Sustainable Façades

Europe is currently facing urgent challenges to meet the climate crisis, challenges which have been accelerated and become a priority item after the start of the COVID-19 pandemic. Such challenges are best summarised by President of the European Commission, Ursula von der Leyen, whose ambition is to build a “a resilient, green, and digital Europe”.

The European construction and façade sectors are facing these challenges, by leading façade engineering consultants addressing them initially and governmental initiative and legation following. The key challenge is achieving netZero carbon buildings, a requirement which is gradually being implemented in European building regulations to meet the 2050 strategy for a net Zero Europe, an initiative that stems in turn from the “European green deal” (European Union 2021) and the recent Paris agreement (United Nations 2015). The debate net Zero carbon for European buildings and facades revolves around the balance between the “embodied” carbon (i.e., the sum of all fuel-related and process-related carbon emissions for a specific product or service, normally measured from cradle to gate, i.e. before entering in operation, (Hammond and Jones 2011) and operational carbon(Hacker et al. 2008), i.e., carbon emission used to operate the building through its lifespan. In the last decades the focus for facades has been on improving operational carbon usage, however, the embodied carbon of the construction materials is currently becoming more important in determining which products can be used on buildings.

In this scenario, research and development play a fundamental role, as existing problems require innovative solutions and methodical processes to resolve the complex challenges, which are often interconnected. Transforming research into practice has always been a fine art, which is impeded by a series of obstacles, for example introduction of new material vs long term warranties; doing so in the construction and façade sectors, commonly known for their risk-aversion, makes the situation even harder. The aim of this paper is to show a series of European research and development activities that, despite being started before the pandemic, are currently emerging as a result of the above-mentioned and renewed European ambitions. This paper will first show how aluminium is currently recycled to unprecedented levels in an attempt to reduce embodied carbon in facades, based on a series of internal research and development efforts and investments from a major aluminium manufacturer. Secondly, it will be shown how currently there is a debate in Europe about increasing the thermal performance of the transparent envelope by adopting triple glazed units. It will be reviewed the latest academic research to help support the decision-making process. The paper will conclude and summarize the key findings from the European research and development activities with current challenges and future perspective regarding the next ambitions for a more sustainable future in Europe.

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