Overview biohydrogen technologies and application in fuel cell technology

Renewable and Sustainable Energy Reviews

Volumn 66, Issue , 2016, Pages 137-162

  Rahman, S N A ^a   Masdar, M S ^a   Rosli, M I ^a   Majlan, E H ^a   Husaini, T ^a   Kamarudin, S K ^a   Daud, W R W ^a  

^a UNIVERSITI KEBANGSAAN MALAYSIA   (Malaysia)

Author keywords

Biohydrogen; Bioreactor; Gas purification; Membrane; PEMFC

Indexed keywords

AIR PURIFICATION; CRUDE OIL; GREENHOUSE GASES; HEAVY OIL PRODUCTION; HYDROGEN PRODUCTION; MEMBRANE TECHNOLOGY; POLYELECTROLYTES; PROTON EXCHANGE MEMBRANE FUEL CELLS (PEMFC);

BIO-HYDROGEN; CARBON-BASED; CLEAN ENERGY; ENERGY CARRIERS; FUEL CELL TECHNOLOGIES; HIGHER ENERGY DENSITY; NAPTHAS; NON-RENEWABLE; RENEWABLE SOURCES; TECHNOLOGIES AND APPLICATIONS;

BIOREACTORS;

EID: 84980416328     PISSN: 13640321     EISSN: 18790690     Source Type: Journal    
DOI: 10.1016/j.rser.2016.07.047     Document Type: Review

References (155)

1. [1] U.S. Energy Information Administration. May 2015 Monthly Energy Review; 2015.
2. [2] U.S. Energy Information Administration. Annual Energy Outlook 2015. Off Integr Int Energy Anal; 2015.1:1–244.
3. [3] Argun, H., Kargi, F., Kapdan, I., Oztekin, R., Biohydrogen production by dark fermentation of wheat powder solution: effects of C/N and C/P ratio on hydrogen yield and formation rate. Int J Hydrog Energy 33 (2008), 1813–1819.
4. [4] Nath, K., Das, D., Hydrogen from biomass. Curr Sci 85 (2003), 265–271.
5. [5] Manish, S., Banerjhee, R., Comparison of biohydrogen production processes. Int J Hydrog Energy 33 (2008), 279–286.
6. [6] Das, D., Hydrogen production by biological processes: a survey of literature. Int J Hydrog Energy 26 (2001), 13–28.
7. [7] Das, D., Veziroglu, T.N., Advances in biological hydrogen production processes. Int J Hydrog Energy 33 (2008), 6046–6057.
8. [8] Chader, S., Mahmah, B., Chetehouna, K., Amrouche, F., Abdeladim, K., Biohydrogen production using green microalgae as an approach to operate a small proton exchange membrane fuel cell. Int J Hydrog Energy 36 (2011), 4089–4093.
9. [9] Levin, D.B., Islam, R., Cicek, N., Sparling, R., Hydrogen production by Clostridium thermocellum 27405 from cellulosic biomass substrates. Int J Hydrog Energy 31 (2006), 1496–1503.
10. [10] Lin, C.N., Wu, S.Y., Lee, K.S., Lin, P.J., Lin, C.Y., Chang, J.S., Integration of fermentative hydrogen process and fuel cell for on-line electricity generation. Int J Hydrogen Energy 32 (2007), 802–808.
11. [11] Larminie, J., Dicks, A., Fuel cell systems explained. 2nd edition, 2013, John Wiley & Sons, Ltd, West Sussex, England.
12. [12] Edlund, D., Hydrogen and Syngas Production and Purification Technologies, 2009, John Wiley & Sons, Inc, Hoboken, NJ, USA.
13. [13] Bakonyi, P., Nemestóthy, N., Bélafi-Bakó, K., Biohydrogen purification by membranes: an overview on the operational conditions affecting the performance of non-porous, polymeric and ionic liquid based gas separation membranes. Int J Hydrog Energy 38 (2013), 9673–9687.
14. [14] Kosourov, S., Tsygankov, A., Seibert, M., Ghirardi, M.L., Sustained hydrogen photoproduction by Chlamydomonas reinhardtii: effects of culture parameters. Biotechnol Bioeng 78 (2002), 731–740.
15. [15] Melis, a, Zhang, L., Forestier, M., Ghirardi, M.L., Seibert, M., Sustained photobiological hydrogen gas production upon reversible inactivation of oxygen evolution in the green alga Chlamydomonas reinhardtii. Plant Physiol 122 (2000), 127–136.
16. [16] Mizuno, O., Dinsdale, R., Hawkes, F.R., Hawkes, D.L., Noike, T., Enhancement of hydrogen production from glucose by nitrogen gas sparging. Bioresour Technol 73 (2000), 59–65.
17. [17] Lay, J.J., Modeling and optimization of anaerobic digested sludge converting starch to hydrogen. Biotechnol Bioeng 68 (2000), 269–278.
18. [18] Ghirardi, M.L., Zhang, L., Lee, J.W., Flynn, T., Seibert, M., Greenbaum, E., et al. Microalgae: a green source of renewable H2. Trends Biotechnol 18 (2000), 506–511.
19. [19] Azwar, M.Y., Hussain, M.A., Abdul-Wahab, A.K., Development of biohydrogen production by photobiological, fermentation and electrochemical processes: a review. Renew Sustain Energy Rev 31 (2014), 158–173.
20. [20] Tamburic, B., Zemichael, F.W., Maitland, G.C., Hellgardt, K., Parameters affecting the growth and hydrogen production of the green alga Chlamydomonas reinhardtii. Int J Hydrog Energy 36 (2011), 7872–7876.
21. [21] Guan, Y., Deng, M., Yu, X., Zhang, W., Two-stage photo-biological production of hydrogen by marine green alga Platymonas subcordiformis. Biochem Eng J 19 (2004), 69–73.
22. [22] Stetson N. Hydrogen Storage Technical Team Roadmap. US Drive; 2013.
23. [23] Das, D., Khanna, N., Dasgupta, C.N., Biohydrogen production: fundamentals and technology advances, 2014, CRC Press, Boca Raton, USA [accessed 12.02.16]. http://www.crcnetbase.com/isbn/9781466518001.
24. [24] Carrieri, D., Wawrousek, K., Eckert, C., Yu, J., Maness, P.C., The role of the bidirectional hydrogenase in cyanobacteria. Bioresour Technol 102 (2011), 8368–8377.
25. [25] Mathews, J., Wang, G., Metabolic pathway engineering for enhanced biohydrogen production. Int J Hydrog Energy 34 (2009), 7404–7416.
26. [26] Frey, M., Hydrogenases: hydrogen-activating enzymes. ChemBioChem 3 (2002), 153–160.
27. [27] Bleijlevens, B., Buhrke, T., van der Linden, E., Friedrich, B., Albracht, S.P.J., The auxiliary protein HypX provides oxygen tolerance to the soluble [NiFe]-hydrogenase of ralstonia eutropha H16 by way of a cyanide ligand to nickel. J Biol Chem 279 (2004), 46686–46691.
28. [28] Nishihara, H., Miyashita, Y., Aoyama, K., Kodama, T., Igarashi, Y., Takamura, Y., Characterization of an extremely thermophilic and oxygen-stable membrane-bound hydrogenase from a marine hydrogen-oxidizing bacterium Hydrogenovibrio marinus. Biochem Biophys Res Commun 232 (1997), 766–770.
29. [29] Yu, J., Takahashi, P., Biophotolysis-based hydrogen production by cyanobacteria and green microalgae. Commun Curr Res Educ Top Trends Appl Microbiol 1 (2007), 79–89.
30. [30] Greenbaum, E., Energetic efficiency of hydrogen photoevolution by algal water splitting. Biophys J 54 (1988), 365–368.
31. [31] Levin, D.B., Pitt, L., Love, M., Biohydrogen production: prospects and limitations to practical application. Int J Hydrog Energy 29 (2004), 173–185.
32. [32] Kapdan, I.K., Kargi, F., Bio-hydrogen production from waste materials. Enzyme Microb Technol 38 (2006), 569–582.
33. [33] Hallenbeck, P.C., Benemann, J.R., Biological hydrogen production; Fundamentals and limiting processes. Int J Hydrog Energy 27 (2002), 1185–1193.
34. *. Annu Rev Plant Biol 58 (2007), 71–91.
35. [35] Lindbald, P., Photoproduction of H2 by wildtype Anabaena PCC 7120 and a hydrogen uptake deficient mutant: from laboratory experiments to outdoor culture. Int J Hydrog Energy 27 (2002), 1271–1281.
36. [36] Dauvillée, D., Chochois, V., Steup, M., Haebel, S., Eckermann, N., Ritte, G., et al. Plastidial phosphorylase is required for normal starch synthesis in Chlamydomonas reinhardtii. Plant J 48 (2006), 274–285.
37. [37] Antal, T.K., Lindblad, P., Production of H2 by sulphur-deprived cells of the unicellular cyanobacteria Gloeocapsa alpicola and Synechocystis sp. PCC 6803 during dark incubation with methane or at various extracellular pH. J Appl Microbiol 98 (2005), 114–120.
38. [38] Tamagnini, P., Axelsson, R., Lindberg, P., Oxelfelt, F., Wünschiers, R., Lindblad, P., Hydrogenases and hydrogen metabolism of cyanobacteria. Microbiol Mol Biol Rev 66 (2002), 1–20 (table of contents).
39. [39] Chader, S., Hacene, H., Agathos, S.N., Study of hydrogen production by three strains of Chlorella isolated from the soil in the Algerian Sahara. Int J Hydrog Energy 34 (2009), 4941–4946.
40. [40] Raksajit, W., Satchasataporn, K., Lehto, K., Mäenpää, P., Incharoensakdi, A., Enhancement of hydrogen production by the filamentous non-heterocystous cyanobacterium Arthrospira sp. PCC 8005. Int J Hydrog Energy 37 (2012), 18791–18797.
41. [41] Troshina, O., Serebryakova, L., Sheremetieva, M., Lindblad, P., Production of H2 by the unicellular cyanobacterium Gloeocapsa alpicola CALU 743 during fermentation. Int. J. Hydrog Energy 27 (2002), 1283–1289.
42. [42] Winkler, M., (Fe)-hydrogenases in green algae: photo-fermentation and hydrogen evolution under sulfur deprivation. Int J Hydrogen Energy 27 (2002), 1431–1439.
43. [43] Ohta, S., Miyamoto, K., Miura, Y., Hydrogen evolution as a consumption mode of reducing equivalents in green algal fermentation. Plant Physiol 83 (1987), 1022–1026.
44. [44] Weissman, J.C., Benemann, J.R., Hydrogen production by nitrogen-starved cultures of Anabaena cylindrica. Appl Environ Microbiol 33 (1977), 123–131.
45. [45] Liu, J., Bukatin, V.E., Tsygankov, A.A., Light energy conversion into H2 by Anabaena variabilis mutant PK84 dense cultures exposed to nitrogen limitations. Int J Hydrog Energy 31 (2006), 1591–1596.
46. [46] Scoma, A., Krawietz, D., Faraloni, C., Giannelli, L., Happe, T., Torzillo, G., Sustained H2 production in a Chlamydomonas reinhardtii D1 protein mutant. J Biotechnol 157 (2012), 613–619.
47. [47] Yoon, J., Haeshin, J., Kim, M., Junsim, S., Park, T., Evaluation of conversion efficiency of light to hydrogen energy by Anabaena variabilis. Int J Hydrog Energy 31 (2006), 721–727.
48. [48] Reith J, Wijffels R, Barten H. Bio-methane and bio-hydrogen: status and perspectives of biological methane and hydrogen production; 2003.
49. [49] Harwood, C., Wall, J., Demain, A., Nitrogenase-catalyzed hydrogen production by purple nonsulfur photosynthetic bacteria. Bioenergy, 2008.
50. [50] Yetis, M., Gündüz, U., Eroglu, I., Yücel, M., Türker, L., Photoproduction of hydrogen from sugar refinery wastewater by Rhodobacter sphaeroides O.U. 001. Int J Hydrog Energy 25 (2000), 1035–1041.
51. [51] Seifert, K., Waligorska, M., Laniecki, M., Brewery wastewaters in photobiological hydrogen generation in presence of Rhodobacter sphaeroides O.U. 001. Int J Hydrog Energy 35 (2010), 4085–4091.
52. [52] Sabourin-Provost, G., Hallenbeck, P.C., High yield conversion of a crude glycerol fraction from biodiesel production to hydrogen by photofermentation. Bioresour Technol 100 (2009), 3513–3517.
53. [53] Keskin, T., Abo-Hashesh, M., Hallenbeck, P.C., Photofermentative hydrogen production from wastes. Bioresour Technol 102 (2011), 8557–8568.
54. [54] Chen, C.Y., Lu, W.B., Wu, J.F., Chang, J.S., Enhancing phototrophic hydrogen production of Rhodopseudomonas palustris via statistical experimental design. Int J Hydrog Energy 32 (2007), 940–949.
55. [55] Xie, G.J., Liu, B.F., Wen, H.Q., Li, Q., Yang, C.Y., Han, W.L., et al. Bioflocculation of photo-fermentative bacteria induced by calcium ion for enhancing hydrogen production. Int J Hydrog Energy 38 (2013), 7780–7788.
56. [56] Ren, N., Liu, B., Ding, J., Guo, W., Cao, G., Xie, G., The effect of butyrate concentration on photo-hydrogen production from acetate by Rhodopseudomonas faecalis RLD-53. Int J Hydrog Energy 33 (2008), 5981–5985.
57. [57] Li, X., Dai, Z.Z., Wang, Y.H., Zhang, S.L., Enhancement of phototrophic hydrogen production by Rhodobacter sphaeroides ZX-5 using fed-batch operation based on ORP level. Int J Hydrog Energy 36 (2011), 12794–12802.
58. [58] Ma, C., Wang, X., Guo, L., Wu, X., Yang, H., Enhanced photo-fermentative hydrogen production by Rhodobacter capsulatus with pigment content manipulation. Bioresour Technol 118 (2012), 490–495.
59. [59] Younesi, H., Najafpour, G., Ku Ismail, K.S., Mohamed, A.R., Kamaruddin, A.H., Biohydrogen production in a continuous stirred tank bioreactor from synthesis gas by anaerobic photosynthetic bacterium: Rhodopirillum rubrum. Bioresour Technol 99 (2008), 2612–2619.
60. [60] Gilbert, J.J., Ray, S., Das, D., Hydrogen production using Rhodobacter sphaeroides (O.U. 001) in a flat panel rocking photobioreactor. Int J Hydrogen Energy 36 (2011), 3434–3441.
61. [61] Lee, C.M., Hung, G.J., Yang, C.F., Hydrogen production by Rhodopseudomonas palustris WP 3-5 in a serial photobioreactor fed with hydrogen fermentation effluent. Bioresour Technol 102 (2011), 8350–8356.
62. [62] Tian, X., Liao, Q., Zhu, X., Wang, Y., Zhang, P., Li, J., et al. Characteristics of a biofilm photobioreactor as applied to photo-hydrogen production. Bioresour Technol 101 (2010), 977–983.
63. [63] Öztürk, Y., Yücel, M., Daldal, F., Mandaci, S., Gunduz, U., Tunker, L., et al. Hydrogen production by using Rhodobacter capsulatus mutants with genetically modified electron transfer chains. Int J Hydrog Energy 31 (2006), 1545–1552.
64. [64] Hallenbeck, P.C., Ghosh, D., Advances in fermentative biohydrogen production: the way forward?. Trends Biotechnol 27 (2009), 287–297.
65. [65] Krupp, M., Widmann, R., Biohydrogen production by dark fermentation: experiences of continuous operation in large lab scale. Int J Hydrog Energy 34 (2009), 4509–4516.
66. [66] Chong, M.-L., Sabaratnam, V., Shirai, Y., Hassan, M.A., Biohydrogen production from biomass and industrial wastes by dark fermentation. Int J Hydrog Energy 34 (2009), 3277–3287.
67. [67] Doi, T., Matsumoto, H., Abe, J., Morita, S., Application of rice rhizosphere microflora for hydrogen production from apple pomace. Int J Hydrog Energy, 35, 2010 7369–76.
68. [68] Yasin, N.H.M., Mumtaz, T., Hassan, M.A., Abd Rahman, N., Food waste and food processing waste for biohydrogen production: a review. J Environ Manag 130 (2013), 375–385.
69. [69] Hallenbeck, P.C., Abo-Hashesh, M., Ghosh, D., Strategies for improving biological hydrogen production. Bioresour Technol 110 (2012), 1–9.
70. [70] Benemann, J., Hydrogen biotechnology: progress and prospects. Nat Biotechnol 14 (1996), 1101–1103.
71. [71] Khanna, N., Kotay, S.M., Gilbert, J.J., Das, D., Improvement of biohydrogen production by Enterobacter cloacae IIT-BT 08 under regulated pH. J Biotechnol 152 (2011), 9–15.
72. [72] Chin, H.L., Chen, Z.S., Chou, C.P., Fedbatch operation using Clostridium acetobutylicum suspension culture as biocatalyst for enhancing hydrogen production. Biotechnol Prog 19 (2003), 383–388.
73. [73] Rao, G., Mutharasan, R., Altered electron flow in continuous cultures of Clostridium acetobutylicum induced by viologen dyes. Appl Environ Microbiol 53 (1987), 1232–1235 doi:papers2://publication/uuid/660100BA-2E74-4E86-BE9d-CC1FDFB7EA0C.
74. [74] Wicher, E., Seifert, K., Zagrodnik, R., Pietrzyk, B., Laniecki, M., Hydrogen gas production from distillery wastewater by dark fermentation. Int J Hydrog Energy 38 (2013), 7767–7773.
75. [75] Kim, M.-S., Lee, D.-Y., Fermentative hydrogen production from tofu-processing waste and anaerobic digester sludge using microbial consortium. Bioresour Technol 101:Suppl (2010), S48–S52.
76. [76] Puhulwella, R.G., Beckers, L., Delvigne, F., Grigorescu, A.S., Thonart, P., Hiligsmann, S., mesophilic biohydrogen production by Clostridium butyricum CWBI1009 in trickling biofilter reactor. Int J Hydrog Energy 39 (2014), 16902–16913.
77. [77] Seifert, K., Waligorska, M., Wojtowski, M., Laniecki, M., Hydrogen generation from glycerol in batch fermentation process. Int J Hydrog Energy 34 (2009), 3671–3678.
78. [78] Kargi, F., Eren, N.S., Ozmihci, S., Hydrogen gas production from cheese whey powder (CWP) solution by thermophilic dark fermentation. Int J Hydrog Energy 37 (2012), 2260–2266.
79. [79] Kamalaskar, L.B., Dhakephalkar, P.K., Meher, K.K., Ranade, D.R., High biohydrogen yielding Clostridium sp. DMHC-10 isolated from sludge of distillery waste treatment plant. Int J Hydrog Energy 35 (2010), 10639–10644.
80. [80] Wu, X., Yang, H., Guo, L., Effect of operation parameters on anaerobic fermentation using cow dung as a source of microorganisms. Int J Hydrog Energy 35 (2010), 46–51.
81. [81] Karadag, D., Puhakka, J.A., Direction of glucose fermentation towards hydrogen or ethanol production through on-line pH control. Int J Hydrog Energy 35 (2010), 10245–10251.
82. [82] Mäkinen, A.E., Nissilä, M.E., Puhakka, J.A., Dark fermentative hydrogen production from xylose by a hot spring enrichment culture. Int J Hydrog Energy 37 (2012), 12234–12240.
83. [83] Bao, M.D., Su, H.J., Tan, T.W., Dark fermentative bio-hydrogen production: effects of substrate pre-treatment and addition of metal ions or L-cysteine. Fuel 112 (2013), 38–44.
84. [84] Ozmihci, S., Kargi, F., Dark fermentative bio-hydrogen production from waste wheat starch using co-culture with periodic feeding: effects of substrate loading rate. Int J Hydrog Energy 36 (2011), 7089–7093.
85. [85] Chen, S.D., Lo, Y.C., Lee, K.S., Huang, T.I., Chang, J.S., Sequencing batch reactor enhances bacterial hydrolysis of starch promoting continuous bio-hydrogen production from starch feedstock. Int J Hydrog Energy 34 (2009), 8549–8557.
86. [86] Chaganti, S.R., Pendyala, B., Lalman, J.A., Veeravalli, S.S., Heath, D.D., Influence of linoleic acid, pH and HRT on anaerobic microbial populations and metabolic shifts in ASBRs during dark hydrogen fermentation of lignocellulosic sugars. Int J Hydrog Energy 38 (2013), 2212–2220.
87. [87] Ghosh, D., Hallenbeck, P.C., Fermentative hydrogen yields from different sugars by batch cultures of metabolically engineered Escherichia coli DJT135. Int J Hydrog Energy 34 (2009), 7979–7982.
88. [88] Lin, C.N., Wu, S.Y., Chang, J.S., Chang, J.S., Biohydrogen production in a three-phase fluidized bed bioreactor using sewage sludge immobilized by ethylene-vinyl acetate copolymer. Bioresour Technol 100 (2009), 3298–3301.
89. [89] Wang, H., Wang, J., Fang, Z., Wang, X., Bu, H., Enhanced bio-hydrogen production by anaerobic fermentation of apple pomace with enzyme hydrolysis. Int J Hydrog Energy 35 (2010), 8303–8309.
90. [90] Baghchehsaraee, B., Nakhla, G., Karamanev, D., Margaritis, A., Fermentative hydrogen production by diverse microflora. Int J Hydrog Energy 35 (2010), 5021–5027.
91. [91] Nath, K., Das, D., Improvement of fermentative hydrogen production: Various approaches. Appl Microbiol Biotechnol 65 (2004), 520–529.
92. [92] Yang, S.-I., Choi, D.-Y., Jang, S.-C., Kim, S.-H., Choi, D.-K., Hydrogen separation by multi-bed pressure swing adsorption of synthesis gas. Adsorption 14 (2008), 583–590.
93. 2 and its separation by polyimide membrane. Int J Hydrog Energy 37 (2012), 5623–5630.
94. [94] Paglieri, S.N., Way, J.D., Innovations in palladium membrane research. Sep Purif Rev 31 (2002), 1–169.
95. [95] Sircar, S., Golden, T.C., Pressure swing adsorption technology for hydrogen production. Hydrog Syngas Prod Purif Technol, 2009, John Wiley & Sons, Inc, Hoboken, NJ, USA, 414–450.
96. [96] Kerry, F., Industrial gas handbook: gas separation and purification, 2007, CRC Press, Florida USA.
97. [97] Morreale, B.D., Ciocco, M.V., Enick, R.M., Morsi, B.I., Howard, B.H., Cugini, A.V., et al. The permeability of hydrogen in bulk palladium at elevated temperatures and pressures. J Memb Sci 212 (2003), 87–97.
98. [98] Gimeno, M.P., Wu, Z.T., Soler, J., Herguido, J., Li, K., Men??ndez, M., Combination of a two-zone fluidized bed reactor with a Pd hollow fibre membrane for catalytic alkane dehydrogenation. Chem Eng J 155 (2009), 298–303.
99. [99] Bi, Y., Xu, H., Li, W., Goldbach, A., Water–gas shift reaction in a Pd membrane reactor over Pt/Ce0.6Zr0.4O2 catalyst. Int J Hydrog Energy 34 (2009), 2965–2971.
100. [100] Shao, L., Low, B.T., Chung, T.-S., Greenberg, A.R., Polymeric membranes for the hydrogen economy: contemporary approaches and prospects for the future. J Memb Sci 327 (2009), 18–31.
101. 2-philic polymers. J Memb Sci 372 (2011), 29–39.
102. 2 post combustion mixtures using a Matrimid membrane. J Memb Sci 378 (2011), 359–368.
103. [103] Mulder, M., Basic principles of membrane technology. J Memb Sci, 72, 1996, 564.
104. [104] Wijmans, J.G., Baker, R.W., The solution-diffusion model: a review. J Memb Sci 107 (1995), 1–21.
105. 2 gas. J Memb Sci 170 (2000), 173–190.
106. [106] Orme, C.J., Harrup, M.K., Luther, T.A., Lash, R.P., Houston, K.S., Weinkauf, D.H., et al. Characterization of gas transport in selected rubbery amorphous polyphosphazene membranes. J Memb Sci 186 (2001), 249–256.
107. [107] Orme, C.J., Klaehn, J.R., Harrup, M.K., Luther, T.A., Peterson, E.S., Stewart, F.F., Gas permeability in rubbery polyphosphazene membranes. J Memb Sci 280 (2006), 175–184.
108. [108] Kim, J.H., Ha, S.Y., Lee, Y.M., Gas permeation of poly(amide-6-b-ethylene oxide) copolymer. J Memb Sci 190 (2001), 179–193.
109. [109] Merkel, T.C., Gupta, R.P., Turk, B.S., Freeman, B.D., Mixed-gas permeation of syngas components in poly(dimethylsiloxane) and poly(1-trimethylsilyl-1-propyne) (at elevated temperatures. J Memb Sci 191 (2001), 85–94.
110. [110] Borisov, S., Khotimsky, V.S., Rebrov, A.I., Rykov, S.V., Slovetsky, D.I., Pashunin, Y.M., Plasma fluorination of organosilicon polymeric films for gas separation applications. J Memb Sci 125 (1997), 319–329.
111. [111] Morisato, A., Pinnau, I., Synthesis and gas permeation properties of poly(4-methyl-2-pentyne). J Memb Sci 121 (1996), 243–250.
112. [112] Orme, C.J., Stone, M.L., Benson, M.T., Peterson, E.S., Testing of polymer membranes for the selective permeability of hydrogen. Sep Sci Technol 38 (2003), 3225–3238.
113. [113] Li, Y., Chung, T.S., Highly selective sulfonated polyethersulfone (SPES)-based membranes with transition metal counterions for hydrogen recovery and natural gas separation. J Memb Sci 308 (2008), 128–135.
114. 2 separation. J Memb Sci 307 (2008), 88–95.
115. 2) gas separation membranes. J Memb Sci 352 (2010), 126–135.
116. [116] Lopes, T., Paganin, V.A., Gonzalez, E.R., The effects of hydrogen sulfide on the polymer electrolyte membrane fuel cell anode catalyst: H2S–Pt/C interaction products. J Power Sources 196 (2011), 6256–6263.
117. [117] Harasimowicz, M., Orluk, P., Zakrzewska-Trznadel, G., Chmielewski, A.G., Application of polyimide membranes for biogas purification and enrichment. J Hazard Mater 144 (2007), 698–702.
118. 2 using matrimid asymmetric hollow fiber membranes. Procedia Eng 44 (2012), 1117–1118.
119. [119] Shalygin, M.G., Abramov, S.M., Netrusov, A.I., Teplyakov, V.V., Membrane recovery of hydrogen from gaseous mixtures of biogenic and technogenic origin. Int J Hydrog Energy 40 (2015), 3438–3451.
120. 2 removal in biohydrogen production. Desalination 224 (2008), 186–190.
121. [121] Beggel, F., Modigell, M., Shalygin, M., Teplyakov, V., Zenkevitch, V., Novel membrane contactor for gas upgrading in biohydrogen production. Chem Eng Trans 18 (2009), 397–402.
122. [122] Beggel, F., Nowik, I.J., Modigell, M., Shalygin, M.G., Teplyakov, V.V., Zenkevitch, V.B., A novel gas purification system for biologically produced gases. J Clean Prod, 2010, 18.
123. [123] Malik, M.A., Hashim, M.A., Nabi, F., Ionic liquids in supported liquid membrane technology. Chem Eng J 171 (2011), 242–254.
124. [124] Molinari, R., Drioli, E., Pantano, G., Stability and effect of diluents in supported liquid membranes for Cr(III), Cr(VI), and Cd(II) recovery. Sep Sci Technol 24 (1989), 1015–1032.
125. [125] Cserjési, P., Nemestóthy, N., Vass, A., Csanádi, Z., Bélafi-Bakó, K., Study on gas separation by supported liquid membranes applying novel ionic liquids. Desalination 245 (2009), 743–747.
126. [126] Cserjési, P., Nemestóthy, N., Bélafi-Bakó, K., Gas separation properties of supported liquid membranes prepared with unconventional ionic liquids. J Memb Sci 349 (2010), 6–11.
127. [127] Neves, L.A., Nemestóthy, N., Alves, V.D., Cserjési, P., Bélafi-Bakó, K., Coelhoso, I.M., Separation of biohydrogen by supported ionic liquid membranes. Desalination 240 (2009), 311–315.
128. [128] Neves, L.A., Crespo, J.G., Coelhoso, I.M., Gas permeation studies in supported ionic liquid membranes. J Memb Sci 357 (2010), 160–170.
129. 2 separation properties of a glassy aromatic polyimide composite membranes containing high-content 1-butyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide ionic liquid. J Memb Sci 430 (2013), 211–222.
130. [130] Gu, Y., Cussler, E.L., Lodge, T.P., ABA-triblock copolymer ion gels for CO2 separation applications. J Memb Sci 423–424 (2012), 20–26.
131. [131] Zha, F.F., Fane, A.G., Fell, C.J.D., Schofield, R.W., Critical displacement pressure of a supported liquid membrane. J Memb Sci 75 (1992), 69–80.
132. [132] Gan, Q., Rooney, D., Xue, M., Thompson, G., Zou, Y., An experimental study of gas transport and separation properties of ionic liquids supported on nanofiltration membranes. J Memb Sci 280 (2006), 948–956.
133. [133] Izák, P., Ruth, W., Fei, Z., Dyson, P.J., Kragl, U., Selective removal of acetone and butan-1-ol from water with supported ionic liquid-polydimethylsiloxane membrane by pervaporation. Chem Eng J 139 (2008), 318–321.
134. [134] Finotello, A., Bara, J.E., Camper, D., Noble, R.D., Room-temperature ionic liquids: temperature dependence of gas solubility selectivity. Ind Eng Chem Res 47 (2008), 3453–3459.
135. [135] Retailers begin sales of Horizon's portable micro fuel cell devices. Fuel Cells Bull 2012; 2012. p.7.
136. [136] eZelleron builds funds on Kickstarter to prep kraftwerk charger unit. Fuel Cells Bull 2015; 2015. p. 6–7.
137. [137] Intelligent Energy's portable power Upp at Apple Stores in UK. Fuel Cells Bull 2014;2014:8.
138. [138] myFC launches JAQ portable fuel cell charger at mobiles fair. Fuel Cells Bull 2015; 2015. p. 6–7.
139. [139] Tabata, T., Yamazaki, O., Degradation factors of polymer electrolyte fuel cells in residential cogeneration systems. Polym Electrolyte Fuel, 2009.
140. 2/CO oxidation mechanism on Pt/C, Ru/C and Pt–Ru/C electrocatalysts. J Appl Electrochem n.d.; 31. p. 325–334.
141. [141] Büchi, F.N., Inaba, M., Schmidt, T.J., (eds.) Polymer electrolyte fuel cell durability, 2009, Springer New York, New York, NY, 10.1007/978-0-387-85536-3.
142. 2, and other trace impurities. Polym Electrolyte Fuel Cell, 2009.
143. 2/CO as fuel gas. J Electrochem Soc, 1996.
144. [144] Mohtadi, R., Lee, W.K., Van Zee, J.W., The effect of temperature on the adsorption rate of hydrogen sulfide on Pt anodes in a PEMFC. Appl Catal B Environ 56 (2005), 37–42.
145. [145] Mathieu, M.V., Primet, M., Sulfurization and regeneration of platinum. Appl Catal 9 (1984), 361–370.
146. [146] Mohtadi, R., Lee, W., Cowan, S., Van Zee, J.W., Murthy, M., Effects of Hydrogen Sulfide on the Performance of a PEMFC. Electrochem Solid-State Lett, 6, 2003, A272.
147. [147] Oncel, S., Vardar-Sukan, F., Application of proton exchange membrane fuel cells for the monitoring and direct use of biohydrogen produced by Chlamydomonas reinhardtii. J Power Sources 196 (2011), 46–53.
148. [148] Wünschiers, R., Lindblad, P., Hydrogen in education-a biological approach. Int J Hydrog Energy 27 (2002), 1131–1140.
149. [149] Nakada, E., Nishikata, S., Asada, Y., Miyake, J., Photosynthetic bacterial hydrogen production combined with a fuel cell. Int J Hydrog Energy(24), 1999, 1053–1057.
150. [150] He, D., Bultel, Y., Magnin, J., Roux, C., Willison, J., Hydrogen photosynthesis by and its coupling to a PEM fuel cell. J Power Sources 141 (2005), 19–23.
151. [151] González del Campo, A., Fernández, F.J., Cañizares, P., Rodrigo, M.A., Pinar, F.J., Lobato, J., Energy recovery of biogas from juice wastewater through a short high temperature PEMFC stack. Int J Hydrog Energy 39 (2014), 6937–6943.
152. [152] García-Peña, E.I., Guerrero-Barajas, C., Ramirez, D., Arriaga-Hurtado, L.G., Semi-continuous biohydrogen production as an approach to generate electricity. Bioresour Technol 100 (2009), 6369–6377.
153. [153] Wei, J., Liu, Z.-T., Zhang, X., Biohydrogen production from starch wastewater and application in fuel cell. Int J Hydrog Energy 35 (2010), 2949–2952.
154. [154] Balat, M., Balat, M., Political, economic and environmental impacts of biomass-based hydrogen. Int J Hydrog Energy 34 (2009), 3589–3603.
155. [155] Meher Kotay, S., Das, D., Biohydrogen as a renewable energy resource-Prospects and potentials. Int J Hydrog Energy 33 (2008), 258–263.