Engineers and architects are exploring an innovative solution to the world’s energy storage challenges through towering skyscrapers capable of holding vast amounts of power. These ambitious designs are being developed by Skidmore, Owings & Merrill (SOM), a global architecture and engineering firm, in collaboration with Energy Vault, a pioneering energy storage company. Together, they aim to integrate gravity-based energy storage systems into the design of skyscrapers, creating buildings that not only serve as urban landmarks but also contribute to renewable energy infrastructure.
SOM’s skyscrapers could reach heights up to 1,000 meters—nearly three times the height of London’s iconic Shard. The idea of combining energy storage with urban architecture marks a significant step forward in the push for sustainable development. This novel concept of using buildings as massive storage devices leverages gravity batteries, an emerging technology that promises to address the challenge of energy storage in an environmentally sustainable way.
Gravity batteries store energy by using the excess electricity generated from renewable sources like solar or wind to power a system that lifts heavy weights within the building. This energy is stored as gravitational potential energy, ready to be converted back into electricity when needed by lowering the weight. This technology is seen as an efficient and environmentally friendly alternative to conventional batteries, which rely on resource-intensive materials like lithium.
Bill Baker, an engineer at SOM and a leading figure in the development of the project, emphasized the potential of these skyscrapers to accelerate the carbon payback period of buildings, making them more environmentally sustainable over their lifespan. “These buildings could play a critical role in addressing two major challenges facing urban development: energy storage and carbon emissions,” Baker explained, noting that the inclusion of gravity-based energy storage systems can drastically reduce a building’s carbon footprint.
The partnership between SOM and Energy Vault was announced earlier this year, and the concept is gaining traction in both architectural and environmental circles. Energy Vault, known for its work in gravity energy storage, has already made waves in the energy sector with its innovative use of gravity to store renewable energy. By partnering with SOM, the firm is taking its vision to new heights—literally—by embedding its technology into urban architecture.
While the concept of gravity-based energy storage is still relatively new, it is viewed as a promising alternative to more conventional forms of energy storage like lithium-ion batteries. Unlike chemical-based batteries, gravity batteries have the advantage of being low-maintenance and long-lasting. They rely on basic physical principles, making them simpler to implement and scale. Moreover, they do not degrade over time like traditional batteries, which is a significant advantage in terms of long-term sustainability.
One of the most appealing aspects of this technology is its adaptability. Gravity batteries can be built into existing infrastructure, or in this case, integrated directly into new skyscraper designs. This means that cities can begin to incorporate energy storage solutions into their very fabric, rather than relying solely on grid-based energy storage systems that are often located outside urban areas. In dense, energy-hungry cities, this could provide a much-needed boost to renewable energy adoption by making energy storage more accessible.
SOM’s skyscraper designs are still in the prototype stage, but they have already sparked significant interest. The buildings are envisioned as both functional and visually striking, with the potential to become new symbols of sustainable urban development. At a time when cities around the world are grappling with how to reduce their carbon footprints and become more energy-efficient, these gravity-powered skyscrapers could provide a solution that meets both aesthetic and environmental needs.
However, challenges remain. The initial cost of constructing such skyscrapers, particularly with the integrated gravity battery system, is expected to be high. Developers will need to weigh the long-term environmental and economic benefits against the upfront financial investment. Nonetheless, proponents of the technology argue that the cost could be offset by the savings in energy and carbon emissions over the building’s lifespan.
Another issue is the scalability of the technology. While the concept works well in theory and small-scale trials, implementing it in skyscrapers across major cities will require extensive testing and refinement. Factors like building materials, weight distribution, and energy conversion efficiency need to be carefully considered. However, SOM and Energy Vault remain optimistic about the project’s future, pointing to the global shift towards renewable energy as a strong motivator for continued innovation.
The potential benefits extend beyond energy storage. These skyscrapers could also serve as models for a new generation of smart buildings that are self-sustaining and energy-efficient. By integrating renewable energy storage with modern architecture, cities could drastically reduce their dependence on fossil fuels, cutting emissions and promoting sustainable growth. This would not only improve the quality of life in urban areas but also set a global standard for sustainable development in the 21st century.
While the United Kingdom is one potential market for these towering energy storage solutions, other regions may be quicker to adopt the technology. Countries with large-scale urbanization projects and a strong focus on renewable energy, such as those in the Middle East or East Asia, could be more likely to invest in these energy-storing skyscrapers as they seek to diversify their energy portfolios and meet growing energy demands.