Research Article
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Year 2020, Volume: 3 Issue: 1, 42 - 47, 22.06.2020

Abstract

References

  • Belete YZ, Leu S, Boussiba S, Zorin B, Posten C, Thomsen L, ... & Bernstein R. 2019. Characterization and utilization of hydrothermal carbonization aqueous phase as nutrient source for microalgal growth. Bioresource technology, 290: 121758.
  • Benelli P, Riehl CAS, Jr AS, Smânia EFA, Ferreira SRS. 2010. Bioactive extracts of orange (Citrus sinensis L. Osbeck) pomace obtained by SFE and low pressure techniques: mathematical modeling and extract composition. J. Supercrit. Fluids, 55: 132–141.
  • Benemann J. 2013. Microalgae for biofuels and animal feeds. Energies, 6: 5869–5886.
  • Bhatnagar A, Chinnasamy S, Singh M, & Das KC. 2011. Renewable biomass production by mixotrophic algae in the presence of various carbon sources and wastewaters. Applied Energy, 88(10): 3425-3431.
  • Biller P, Ross AB, Skill SC, Lea-Langton A, Balasundaram B, Hall C, Riley R, Llewellyn CA. 2012. Nutrient recycling of aqueous phase for microalgae cultivation from the hydrothermal liquefaction process. Algal Res., 1: 70–76
  • Bligh EG, & Dyer WJ. 1959. A rapid method of total lipid extraction and purification. Canadian journal of biochemistry and physiology, 37(8): 911-917.
  • Du Z, Hu B, Shi A, Ma X, Cheng Y, Chen P, ... & Ruan R. 2012. Cultivation of a microalga Chlorella vulgaris using recycled aqueous phase nutrients from hydrothermal carbonization process. Bioresource technology, 126: 354-357.
  • Dubois M, Gilles KA, Hamilton JK, Rebers PA and Smith F. 1956. Colorimetric method for determination of sugars and related substances. Anal. Chem., 28: 350-356.
  • Erdogan E, Atila B, Mumme J, Reza MT, Toptas A, Elibol M, & Yanik J. 2015. Characterization of products from hydrothermal carbonization of orange pomace including anaerobic digestibility of process liquor. Bioresource technology, 196: 35-42.
  • Gibbons G, Goad L and Goodwin T. 1968. The identification of 28-isofucosterol in the marine green algae Enteromorpha intestinalis and Ulva lactuca. Phytochemistry, 7: 983–988.
  • Giordano M, Kansiz M, Heraud P, Beardall J, Wood B, McNaughton D. 2001. Fourier transform infrared spectroscopy as a novel tool to investigate changes in intracellular macromolecular pools in the marine microalga Chaetoceros muellerii (bacillariophyceae). J Phycol, 37: 271–279.
  • Grobbelaar JU. 2004. Algal nutrition. In: Richmond A, editor. Handbook of microalgal culture: biotechnology and applied phycology. Oxford: Blackwell, pp. 97–115.
  • Hastings A, Clifton-Brown J, Wattenbach M, Mitchell CP, Stampfl P, Smith P. 2009. Future energy potential of Miscanthusin Europe. GCB Bioenergy, 1: 180–96.
  • Hillier J, Whittaker C, Dailey G, Aylott M, Casella E, Richter GM, et al. 2009. Greenhouse gas emissions from four bioenergy crops in England and Wales: integrating spatial estimates of yield and soil carbon balance in life cycle analyses. GCB Bioenergy, 1: 267–81.
  • Hoshino M, Tanaka M, Terada A, Sasaki M, Goto M. 2009. Separation and Characterization of Pectin from Juice Processing Residue Extracted By Sub- Critical Water. The 5th ISFR.
  • Jena U, Vaidyanathan N, Chinnasamy S, & Das KC. 2011. Evaluation of microalgae cultivation using recovered aqueous co-product from thermochemical liquefaction of algal biomass. Bioresource technology, 102(3): 3380-3387.
  • Karbowiak T, Ferret E, Debeaufort F, et al. 2011. Investigation of water transfer across thin layer biopolymer films by infrared spectroscopy. Journal of Membrane Science, 370: 82–90.
  • Khan SA, Malla FA, Malav LC, Gupta N, & Kumar A. 2018. Potential of wastewater treating Chlorella minutissima for methane enrichment and CO2 sequestration of biogas and producing lipids. Energy, 150: 153-163.
  • Lowry OH, Rosebrough NJ, Lewis Farr A, Randall RJ. 1951. Protein measurement with Folin phenol reagent. J. Biol. Chem., 193 (1): 265–275.
  • Maddi B, Panisko E, Wietsma T, Lemmon T, Swita M, Albrecht K, & Howe D. 2017. Quantitative characterization of aqueous byproducts from hydrothermal liquefaction of municipal wastes, food industry wastes, and biomass grown on waste. ACS Sustainable Chemistry & Engineering, 5(3): 2205-2214.
  • Madsen RB, Biller P, Jensen MM., Becker J, Iversen BB, & Glasius M. 2016. Predicting the chemical composition of aqueous phase from hydrothermal liquefaction of model compounds and biomasses. Energy & Fuels, 30(12): 10470-10483.
  • Marinovic A, Pileidis FD, & Titirici MM. 2015. Hydrothermal carbonisation (HTC): history, state-of-the-art and chemistry. Porous Carbon Materials from Sustainable Precursors, 32: 129.
  • Molino A, Iovine A, Casella P, Mehariya S, Chianese S, Cerbone A, Rimauro J, Musmarra D. 2018. Microalgae characterization for consolidated and new application in human food, animal feed and nutraceuticals. Int. J. Environ. Res. Public Health, 15: 1–21.
  • Oswald WJ. 1988. Large-scale algal culture systems (engineering aspects). In: Borowitzka MA, Borowitzka LJ (eds), Micro- Algal Biotechnology. Cambridge: Cambridge Univ. Press, pp. 357–394.
  • Ozcimen D, Missaoui A, Bostyn S, Belandria V, Gökalp I. 2019. Characterization of solid and aqueous phase products from hydrothermal carbonization of orange pomace. 2nd International Symposium on Hydrothermal Carbonization, Berlin, Germany.
  • Panisko E, Wietsma T, Lemmon T, Albrecht K, & Howe D. 2015. Characterization of the aqueous fractions from hydrotreatment and hydrothermal liquefaction of lignocellulosic feedstocks. Biomass and Bioenergy, 74: 162-171.
  • Radhika D and Mohaideen A. 2015. Fourier transform infrared analysis of Ulva lactuca and Gracilaria corticata and their effect on antibacterial activity. Asian Journal of Pharmaceutical and Clinical Research, 8: 209–212.
  • Rai LC, Gour JP, Kumar HD. 1981. Phycology and heavy metal pollution. Biol. Rev., 56: 99–151.
  • Richmond A. 1986. Handbook of microalgal mass culture. Boca Raton, Florida: CRC Press, 528 pp.
  • Rivas-Cantu RC, Jones KD, & Mills PL. 2013. A citrus waste-based biorefinery as a source of renewable energy: technical advances and analysis of engineering challenges. Waste management & research, 31(4): 413-420.
  • Sharma AK, Sahoo PK, Singhal S, & Patel A. 2016. Impact of various media and organic carbon sources on biofuel production potential from Chlorella spp. 3 Biotech, 6(2): 116.
  • Tam NFY, Wong YS. 1995. Wastewater treatment with microorganisms. Hong Kong: The commercial Press (H.K.) Ltd. 2D Finnie St. Quarry Bay.
  • Wang L, Min M, Li Y, Chen P, Chen Y, Liu Y & Ruan R. 2010. Cultivation of green algae Chlorella sp. in different wastewaters from municipal wastewater treatment plant. Applied biochemistry and biotechnology, 162(4): 1174-1186.
  • Wang X, Chen Q, Lü X. 2014. Pectin extracted from apple pomace and citrus peel by subcritical water. Food Hydrocolloids, 38: 129–137.
  • Wijngaard H, Brunton N. 2009. The optimization of extraction of antioxidants from apple pomace by pressurized liquids. J. Agric. Food Chem., 57: 10625–10631.
  • Wijngaard H, Hossain MB, Rai DK, Brunton N. 2012. Techniques to extract bioactive compounds from food by-products of plant origin. Food Res. Int., 46: 505–513.
  • Yang J, Cao J, Xing G, & Yuan H. 2015. Lipid production combined with biosorption and bioaccumulation of cadmium, copper, manganese and zinc by oleaginous microalgae Chlorella minutissima UTEX2341. Bioresource technology, 175: 537-544.
  • Yu S, Forsberg Å, Kral K, & Pedersén M. 1990. Furfural and Hydroxymethylfurfural inhibition of growth and photosynthesis in Spirulina. British Phycological Journal, 25(2): 141-148.

Utilization of hydrothermal process water for microalgae growth

Year 2020, Volume: 3 Issue: 1, 42 - 47, 22.06.2020

Abstract

Microalgae are one of the most effective biological sources for renewable energy production. They can be produced at rates that can be 50 times more than that of the conventional crops. They have a production capacity throughout the year. Comparing with other biomass sources such as terrestrial, agricultural and solid waste, algal biomass provides a more stable and manageable energy production system. However, there are some constraints for efficient microalgae production such as the need for large quantities of nutrients, high cost of installations and operation of production systems. For these reasons, using wastewaters obtained from different processes as a medium to grow microalgae has attracted new research interest. In the present study, the aqueous phase obtained from hydrothermal carbonization of orange pomace was utilized as a nutrient source in Chlorella minutissima growth. Different dilution rates (50x, 100x, 200x and 400x) were used to observe the effect of aqueous phase concentration on algal growth during 30 days. According to the results of microalgae cultivation, the medium with the lowest dilution rate was determined as the optimum medium because of giving the best growth value compared to other dilution rates.

Supporting Institution

TUBITAK-BIDEB, the French Embassy in Turkey and CNRS

Thanks

Anıl Tevfik Koçer and Seray Zora Tarhan were supported by TUBITAK BIDEB National Scholarship Program. Didem Özçimen was supported by the French Embassy in Turkey and the CNRS for her scholarship at ICARE-CNRS, Orléans.

References

  • Belete YZ, Leu S, Boussiba S, Zorin B, Posten C, Thomsen L, ... & Bernstein R. 2019. Characterization and utilization of hydrothermal carbonization aqueous phase as nutrient source for microalgal growth. Bioresource technology, 290: 121758.
  • Benelli P, Riehl CAS, Jr AS, Smânia EFA, Ferreira SRS. 2010. Bioactive extracts of orange (Citrus sinensis L. Osbeck) pomace obtained by SFE and low pressure techniques: mathematical modeling and extract composition. J. Supercrit. Fluids, 55: 132–141.
  • Benemann J. 2013. Microalgae for biofuels and animal feeds. Energies, 6: 5869–5886.
  • Bhatnagar A, Chinnasamy S, Singh M, & Das KC. 2011. Renewable biomass production by mixotrophic algae in the presence of various carbon sources and wastewaters. Applied Energy, 88(10): 3425-3431.
  • Biller P, Ross AB, Skill SC, Lea-Langton A, Balasundaram B, Hall C, Riley R, Llewellyn CA. 2012. Nutrient recycling of aqueous phase for microalgae cultivation from the hydrothermal liquefaction process. Algal Res., 1: 70–76
  • Bligh EG, & Dyer WJ. 1959. A rapid method of total lipid extraction and purification. Canadian journal of biochemistry and physiology, 37(8): 911-917.
  • Du Z, Hu B, Shi A, Ma X, Cheng Y, Chen P, ... & Ruan R. 2012. Cultivation of a microalga Chlorella vulgaris using recycled aqueous phase nutrients from hydrothermal carbonization process. Bioresource technology, 126: 354-357.
  • Dubois M, Gilles KA, Hamilton JK, Rebers PA and Smith F. 1956. Colorimetric method for determination of sugars and related substances. Anal. Chem., 28: 350-356.
  • Erdogan E, Atila B, Mumme J, Reza MT, Toptas A, Elibol M, & Yanik J. 2015. Characterization of products from hydrothermal carbonization of orange pomace including anaerobic digestibility of process liquor. Bioresource technology, 196: 35-42.
  • Gibbons G, Goad L and Goodwin T. 1968. The identification of 28-isofucosterol in the marine green algae Enteromorpha intestinalis and Ulva lactuca. Phytochemistry, 7: 983–988.
  • Giordano M, Kansiz M, Heraud P, Beardall J, Wood B, McNaughton D. 2001. Fourier transform infrared spectroscopy as a novel tool to investigate changes in intracellular macromolecular pools in the marine microalga Chaetoceros muellerii (bacillariophyceae). J Phycol, 37: 271–279.
  • Grobbelaar JU. 2004. Algal nutrition. In: Richmond A, editor. Handbook of microalgal culture: biotechnology and applied phycology. Oxford: Blackwell, pp. 97–115.
  • Hastings A, Clifton-Brown J, Wattenbach M, Mitchell CP, Stampfl P, Smith P. 2009. Future energy potential of Miscanthusin Europe. GCB Bioenergy, 1: 180–96.
  • Hillier J, Whittaker C, Dailey G, Aylott M, Casella E, Richter GM, et al. 2009. Greenhouse gas emissions from four bioenergy crops in England and Wales: integrating spatial estimates of yield and soil carbon balance in life cycle analyses. GCB Bioenergy, 1: 267–81.
  • Hoshino M, Tanaka M, Terada A, Sasaki M, Goto M. 2009. Separation and Characterization of Pectin from Juice Processing Residue Extracted By Sub- Critical Water. The 5th ISFR.
  • Jena U, Vaidyanathan N, Chinnasamy S, & Das KC. 2011. Evaluation of microalgae cultivation using recovered aqueous co-product from thermochemical liquefaction of algal biomass. Bioresource technology, 102(3): 3380-3387.
  • Karbowiak T, Ferret E, Debeaufort F, et al. 2011. Investigation of water transfer across thin layer biopolymer films by infrared spectroscopy. Journal of Membrane Science, 370: 82–90.
  • Khan SA, Malla FA, Malav LC, Gupta N, & Kumar A. 2018. Potential of wastewater treating Chlorella minutissima for methane enrichment and CO2 sequestration of biogas and producing lipids. Energy, 150: 153-163.
  • Lowry OH, Rosebrough NJ, Lewis Farr A, Randall RJ. 1951. Protein measurement with Folin phenol reagent. J. Biol. Chem., 193 (1): 265–275.
  • Maddi B, Panisko E, Wietsma T, Lemmon T, Swita M, Albrecht K, & Howe D. 2017. Quantitative characterization of aqueous byproducts from hydrothermal liquefaction of municipal wastes, food industry wastes, and biomass grown on waste. ACS Sustainable Chemistry & Engineering, 5(3): 2205-2214.
  • Madsen RB, Biller P, Jensen MM., Becker J, Iversen BB, & Glasius M. 2016. Predicting the chemical composition of aqueous phase from hydrothermal liquefaction of model compounds and biomasses. Energy & Fuels, 30(12): 10470-10483.
  • Marinovic A, Pileidis FD, & Titirici MM. 2015. Hydrothermal carbonisation (HTC): history, state-of-the-art and chemistry. Porous Carbon Materials from Sustainable Precursors, 32: 129.
  • Molino A, Iovine A, Casella P, Mehariya S, Chianese S, Cerbone A, Rimauro J, Musmarra D. 2018. Microalgae characterization for consolidated and new application in human food, animal feed and nutraceuticals. Int. J. Environ. Res. Public Health, 15: 1–21.
  • Oswald WJ. 1988. Large-scale algal culture systems (engineering aspects). In: Borowitzka MA, Borowitzka LJ (eds), Micro- Algal Biotechnology. Cambridge: Cambridge Univ. Press, pp. 357–394.
  • Ozcimen D, Missaoui A, Bostyn S, Belandria V, Gökalp I. 2019. Characterization of solid and aqueous phase products from hydrothermal carbonization of orange pomace. 2nd International Symposium on Hydrothermal Carbonization, Berlin, Germany.
  • Panisko E, Wietsma T, Lemmon T, Albrecht K, & Howe D. 2015. Characterization of the aqueous fractions from hydrotreatment and hydrothermal liquefaction of lignocellulosic feedstocks. Biomass and Bioenergy, 74: 162-171.
  • Radhika D and Mohaideen A. 2015. Fourier transform infrared analysis of Ulva lactuca and Gracilaria corticata and their effect on antibacterial activity. Asian Journal of Pharmaceutical and Clinical Research, 8: 209–212.
  • Rai LC, Gour JP, Kumar HD. 1981. Phycology and heavy metal pollution. Biol. Rev., 56: 99–151.
  • Richmond A. 1986. Handbook of microalgal mass culture. Boca Raton, Florida: CRC Press, 528 pp.
  • Rivas-Cantu RC, Jones KD, & Mills PL. 2013. A citrus waste-based biorefinery as a source of renewable energy: technical advances and analysis of engineering challenges. Waste management & research, 31(4): 413-420.
  • Sharma AK, Sahoo PK, Singhal S, & Patel A. 2016. Impact of various media and organic carbon sources on biofuel production potential from Chlorella spp. 3 Biotech, 6(2): 116.
  • Tam NFY, Wong YS. 1995. Wastewater treatment with microorganisms. Hong Kong: The commercial Press (H.K.) Ltd. 2D Finnie St. Quarry Bay.
  • Wang L, Min M, Li Y, Chen P, Chen Y, Liu Y & Ruan R. 2010. Cultivation of green algae Chlorella sp. in different wastewaters from municipal wastewater treatment plant. Applied biochemistry and biotechnology, 162(4): 1174-1186.
  • Wang X, Chen Q, Lü X. 2014. Pectin extracted from apple pomace and citrus peel by subcritical water. Food Hydrocolloids, 38: 129–137.
  • Wijngaard H, Brunton N. 2009. The optimization of extraction of antioxidants from apple pomace by pressurized liquids. J. Agric. Food Chem., 57: 10625–10631.
  • Wijngaard H, Hossain MB, Rai DK, Brunton N. 2012. Techniques to extract bioactive compounds from food by-products of plant origin. Food Res. Int., 46: 505–513.
  • Yang J, Cao J, Xing G, & Yuan H. 2015. Lipid production combined with biosorption and bioaccumulation of cadmium, copper, manganese and zinc by oleaginous microalgae Chlorella minutissima UTEX2341. Bioresource technology, 175: 537-544.
  • Yu S, Forsberg Å, Kral K, & Pedersén M. 1990. Furfural and Hydroxymethylfurfural inhibition of growth and photosynthesis in Spirulina. British Phycological Journal, 25(2): 141-148.
There are 38 citations in total.

Details

Primary Language English
Subjects Chemical Engineering
Journal Section Research Articles
Authors

Seray Zora Tarhan

Anıl Tevfik Koçer

Didem Özçimen

Iskender Gökalp

Publication Date June 22, 2020
Acceptance Date June 5, 2020
Published in Issue Year 2020 Volume: 3 Issue: 1

Cite

APA Zora Tarhan, S., Koçer, A. T., Özçimen, D., Gökalp, I. (2020). Utilization of hydrothermal process water for microalgae growth. Eurasian Journal of Biological and Chemical Sciences, 3(1), 42-47.
AMA Zora Tarhan S, Koçer AT, Özçimen D, Gökalp I. Utilization of hydrothermal process water for microalgae growth. Eurasian J. Bio. Chem. Sci. June 2020;3(1):42-47.
Chicago Zora Tarhan, Seray, Anıl Tevfik Koçer, Didem Özçimen, and Iskender Gökalp. “Utilization of Hydrothermal Process Water for Microalgae Growth”. Eurasian Journal of Biological and Chemical Sciences 3, no. 1 (June 2020): 42-47.
EndNote Zora Tarhan S, Koçer AT, Özçimen D, Gökalp I (June 1, 2020) Utilization of hydrothermal process water for microalgae growth. Eurasian Journal of Biological and Chemical Sciences 3 1 42–47.
IEEE S. Zora Tarhan, A. T. Koçer, D. Özçimen, and I. Gökalp, “Utilization of hydrothermal process water for microalgae growth”, Eurasian J. Bio. Chem. Sci., vol. 3, no. 1, pp. 42–47, 2020.
ISNAD Zora Tarhan, Seray et al. “Utilization of Hydrothermal Process Water for Microalgae Growth”. Eurasian Journal of Biological and Chemical Sciences 3/1 (June 2020), 42-47.
JAMA Zora Tarhan S, Koçer AT, Özçimen D, Gökalp I. Utilization of hydrothermal process water for microalgae growth. Eurasian J. Bio. Chem. Sci. 2020;3:42–47.
MLA Zora Tarhan, Seray et al. “Utilization of Hydrothermal Process Water for Microalgae Growth”. Eurasian Journal of Biological and Chemical Sciences, vol. 3, no. 1, 2020, pp. 42-47.
Vancouver Zora Tarhan S, Koçer AT, Özçimen D, Gökalp I. Utilization of hydrothermal process water for microalgae growth. Eurasian J. Bio. Chem. Sci. 2020;3(1):42-7.