利用太阳光培养微藻生产甲烷的 haloalkaline 生物转化。

Haloalkaline Bioconversions for Methane Production from Microalgae Grown on Sunlight.

机构信息

Department of Biotechnology, Delft University, Delft, The Netherlands.

Department of Biotechnology, Delft University, Delft, The Netherlands; Winogradsky Institute of Microbiology, Research Center of Biotechnology, Russian Academy of Sciences, Moscow, Russia.

出版信息

Trends Biotechnol. 2016 Jun;34(6):450-457. doi: 10.1016/j.tibtech.2016.02.008. Epub 2016 Mar 8.

DOI:10.1016/j.tibtech.2016.02.008

PMID:26968613

Abstract

Microalgal biomass can be converted to biofuels to replace nonsustainable fossil fuels, but the widespread use of microalgal biofuels remains hampered by the high energetic and monetary costs related to carbon dioxide supply and downstream processing. Growing microalgae in mixed culture biofilms reduces energy demands for mixing, maintaining axenic conditions, and biomass concentration. Furthermore, maintaining a high pH improves carbon dioxide absorption rates and inorganic carbon solubility, thus overcoming the carbon limitation and increasing the volumetric productivity of the microalgal biomass. Digesting the microalgal biomass anaerobically at high pH results in biogas that is enriched in methane, while the dissolved carbon dioxide is recycled to the phototrophic reactor. All of the required haloalkaline conversions are known in nature.

摘要

微藻生物质可以转化为生物燃料，以替代不可持续的化石燃料，但由于二氧化碳供应和下游处理相关的高能源和货币成本，微藻生物燃料的广泛应用仍然受到阻碍。在混合培养生物膜中培养微藻可以降低混合、保持无菌条件和生物质浓缩所需的能源。此外，保持高 pH 值可以提高二氧化碳吸收率和无机碳溶解度，从而克服碳限制，提高微藻生物质的体积生产率。在高 pH 值下进行厌氧消化可以得到富含甲烷的沼气，同时将溶解的二氧化碳循环回光合反应器。所有需要的卤代碱转化在自然界中都是已知的。

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利用太阳光培养微藻生产甲烷的 haloalkaline 生物转化。

Haloalkaline Bioconversions for Methane Production from Microalgae Grown on Sunlight.

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