الفهرس | Only 14 pages are availabe for public view |
Abstract REFERENCES 1. Nguyen, D.M., Colour removal from sugar cane juice. 2014, Queensland University of Technology: Australia. 2. Chou, C.C., Handbook of sugar refining: a manual for the design and operation of sugar refining facilities. Vol. 467. 2000: John Wiley & Sons. 3. Doherty, W. and L. Edye. An overview on the chemistry of clarification of cane sugar juice. in Proceedings-Australian Society of Sugar Cane Technologists. 1999. Watson ferguson and company. 4. Baikow, V.E., Manufacture and refining of raw cane sugar. 2013: Elsevier. 5. Delden, E., Standard Fabrication practices for cane sugar mills. 2015: Elsevier. 6. Doherty, W., J. Greenwood, D. Pilaski, and P. Wright. The effect of liming conditions in juice clarification. in Proceedings of the 2002 Conference of the Australian Society of Sugar Cane Technologists held at Cairns, Queensland, Australia, 29 April-2 May 2002. 2002. PK Editorial Services Pty Ltd. 7. Honig, P., Principles of sugar technology. Vol. III. Principles of sugar technology. Vol. III. 1963: Elsevier, Amsterdam. 8. Hamerski, F., V.R. da Silva, M.L. Corazza, P.M. Ndiaye, and A.D. de Aquino, Assessment of variables effects on sugar cane juice clarification by carbonation process. International journal of food science & technology, 2012. 47(2): p. 422- 428. References - 333 - 9. Ramos, E. and S. Ravelo, Sugarcane oligosaccharides and their impact on sucrose quality and factory efficiency. Sugar Tech, 2009. 11(2): p. 185-188. 10. Yates, R., Factors that affect the quality of sugarcane-Part II: Management practices. International sugar journal, 1996. 98(1171): p. 362-368. 11. Moodley, M., P. Schorn, D. Walthew, and P. Masinga, Optimising the carbonatation process. International sugar journal, 2002. 76: p. 469-476. 12. San Miguel, B., Colorants through cane sugar production and refining (Part 1). Sugar Industry/Zuckerindustrie, 2009. 134(3): p. 168-176. 13. Mersad, A., R. Lewandowski, B. Heyd, and M. Decloux, Colorants in the sugar industry: Laboratory preparation and spectrometric analysis. International sugar journal, 2003. 105(1254): p. 269-281. 14. Hafid, H.S., A.R. Nor’Aini, M.N. Mokhtar, A.T. Talib, A.S. Baharuddin, and M.S.U. Kalsom, Over production of fermentable sugar for bioethanol production from carbohydrate-rich Malaysian food waste via sequential acidenzymatic hydrolysis pretreatment. Waste management, 2017. 67: p. 95-105. 15. Lindeman, P. and M. O’Shea, High molecular weight (HMW) colorants and their impact on the refinability of raw sugar. A study of Australian and overseas raw sugars, in Proceedings of the 2001 Conference of the Australian Society of Sugar Cane Technologists held at Mackay, Queensland, Australia, References - 337 - 1st-4th May 2001. 2001, PK Editorial Services Pty Ltd. p. 322-329. 16. Li, X., S. Yao, B. Tu, X. Li, C. Jia, and H. Song, Determination and comparison of flavonoids and anthocyanins in Chinese sugarcane tips, stems, roots and leaves. Journal of Separation Science, 2010. 33(9): p. 1216- 1223. 17. Nguyen, D. and W. Doherty, Phenolics in sugar cane juice: potential degradation by hydrogen peroxide and Fenton’s reagent. Proceedings of the 33rd Annual Conference of the Australian Society of Sugar Cane Technologists 2011. 2011: Australian Society of Sugar Cane Technologists 2011/Curran Associates, Inc. 377-386. 18. Riffer, R., The nature of colorants in sugarcane and cane sugar manufacture, in Sugar Series. 1988, Elsevier. p. 186- 207. 19. Rein, P., White cane sugar production. International sugar journal, 2009. 111(1321): p. 27. 20. Salaheldin, T.A., M.M. Abd El Wahab, H.A. Awadalla, and A.N. Gad, Application of Nano-Hydroxyapatite in Sugarcane Juice Clarification. Egyptian Sugar Journal, 2018. 11: p. 25- 44. 21. Coca, M., M.T. arc a, . onz lez, M. Pe a, and J.A. arc a, Study of coloured components formed in sugar beet processing. Food chemistry, 2004. 86(3): p. 421-433. 22. Alobaidi, Y.M., M. M. Ali, and A.M. Mohammed, Synthesis of Calcium Oxide Nanoparticles from Waste Eggshell by References - 330 - Thermal Decomposition and their Applications. Jordan Journal of Biological Sciences, 2021. 15(2): p. 269 – 274 23. Doherty, W. and D. Rackemann, Some aspects of calcium phosphate chemistry in sugarcane clarification. International sugar journal, 2009. 111(1327): p. 448-454. 24. Oates, J.A., Lime and limestone: chemistry and technology, production and uses. 2008: John Wiley & Sons. 472. 25. Murray, J.A., H.C. Fischer, and L.S. Rolnick, Shrinkage of High‐Calcium Limestones During Burning. Journal of the American Ceramic Society, 1954. 37(7): p. 323-328. 26. Masharipova, S., Application of defecation lime from sugar industry in Uzbekistan, in master of Science Thesis Stockholm. 2006. 27. Vaccari, G., E. Tamburini, G. Sgualdino, K. Urbaniec, and J. Klemeš, Overview of the environmental problems in beet sugar processing: possible solutions. Journal of Cleaner Production, 2005. 13(5): p. 499-507. 28. Moraes, B.S., M. Zaiat, and A. Bonomi, Anaerobic digestion of vinasse from sugarcane ethanol production in Brazil: Challenges and perspectives. Renewable and Sustainable energy reviews, 2015. 44: p. 888-903. 29. Tuck, C.O., E. Pérez, I.T. Horváth, R.A. Sheldon, and M. Poliakoff, Valorization of biomass: deriving more value from waste. Science, 2012. 337(6095): p. 695-699. 30. Ławińska, K., S. Szufa, A. Obraniak, T. Olejnik, R. Siuda, J. Kwiatek, and D. Ogrodowczyk, Disc granulation process of carbonation lime mud as a method of post-production waste management. Energies, 2020. 13(13): p. 3419. References - 333 - 31. Gharieb, M. and A.M. Rashad, An initial study of using sugar-beet waste as a cementitious material. Construction and Building Materials, 2020. 250: p. 118843. 32. Š rka, E., Z. Bubník, P. Kadlec, and A. Vesel -Trilčov , The particle size of carbonation mud, and possibilities for influencing it. Journal of food engineering, 2008. 87(1): p. 45- 50. 33. Satisha, G. and L. Devarajan, Effect of amendments on windrow composting of sugar industry pressmud. Waste management, 2007. 27(9): p. 1083-1091. 34. Hillion, M.-L., R. Moscoviz, E. Trably, Y. Leblanc, N. Bernet, M. Torrijos, and R. Escudié, Co-ensiling as a new technique for long-term storage of agro-industrial waste with low sugar content prior to anaerobic digestion. Waste management, 2018. 71: p. 147-155. 35. Kantiranis, N., Re-cycling of sugar-ash: a raw feed material for rotary kilns. Waste management, 2004. 24(10): p. 999- 1004. 36. Fantaye, A., A. Fanta, and A.M. Melesse, Effect of filter press mud application on nutrient availability in aquert and fluvent soils of Wonji/Shoa sugarcane plantation of Ethiopia. Landscape Dynamics, Soils and Hydrological Processes in Varied Climates. 2016: Springer International Publishing. 549-563. 37. Sims, A.L., C. Windels, and C. Bradley, Content and potential availability of selected nutrients in field‐applied sugar beet factory lime. Communications in soil science and plant analysis, 2010. 41(4): p. 438-453. References - 333 - 38. Sviklas, A. and R. Paletskene, Physicochemical principles of synthesis of liquid fertilizers based on potassium hydrophosphate. Russian journal of applied chemistry, 2004. 77: p. 521-526. 39. Sviklas, A. and R. Shlinkshene, Liquid fertilizers based on dolomite, nitric acid, and ammonia. Russian journal of applied chemistry, 2003. 76(12): p. 1885-1890. 40. Paleckienė, R., A. Sviklas, and R. Šlinkšienė, The role of sugar factory lime on compound fertilizer properties. Polish J. of Environ. Stud, 2007. 16(3): p. 423-426. 41. Bundschuh, M., J. Filser, S. Lüderwald, M.S. McKee, G. Metreveli, G.E. Schaumann, R. Schulz, and S. Wagner, Nanoparticles in the environment: where do we come from, where do we go to? Environmental Sciences Europe, 2018. 30(1): p. 1-17. 42. Bano, S. and S. Pillai, Green synthesis of calcium oxide nanoparticles at different calcination temperatures. World Journal of Science, Technology and Sustainable Development, 2020. 17(3): p. 283-295. 43. Heiligtag, F.J. and M. Niederberger, The fascinating world of nanoparticle research. Materials today, 2013. 16(7-8): p. 262- 271. 44. Alavi, M. and A. Morsali, Alkaline-Earth Metal Carbonate, Hydroxide and Oxide Nano-Crystals Synthesis Methods, Size and Morphologies Consideration. Nanocrystal. 2011: Nagoya University Japan. 506. 45. Auffan, M., J. Rose, M.R. Wiesner, and J.-Y. Bottero, Chemical stability of metallic nanoparticles: a parameter References - 333 - controlling their potential cellular toxicity in vitro. Environmental Pollution, 2009. 157(4): p. 1127-1133. 46. Chandra, R., A. Chawla, and P. Ayyub, Optical and structural properties of sputter-deposited nanocrystalline Cu2O films: Effect of sputtering gas. Journal of nanoscience and nanotechnology, 2006. 6(4): p. 1119-1123. 47. Jamkhande, P.G., N.W. Ghule, A.H. Bamer, and M.G. Kalaskar, Metal nanoparticles synthesis: An overview on methods of preparation, advantages and disadvantages, and applications. Journal of drug delivery science and technology, 2019. 53: p. 101174. 48. Qi, H. and C. Zhang, Organic nanoparticles for electrogenerated chemiluminescence assay. Current Opinion in Electrochemistry, 2022. 34: p. 101023. 49. Varma, R.S., Greener approach to nanomaterials and their sustainable applications. Current Opinion in Chemical Engineering, 2012. 1(2): p. 123-128. 50. Rafique, M., I. Sadaf, M.S. Rafique, and M.B. Tahir, A review on green synthesis of silver nanoparticles and their applications. Artificial cells, nanomedicine, and biotechnology, 2017. 45(7): p. 1272-1291. 51. Kou, J. and R.S. Varma, Beet juice utilization: Expeditious green synthesis of noble metal nanoparticles (Ag, Au, Pt, and Pd) using microwaves. RSC advances, 2012. 2(27): p. 10283- 10290. 52. Baruwati, B., V. Polshettiwar, and R.S. Varma, Glutathione promoted expeditious green synthesis of silver |