Luisa Blaesing scite author profile

Luisa Blaesing

3Publications

33Citation Statements Received

111Citation Statements Given

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TU Bergakademie Freiberg

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Electrochemical Recycling of Photovoltaic Modules to Recover Metals and Silicon Wafers

Modrzynski

Blaesing

Hippmann

et al. 2021

Chemie Ingenieur Technik

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An electrochemical‐assisted leaching process using boron‐doped diamond (BDD) electrodes was developed to recover valuable metals from photovoltaic modules. With BDD electrodes peroxydisulfate is generated from sulfuric acid to oxidatively dissolve copper, tin and silver from solar cell contacts. Since the oxidant is regenerated in the developed process, no additional hazardous and volatile chemicals are required, and the process can be operated solely by electricity. In addition, the dissolved metals can be electrochemically recovered at the cathode of the same cell.

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Lignin from Annual Plants as Raw Material Source for Flavors and Basic Chemicals

Jahn

Hoffmann

Blaesing

et al. 2020

Chemie Ingenieur Technik

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The enzymatic conversion of lignins, possibly in combination with electrochemical oxidation, makes aromatics such as syringol, guaiacol, vanillin and catechol available in the qualities required by the fragrance industry. The lignins were obtained by soda digestion from wheat straw and Miscanthus, characterized and then converted with laccases. The overall yield amounted up to 9 wt % with a product spectrum confined to four substances. Catechol was the major product, with a fraction of 75 %. It can easily be isolated by extraction with acetone.

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Liquid Membranes for Efficient Recovery of Phenolic Compounds Such as Vanillin and Catechol

et al. 2020

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Investigations were carried out to obtain different lignin monomers such as vanillin and catechol as efficiently as possible, to prevent side reactions e.g., during lignin degradation. Therefore, extraction experiments were performed to determine the influence of parameters such as initial pH in the aqueous phase, organic phases containing alcohols or solvating extractants, and monomer concentrations. Cyanex 923 (Cy923) and tri-n-butyl-phosphat (TBP) diluted in kerosene were the organic phases chosen to evaluate the transport of vanillin because of their high efficiencies (>76.8%) and suitability in membrane technologies. The most efficient vanillin transport was accomplished with Cy923, as > 90% of vanillin was transferred after 5 h. However, the permeability coefficient at carrier concentration of > 0.48 mol/L was influenced not only by the diffusion but also by the organic mixture viscosity. Thus, this concentration was used in the membrane experiment containing a mixture of vanillin and catechol in the feed phase. Catechol was transported about 7% faster to the receiving phase than vanillin, presumably due to its chemical structure. Side reactions were avoided using the current liquid membrane set-up, allowing the further industrial application of an entire process, which, e.g., recovers vanillin from enzymatic lignin conversion by membrane technology.

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Luisa Blaesing

Electrochemical Recycling of Photovoltaic Modules to Recover Metals and Silicon Wafers

Lignin from Annual Plants as Raw Material Source for Flavors and Basic Chemicals

Liquid Membranes for Efficient Recovery of Phenolic Compounds Such as Vanillin and Catechol

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