Blockchain: A New Tool to Accelerate the Global Energy Transformation
But cryptocurrencies are only one application of blockchain (which is in itself an example of distributed ledger technology), and for many, the Bitcoin hype is merely a distraction from the transformative potential that blockchain technology could offer to a wide range of industries, including energy.
Blockchain was one of the big topics of conversation in September 2018 at IRENA Innovation Week, where more than 400 corporate leaders, government officials and experts at the forefront of energy gathered to discuss the innovations driving the energy transformation forward.
A blockchain is, in a basic sense, a secure, continuously growing list of records. It is constructed as a decentralised database that is distributed and managed by peers, rather than by a central server or authority. This technology is enabling a new world of decentralised communication and coordination, by building the infrastructure to allow peers to safely and quickly connect with each other without a centralised intermediary. Cryptography ensures security and data integrity, while privacy remains intact.
Greater complexity requires greater network intelligence, transparency and visibility
To understand the disruptive potential of blockchain to the energy sector, consider how electricity is generated. By and large, most countries rely on large, centralised power plants that generate electricity and then send it across long distances over power grids that were built as a one-way street, sending electricity from the producer to your home. Moreover, the markets in which grids operate are complex multi-party interactions involving grid operators, energy companies, and energy producers that run on a country-wide level.
Today, grids have become increasingly complex, with increasing shares of variable distributed generation (such as rooftop solar), increasing numbers of internet-connected devices (such as smart appliances), and increased loads from the influx of electric vehicles. Blockchain can help operate power grids with high penetration of variable distributed generation and flexible demand-side resources in a more efficient, automated way, all with lower transaction costs.
Blockchain can allow system operators of distributed generation to optimise grid operation by managing all connected devices through automated smart contracts, enabling flexibility and real-time pricing. Blockchain also empowers consumers to become ‘prosumers’ by enabling them to monetise their excess electricity (generated by rooftop solar for example) by securely recording data and sending and receiving payments automatically, through smart contracts built on platforms such as Ethereum.
Increased digitalization and interconnection have led to increased risks with regards to security. Blockchain, due to its distributed nature, can greatly increase the security of a network if implemented correctly. In coordination with burgeoning technologies such as AI, blockchain can play an important role is securing networks and grids.
An explosion of startups, but a long road ahead
Since the start of 2017 alone, more than fifty new startups launched that are working specifically on energy, raising more than USD$320 million. Today, there are more than 70 demonstration projects deployed or planned around the world, such as LO3’s Brooklyn Microgrid project, where customers can choose to power their homes from a range of renewable energy sources, and people with their own solar panels can sell surplus electricity to their neighbors. Another, from German power giant RWE, is using the Ethereum blockchain to authenticate users and manage billing at electric car charging stations.
But there’s still a way to go before blockchain is mature enough to play a major role in the energy sector. One major hurdle is the fact that the energy sector is highly regulated and widespread adoption of blockchain will require a clear, stable regulatory framework. While there are early signs of progress, such as Ofgem’s roundtable on UK blockchain regulation in September of last year, Singapore’s launch of a sandbox for energy innovations, and new legislation in US states like Vermont to help apply blockchain technology, the regulatory environment still needs to be defined.
Another is a more fundamental question around the consensus mechanism that blockchains use. Because blockchains are decentralised, they need some way to make collective decisions that are quick, secure, and trustworthy. Right now, there are a number of different ways to do this, including ‘proof of work’, which relies on increasingly computationally expensive (and energy-intense) puzzle solving, and ‘proof of stake’, which relies on those with the largest stake in the network to add the next block of transactions to the blockchain, and ‘proof of authority’, which relies on the identity of validators to function as their stake, among others. As yet, all of these mechanisms continue to be developed and none has been fully proven to be 100% reliable, secure, scalable and energy efficient, yet the potential risks—ranging from billion-dollar hacking losses to power-sucking coal-powered bitcoin mines—are huge.
However, new consensus protocols are being developed and tested all the time. As the technology matures, software platforms built on blockchain will be an increasingly attractive method to handle the increasingly complex and decentralised transactions between energy users, producers of various sizes, traders and utilities, and retailers. Furthermore, blockchain’s ability to autonomously reconcile supply and demand between meters and computers based on smart contracts is a revolutionary efficiency improvement.
This makes it well-suited to support an energy system of the future that is renewables-based, decentralised and distributed, digital, and democratic. The real relevance and impact of blockchain in the energy sector remains to be seen. How the technology and its application matures in coming years is going to be an exciting part of the story of the global energy transformation.Back to overview
Source IRENA 2018