Net-Zero/Positive Energy Buildings and Districts

© 2022 by the authors; CC BY-NC-ND license

energy storage; hydrogen; power-to-gas; reversible solid oxide cell; optimization; mixed integer linear programming; MILP; microgrid; PV; peer to peer; self-consumption; energy community; local market; PVT; water-based PVT; techno-economic analysis; digital mapping; seasonal thermal energy storage; waste incineration; district heating; waste heat; energy retrofit; heat pump; CO₂ emissions; building stock; PED; energy flexibility; socioeconomic analysis; techno-economic analysis; regions; regulation; renewable energy; energy storage; urban environment; climatic zones; gaussian mixture model; Expectation-Maximization; urban building energy modeling; data acquisition; building optimisation design; Saharan; cool climate; genetic algorithm; low energy buildings; digital mapping; spatial; temporal; energy use; smart city; net‐ and nearly‐zero‐energy buildings; positive energy communities and districts; renewable energy integration; energy flexibility in buildings and communities; simulation and optimization methods; practical experience from demo sites; buildings; construction; efficient homes; energy efficiency; GHG emissions; homes; net-zero energy (NZE); NZE building technology; positive energy districts; citizen; cities; participation; citizen engagement; PED; stakeholder engagement; urban energy transition; bi-directional grid; urban photovoltaic systems; energy communities; agent based modelling; techno-economic modelling; market design; distributed renewable energy; PED; characterization; review; text mining; nearly zero-energy building; renewable energy integration; container building; building design; energy simulation; climate study; renewable energy; plus energy buildings; plus energy districts; energy communities; energy sharing; energy trading; clean energy package; n/a