[1]Velmurugan R, Incharoensakdi A. Nanoparticle mediated NADPH regeneration for enhanced ethanol pro- duction

by engineered Synechocystis sp. PCC 6803. bioRxiv. 2019.

[2]Xu Y, Wang X, Fu Y, et al. Interaction energy and

detachment of magnetic nanoparticles-algae. Environ Technol.

2019: 29:1–7.

[3]Zhang X, Yan S, Tyagi RD, et al. Biodiesel production

from heterotrophic microalgae through transesterification and

nanotechnology application in the pro- duction. Renew Sustain

Energy Rev. 2013; 26: 216–223.

[4]Sarma SJ, DAS RK, Brar SK, et al. Application of

magnesium sulfate and its nanoparticles for enhanced lipid

production by mixotrophic cultivation of algae using biodiesel

waste. Energy. 2014; 78: 16–22.

[5]Golueke CG, Oswald WJ, Gotaas HB. Anaerobic

diges- tion of algae. Appl Microbiol. 1957; 5(1): 47.

[6]Khalid M, Johnson E, Vij A, et al. Anaerobic digestion

restricted to phase I for nutrient release and energy production

using waste-water grown Chlorella vulgaris. Chem Eng J.

2018; 352: 756–764.

[7]Ehimen E, Sun Z, Carrington C, et al. Anaerobic

digestion of microalgae residues resulting from the biodiesel

production process. Appl Energy. 2011; 88(10): 3454–3463.

[8]Hern´andez ES, Co´rdoba LT. Anaerobic digestion of

Chlorella vulgaris for energy production. Resources Conserv

Recycl. 1993; 9: 127–132.

[9]Chakraborty D, Mohan SV. Effect of food to vege- table

waste ratio on acidogenesis and methanogenesis during twostage integration. Bioresource Technol. 2018; 254: 256–263.

[10]Ding L, Gutierrez EC, Cheng J, et al. Assessment of

continuous fermentative hydrogen and methane co- production

using macro-and micro-algae with increasing organic loading

rate. Energy. 2018; 151: 760–770.

合作支持单位

数据库合作单位