Treatment and Reuse of Effluents from Palm Oil, Pulp, and Paper Mills as a Combined Substrate by Using Purple Nonsulfur Bacteria

Budiman, Pretty Mori; Wu, Ta Yeong; Ramanan, Ramakrishnan Nagasundara; Hay, Jacqueline Xiao Wen

doi:10.1021/ie501798f

Cited by 17 publications

(19 citation statements)

References 31 publications

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“…CQK 01 to produce hydrogen Electronic Journal of Biotechnology 18 (2015) 221-230 [17]. PNSB are widely distributed in aquatic and wastewater environments [18,19,20]. They can be isolated from the environment using conventional enrichment techniques.…”

Section: Introductionmentioning

confidence: 99%

Photo-fermentational hydrogen production of Rhodobacter sp. KKU-PS1 isolated from an UASB reactor

Assawamongkholsiri

Reungsang

2015

Electronic Journal of Biotechnology

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Background: In this study, the detection of nifH and nifD by a polymerase chain reaction assay was used to screen the potential photosynthetic bacteria capable of producing hydrogen from five different environmental sources. Efficiency of photo-hydrogen production is highly dependent on the culture conditions. Initial pH, temperature and illumination intensity were optimized for maximal hydrogen production using response surface methodology with central composite design. Results: Rhodobacter sp. KKU-PS1 (GenBank Accession No. KC478552) was isolated from the methane fermentation broth of an UASB reactor. Malic acid was the favored carbon source while Na-glutamate was the best nitrogen source. The optimum conditions for simultaneously maximizing the cumulative hydrogen production (H max ) and hydrogen production rate (R m ) from malic acid were an initial of pH 7.0, a temperature of 25.6°C, and an illumination intensity of 2500 lx. H max and R m levels of 1264 ml H 2 /l and 6.8 ml H 2 /L-h were obtained, respectively. The optimum initial pH and temperature were further used to optimize the illumination intensity for hydrogen production. An illumination intensity of 7500 lx gave the highest values of H max (1339 ml H 2 /l) and R m (12.0 ml H 2 /L-h) with a hydrogen yield and substrate conversion efficiency of 3.88 mol H 2 /mol malate and 64.7%, respectively. Conclusions: KKU-PS1 can produce hydrogen from at least 8 types of organic acids. By optimizing pH and temperature, a maximal hydrogen production by this strain was obtained. Additionally, by optimizing the light intensity, R m was increased by approximately two fold and the lag phase of hydrogen production was shortened.

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Section: Introductionmentioning

confidence: 99%

Photo-fermentational hydrogen production of Rhodobacter sp. KKU-PS1 isolated from an UASB reactor

Assawamongkholsiri

Reungsang

2015

Electronic Journal of Biotechnology

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“…Hence, an introduction of PPME as a diluting agent in this study was necessary to promote photo-biohydrogen production by increasing the visibility of substrate and improving the light penetration into the system. Budiman et al 19 also reported that a combination of POME and PPME as single substrate could be applied as a suitable growth medium for R. sphaeroides because of the enhanced light penetration and faster adaptation in the diluted media. 19 Furthermore, the introduction of PPME (a low nitrogen source) helped increase the C/N ratio of photofermentation substrate (Table 1).…”

Section: Effect Of Pome Concentration On Biohydrogen Productionmentioning

confidence: 99%

“…Budiman et al 19 also reported that a combination of POME and PPME as single substrate could be applied as a suitable growth medium for R. sphaeroides because of the enhanced light penetration and faster adaptation in the diluted media. 19 Furthermore, the introduction of PPME (a low nitrogen source) helped increase the C/N ratio of photofermentation substrate (Table 1). It was reported that high C/N ratio promoted the production of biohydrogen by allowing PNS bacteria to dispose their excess energy and reducing power through production of hydrogen.…”

Section: Effect Of Pome Concentration On Biohydrogen Productionmentioning

confidence: 99%

“…12 Besides, Budiman et al 19 reported that a concentration of 25% (v/v) POME was the best to be reused as a growth medium for R. sphaeroides due to the presence of adequate nutrients and light penetration. However, Budiman et al 19 did not further investigate if the diluted POME could be reused as a substrate in biohydrogen production through photofermentation process. During photofermentation, natural or artificial illumination is supplied to support the bacterial growth and initiate biohydrogen production.…”

Section: Introductionmentioning

confidence: 99%

“…biological degradation. The physical and chemical characteristics of both effluents are summarized in Table 1 19 before the bacteria were transferred into photo-biohydrogen production medium. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 …”

Section: Introductionmentioning

confidence: 99%

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Improvement of Biohydrogen Production through Combined Reuses of Palm Oil Mill Effluent Together with Pulp and Paper Mill Effluent in Photofermentation

Budiman

Ramanan

et al. 2015

Energy Fuels

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Rhodobacter sphaeroides NCIMB8253 and palm oil mill effluent (POME) were applied as the purple non-sulfur bacteria and substrate, respectively to produce biohydrogen in photofermentation process. Due to the dark color of POME, pulp and paper mill effluent (PPME) was used as a diluting agent to reduce the turbidity of substrate and thus, improving light penetration. Anaerobic batch experiments were performed by varying the concentration of POME from 12.5 to 100% (v/v) with 10% (v/v) inoculum in a total of 100 ml substrate. The highest biohydrogen yield of 4.670 ml H 2 /ml medium was obtained using NS4 treatment containing 25 and 75 % (v/v) of POME and PPME, respectively. A maximum production rate of 0.496 ml H 2 /ml medium/h and light efficiency of 2.40% were also achieved in NS4.Furthermore, a simultaneous 28.8% COD total removal was obtained after 3 days of photofermentation. Additional increase of POME concentration (>25%, v/v) did not support higher production of biohydrogen due to the increase of turbidity (>16,450 NTU) which resulted in hindrance of light penetration. This study showed that the potential of reusing and combining two different effluents together, in which case one had lower turbidity than the other wastewater, for improving light penetration and thus, photo-biohydrogen production.

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Effect of adding brewery wastewater to pulp and paper mill effluent to enhance the photofermentation process: wastewater characteristics, biohydrogen production, overall performance, and kinetic modeling

Hay

Juan

et al. 2017

Environ Sci Pollut Res

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Although a significant amount of brewery wastewater (BW) is generated during beer production, the nutrients in the BW could be reused as a potential bio-resource for biohydrogen production. Therefore, improvements in photofermentative biohydrogen production due to a combination of BW and pulp and paper mill effluent (PPME) as a mixed production medium were investigated comprehensively in this study. The experimental results showed that both the biohydrogen yield and the chemical oxygen demand removal were improved through the combination of BW and PPME. The best biohydrogen yield of 0.69 mol H/L medium was obtained using the combination of 10 % BW + 90 % PPME (10B90P), while the reuse of the wastewater alone (100 % BW and 100 % PPME) resulted in 42.3 and 44.0 % less biohydrogen yields than the highest yield, respectively. The greatest light efficiency was 1.97 % and was also achieved using the combination of both wastewaters at 10B90P. This study revealed the potential of reusing and combining two different effluents together, in which the combination of BW and PPME improved the nutrients and light penetration into the mixed production medium.

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Treatment and Reuse of Effluents from Palm Oil, Pulp, and Paper Mills as a Combined Substrate by Using Purple Nonsulfur Bacteria

Cited by 17 publications

References 31 publications

Photo-fermentational hydrogen production of Rhodobacter sp. KKU-PS1 isolated from an UASB reactor

Photo-fermentational hydrogen production of Rhodobacter sp. KKU-PS1 isolated from an UASB reactor

Improvement of Biohydrogen Production through Combined Reuses of Palm Oil Mill Effluent Together with Pulp and Paper Mill Effluent in Photofermentation

Effect of adding brewery wastewater to pulp and paper mill effluent to enhance the photofermentation process: wastewater characteristics, biohydrogen production, overall performance, and kinetic modeling

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