一种用于节能型食物生产的混合无机-生物人工光合作用系统。

A hybrid inorganic-biological artificial photosynthesis system for energy-efficient food production.

机构信息

Center for Industrial Biotechnology, Department of Chemical and Environmental Engineering, University of California, Riverside, CA, USA.

Center for Plant Cell Biology, Department of Botany and Plant Sciences, University of California, Riverside, CA, USA.

出版信息

Nat Food. 2022 Jun;3(6):461-471. doi: 10.1038/s43016-022-00530-x. Epub 2022 Jun 23.

DOI:10.1038/s43016-022-00530-x

PMID:37118051

Abstract

Artificial photosynthesis systems are proposed as an efficient alternative route to capture CO to produce additional food for growing global demand. Here a two-step CO electrolyser system was developed to produce a highly concentrated acetate stream with a 57% carbon selectivity (CO to acetate), allowing its direct use for the heterotrophic cultivation of yeast, mushroom-producing fungus and a photosynthetic green alga, in the dark without inputs from biological photosynthesis. An evaluation of nine crop plants found that carbon from exogenously supplied acetate incorporates into biomass through major metabolic pathways. Coupling this approach to existing photovoltaic systems could increase solar-to-food energy conversion efficiency by about fourfold over biological photosynthesis, reducing the solar footprint required. This technology allows for a reimagination of how food can be produced in controlled environments.

摘要

人工光合作用系统被提议作为一种有效的替代途径来捕获 CO，以生产额外的食物来满足全球不断增长的需求。在这里，开发了一种两步 CO 电解系统，以生产具有 57%碳选择性（CO 到乙酸盐）的高浓度乙酸盐流，允许其直接用于酵母、蘑菇生产真菌和光合绿藻的异养培养，在没有生物光合作用输入的情况下在黑暗中进行。对九种作物的评估发现，来自外源供应的乙酸盐的碳通过主要代谢途径掺入生物量。将这种方法与现有的光伏系统相结合，可以使太阳能到食物的能量转换效率比生物光合作用提高约四倍，从而减少所需的太阳能足迹。这项技术为如何在受控环境中生产食物提供了新的思路。

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一种用于节能型食物生产的混合无机-生物人工光合作用系统。

A hybrid inorganic-biological artificial photosynthesis system for energy-efficient food production.

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