Showing total 2 results

1. Artificial cellulosic leaf with adjustable enzymatic CO 2 sequestration capability.

Author

Zhu X, Du C, Gao B, and He B

Subjects

Ecosystem, Plant Stomata metabolism, Photosynthesis, Light, Carbon Dioxide metabolism, Carbon Dioxide chemistry, Plant Leaves metabolism, Cellulose metabolism, Cellulose chemistry, Carbon Sequestration

Abstract

Developing artificial leaves to address the environmental burden of CO 2 is pivotal for advancing our Net Zero Future. In this study, we introduce EcoLeaf, an artificial leaf that closely mimics the characteristics of natural leaves. It harnesses visible light as its sole energy source and orchestrates the controlled expansion and contraction of stomata and the exchange of petiole materials to govern the rate of CO 2 sequestration from the atmosphere. Furthermore, EcoLeaf has a cellulose composition and mechanical strength similar to those of natural leaves, allowing it to seamlessly integrate into the ecosystem during use and participate in natural degradation and nutrient cycling processes at the end of its life. We propose that the carbon sequestration pathway within EcoLeaf is adaptable and can serve as a versatile biomimetic platform for diverse biogenic carbon sequestration pathways in the future., (© 2024. The Author(s).)

Published

2024

2. Engineered microbial biofuel production and recovery under supercritical carbon dioxide.

Author

Boock JT, Freedman AJE, Tompsett GA, Muse SK, Allen AJ, Jackson LA, Castro-Dominguez B, Timko MT, Prather KLJ, and Thompson JR

Subjects

Bacillus megaterium metabolism, Butanols metabolism, Fermentation, Hemiterpenes, Keto Acids metabolism, Pentanols metabolism, Biofuels, Carbon Dioxide metabolism

Abstract

Culture contamination, end-product toxicity, and energy efficient product recovery are long-standing bioprocess challenges. To solve these problems, we propose a high-pressure fermentation strategy, coupled with in situ extraction using the abundant and renewable solvent supercritical carbon dioxide (scCO 2 ), which is also known for its broad microbial lethality. Towards this goal, we report the domestication and engineering of a scCO 2 -tolerant strain of Bacillus megaterium, previously isolated from formation waters from the McElmo Dome CO 2 field, to produce branched alcohols that have potential use as biofuels. After establishing induced-expression under scCO 2 , isobutanol production from 2-ketoisovalerate is observed with greater than 40% yield with co-produced isopentanol. Finally, we present a process model to compare the energy required for our process to other in situ extraction methods, such as gas stripping, finding scCO 2 extraction to be potentially competitive, if not superior.

Published

2019