Journal of Fundamentals of Renewable Energy and Applications

Journal of Fundamentals of Renewable Energy and Applications
Open Access

ISSN: 2090-4541

+44 1300 500008

Cellulose-based films for electronics: Enzymatic triggered degradation for metal recovery


Euro-Global Summit and Expo on Biomass

August 08-09, 2016 Birmingham, UK

Alvaro Cruz-Izquierdo

University of Bath, UK

Scientific Tracks Abstracts: J Fundam Renewable Energy Appl

Abstract :

Cellulose, the most abundant polymer in nature, is composed of glucose units with the resulting linear polymeric chains having both inter- and intra-chain hydrogen bonding in the crystalline polymer. In recent years, ionic liquids have been shown to be exceptional solvents for cellulose and thus hold great promise as biomass pre-treatment media. Additionally, the reconstitution of cellulose after ionic liquid not only facilitates formation of films, but also the pre-treatment increases enzymatic digestibility by cellulases. Different fillers can be also added to cellulose in order to give new properties to the regenerated films, such as greater flame retardancy or hydrophobicity. The aim of this work is to develop new cellulose-based films in order to use them as printing board for electronics. In this way, this new bio-based scaffold will hold conductive ink and different metals that are found in electronics. Moreover, an enzymatic treatment with cellulases will decompose the cellulose scaffolds and will facilitate the recovery of the precious metals in the material. In this work, �±-cellulose was solubilized by 1-ethyl-3-methylimidazolium acetate and cellulose films were obtained by phase inversion and treated with different fillers (e.g. laponite, amonium polyphosphate) and hydrophobizing agents (e.g. ethyl 2-cyanoacrylate, lignin). Different enzymatic studies were carried out in order to understand how they are affected by added fillers, agents and most metals found in e-waste. Moreover, a particular effort was made in order to develop specific method to use lignin as hydrophobizing agent.

Biography :

Álvaro Cruz-Izquierdo has completed his PhD in Enzymatic Biosynthesis of Biodiesel and Biopolymers in 2013 from University of Basque Country (Spain). He has worked on bio-based technology in the last 8 years and also has teaching experience on Molecular Biology, Enzymology and Analytical Chemistry. He currently works as Research Associate at the Centre for Sustainable Chemical Technologies at the University of Bath in the framework of CLEVER (Closed Loop Emotionally Valuable E-waste Recovery) project lead by Dr Janet L. Scott.

Email: A.Cruz-Izquierdo@bath.ac.uk

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