As the world moves towards cleaner energy, the traditional power grid requires transformative changes. The emergence of a 'supergrid' aims to connect nations, leveraging optimal renewable energy sources geographically. Although promising in counteracting severe climate change effects, the development of such infrastructure faces practical challenges, particularly due to political and logistical issues.

From the historical reliance on Thomas Edison’s direct current to Nikola Tesla’s alternating current, technological innovation has continuously increased transmission capacity. Today, advancements in high-voltage direct current (HVDC) technology promise efficient long-distance electricity movement, imperative for the integration of renewable energy. Europe has made progress with interconnectors linking various countries, enabling shared renewable resources; however, similar initiatives in the United States encounter bureaucratic and societal hurdles.

Main takeaways from the video:

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Key Vocabularies and Common Phrases:

1. decarbonization [ˌdiːˈkɑːrbənaɪˌzeɪʃən] - (noun) - The process of reducing carbon dioxide emissions resulting from human activities, particularly those from burning fossil fuels. - Synonyms: (decarbonisation, carbon reduction, carbon removal)

We are seeing so many countries and governments announcing high targets when it comes to decarbonization and being climate neutral.

2. interconnectors [ˌɪntərkəˈnektərz] - (noun) - Physical infrastructure that links separate electrical grids, allowing for the exchange of electricity between them. - Synonyms: (connections, links, joiners)

interconnectors let countries take advantage of renewable energy wherever it's being generated.

3. eminent domain [ˈɛmɪnənt doʊˈmeɪn] - (noun) - The right of a government or its agent to expropriate private property for public use, with compensation. - Synonyms: (expropriation, compulsory purchase, land acquisition)

If he waited and they actually filed eminent domain papers, then the value of what he could get out of that deal would fall tremendously

4. Alternating Current (Ac) [ˈɔːltərˌneɪtɪŋ ˈkʌrənt] - (noun) - An electric current that reverses its direction many times a second at regular intervals. - Synonyms: (AC power, alternating flow, reversible current)

Tesla came up with the idea of an alternating current, which doesn't just flow in one direction, it keeps alternating back and forth on a cable.

5. Direct Current (Dc) [dəˈrɛkt ˈkʌrənt] - (noun) - An electric current flowing in one direction only and used primarily for low-voltage applications. - Synonyms: (DC power, unidirectional flow, constant current)

DC Power, the loser of the 19th century current wars, is making a comeback.

6. High Voltage Direct Current (Hvdc) [haɪ ˈvoʊltɪdʒ dəˈrɛkt ˈkʌrənt] - (noun) - An electricity transmission system using direct current, which is capable of transmitting large amounts of electricity over long distances with minimal loss. - Synonyms: (high-voltage DC, HV DC, high-energy DC)

The solution that has become a consensus in the industry now is to use direct current, or more specifically, high voltage direct current.

7. surplus power [ˈsɜːrpləs ˈpaʊər] - (noun) - Excess electricity that is generated but not consumed within the intended distribution area and is available for external sale or storage. - Synonyms: (excess power, additional energy, surplus energy)

An interconnector allows surplus power that isn't used in the UK to be transmitted over to France.

8. ambitious [æmˈbɪʃəs] - (adjective) - Having a strong desire for success or achievement, or difficult to achieve. - Synonyms: (aspiring, determined, visionary)

It's an ambitious and potentially transformative plan, but it's not even close to the biggest idea coming out of Asia.

9. evolve [ɪˈvɒlv] - (verb) - To develop gradually, especially from a simple to a more complex form. - Synonyms: (develop, progress, transform)

As the grid's evolved, we have had to cooperate on larger and larger scales.

10. leverage [ˈlɛvərɪdʒ] - (verb) - To use something to maximum advantage. - Synonyms: (utilize, exploit, capitalize on)

I have no leverage

The World Needs Supergrids, But There's a Problem

Most of us don't spend much time thinking about the grid, the dizzyingly huge system of cables, transformers and outlets that reliably powers our lives. It's an easily ignored, change resistant part of the modern world, and that's the way we like it. But as we move towards less planet melting ways of producing electricity, the grid is going to have to evolve too. We are seeing so many countries and governments announcing high targets when it comes to decarbonization and being climate neutral. But this is just one side of the coin. It's not enough to simply generate green energy. We also need to make sure that this transmitted and distributed to the end consumers.

The grid of today just isn't equipped for renewables. So a new kind of grid is. Is starting to take shape. The supergrid. The idea behind a supergrid is basically a grid that connects nations, not just different parts of a country. And the goal is to try and maximize the use of renewables wherever they are generating electricity. It's an ambitious idea, and one that could be necessary to avoid the worst case scenarios of climate change. But actually building it is a tough proposition. I have to say. Politics is the most difficult thing. We are still trying to struggle each other, competing each other.

A supergrid seems like a super good idea. The question is, will it ever become a reality? Since the earliest days of harnessing electricity, getting power where it needs to go has been at least as big a challenge as making it in the first place. And we're talking about the earliest days since Thomas Edison's first electric grid in downtown Manhattan in the 1880s. What Edison gave us, that system ran on what's called direct current, and direct current at the voltages he was producing only goes about a mile. Gretchen Bakke is a cultural anthropologist who writes about, among other things, the grid.

He illuminated office buildings on Wall street, for example, mansions and then small factory spaces. But every time you wanted to go more than a mile, you needed to build a new power plant. And he thought this was fine. He was like, this will be fine. We'll just build another one 1 mile over, and then another one, and another one. And it was pretty clear that probably direct current was not going to be the long term answer. And so that set up the next problem, which was, how can we transmit electricity further?

And the answer to that was given to us by the famous Nikola Tesla, who was quite the guy. Tesla came up with the idea of an alternating current, which doesn't just flow in one direction, it keeps alternating back and forth on a cable, alternating current, it allows you to increase the voltage to a very high level, whereas you couldn't do it with direct current. Bump up your current to higher voltage and you can move your electricity along further. There was some early rivalry over this. Edison electrocuted an elephant to demonstrate that AC was dangerous and shouldn't be used. But ultimately AC was the clear winner. Electricity was finally able to break out of the 1 mile barrier. And that's why alternating current became the dominant form of transporting and using electricity world over.

And that's the story of electricity. Just kidding. Actually, renewables ruined everything. Solar panels or even a wind farm are not a corollary to a coal burning power plant. They are usually in different places. So coal, we can bring it where we want to burn it. Wind, we have to build where it's windy and wind is often happening where there's not that many people. Currently we use alternating current to be able to move electricity. But the problem with alternating current is that if you move it over a very long distance, hundreds or even thousands of miles, you lose too much of that electricity. And so moving it long distances makes it an uneconomical choice. If we can't get renewable energy where it needs to go, we can't transition away from fossil fuels. So we need a better way to move electrons.

When we're talking about the history of the grid, the AC technology becomes the dominant approach to distribute and to transmit energy. Nevertheless, the DC technology did not die. The opposite is actually the case. Jochen Kossmann is in charge of onshore DC power systems at Siemens Energy. Yes, thats right. DC Power, the loser of the 19th century current wars, is making a comeback. The solution that has become a consensus in the industry now is to use direct current, or more specifically, high voltage direct current. HVDC turns out to be the best of all worlds, travelling long distances without losing as much power as ac along the way.

DC wasn't able to go long distances previously because you couldn't create a high voltage version. But inventions in the past few decades have enabled us to have the equipment and the power electronics needed to generate high voltage direct current. The engineers here make building size machines that generate that sweet, sweet high voltage dc. They partner with companies like Italy based Prizmian, which make the the cables themselves long strands of insulated copper or aluminium that can span hundreds of miles.

Another important use case of the HVDC technology is the interconnections of countries to allow efficient energy trading between the countries and the network. The supergrid, in a way, is already a reality in Europe. Denmark is connected to Norway. France is connected to Spain, Sweden is connected to Germany. interconnectors let countries take advantage of renewable energy wherever it's being generated. If one country is having a particularly windy day, they can share some of that power with their neighbours. That's the idea behind the most recent interconnector to be installed, a project called Eleclink that's routed through the Channel Tunnel. An interconnector allows surplus power that isn't used in the UK to be transmitted over to France, or alternately, take some energy from France and transmit it back to the UK.

Philipp O'Gorman and his colleagues have been working on electlink for more than a decade and finally transmitted power for the first time in May this year. We transmit up to 1000 mw in either direction, enough to power a million to a million and a half homes. You're moving clean energy from a place where it's in surplus to a place where it's in demand. Certainly throughout the world, we're going to be seeing a lot more interconnectors across the world, across the globe. There is potential for them to do exactly as we are doing now.

But in other parts of the world, this idea has run into some trouble. When I was first beginning to research the grid book, which was in 2007, there was a thing in America called the super Grid. It didn't exist, but anytime you talk to anybody, they would show you this beautiful little map. They'd be like, here's the map. Here's how we're going to build these giant long distance, high voltage dc cables and link the country. The problem is, nobody would let anybody build a long distance power line like you couldn't build a transmission line in America. There is a surge of renewables being built around the country, and a lot of the best renewable solar and wind resources are in places like in the central part of the country.

But building transmission is really difficult in this country. There is a patchwork of federal, state, local landowner rights that all have to be heard of. Communities all have to have a say. So transwest is a planned transmission line that would take about 3000 wind power from Wyoming into Vegas, more than 700 miles. And Transwest has been in development for 17 years. Part of the reason it's taken that long. The project has had to secure permission from more than 400 landowners along the route. And even a single holdout can delay a project for years.

Ranch owner Andy Miniotis did ultimately sell a chunk of his land to Transwest, but he's not happy about it. Transwest they sent a young guy in, pretty pushy, and I. He'd get you flared up real quick with his pushing you. They were going to condemn you if you didn't agree with what they wanted. They're just going to take the land and nothing you're going to do about it. I have no leverage. I think they like to pick on the guys. They know that they've not got the money to hire the lawyers to go to federal court. If he waited and they actually filed eminent domain papers, then the value of what he could get out of that deal would fall tremendously.

I'm really not against, you know, the power lines itself because I understand that, you know, people need electricity, but it's the way they come in here and now I'm going to be dealing with it with construction, with people tearing the land up. I've already got a full plate to handle with this ranch. Just this year, transwest settled with the last holdout, property owners, meaning that finally, after 17 years, construction of the line can get started. And this is one of the more successful examples.

In the US, there are several transmission lines that have been going through the process. It's been taking years. They're all held up for different reasons. If we have this mandate to clean up the grid by 2035, we're going to have to figure out how to speed up the construction of transmission now to be able to build it in time. Meanwhile, Asia is trying to be less like America and more like Europe.

Mika Obayashi runs Japan's Renewable energy institute, which has come up with a plan to link up the grids of some of the region's biggest economies. So the Asia superglid is a concept to intangulate asian countries. We started to focus on the eastern asian countries, like China, Korea. We focused because in far East Asia there is Mongolia, which has the best renewable energy potential in that will benefit all asian countries.

In theory, wind and solar energy from Mongolias Gobi desert could produce as much as 2.6 terawatts of electricity, more than twice the capacity of the entire United States. The Asia supergrid would link that power to countries that produce more than a third of the world's CO2 emissions. It's an ambitious and potentially transformative plan, but it's not even close to the biggest idea coming out of Asia.

There is an idea that's being floated by China to try and build a global grid. China has a state owned company called State Grid that has the technology build HVDC lines and has built many of them across China and they want to try and promote this idea of a globally interconnected electric grid. It's hard to overstate the potential climate impact of a global grid connecting the most renewable, rich parts of the world to the most energy hungry population centres. But these proposals from Asia are just that, proposals, and that might not be changing anytime soon.

I have to say, politics is the most difficult thing. We are still trying to struggle each other, competing each other. The japanese government has tension with other countries, especially that China, Korea, countries that arent 100% friendly arent likely to want to link their energy systems together. And with the war in Ukraine making european countries regret their dependency on russian oil, any notion of a global supergrid is likely to be off the table for a good while.

But the way Mika sees it, we are past the point where the actions of individual countries can move the needle on climate change. Developed countries like Japan, western world has to be renewable energy, like a kind of more than 60% or 70%, 80% by 2030. So we don't have enough time to do it. So I'm always saying, every single cent or every single yen that we invest, something has to be invested for climate change actions. From now on, as the grid's evolved, we have had to cooperate on larger and larger scales.

Edison's DC grids serve just a few factories and rich people's homes. The grids of the 20th century spanned nations, and now the grids of the 21st century would forge links between people hundreds or even thousands of miles apart. But if we can all get used to the idea of being a little less isolated, we might find the puzzle of decarbonisation gets a lot easier to solve, which would be super. If we are going to hit net zero goals and have 80, 90 or 100% renewable powered grids, then there is little chance to do that without having really good transmission across long distances. If we look to our targets and the ambitions we have, we need to accelerate these processes. And I think this is doable. If we enable the grid to deal with this new green energy generation, I do believe that a climate neutral world will be possible.

Technology, Global, Innovation, Renewable Energy, Energy Transition, Decarbonization, Bloomberg Originals