nanopaper using cellulose nanofibrils as templat. Nature Nanotechnology, 5: 584 – 595.
-Orand, M., 2106. Influence of Zein and Chitosan Coating on Strength and Barrier Properties of Liner board. M.Sc. Thesis, Sari Agricultural and Natural Resources University. Iran.
-Rashid, M., Abdul ghafur, M., Sharafat, K.M., Minami, H., Miah, M.J. and Ahmad, H., 2017. Biocompatible microcrystalline cellulose particles from cotton wool and magnrtization via a simple in situ co-precipitation method. Carbohydrate Polymers, 170: 72 – 79.
-Small, A.C. and Johnston, J.H., 2009. Novel hybrid materials of magnetic nanoparticles and cellulose fibers. Journal of Coloid and Interface Science, 331:122 – 126.
-Wu, W.B., Jing, Y., Gong, M.R., Zhou, X. F. and Dai, H.Q., 2011. Preparation and properties of magnetic cellulose fiber composites. Bioresources, 6(3): 3396 – 3409.
-Xiong, R., Lu, C. Wang, Y., Zhou, Z. and Zhang, X., 2013. Nanofibrillated cellulose as the support and reductant for the facile synthesis of Fe3O4/Ag nanocomposites with catalytic and antibacterial activity. Journal of Materials Chemistry A, 1: 14910 – 14918.
-Zarnegar, Z. and Safari, J., 2010. Magnetic intelligence of nanoparticles. Journal of Nanotechnology, 7(156): 29 – 35.
-Zakaria, S., Ong, B.H. and Vande Ven, T.G.M., 2004. Lumen loading magnetic paper l: flocculation. Colloids and surfaces A: phisicochem Engineering, Aspect 251: 1 – 4.
-Zakaria, S., Ong, B.H., Ahmad, S.H., Abdullah, M. and Yamauchi, T., 2005. Preparation of lumen – loaded kenaf pulp with magnetite (Fe3O4). Materials Chemistry and Physics, 89: 216 – 220.