Beet pulp |
pH 12 with NaOH for 30 min |
anaerobic sludge |
35 |
115.6 mL of H2/g of COD |
- |
Ozkan et al., 2011Ozkan L, Erguder TH, Demirer GN (2011) Effects of pretreatment methods on solubilization of beet-pulp and biohydrogen production yield. Int J Hydrogen Energy 36:382–389.
|
Corn stalk |
Lime loading of 0.10 g/g of biomass for 96 h |
mixed microflora from rotted wood crumb |
60 |
155.4 mL of H2/g of TVS |
5.69 |
Cao et al., 2012Cao GL, Guo WQ, Wang AJ et al. (2012) Enhanced cellulosic hydrogen production from lime-treated cornstalk wastes using thermophilic anaerobic microflora. Int J Hydrogen Energy 37:13161–13166.
|
Cornstalk |
Phanerochaete chrysosporium
|
T. thermosaccharolyticum
|
50 |
89.3 mL of H2/g |
3.99 |
Zhao et al., 2013Zhao L, Cao G-L, Wang A-J et al. (2013) Simultaneous saccharification and fermentation of fungal pretreated cornstalk for hydrogen production using Thermoanaerobacterium thermosaccharolyticum W16. Bioresour Technol 145:103–107.
|
|
Trichoderma viride
|
T. thermosaccharolyticum
|
50 |
90.6 mL of H2/g |
4.04 |
Zhao et al., 2013Zhao L, Cao G-L, Wang A-J et al. (2013) Simultaneous saccharification and fermentation of fungal pretreated cornstalk for hydrogen production using Thermoanaerobacterium thermosaccharolyticum W16. Bioresour Technol 145:103–107.
|
Cornstalk |
solid state enzymolysis |
panda manure |
36 |
205.5 mL of H2/g of TVS |
8.11
|
Xing et al., 2011Xing Y, Fan SQ, Zhang JN (2011) Enhanced bio-hydrogen production from corn stalk by anaerobic fermentation using response surface methodology. Int J Hydrogen Energy 36:12770–12779.
|
Cornstalk |
H2SO4 0.5% at 121°C for 60 min |
microwave irradiated cow dung compost |
36 |
144.3 mL of H2/g |
6.44 |
Song et al., 2012Song ZX, Wang ZY, Wu LY et al. (2012) Effect of microwave irradiation pretreatment of cow dung compost on bio-hydrogen process from corn stalk by dark fermentation. Int J Hydrogen Energy 37:6554–6561.
|
Cornstalk |
NaOH at 120 °C for 20 min |
anaerobic sludge |
55 |
45.7 mL of H2/g |
1.70 |
Cheng and Liu, 2012Cheng XY, Liu CZ (2012a) Enhanced coproduction of hydrogen and methane from cornstalks by a three-stage anaerobic fermentation process integrated with alkaline hydrolysis. Bioresour Technol 104:373–379.
|
Cornstalk |
Fungal pretreatment |
anaerobic sludge |
55 |
54.1 mL of H2/g of VS |
2.01
|
Cheng and Liu, 2012Cheng XY, Liu CZ (2012a) Enhanced coproduction of hydrogen and methane from cornstalks by a three-stage anaerobic fermentation process integrated with alkaline hydrolysis. Bioresour Technol 104:373–379.
|
Cornstalk |
Acidification 0.2% HCl |
cow dung compost |
36 |
149.69 mL of H2/g of TVS |
5.90
|
Zhang et al., 2007Zhang M-L, Fan Y-T, Xing Y et al. (2007) Enhanced biohydrogen production from cornstalk wastes with acidification pretreatment by mixed anaerobic cultures. Biomass Bioenergy 31:250–254.
|
Corn stover |
1.2% H2SO4/2 h and steam explosion 200 °C for 1 min |
dried sludge |
35 |
184.71 mL of H2/10 g (18.47 mL/g) |
0.73 |
Datar et al., 2007Datar R, Huang J, Maness P-C et al. (2007) Hydrogen production from the fermentation of corn stover biomass pretreated with a steam-explosion process Int J Hydrogen Energy 32:932–939.
|
Corn stover |
Microwave assisted acid pretreatment (H2SO4 0.3 N for 45 min) |
anaerobic sludge |
55 |
18.22 mL of H2/g |
0.68 |
Liu and Cheng, 2010Liu CZ, Cheng XY (2010) Improved hydrogen production via thermophilic fermentation of corn stover by microwave-assisted acid pretreatment. Int J Hydrogen Energy 35:8945–8952.
|
Grass |
4% HCl |
anaerobic |
35 |
72.21 mL of H2/g |
2.86 |
Cui and Shen 2012Cui M, Shen J (2012) Effects of acid and alkaline pretreatments on the biohydrogen production from grass by anaerobic dark fermentation. Int J Hydrogen Energy 37:1120–1124.
|
|
0.5% NaOH |
mixed bacteria |
35 |
19.25 mL of H2/g |
0.86 |
Cui and Shen 2012Cui M, Shen J (2012) Effects of acid and alkaline pretreatments on the biohydrogen production from grass by anaerobic dark fermentation. Int J Hydrogen Energy 37:1120–1124.
|
Grass (Reed canary) |
3% HCl solution for 90 min at 121 °C |
H2-fermenting microbial enrichment culture |
35 |
1.25 mmol of H2/g |
1.25 |
Lakaniemi et al., 2011Lakaniemi AM, Koskinen PEP, Nevatalo LM et al. (2011) Biogenic hydrogen and methane production from reed canary grass. Biomass Bioenergy 35:773–780.
|
Rapeseed stillage |
Alkaline peroxide with steam treatment |
digested manure |
55 |
79 mL of H2/gVS |
2.94
|
Luo et al., 2011Luo G, Talebnia F, Karakashev D et al. (2011). Enhanced bioenergy recovery from rapeseed plant in a biorefinery concept. Bioresour Technol 102:1433–1439.
|
Rapeseed cake |
Alkaline peroxide with steam treatment |
digested manure |
55 |
24 mL of H2/gVS |
0.89
|
Luo et al., 2011Luo G, Talebnia F, Karakashev D et al. (2011). Enhanced bioenergy recovery from rapeseed plant in a biorefinery concept. Bioresour Technol 102:1433–1439.
|
Rice straw |
10% ammonia and 1.0% H2SO4
|
T. neapolitana
|
75 |
2.7 mmol of H2/g |
2.70 |
Nguyen et al., 2010Nguyen T-AD, Kim K-R, Kim MS et al. (2010) Thermophilic hydrogen fermentation from Korean rice straw by Thermotoga neapolitana. Int J Hydrogen Energy 35:13392–13398.
|
Sugarcane bagasse |
0.5% H2SO4 for 60 min at 121 °C |
C. butyricum
|
37 |
1.73 mol of H2/mol sugar |
- |
Pattra et al., 2008Pattra S, Sangyoka S, Boonmee M et al. (2008) Bio-hydrogen production from the fermentation of sugarcane bagasse hydrolysate by Clostridium butyricum. Int J Hydrogen Energy 33:5256–5265.
|
Sugarcane bagasse |
H2SO4 at 1% for 60 min at 121 °C |
preheated elephant dung |
37 |
0.84 mol of H2/mol sugar |
- |
Fangkum and Reunsang, 2011Fangkum A, Reungsang A (2011) Biohydrogen production from sugarcane bagasse hydrolysate by elephant dung: Effects of initial pH and substrate concentration. Int J Hydrogen Energy 36:8687–8696.
|
Sugarcane bagasse |
H2SO4 at 1% for 60 min at 121 °C |
T. thermosaccharolyticum
|
55 |
1.12 mol of H2/mol sugar |
- |
Saripan and Reungsang, 2013Saripan AF, Reungsang A (2013) Biohydrogen production by Thermoanaerobacterium thermosaccharolyticum KKU-ED1: Culture conditions optimization using xylan as the substrate. Int J Hydrogen Energy 38:6167–6173.
|
Waste ground wheat |
H2SO4, pH 3.0, 90 °C for 15 min |
preheated anaerobic sludge |
37 |
946.2 mL |
- |
Sagnak et al., 2011Sagnak R, Kargi F, Kapdan IK (2011) Bio-hydrogen production from acid hydrolyzed waste ground wheat by dark fermentation. Int J Hydrogen Energy 36:12803–12809.
|
Wheat straw |
HCl pretreated |
cow dung compost |
36 |
68.1 mL of H2/g TVS |
3.04
|
Fan et al., 2006Fan YT, Zhang YH, Zhang SF et al. (2006) Efficient conversion of wheat straw wastes into biohydrogen gas by cow dung compost. Bioresour Technol 97:500–505.
|
Wheat straw |
Hydrothermic 180 °C for 15 min |
preheated anaerobic sludge |
70 |
7.36 mmol of H2/g sugars |
- |
Kongjan et al., 2010Kongjan P, O-Thong S, Kotay M et al. (2010) Biohydrogen Production From Wheat Straw Hydrolysate by Dark Fermentation Using Extreme Thermophilic Mixed Culture. Biotechnol Bioeng 105:899–908.
|