[1] Mazandarani, M., 2014. Color and resin technology. Pishro publications, 750p.
[2] Ghofrani, M. and khojasteh khosro, S., 2013. The Effect of Wood Surface Finishing Quality on the Adhesion Strength of Clear Coat. Journal of Color Science and Technology, 1412-1425.
[3] Veronovski, N., Verhovsek, D. and Godnjavec, J., 2013. The influence of surface-treated nano-TiO2 (rutile) incorporation in water-based acrylic coatings on wood protection. Wood Sci Technol, 47: 317-328.
[4] Profili, J., Levasseur, O., Koronai, A., Stafford, L. and Gherardi, N., 2017. Deposition of nanocomposite coatings on wood using cold discharges at atmospheric pressure. Surface & Coatings Technology, 309. 729–737.
[5] Busseya, D., Perinab, V., Jonesa, F. and Cechc, V., 2018. Effect of chemical modification on the mechanical properties of plasma-polymerized organosilicones. Prog Org Coat, 119: 85-90.
[6] Gholamiyan, H., Tarmian, A. and Pourtahmasi, K., 2018. Microscopic investigation on the effects of wood surface modification with sol-gel method on the quality of polyurethane and alkyd coatings. Iranian Journal of Wood and Paper Industries, 8:4. 509-520.
[7] Hogger, H., Bauer, K., Höllbacher, E., Gierlinger, N., Konnerth, J., W.G. H and Herwijnen, V., 2018. Time-dependent ammonia emissions from fumed oak wood determined by micro-chamber/thermal extractor (μCTE) and FTIR-ATR spectroscopy. Holzforschung. Acceptant 2018-07-06.
[8] Pařil, P., Brabec, M., Maňák, O., Rousek, R., Rademacher, P., Čermák, P .and Dejmal, A., 2014. Comparison of selected physical and mechanical properties of densified beech wood plasticized by ammonia and saturated steam. European Journal of Wood and Wood Products, 72(5):583-591.
[9] Rousek, R., Rademacher, P., Brabec, M., Dejmal, A., Hornicek, S., Baar, J. and Sprdlik, V., 2015. Beech wood modification with ammonia gas – improved properties. Pro Ligno, 11:230–238.
[10] Rodel, K. 1999. Fuming with ammonia, In: Finishes & Finishing Technique, The Taunton Press Inc., Newtown, CT, USA.
[11] Weigl, M., Müller, U., Wimmer, R. and Hansmann, C., 2012. Ammonia vs. thermally modified timber-comparison of physical and mechanical properties, Eur. J. Wood Prod,70(1-3), 233-239.
[12] Čermák, P. and Dejmal, A., 2013. The effect of heat and ammonia treatment colour response of oak wood (Quercus robur) and comparison of some physical and mechanical properties. Maderas-Ciencia Tecnol. 15(3): 375-389.
[13] Tinkler, C. K., 1921. Fumed oak and natural brown oak, Biochem. J. 15(4), 477-486.
[14] Weigl, M., Kandelbauer, A., Hansmann, C., Pöckl, J., Müller, U. and Grabner, M., 2009a. Application of natural dyes in the coloration of wood,” In: Handbook of Natural Colorant, T. Bechtold, and R. Mussak (eds.), Willey and Sons Ltd, UK.
[15] Peipher, J., 2010. Fumed wood rich in color and in history. (http://www.premiercb.com/blog/2010/09/fumed-wood/).
[16] Pařil, P., Brabec, M., Rousek, R., Maňák, O., Rademacher, P., Čermák, P. and Dejmal, A., 2013. Physical and mechanical properties of densified beech wood plasticized by ammonia. Pro Ligno, 9(4):195-202.
[17] Miklečić, J., Kaša, A. and Jirouš-Rajković, V., 2012a. Colour changes of modified oak wood in indoor environment, Eur. J. Wood Prod, 70(1-3), 385-387.
[18] Weigl, M., Pöckl, J., Müller, U., Pretzl, H.and Grabner, M., 2007. UV-resistance of ammonia treated wood, 3rd European Conference on Wood Modification, Hill, C. A. S., Jones, D., Militz, H., and Ormondroyd, G. A. (eds.), 15-16 October, Cardiff, UK.
[19] Weigl, M., Pöckl, J. and Grabner, M., 2009b. Selected properties of gas phase ammonia treated wood. Eur. J. Wood Prod, 67(1), 103-109.
[20] Pawlak, Z. and Pawlak, A.S., 1997. A review of infrared spectra from wood and wood components following treatment with liquid ammonia and solvated electrons in liquid ammonia, Appl. Spectrosc. Rev, 32(4), 349-383.
[21] Miklečić, J., Španić, N. and Jirouš-Rajković, V., 2012b. Wood color changes by ammonia fuming. BioResources, 7(3):3767-3778.
[22] Šprdlík, V., Brabec, M., Mihailović, S. and Rademacher, P., 2016. Plasticity increase of beech veneer by steaming and gaseous ammonia treatment. Maderas. Ciencia y tecnología, 18(1): 91- 98.