Anticipatory Life Cycle Assessment of sol-gel derived anti-reflective coating for greenhouse glass

Environmental analysis should be performed early in the Research and Development (R&D) phases of new technologies to timely determine potential impact and, thereby, include prevention and minimization of unfavorable ecological impact into the innovation process. Here, we demonstrate the applicat...

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Bibliographic Details
Published in:Journal of cleaner production 2019-06, Vol.221, p.365-376
Main Authors: Tsoy, Natalya, Prado, Valentina, Wypkema, Aike, Quist, Jaco, Mourad, Maurice
Format: Article
Language:English
Subjects:
Anti-reflective coating
Anticipatory LCA
Dip coating
Greenhouse glass
Scale-up
Scenarios
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Summary:Environmental analysis should be performed early in the Research and Development (R&D) phases of new technologies to timely determine potential impact and, thereby, include prevention and minimization of unfavorable ecological impact into the innovation process. Here, we demonstrate the application of anticipatory Life Cycle Assessment (LCA) on novel anti-reflective coatings used for greenhouses in the Netherlands. Currently, these coating technologies are developed at the laboratory scale (lab-scale), but they have the potential to be transferred to commercial scale on the short term. What-if scenarios have been used to scale-up the coating production process to pilot and industrial scales. The scenarios were developed by optimizing the laboratory scale coating production parameters. A cradle-to-grave LCA has been done to compare novel coatings with conventional coatings. The functional unit has been defined as the production of 1692.30 kg of tomatoes in greenhouses during 30 years. Results indicate that the novel coating manufactured at industrial scale can compete with conventional coatings in terms of the environmental performance. Furthermore, LCA shows that the novel coating assessed does not bring environmental benefits as compared to employing uncoated glass. However, the use of the glass coating in the greenhouse may bring economic benefits during functional lifetime by means of increased yield of crop (e.g. tomatoes). Different pathways of the technological development of the novel coating have been considered in the sensitivity analysis. The option that includes glass manufacturing in the Netherlands rather than China has led to the best environmental impact results. •LCA was used to guide coating innovation towards decreased environmental burden.•Scenarios were used to scale-up coating production from lab-scale to larger scales.•The LCA results of novel and conventional coatings were within the same magnitude.•Change of the location for the glass production significantly affected LCA results.
ISSN:0959-6526
1879-1786
DOI:10.1016/j.jclepro.2019.02.246