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This Special Issue aims at reporting current investigations on emerging materials and devices taking up the challenge of pursuing a significant improvement in the energy performance of buildings and indoor comfort. What is the contribution of innovative technologies in the epochal transition to low environmental impact buildings? This is the question addressed in this Special Issue, in order to offer a wide and heterogeneous amount of data to readers, along with results of high scientific impact concerning the application of innovative technologies in construction. The 2015 Paris Agreement on climate change following the COP 21 Conference on Climate Change, organized by United Nations, required the States to reduce carbon emissions in the building stock. In the European Union, almost 50% of final energy consumption is used for heating and cooling; out of this huge amount, 80% is used in buildings. It makes sense, then, that the Union’s goals are inherently linked to the real effort to renovate the building stock. To do this, in the EU and worldwide, the priority is to enhance energy efficiency, by deploying low-cost renewable energies and innovative technologies, especially those derived from recent achievements in the field of nanomaterials research, with special reference to building integration of novel technologies, spanning from chromogenics to semitransparent photovoltaics, super-insulating materials, and phase change materials. Articles here proposed deal with every construction or plant component of the building organism, taking advantage of novel technologies to improve their performance, from the envelope to structures, HVAC, and other technical systems, as well as indoor climate analyses in buildings and indoor environmental quality (IEQ), as well as visual comfort indoors.

Technology: general issues --- window frame --- granular aerogel --- energy saving --- IEQ --- bioaerosols --- airborne bacteria --- airborne fungi --- ozone --- portable air purifier --- ozone generation --- biomimetics --- building skin --- multifunctionality --- architectural design --- building envelope --- adaptability --- design framework --- building performance simulation --- renewable energy --- perovskite solar cells --- BIPV --- semi-transparent --- challenges --- indoor air quality (IAQ) --- CO2 production rate --- CO2 concentration --- occupancy estimation --- demand controlled ventilation (DCV) --- energy efficiency --- Cu-Zn-Al --- shape memory --- SMA --- seismic --- ausforming --- transformation temperatures --- super elasticity --- microstructure --- ventilated facade --- second-skin materials --- 3D printed materials --- additive manufacturing --- TRNSYS --- full-scale facility --- retrofit action --- deep reinforcement learning --- optimal control --- optimization --- HYBUILD --- thermal energy storage --- residential buildings --- noise pollution --- environmental factors --- property prices --- genetic algorithm --- residential market --- phase change materials --- hybrid ventilated school building --- indoor thermal comfort --- thermal management --- energy conservation --- window frame --- granular aerogel --- energy saving --- IEQ --- bioaerosols --- airborne bacteria --- airborne fungi --- ozone --- portable air purifier --- ozone generation --- biomimetics --- building skin --- multifunctionality --- architectural design --- building envelope --- adaptability --- design framework --- building performance simulation --- renewable energy --- perovskite solar cells --- BIPV --- semi-transparent --- challenges --- indoor air quality (IAQ) --- CO2 production rate --- CO2 concentration --- occupancy estimation --- demand controlled ventilation (DCV) --- energy efficiency --- Cu-Zn-Al --- shape memory --- SMA --- seismic --- ausforming --- transformation temperatures --- super elasticity --- microstructure --- ventilated facade --- second-skin materials --- 3D printed materials --- additive manufacturing --- TRNSYS --- full-scale facility --- retrofit action --- deep reinforcement learning --- optimal control --- optimization --- HYBUILD --- thermal energy storage --- residential buildings --- noise pollution --- environmental factors --- property prices --- genetic algorithm --- residential market --- phase change materials --- hybrid ventilated school building --- indoor thermal comfort --- thermal management --- energy conservation

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

This Special Issue aims at reporting current investigations on emerging materials and devices taking up the challenge of pursuing a significant improvement in the energy performance of buildings and indoor comfort. What is the contribution of innovative technologies in the epochal transition to low environmental impact buildings? This is the question addressed in this Special Issue, in order to offer a wide and heterogeneous amount of data to readers, along with results of high scientific impact concerning the application of innovative technologies in construction. The 2015 Paris Agreement on climate change following the COP 21 Conference on Climate Change, organized by United Nations, required the States to reduce carbon emissions in the building stock. In the European Union, almost 50% of final energy consumption is used for heating and cooling; out of this huge amount, 80% is used in buildings. It makes sense, then, that the Union’s goals are inherently linked to the real effort to renovate the building stock. To do this, in the EU and worldwide, the priority is to enhance energy efficiency, by deploying low-cost renewable energies and innovative technologies, especially those derived from recent achievements in the field of nanomaterials research, with special reference to building integration of novel technologies, spanning from chromogenics to semitransparent photovoltaics, super-insulating materials, and phase change materials. Articles here proposed deal with every construction or plant component of the building organism, taking advantage of novel technologies to improve their performance, from the envelope to structures, HVAC, and other technical systems, as well as indoor climate analyses in buildings and indoor environmental quality (IEQ), as well as visual comfort indoors.

window frame --- granular aerogel --- energy saving --- IEQ --- bioaerosols --- airborne bacteria --- airborne fungi --- ozone --- portable air purifier --- ozone generation --- biomimetics --- building skin --- multifunctionality --- architectural design --- building envelope --- adaptability --- design framework --- building performance simulation --- renewable energy --- perovskite solar cells --- BIPV --- semi-transparent --- challenges --- indoor air quality (IAQ) --- CO2 production rate --- CO2 concentration --- occupancy estimation --- demand controlled ventilation (DCV) --- energy efficiency --- Cu-Zn-Al --- shape memory --- SMA --- seismic --- ausforming --- transformation temperatures --- super elasticity --- microstructure --- ventilated facade --- second-skin materials --- 3D printed materials --- additive manufacturing --- TRNSYS --- full-scale facility --- retrofit action --- deep reinforcement learning --- optimal control --- optimization --- HYBUILD --- thermal energy storage --- residential buildings --- noise pollution --- environmental factors --- property prices --- genetic algorithm --- residential market --- phase change materials --- hybrid ventilated school building --- indoor thermal comfort --- thermal management --- energy conservation --- n/a