In the first half of the 21st century, a soaring urban population posed serious problems for the environment, health and infrastructure of many cities. In newly industrialised nations especially, urban centres became polluted, overcrowded and chronically inefficient. Throughout the world, metropolitan areas grew to unprecedented sizes – putting huge and increasing pressure on city planners to adapt.*
Amid worsening climate change and resource depletion, urban regions were forced to either evolve, or die off. Countless cities failed to make this transition in time, and went the way of Detroit, many being abandoned and left to decay, or subject to intense military control and martial law. In those that survived, a new generation of buildings and infrastructure emerged based on these rapidly changing social and environmental needs.*
Among the most important trends in modern architecture has been self-sufficiency. By 2050, environmental and resource degradation have become so obvious and huge, it has triggered a radical rethink of production and consumption by citizens. As such, many modern skyscrapers now come complete with the internalised creation of food, water and other resources. Farms often comprise multiple floors of a tower – regardless of its purpose – while rain, mist and condensation are constantly trapped and stored. Advanced 3D printers are available locally on site to manufacture everything from household furniture, to personal transportation, to replacement parts for the building itself. Energy is typically provided by photovoltaics and wind turbines. These are often integrated seamlessly into the building design, so as not to harm the aesthetic appeal. Solar power, for instance, can be collected by window panes or special photovoltaic paints applied to outside surfaces.* The efficiencies for solar have been improving steadily for decades.*
Nature features heavily in these structures. Many towers incorporate parks and sky gardens, helping to increase the overall biodiversity of a city, with numerous bird and small animal species finding homes and nesting places. Careful environmental controls ensure that these creatures are protected while not becoming a nuisance for human residents. The outside of buildings are often covered with vegetation, or special membranes, designed to filter pollutants and capture CO2.* Government regulations now require a large percentage of buildings to be fitted in this way, making it a dominant style of architecture today. The artificial parts of this outer layer can also adjust to wind conditions, temperatures, moisture levels and sunlight in order to produce optimal thermal comfort for the human and animal occupants. Algae bio-fuel cells adorning the facade can also absorb CO2 while acting as an additional source of electricity.*
Buildings are integrated into the city around them in a number of ways. Fuel restrictions and other factors have led to increasingly socialised transportation. The bottom floors of most towers have dedicated public car share (AI controlled) and bike share facilities, while bus and other mass transit stations are often built into the structures themselves. Pedestrian sky-walkways feature heavily in most modern cities, improving access and permeability of the urban realm, while shielding walkers from the elements. If ornamented with foliage, they can also function as elevated parks and gardens.
Buildings are making cities more comfortable and inviting in various other ways. By tightly controlling a tower's reflectivity, heat absorption and heat balance, for example, planners can significantly reduce the temperatures associated with urban heat island effects. This comes at a time when temperatures in less developed cities are soaring from the combined effects of climate change and urbanisation.*
The average modern building in 2050 is seamlessly integrated into a city's power supply, acting as another node in a city-wide smart grid. Nearly all buildings are able to transmit locally produced energy back into the system. Wireless electricity transfer is also common, with energy beamed invisibly between buildings, which eliminates the need for unsightly poles and cables. AI systems within each building direct its total power consumption, adjusting according to the varying needs of occupants and taking into account even the most minor of details.
Overall, this new smart infrastructure is helping to drastically improve the nature of urban living. Cities following this model are becoming far more liveable, clean, efficient and modernised. Though many regions have collapsed into chaos, others are now leading the way in providing a more sustainable path for humanity.
Amid worsening climate change and resource depletion, urban regions were forced to either evolve, or die off. Countless cities failed to make this transition in time, and went the way of Detroit, many being abandoned and left to decay, or subject to intense military control and martial law. In those that survived, a new generation of buildings and infrastructure emerged based on these rapidly changing social and environmental needs.*
Among the most important trends in modern architecture has been self-sufficiency. By 2050, environmental and resource degradation have become so obvious and huge, it has triggered a radical rethink of production and consumption by citizens. As such, many modern skyscrapers now come complete with the internalised creation of food, water and other resources. Farms often comprise multiple floors of a tower – regardless of its purpose – while rain, mist and condensation are constantly trapped and stored. Advanced 3D printers are available locally on site to manufacture everything from household furniture, to personal transportation, to replacement parts for the building itself. Energy is typically provided by photovoltaics and wind turbines. These are often integrated seamlessly into the building design, so as not to harm the aesthetic appeal. Solar power, for instance, can be collected by window panes or special photovoltaic paints applied to outside surfaces.* The efficiencies for solar have been improving steadily for decades.*
Nature features heavily in these structures. Many towers incorporate parks and sky gardens, helping to increase the overall biodiversity of a city, with numerous bird and small animal species finding homes and nesting places. Careful environmental controls ensure that these creatures are protected while not becoming a nuisance for human residents. The outside of buildings are often covered with vegetation, or special membranes, designed to filter pollutants and capture CO2.* Government regulations now require a large percentage of buildings to be fitted in this way, making it a dominant style of architecture today. The artificial parts of this outer layer can also adjust to wind conditions, temperatures, moisture levels and sunlight in order to produce optimal thermal comfort for the human and animal occupants. Algae bio-fuel cells adorning the facade can also absorb CO2 while acting as an additional source of electricity.*
Buildings are integrated into the city around them in a number of ways. Fuel restrictions and other factors have led to increasingly socialised transportation. The bottom floors of most towers have dedicated public car share (AI controlled) and bike share facilities, while bus and other mass transit stations are often built into the structures themselves. Pedestrian sky-walkways feature heavily in most modern cities, improving access and permeability of the urban realm, while shielding walkers from the elements. If ornamented with foliage, they can also function as elevated parks and gardens.
Buildings are making cities more comfortable and inviting in various other ways. By tightly controlling a tower's reflectivity, heat absorption and heat balance, for example, planners can significantly reduce the temperatures associated with urban heat island effects. This comes at a time when temperatures in less developed cities are soaring from the combined effects of climate change and urbanisation.*
The average modern building in 2050 is seamlessly integrated into a city's power supply, acting as another node in a city-wide smart grid. Nearly all buildings are able to transmit locally produced energy back into the system. Wireless electricity transfer is also common, with energy beamed invisibly between buildings, which eliminates the need for unsightly poles and cables. AI systems within each building direct its total power consumption, adjusting according to the varying needs of occupants and taking into account even the most minor of details.
Overall, this new smart infrastructure is helping to drastically improve the nature of urban living. Cities following this model are becoming far more liveable, clean, efficient and modernised. Though many regions have collapsed into chaos, others are now leading the way in providing a more sustainable path for humanity.
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