Utilization of the aqueous phase of the hydrothermal liquefaction process as a substrate for microalgae cultivation

S. V. Klementev; Клементьев С. В.; E. A. Budenkova; Буденкова Е. А.; Yu. V. Kulikova; Куликова Ю. В.; A. S. Sirotkin; Сироткин А. С.

doi:10.21285/achb.940

Utilization of the aqueous phase of the hydrothermal liquefaction process as a substrate for microalgae cultivation

Autores: Klementev S.V.¹, Budenkova E.A.², Kulikova Y.V.², Sirotkin A.S.¹
Afiliações:
1. Kazan National Research Technological University
2. Immanuel Kant Baltic Federal University
Edição: Volume 14, Nº 4 (2024)
Páginas: 537-547
Seção: Physico-chemical biology
URL: https://journal-vniispk.ru/2227-2925/article/view/302278
DOI: https://doi.org/10.21285/achb.940
EDN: https://elibrary.ru/EFTDQV
ID: 302278

Citar

Texto integral

Resumo
Sobre autores
Bibliografia
Arquivos suplementares
Estatísticas

Resumo

The article presents the culturing of nine microalgae strains from the IPPAS collection of IFR RAS using components of the aqueous phase of the excessive activated sludge hydrothermal revitalization process as a substrate. In order to select the most promising cultures, their growth characteristics and efficient removal of NH4+ ions, PO43- and organic compounds were studied. All the studied cultures are shown to be able to utilize components of the aqueous phase as a nutrient substrate. The highest specific growth rate of 0.92 day-1 was observed in the strain Chlorella sp. IPPAS C-1210. However, the Parachlorella kessleri IPPAS C-9 and Chlorella minutissima IPPAS C-123 strains were also promising in terms of their efficiency of pollutant removal from the medium: efficiency of ammonium nitrogen assimilation was 78 and 81%, while phosphate ion assimilation was 89 and 91%, respectively. The biomass composition of C-9 and C-123 cultures was investigated, mainly consisting of polysaccharides – at 41 and 44% – and proteins – at 31 and 25% of the total mass, respectively. A high degree of neutralization of the medium was additionally achieved as a result of consecutive two-stage purification of the aqueous phase of the process of hydrothermal revitalization of excessive activated sludge with the use of microorganisms-destructors (Paenarthrobacter nicotinovorans and Comamonas testosteroni) and the studied microalgae cultures. During 17 days of the purification process, the concentration of ammonium ions decreased from 289.8±14.9 to 51.1±2.2 mg/dm3, phosphates from 116.3±8.1 to 11.3 mg/dm3; the overall efficiency of the process of pollutants removal from the aqueous phase was up to 90%.

Palavras-chave

microalgae, hydrothermal liquefaction, water phase, growth characteristics

Bibliografia

Aktas K., Liu H., Eskicioglu C. Treatment of aqueous phase from hydrothermal liquefaction of municipal sludge by adsorption: comparison of biochar, hydrochar, and granular activated carbon // Journal of Environmental Management. 2024. Vol. 356. P. 120619. doi: 10.1016/j.jenvman.2024.120619.
Basar I.A., Liu H., Eskicioglu C. Incorporating hydrothermal liquefaction into wastewater treatment – Part III: Aqueous phase characterization and evaluation of on-site treatment // Chemical Engineering Journal. 2023. Vol. 467. P. 143422. doi: 10.1016/j.cej.2023.143422.
Liu H., Lyczko N., Nzihou A., Eskicioglu C. Incorporating hydrothermal liquefaction into wastewater treatment – Part II: Characterization, environmental impacts, and potential applications of hydrochar // Journal of Cleaner Production. 2023. Vol. 383. P. 135398. doi: 10.1016/j.jclepro.2022.135398.
Liew C.S., Yunus N.M., Chidi B.S., Lam M.K., Goh P.S., Mohamad M., et al. A review on recent disposal of hazardous sewage sludge via anaerobic digestion and novel composting // Journal of Hazardous Materials. 2022. Vol. 423. P. 126995. doi: 10.1016/j.jhazmat.2021.126995.
Yu J., Audu M., Myint M.T., Cheng F., Jarvis J.M., Jena U., et al. Bio-crude oil production and valorization of hydrochar as anode material from hydrothermal liquefaction of algae grown on brackish dairy wastewater // Fuel Processing Technology. 2022. Vol. 227. P. 107119. doi: 10.1016/j.fuproc.2021.107119.
Leng L., Zhang W., Leng S., Chen J., Yang L., Li H., et al. Bioenergy recovery from wastewater produced by hydrothermal processing biomass: progress, challenges, and opportunities // Science of the Total Environment. 2020. Vol. 748. P. 142383. doi: 10.1016/j.scitotenv.2020.142383.
Watson J., Wang T., Si B., Chen W.-T., Aierzhati A., Zhang Y. Valorization of hydrothermal liquefaction aqueous phase: pathways towards commercial viability // Progress in Energy and Combustion Science. 2020. Vol. 77. P. 100819. doi: 10.1016/j.pecs.2019.100819.
Yuan C., Zhao S., Ni J., He Y., Cao B., Hu Y. Integrated route of fast hydrothermal liquefaction of microalgae and sludge by recycling the waste aqueous phase for microalgal growth // Fuel. 2023. Vol. 334. P. 126488. doi: 10.1016/j.fuel.2022.126488.
Chen L., Zhu T., Martinez Fernandez J.S., Chen S., Li D. Recycling nutrients from a sequential hydrothermal liquefaction process for microalgae culture // Algal Research. 2017. Vol. 27. P. 311–317. doi: 10.1016/j.algal.2017.09.023.
Ramírez-Romero A., Martin M., Boyer A., Bolzoni R., Matricon L., Sassi J.-F., et al. Microalgae adaptation as a strategy to recycle the aqueous phase from hydrothermal liquefaction // Bioresource Technology. 2023. Vol. 371. P. 128631. doi: 10.1016/j.biortech.2023.128631.
Belete Y.Z., Leu S., Boussiba S., Zorin B., Posten C., Thomsen L., et al. Characterization and utilization of hydrothermal carbonization aqueous phase as nutrient source for microalgal growth // Bioresource Technology. 2019. Vol. 290. P. 121758. doi: 10.1016/j.biortech.2019.121758.
Orfield N.D., Fang A.J., Valdez P.J., Nelson M.C., Savage P.E., Lin X.N., et al. Life cycle design of an algal biorefinery featuring hydrothermal liquefaction: effect of reaction conditions and an alternative pathway including microbial regrowth // ACS Sustainable Chemistry & Engineering. 2014. Vol. 2, no. 4. P. 867–874. doi: 10.1021/sc4004983.
Jayakody L.N., Johnson C.W., Whitham J.M., Giannone R.J., Black B.A., Cleveland N.S., et al. Thermochemical wastewater valorization via enhanced microbial toxicity tolerance // Energy & Environmental Science. 2018. Vol. 11, no. 6. P. 1625–1638. doi: 10.1039/C8EE00460A.
Shende A., Nan W., Kodzomoyo E., Shannon J., Nicpon J., Shende R. Evaluation of aqueous product from hydrothermal liquefaction of cardboard as bacterial growth medium: co-liquefaction of cardboard and bacteria for higher bio-oil production // Journal of Sustainable Bioenergy System. 2017. Vol. 7, no. 2. P. 51–64. doi: 10.4236/jsbs.2017.72005.
He Y., Li X., Xue X., Swita M.S., Schmidt A.J., Yang B. Biological conversion of the aqueous wastes from hydrothermal liquefaction of algae and pine wood by Rhodococci // Bioresource Technology. 2017. Vol. 224. P. 457–464. doi: 10.1016/j.biortech.2016.10.059.
Клементьев С.В., Сироткин А.С., Хасанова А.А., Куликова Ю.В. Обезвреживание компонентов водной фазы гидротермального ожижения избыточного активного ила в биосорбционных системах // Бутлеровские сообщения. 2024. Т. 77. № 3. С. 113–121. doi: 10.37952/ROI-jbc-01/24-77-3-113. EDN: HIZMCU.
Синетова М.А., Сидоров Р.А., Стариков А.Ю., Воронков А.С., Медведева А.С., Кривова З.В.. Характеристика биотехнологического потенциала штаммов цианобактерий и микроводорослей коллекции IPPAS // Биотехнология. 2019. Т. 35. N 3. С. 12–29. doi: 10.21519/0234-2758-2019-35-3-12-29. EDN: HVYYGM.
Pérez-Rodriguez S., Ramírez O.T., Trujillo-Roldán M.A., Valdez-Cruz N.A. Comparison of protein precipitation methods for sample preparation prior to proteomic analysis of Chinese hamster ovary cell homogenates // Electronic Journal of Biotechnology. 2020. Vol. 48. P. 86–94. doi: 10.1016/j.ejbt.2020.09.006.
Leyva A., Quintana A., Sánchez M., Rodríguez E.N., Cremata J., Sánchez J.C. Rapid and sensitive anthrone-sulfuric acid assay in microplate format to quantify carbohydrate in biopharmaceutical products: method development and validation // Biological. 2008. Vol. 36, no. 2. P. 134–141. doi: 10.1016/j.biologicals.2007.09.001.
SundarRajan P., Gopinath K.P., Arun J., Grace-Pavithra K., Adithya Joseph A., Manasa S. Insights into valuing the aqueous phase derived from hydrothermal liquefaction // Renewable and Sustainable Energy Reviews. 2021. Vol. 144. P. 111019. doi: 10.1016/j.rser.2021.111019.
Parsy A., Monlau F., Guyoneaud R., Sambusiti C. Nutrient recovery in effluents from the energy sectors for microalgae and cyanobacteria biomass production: a review // Renewable and Sustainable Energy Reviews. 2024. Vol. 191. P. 114207. doi: 10.1016/j.rser.2023.114207.
Hasan M.R., Chakrabarti R. Use of algae and aquatic macrophytes as feed in small-scale aquaculture: a review. Rome: Food AND Agriculture Organization of the United Nations, 2009. 135 p.
Ratha S.K., Renuka N., Abunama T., Rawat I., Bux F. Hydrothermal liquefaction of algal feedstocks: the effect of biomass characteristics and extraction solvents // Renewable and Sustainable Energy Reviews. 2022. Vol. 156. P. 111973. doi: 10.1016/j.rser.2021.111973.
Haider M.S., Castello D., Rosendahl L.A. Twostage catalytic hydrotreatment of highly nitrogenous biocrude from continuous hydrothermal liquefaction: a rational design of the stabilization stage // Biomass and Bioenergy. 2020. Vol. 139. P. 105658 doi: 10.1016/j.biombioe.2020.105658.

Arquivos suplementares

Ação

1. JATS XML

Baixar

Nome de usuário
Senha
Lembrar usuário

Esqueceu a senha?	Cadastro

Nome de usuário
Senha
Lembrar usuário

Esqueceu a senha?	Cadastro

Volume 14, Nº 4 (2024)

Utilization of the aqueous phase of the hydrothermal liquefaction process as a substrate for microalgae cultivation

Texto integral

Resumo

Palavras-chave

Sobre autores

S. Klementev

E. Budenkova

Yu. Kulikova

A. Sirotkin

Bibliografia

Arquivos suplementares