Your search keyword '"Frauke Kracke"' showing total 4 results

1. Designing a Zn–Ag Catalyst Matrix and Electrolyzer System for CO 2 Conversion to CO and Beyond

Author

John M. Gregoire, Alfred M. Spormann, McKenzie A. Hubert, Frauke Kracke, Victor A. Beck, Marc Fontecave, Lei Wang, Dong Un Lee, Thomas F. Jaramillo, Sarah E. Baker, Christopher Hahn, Jaime E. Aviles Acosta, David W. Wakerley, Lan Zhou, Eric B. Duoss, Sarah Lamaison, and Thomas A. Moore

Subjects

Electrolysis, Materials science, Gas diffusion electrode, Mechanical Engineering, Halide, Electrolyte, Electrocatalyst, Catalysis, law.invention, chemistry.chemical_compound, Chemical engineering, chemistry, Mechanics of Materials, law, Electrode, General Materials Science, Carbon monoxide

Abstract

CO2 emissions can be transformed into high-added-value commodities through CO2 electrocatalysis; however, efficient low-cost electrocatalysts are needed for global scale-up. Inspired by other emerging technologies, the authors report the development of a gas diffusion electrode containing highly dispersed Ag sites in a low-cost Zn matrix. This catalyst shows unprecedented Ag mass activity for CO production: -614 mA cm-2 at 0.17 mg of Ag. Subsequent electrolyte engineering demonstrates that halide anions can further improve stability and activity of the Zn-Ag catalyst, outperforming pure Ag and Au. Membrane electrode assemblies are constructed and coupled to a microbial process that converts the CO to acetate and ethanol. Combined, these concepts present pathways to design catalysts and systems for CO2 conversion toward sought-after products.

Published

2021

2. Nontoxic, Hydrophilic Cationic Polymers-Identified as Class of Antimicrobial Polymers

Author

Frauke Kracke, Anna Jemeljanova, Arne Strassburg, Hanne Petersen, Jannis Kuepper, Julia Wenners, and Joerg C. Tiller

Subjects

chemistry.chemical_classification, Biocide, Polymers and Plastics, Chemistry, Cationic polymerization, Bioengineering, Polymer, Antimicrobial, Biomaterials, chemistry.chemical_compound, Minimum inhibitory concentration, Amphiphile, Materials Chemistry, Polyquaternium, Organic chemistry, Selectivity, Biotechnology

Abstract

Amphiphilic polycations are an alternative to biocides but also toxic to mammalian cells. Antimicrobially active hydrophilic polycations based on 1,4-dibromo-2-butene and tetramethyl-1,3-propanediamine named PBI are not hemotoxic for porcine red blood cells with a hemocytotoxicity (HC50) of more than 40,000 μg · mL(-1). They are quickly killing bacterial cells at their MIC (minimal inhibitory concentration). The highest found selectivity HC50 /MIC is more than 20,000 for S. epidermidis. Investigations on sequentially prepared PBIs with defined molecular weight Mn and tailored end groups revealed that there is a dependence of antimicrobial activity and selectivity on Mn and nature of the end groups.

Published

2015

3. Cover Picture: Electrifying White Biotechnology: Engineering and Economic Potential of Electricity-Driven Bio-Production (ChemSusChem 5/2015)

Author

Falk Harnisch, Bernardino Virdis, Frauke Kracke, Jens O. Krömer, and Luis F. M. Rosa

Subjects

Engineering, General Energy, business.industry, Natural resource economics, General Chemical Engineering, Environmental Chemistry, Industrial chemistry, Production (economics), General Materials Science, Nanotechnology, Electricity, business, Economic potential

Published

2015

4. Electrifying White Biotechnology: Engineering and Economic Potential of Electricity-Driven Bio-Production

Author

Falk Harnisch, Jens O. Krömer, Bernardino Virdis, Luis F. M. Rosa, and Frauke Kracke

Subjects

business.industry, General Chemical Engineering, Electrons, Cost savings, Biotechnology, Electric energy, Electrification, Engineering, General Energy, Electricity, Market potential, Electrochemistry, Production (economics), Biochemical reactions, Environmental science, Environmental Chemistry, General Materials Science, business, Economic potential

Abstract

The production of fuels and chemicals by electricity-driven bio-production (i.e., using electric energy to drive biosynthesis) holds great promises. However, this electrification of white biotechnology is particularly challenging to achieve because of the different optimal operating conditions of electrochemical and biochemical reactions. In this article, we address the technical parameters and obstacles to be taken into account when engineering microbial bioelectrochemical systems (BES) for bio-production. In addition, BES-based bio-production processes reported in the literature are compared against industrial needs showing that a still large gap has to be closed. Finally, the feasibility of BES bio-production is analysed based on bulk electricity prices. Using the example of lysine production from sucrose, we demonstrate that there is a realistic market potential as cost savings of 8.4 % (in EU) and 18.0 % (in US) could be anticipated, if the necessary yields can be obtained.

Published

2015