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Gas-Sparged Ultrafiltration: Recent Trends, Applications and Future Challenges 695 50. Smith SR, Cui ZF (2004) Analysis of developing laminar pipe flow – an application to gas slug enhanced hollow fibre ultrafiltration. Chem Eng Sci 59:5975–5986 51. Li QY, Cui ZF, Pepper DS (1998) Enhancement of ultrafiltration by gas sparging with flat sheet membrane modules. Sep Purif Technol 14:79–83 52. Ghosh R, Li QY, Cui ZF (1998) Fractionation of BSA and lysozyme using ultrafiltration: effect of gas sparging. AIChE J 44:61–67 53. Mercier-Bonin M, Lagane C, Fonade C (2000) Influence of a gas/liquid two-phase flow on the ultrafiltration and microfiltration performances: case of a ceramic flat sheet membrane. J Memb Sci 180:93–102 54. Cheng T, Lin C (2004) A study on cross-flow ultrafiltration with various membrane orientations. Sep Purif Technol 39:13–22 55. Kenning DBR, Kao YS (1972) Convective heat transfer to water containing bubbles: enhancement not dependent on thermocapillary. Int J Heat Mass Transf 15:1709–1717 56. Tokuhiro AT, Lykoudis PS (1994) Natural convection heat transfer from a vertical plate. 1. Enhancement with gas injection. Int J Heat Mass Transf 37:997 57. Chang IS, Clech PL, Jefferson B, Judd S (2002) Membrane fouling in membrane bioreactors for wastewater treatment. J Environ Eng 128(11):1018–1029 58. Churchouse S (1997) Membrane bioreactors for wastewater treatment – operating experiences with the Kubota submerged membrane activated sludge process. Memb Technol 83:5–9 59. Gunder B, Krauth K (1998) Replacement of secondary clarification by membrane separation – results with plate and hollow fibre modules. Water Sci Technol 38:383–393 60. Calabro V, Curcio S, Iorio G (2002) A theoretical analysis of transport phenomena in a hollow fibre membrane bioreactor with immobilized biocatalyst. J Memb Sci 206:217–241 61. van Dijk L, Roncken GCG (1997) Membrane bioreactors for wastewater treatment: the state of the art and new developments. Water Sci Technol 35(10):35–41 62. Tajima F, Yamamoto T (1988) Apparatus for filtering water containing radioactive substances in nuclear power plants, Toshiba, US Patent 4 756 875 63. Yamamoto K, Hiasa M, Mahmood T, Matsuo T (1989) Direct solid–liquid separation using hollow fiber membrane in an activated sludge aeration tank. Water Sci Technol 21:43–54 64. Chiemchaisri C, Wong YK, Urase T, Yamamoto K (1992) Organic stabilization and nitrogen removal in membrane separation bioreactor for domestic wastewater treatment. Water Sci Technol 25:231–240 65. Futamura O, Katoh M, Takeuchi K (1994) Organic waste water treatment by activated sludge process using integrated type membrane separation. Desalination 98:17–25 66. Cote PL, Smith BM, Deutschmann AA, Rodrigues CF, Pedersen SK (1994) Frameless array of hollow fiber membranes and method of maintaining clean fiber surfaces while filtering a substrate to withdraw a permeate. PCT WO 94/11094 67. Mahendran M, Pedersen SK, Henshaw WJ, Behmann H, Rodrigues CF (1997) Vertical skein of hollow fiber membranes and method of maintaining clean fiber surfaces. PCT WO 97/06880 68. Leonard D, Mercier-Bonin M, Lindley ND, Lafforgue C (1998) Novel membrane bioreactor with gas/liquid two-phase flow for high-performance degradation of phenol. Biotechnol Prog 14:680–688 69. Lee SM, Jung JY, Chung YC (2001) Novel method for enhancing permeate flux of submerged membrane system in two-phase anaerobic reactor. Water Res 35:471–477
696 K. Mohanty and R. Ghosh 70. Futselaar H, Zoontjes RJC, Reith T, Rácz IG (1993) Economics comparison of transverse and longitudinal flow hollow fibre membrane modules for reverse osmosis and ultrafiltration. Desalination 90:345–361 71. Bouhabila EH, Ben Aim R, Buisson H (2001) Fouling characterization in membrane bioreactors. Sep Purif Technol 1(22–23):123–132 72. Posch C, Schiewer S (2005) Critical flux aspect of air sparging and backflushing on membrane bioreactors. Desalination 175:61–71 73. Guibert D, Ben Aim R, Rabie H, Cote P (2002) Aeration performance of immersed hollow-fiber membranes in a bentonite suspension. Desalination 148:395–400 74. Ghosh R (2006) Enhancement of membrane permeability by gas sparging in submerged hollow fibre ultrafiltration of macromolecular solutions: role of module design. J Memb Sci 274:73–82 75. Chang S, Fane AG (2001) The effect of fibre diameter on filtration and flux distribution – relevance to submerged hollow fibre modules. J Memb Sci 184:221–231 76. Chang S, Fane AG, Vigneswaran S (2002) Experimental assessment of filtration of biomass with model axial and transverse fibres. Chem Eng J 87:121–127 77. Chang S, Fane AG, Vigneswaran S (2002) Modelling and optimisation of submerged hollow fibre membrane modules. AIChE J 48:2203–2212 78. Field RW, Wu D, Howell JA, Gupta BB (1995) Critical flux concept for microfiltration fouling. J Memb Sci 100:259–272 79. Churchouse S, Wildgoose D (1999) Membrane bioreactors progress from the laboratory to fullscale use. Memb Technol 111:4–8 80. Yang W, Cicek N, Ilg J (2006) State-of-the-art of membrane bioreactors: worldwide research and commercial applications in North America. J Memb Sci 270:201–211 81. Chua HC, Arnot TC, Howell JA (2002) Controlling fouling in membrane bioreactors operated with a variable throughput. Desalination 149:225–229 82. Chang IS, Judd SJ (2002) Air sparging of a submerged MBR for municipal wastewater treatment. Process Biochem 37:915–920 83. Chang IS, Judd SJ (2003) Domestic wastewater treatment by a submerged MBR (membrane bioreactor) with enhanced air sparging. Water Sci Technol 47(12):149–154 84. Ebrahim S (1994) Cleaning and regeneration of membranes in desalination and wastewater applications: State-of-the-art. Desalination 96:225–238 85. Paul Chen J, Kim SL, Ting YP (2003) Optimization of membrane physical and chemical cleaning by a statistically designed approach. J Memb Sci 219:27–45 86. Tanaka T, Itoh H, Nakanishi K, Kume T, Matsumo R (1995) Crossflow filtration of Baker’s yeast with periodical stopping of permeation flow and bubbling. Biotechnol Bioeng 47:404–410 87. Serra C, Durand-Bourlier L, Clifton MJ, Moulin P, Rouch JC, Aptel P (1999) Use of air sparging to improve backwashing efficiency in hollow-fibre modules, J Memb Sci 161:95–113 88. Verbeck J, Worm G, Futselaar H, van Dijk JC (2000) Combined air–water flush in dead-end ultrafiltration. In: Proceedings of the IWA Conference on Drinking and Industrial Water Production, Paris, pp 655–663 89. Clarkson JR, Cui ZF, Darton RC (1999) Protein denaturation in foam. I. Mechanism study. J Colloid Interface Sci 215:323–332 90. Clarkson JR, Cui ZF, Darton RC (1999) Protein denaturation in foam. II. Surface activity and conformational change. J Colloid Interface Sci 215:333–338 91. Clarkson JR, Cui ZF, Darton RC (2000) Effect of solution conditions on protein damage in foam. Biochem Eng J 2:107–114
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Membrane and Desalination Technolog
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Editors Dr. Lawrence K. Wang Zorex
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vi Preface Our treatment of polluti
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Contents Preface . ................
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Contents xi 3.4. Considering Existi
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Contents xiii 7. Membrane Separatio
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Contents xv 6. Design for Large Com
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Contents xvii 13. Desalination of S
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Contributors JIRAPAT ANANPATTARACHA
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CONTENTS 1 Membrane Technology: Pas
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Membrane Technology: Past, Present
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48 J. Ren and R. Wang Key Words Pol
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50 J. Ren and R. Wang Nonporous den
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52 J. Ren and R. Wang pervaporation
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54 J. Ren and R. Wang HO HO OH O OH
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56 J. Ren and R. Wang Fig. 2.7 Chem
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58 J. Ren and R. Wang N O O 3.10. P
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60 J. Ren and R. Wang inversion, th
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62 J. Ren and R. Wang where Dm i an
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64 J. Ren and R. Wang as nucleation
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66 J. Ren and R. Wang and no polyme
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68 J. Ren and R. Wang where b ¼ v1
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70 J. Ren and R. Wang S gelation ti
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72 J. Ren and R. Wang structure wil
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74 J. Ren and R. Wang Viscous finge
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76 J. Ren and R. Wang nonsolvent so
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78 J. Ren and R. Wang Thickness of
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80 J. Ren and R. Wang 5.1.1. Rheolo
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82 J. Ren and R. Wang the spinneret
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84 J. Ren and R. Wang Dynamic visco
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86 J. Ren and R. Wang where A is th
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88 J. Ren and R. Wang In the spinni
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90 J. Ren and R. Wang stress, espec
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92 J. Ren and R. Wang solution at t
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94 J. Ren and R. Wang TIPS ¼ Therm
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96 J. Ren and R. Wang 5. Kesting RE
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98 J. Ren and R. Wang 51. Matsuyama
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100 J. Ren and R. Wang 92. Ren J, C
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102 L. Song and K.Guan Tay Key Word
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104 L. Song and K.Guan Tay Flux A A
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106 L. Song and K.Guan Tay increase
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108 L. Song and K.Guan Tay Table 3.
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110 L. Song and K.Guan Tay • A fe
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112 L. Song and K.Guan Tay Feed wat
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114 L. Song and K.Guan Tay Fouling
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116 L. Song and K.Guan Tay Fouling
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118 L. Song and K.Guan Tay The symb
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120 L. Song and K.Guan Tay Table 3.
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122 L. Song and K.Guan Tay Permeate
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124 L. Song and K.Guan Tay Average
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128 L. Song and K.Guan Tay generati
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132 L. Song and K.Guan Tay flux. Un
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134 L. Song and K.Guan Tay 14. Kaak
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136 N.K. Shammas and L.K. Wang remo
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138 N.K. Shammas and L.K. Wang The
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140 N.K. Shammas and L.K. Wang excu
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142 N.K. Shammas and L.K. Wang dire
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144 N.K. Shammas and L.K. Wang broa
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146 N.K. Shammas and L.K. Wang remo
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148 N.K. Shammas and L.K. Wang 4. T
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150 N.K. Shammas and L.K. Wang 8. S
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152 N.K. Shammas and L.K. Wang 4.5.
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154 N.K. Shammas and L.K. Wang Tabl
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156 N.K. Shammas and L.K. Wang phys
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158 N.K. Shammas and L.K. Wang mono
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164 N.K. Shammas and L.K. Wang Fig.
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170 N.K. Shammas and L.K. Wang CSTR
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172 N.K. Shammas and L.K. Wang chec
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174 N.K. Shammas and L.K. Wang due
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178 N.K. Shammas and L.K. Wang 4. C
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182 N.K. Shammas and L.K. Wang Sens
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186 N.K. Shammas and L.K. Wang Maxi
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188 N.K. Shammas and L.K. Wang 2. 2
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196 N.K. Shammas and L.K. Wang PFR
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198 N.K. Shammas and L.K. Wang 16.
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5 Treatment of Industrial Effluents
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Treatment of Industrial Effluents,
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CONTENTS 6 Treatment of Food Indust
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Treatment of Food Industry Foods an
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272 J. Paul Chen et al. formation a
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274 J. Paul Chen et al. the rejecte
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276 J. Paul Chen et al. The MF memb
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278 J. Paul Chen et al. Most UF mem
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280 J. Paul Chen et al. The applica
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282 J. Paul Chen et al. solutions a
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284 J. Paul Chen et al. Salt cheese
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286 J. Paul Chen et al. Table 7.2 L
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288 J. Paul Chen et al. Table 7.3 L
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290 J. Paul Chen et al. Fig. 7.7. V
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292 J. Paul Chen et al. Considering
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294 J. Paul Chen et al. Approximati
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296 J. Paul Chen et al. 5.2. The Po
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298 J. Paul Chen et al. into a smal
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300 J. Paul Chen et al. 6.2.3. Tubu
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302 J. Paul Chen et al. Fig. 7.13.
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304 J. Paul Chen et al. a Feed b Me
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306 J. Paul Chen et al. l Product c
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308 J. Paul Chen et al. Feed Permea
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310 J. Paul Chen et al. From Table
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312 J. Paul Chen et al. To calculat
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314 J. Paul Chen et al. biofilm for
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316 J. Paul Chen et al. magnesium,
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318 J. Paul Chen et al. reduction o
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320 J. Paul Chen et al. Table 7.6 C
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322 J. Paul Chen et al. many factor
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324 J. Paul Chen et al. 9.2. Gas Se
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326 J. Paul Chen et al. c w2 ¼ Con
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328 J. Paul Chen et al. 14. Economi
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330 J. Paul Chen et al. 55. Basu OD
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332 J. Paul Chen et al. 99. Teodosi
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334 N.K. Shammas and L.K. Wang 1. I
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336 N.K. Shammas and L.K. Wang dete
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338 N.K. Shammas and L.K. Wang for
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342 N.K. Shammas and L.K. Wang impo
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346 N.K. Shammas and L.K. Wang prio
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348 N.K. Shammas and L.K. Wang 5-20
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354 N.K. Shammas and L.K. Wang cour
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358 N.K. Shammas and L.K. Wang wher
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360 N.K. Shammas and L.K. Wang and
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362 N.K. Shammas and L.K. Wang syst
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364 N.K. Shammas and L.K. Wang blee
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370 N.K. Shammas and L.K. Wang oxid
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372 N.K. Shammas and L.K. Wang memb
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376 N.K. Shammas and L.K. Wang capa
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378 N.K. Shammas and L.K. Wang Disp
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380 N.K. Shammas and L.K. Wang sali
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384 N.K. Shammas and L.K. Wang the
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386 N.K. Shammas and L.K. Wang 9. N
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388 N.K. Shammas and L.K. Wang 16.
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CONTENTS 9 Adsorption Desalination:
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Adsorption Desalination: A Novel Me
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434 J. Qin and K.A. Kekre 1. INTROD
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436 J. Qin and K.A. Kekre utilized
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438 J. Qin and K.A. Kekre 3.2. Desc
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440 J. Qin and K.A. Kekre Table 10.
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442 J. Qin and K.A. Kekre Fig. 10.4
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446 J. Qin and K.A. Kekre different
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448 J. Qin and K.A. Kekre protectin
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462 J. Qin and K.A. Kekre 7.2. Desc
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468 J. Qin and K.A. Kekre and anion
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470 J. Qin and K.A. Kekre become on
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472 J. Qin and K.A. Kekre COD ¼ Ch
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474 J. Qin and K.A. Kekre 25. Parso
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476 J. Qin and K.A. Kekre technique
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478 P. Kajitvichyanukul et al. 1. I
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480 P. Kajitvichyanukul et al. of 5
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482 P. Kajitvichyanukul et al. well
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484 P. Kajitvichyanukul et al. The
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486 P. Kajitvichyanukul et al. 3.3.
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488 P. Kajitvichyanukul et al. 4. C
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490 P. Kajitvichyanukul et al. nonp
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492 P. Kajitvichyanukul et al. rDNA
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494 P. Kajitvichyanukul et al. 3. E
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496 P. Kajitvichyanukul et al. Form
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500 P. Kajitvichyanukul et al. do n
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502 P. Kajitvichyanukul et al. Wate
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504 P. Kajitvichyanukul et al. Tabl
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506 P. Kajitvichyanukul et al. Fig.
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508 P. Kajitvichyanukul et al. Tabl
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512 P. Kajitvichyanukul et al. solu
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516 P. Kajitvichyanukul et al. (b)
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518 P. Kajitvichyanukul et al. 8. A
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520 P. Kajitvichyanukul et al. 52.
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12 Desalination of Seawater by Ther
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Desalination of Seawater by Thermal
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CONTENTS 13 Desalination of Seawate
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Desalination of Seawater by Reverse
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610 P. Kajitvichyanukul et al. UV i
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618 P. Kajitvichyanukul et al. larg
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620 P. Kajitvichyanukul et al. insi
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624 P. Kajitvichyanukul et al. wate
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628 P. Kajitvichyanukul et al. Adju
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630 P. Kajitvichyanukul et al. 4. D
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632 P. Kajitvichyanukul et al. For
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634 P. Kajitvichyanukul et al. Cc
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640 P. Kajitvichyanukul et al. grea
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642 P. Kajitvichyanukul et al. 2. F
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Page 711 and 712: Acceptance testing, 384-385 ACF. Se
Page 713 and 714: Index 701 Challenge test solution d
Page 715 and 716: Index 703 Disinfection by-products
Page 717 and 718: Index 705 Hemodialysis, 2, 6, 281 H
Page 719 and 720: Index 707 Membrane bioreactor-rever
Page 721 and 722: Index 709 Microfiltration-reverse o
Page 723 and 724: Index 711 Physical cleaning, 322-32
Page 725 and 726: Index 713 Reynolds number, 676, 679
Page 727 and 728: Index 715 Thermal concentration, 25
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