Intensified technology for microalgal CO2 fixation and conversion from flue gas

Abstract

Abstract: Microalgae has the strong ability to convert CO2 into cellular lipid product，better environmental adaptability，higher photosynthetic efficiency and the higher reproduction rate. Therefore，carbon dioxide fixation by microalgae has become one of the effective solutions to greenhouse effect and energy crisis. The bottle neck of this technology lies in the low efficiency of CO2 fixation and conversion into cellular lipid product. This paper introduced the process of CO2 fixation and conversion into organic carbon components of microalgae cell. The progresses on intensified fixation and conversion of CO2 from flue gas，including the stimulated CO2 fixation and conversion into lipid，the intensified CO2 fixation by membrane technology in a photobioreactor and the coupling of various technologies. The application of biotechnology and the membrane technology in microalgae field were elaborated and discussed. This paper also discussed the integration of microalgae biotechnology，membrane technology and the coupling of other technologies，in order to investigate further improvement of the fixation and conversion of CO2 from flue gas by microalgae，showing its importance of research directions for the microalgal CO2 fixation and conversion from flue gas in the future.

Key words: microalgae, flue gas, CO2 fixation and conversion, biotechnology, membrane technology

摘要： 全球气候变暖和能源危机是21世纪影响人类生存发展的重要问题。微藻由于具有利用太阳能、固定CO2并转化为油脂等产物的能力以及环境适应性强、光合效率高、繁殖快等优势，微藻固碳技术有望成为缓解温室效应和能源危机的有效方法之一，但是该技术目前仍存在去除烟气CO2转化油脂效率低的问题。本文分析了微藻固碳过程中碳传递转化途径，介绍了强化微藻固定与转化烟气CO2的技术研究，包括微藻固碳与转化油脂的生物强化、微藻固定CO2的反应器强化、微藻固定与转化CO2技术的耦合，重点讨论了强化微藻固碳与转化的生物技术和膜技术研究现状及存在问题。最后指出微藻固碳的生物技术、膜技术及其他多技术的耦合有望进一步提升烟气CO2的高效固定与转化，是强化微藻固定转化烟气CO2的重要研究方向。

关键词: 微藻, 烟气, CO2固定转化, 生物技术, 膜技术

JIANG Jiawei1，CHENG Lihua1，XU Xinhua1，ZHANG Lin2，CHEN Huanlin2. Intensified technology for microalgal CO2 fixation and conversion from flue gas[J]. Chemical Industry and Engineering Progree.

姜加伟1，程丽华1，徐新华1，张林2，陈欢林2 . 微藻固定转化烟气CO2强化技术[J]. 化工进展.

[1]	Guohua SHI, Linshen HE, Xiling ZHAO, Shigang ZHANG. Study of removal characteristics of particulate matters within flue gas by spray tower for waste-heat recovery [J]. CIESC Journal, 2023, 74(4): 1735-1745.
[2]	Shaozhuang WANG, Dunxi YU, Jiayi LI, Jingkun HAN, Xin YU, Fangqi LIU. Effects of torrefaction with flue gas on grindability of corn stalk [J]. CIESC Journal, 2023, 74(2): 861-870.
[3]	Caifeng LI, Xiao WANG, Gangjian LI, Junzhang LIN, Weidong WANG, Qinglin SHU, Yanbin CAO, Meng XIAO. Synergistic relationship between hydrocarbon degrading and emulsifying strain SL-1 and endogenous bacteria during oil displacement [J]. CIESC Journal, 2022, 73(9): 4095-4102.
[4]	Yujun MA, Xiangjun LIU. Theoretical studies of water recovery from flue gas by using ceramic membrane [J]. CIESC Journal, 2022, 73(9): 4103-4112.
[5]	Jiaming WANG, Xuehua RUAN, Gaohong HE. Research progress of membrane separation materials for different industrial CO₂-containing mixtures [J]. CIESC Journal, 2022, 73(8): 3417-3432.
[6]	Chao JI, Wei LIU, Hong QI. Flue gas dehumidification through air cooling enhanced by hydrophobic ceramic membranes [J]. CIESC Journal, 2022, 73(5): 2174-2182.
[7]	Xiaosong HOU, Chenxing LIU, Ailing REN, Bin GUO, Yuanming GUO. Study on purification of toluene waste gas by ultrasonic atomization/surfactants-enhanced absorption coupled with biological scrubbing [J]. CIESC Journal, 2022, 73(10): 4692-4706.
[8]	Wei SONG, Jinhui WANG, Guipeng HU, Xiulai CHEN, Liming LIU, Jing WU. Cascade catalysis for the synthesis of (R)-β-tyrosine [J]. CIESC Journal, 2022, 73(1): 352-361.
[9]	YIN Zijun, SU Sheng, QING Mengxia, ZHAO Zhigang, WANG Zhonghui, WANG Lele, JIANG Long, WANG Yi, HU Song, XIANG Jun. Study on SO₃ formation characteristics of a typical vanadium titanium SCR catalyst [J]. CIESC Journal, 2021, 72(5): 2596-2603.
[10]	MAO Jinzhu, XIAO Shuling, YANG Zhichun, WANG Xiaoyu, ZHANG Shi, CHEN Junhong, XIE Jisheng, CHEN Fude, HUANG Zinuo, FENG Tianyu, ZHANG Aihui, FANG Baishan. Application of synthetic biology in pesticides residues detection [J]. CIESC Journal, 2021, 72(5): 2413-2425.
[11]	YOU Yang, LIU Yingshu, YANG Xiong, WU Xiaoyong, ZHAO Chunyu, WANG Zheng, HOU Huanyu, LI Ziyi. A new adsorption process for flue gas NO_x purification and recovery [J]. CIESC Journal, 2021, 72(4): 2132-2138.
[12]	YANG Lin, MENG Xiaomi, YAO Lu, LAI Yuguo, JIANG Wenju. Combined low-temperature flue gas denitrification and desulfurization over the natural mineral blending modified activated coke [J]. CIESC Journal, 2021, 72(4): 2241-2248.
[13]	ZHANG Hao, DONG Yong, LAI Yanhua, CUI Lin, YANG Xiao. Simulation and experimental analysis on dehumidification and white smoke removal of coal-fired flue gas in falling-film plate used in WESP [J]. CIESC Journal, 2021, 72(4): 2249-2257.
[14]	Nan SU, Yinan WU, Yinyee TAN, Lihua JIN, Chong ZHANG, Aikawa SHIMPEI, Hasunuma TOMOHISA, Kondo AKIHIKO, Xinhui XING. Comparative omics study of Spirulinaplatensis mutants based on ARTP mutagenesis breeding system [J]. CIESC Journal, 2021, 72(12): 6298-6310.
[15]	Yi ZHOU,Yonghong WANG,Xinru ZHANG,Jinping LI. Preparation of PEBA/N, S co-doped porous carbon sphere mixed matrix membrane for CO₂ separation [J]. CIESC Journal, 2021, 72(10): 5237-5246.

Intensified technology for microalgal CO2 fixation and conversion from flue gas

微藻固定转化烟气CO2强化技术

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments