Massive Russian Missile Assault on Ukraine Causes Widespread Blackouts

Massive Missile Assault on Ukraine Leaves Millions in Darkness In the early hours of Thursday morning, Russia launched a significant attack on Ukraine, unleashing a barrage of missiles and drones that rippled across the nation. This coordinated assault targeted the energy infrastructure, resulting in approximately 1 million Ukrainians being plunged into darkness. Explosions were reported in…

Pass legislation to significantly expand transmission for clean energy NOW!

AN OPEN LETTER to THE PRESIDENT & U.S. CONGRESS

820 so far! Help us get to 1,000 signers!

Right now, there are at least 2,000 gigawatts of renewable energy waiting for permission to connect to power lines in the U.S., which is more than the total capacity of the country’s existing power plants. Wait times to connect new power plants to the grid can reach five years or more. Without rapidly improving transmission, the United States will not be able to achieve Biden's goal of 100% clean energy by 2035 or provide cheaper, more reliable electricity to American households. If the U.S. can’t build new transmission at a faster pace, roughly 80 percent of the emissions reductions expected from the Inflation Reduction Act–the largest climate legislation in U.S. history–might not happen.

That’s why I’m writing to urge Congress to pass legislation to significantly expand transmission for clean energy.

Multiple efforts are currently in play. Most recently in the House, Representatives Sean Casten and Mike Levin introduced the Clean Energy and Transmission Acceleration Act, (HR 6747) which would encourage the development of new transmission lines to carry renewable power where it’s needed while protecting the rights of communities to provide input on where lines are built and to benefit from their construction. I strongly support this bill.

But any legislation is better than none, and NONE of the bills proposed so far have been passed. This is not good.

Increasing access to clean energy will help tackle the climate crisis by ensuring the reliability of the grid and reducing consumers' bills. Renewable energies like wind and solar are quickly becoming the least expensive source of energy and we need to make sure as many people as possible get access to these clean, abundant energy sources.

Please pass a strong, fair transmission bill—like HR 6747—that prioritizes clean energy, climate change, and environmental justice. This is urgent; all of our children are counting on us to secure their futures. Thanks.

▶ Created on April 23 by Jess Craven · 819 signers in the past 7 days

📱 Text SIGN PMNVSR to 50409

🤯 Liked it? Text FOLLOW JESSCRAVEN101 to 50409

Building on Abraham Accords: US-Israel AI Deal Creates Middle East Technology Corridor

The AI Deal That Slipped Under the Radar While Gaza Dominated Headlines While International media were fixated on Gaza ceasefire talks and regional tensions, a pivotal development quietly took place at the White House during a meeting between U.S. President Donald Trump and Israeli Prime Minister Benjamin Netanyahu. Beyond the headlines of war and diplomacy, the United States and Israel signed a…

£500m boost for hydrogen to create thousands of British jobs

Thousands of clean energy jobs to be created through new hydrogen funding. From: Department for Energy Security and Net Zero and The Rt Hon Ed Miliband MP – Published13 June 2025 Funding for first regional hydrogen transport and storage network to unlock growth and drive investment in Britain’s renewal Secures thousands of jobs boosting industrial heartlands as part of the government’s Plan…

Trump’s America and the New Land War: Federal Judge Grants PSEG Access to Private Property Without Consent

By Michael Phillips In a blow to private landowners and local government oversight, a federal judge has ruled in favor of Public Service Enterprise Group (PSEG), granting the utility company temporary access to over 90 private properties in Maryland to conduct survey work tied to the controversial Maryland Piedmont Reliability Project (MPRP). The decision means that PSEG can immediately begin…

GE Vernova to Invest ₹1,400 Million in India to Expand Grid Infrastructure Manufacturing

GE Vernova (NYSE: GEV), a global leader in energy solutions, has announced an investment of approximately ₹1,400 million (USD 16 million) in India to expand its electrification manufacturing and engineering footprint. The move aims to address surging demand for advanced grid technologies essential for a stable, secure, and renewable-powered electricity ecosystem. The investment will be routed…

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LNG Storage Tank Market Outlook 2025: Growth Drivers, Trends & Future Opportunities

As the world continues to transition toward cleaner and more sustainable energy sources, Liquefied Natural Gas (LNG) is becoming an essential part of the global energy mix. Nations across the globe are striving to balance energy security with carbon reduction goals, and in this evolving landscape, LNG infrastructure—especially LNG storage tanks—has taken center stage. These tanks are no longer just a part of the supply chain; they’re strategic assets that enable safe, efficient, and scalable distribution of natural gas.

The LNG Storage Tank market is projected to reach USD 21.22 billion by 2029 from USD 14.64 billion in 2024, at a CAGR of 7.7% from 2024 to 2029. LNG Storage Tanks are a class of specialized storage tanks for LNG storage. These tanks are usually located in ground, above ground, and in LNG operated vehicles or ships. They are fabricated in different arrangements, including vertical, horizontal, double-walled, and insulated. 

 Let’s explore the dynamics of this critical sector.

LNG storage tanks are engineered to store liquefied natural gas at ultra-low temperatures—around -162°C. At this temperature, natural gas becomes a liquid, significantly reducing its volume and making it easier and more economical to transport and store. These tanks are built using specialized materials and advanced insulation systems that help maintain cryogenic conditions and ensure safety under extreme pressures. They serve as vital links in the LNG supply chain, enabling the seamless movement of gas from production plants to terminals and end users. Depending on operational needs and geographic constraints, LNG tanks come in two main types: above-ground tanks, which are easier to access and maintain, and in-ground or underground tanks, which are favored in space-limited or high-risk areas due to their added safety benefits.

As of 2023, the global LNG storage tank market was valued in the multi-billion-dollar range, and projections indicate a steady compound annual growth rate (CAGR) of over 6% through 2030. Several key factors are driving this momentum. First, there's the global surge in LNG demand as countries look to move away from coal and oil. LNG is increasingly seen as a “transition fuel” that helps bridge the gap between fossil fuels and renewables, offering lower emissions and high energy efficiency.

Another major driver is the push for energy security. Countries like India, China, Japan, and Germany are significantly expanding their strategic LNG reserves to mitigate supply risks. This has led to increased investment in large-scale storage facilities, giving a notable boost to the tank market. Additionally, the maritime sector is turning toward LNG as a cleaner alternative to traditional marine fuels. As a result, the demand for LNG bunkering infrastructure—including port-based and onboard LNG tanks—is growing, especially in Europe and Southeast Asia. On the technology front, innovations in tank design, insulation materials, and modular construction are making LNG tanks safer, more cost-effective, and faster to deploy. Full-containment tanks and digital monitoring systems are also enhancing operational reliability, attracting more investment into the space.

Regionally, the Asia-Pacific market is leading in both growth and demand. Countries like China, India, and South Korea are rapidly building import terminals and expanding their LNG storage capacities to meet rising industrial and urban energy needs. North America is also seeing significant activity, driven by the U.S. and Canada’s vast shale gas resources and increasing LNG exports. The region is further focusing on small-scale LNG storage solutions to serve remote or off-grid areas. In Europe, the focus has shifted sharply toward energy diversification, especially in response to recent geopolitical tensions. Nations like Germany, France, and the Netherlands are fast-tracking LNG infrastructure projects to reduce dependence on pipeline gas, with storage tanks playing a central role.

Key players operating in the LNG storage tank market include McDermott International, IHI Corporation, Wartsila, L&T Hydrocarbon Engineering, and CIMC Enric. These companies specialize in engineering, procurement, and construction (EPC) of both onshore and offshore storage solutions. Their innovations and global reach are helping shape the next generation of LNG infrastructure.

Despite the optimistic outlook, the market is not without its challenges. High capital investment remains a significant barrier, particularly for developing countries. The complexity of regulations and the need to meet stringent safety standards also add layers of cost and time to project development. Additionally, fluctuations in global LNG prices can affect the pace of infrastructure expansion. However, collaboration between governments, private sector stakeholders, and technology providers is helping to ease these constraints through streamlined regulations, standardized designs, and new financing models.

Looking forward, the LNG storage tank market is set to remain a crucial part of the global energy transition. The next few years will likely see the emergence of floating storage and regasification units (FSRUs), growth in small-scale and mobile LNG solutions, and the broader adoption of digital systems for real-time monitoring and safety control. These trends point toward a more agile, resilient, and environmentally aligned LNG infrastructure landscape.

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In conclusion, the LNG storage tank market is more than just a support system for gas logistics—it's a vital enabler of sustainable energy strategies worldwide. As countries invest in cleaner, more secure energy solutions, these tanks will continue to play a foundational role in powering industries, cities, and economies. For investors, energy professionals, and policy-makers alike, this is a space to watch closely in the years to come.

Global Heavy Duty Connector Market Analysis: Trends, Innovations, and 2024 Forecast Study

Global Heavy Duty Connector Market: A Comprehensive Guide

The Global Heavy Duty Connector Market is expected to witness significant growth in the coming years, reaching USD 3.8 billion by 2024, with a steady compound annual growth rate (CAGR) of 5.7% until 2033, which will bring the total market value to USD 6.3 billion. Heavy Duty Connectors (HDCs) play a crucial role in ensuring reliable electrical and data connections across a variety of industries, particularly where harsh environmental conditions are present.

These industrial-grade connectors are designed to withstand dust, moisture, extreme temperatures, mechanical impacts, and vibrations, all while maintaining their functionality in sectors such as manufacturing, construction, energy, and transportation. With industrial applications requiring utmost reliability, the demand for heavy-duty connectors has grown exponentially. The increasing focus on automation, renewable energy, and electric vehicles (EVs), alongside growing industrialization in key regions, is further propelling this market.

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What are Heavy Duty Connectors?

Heavy Duty Connectors (HDCs) are rugged electrical connectors that ensure secure and stable connections in harsh environments. These connectors are used to link various systems and devices within industrial, commercial, and energy applications. Their robust construction includes components such as housings, inserts, hoods, and termination styles, which collectively provide a high level of protection against environmental elements such as dust, moisture, and mechanical stress.

These connectors are essential for sectors where reliability and high performance are crucial. For example, in automated manufacturing plants, where machinery and robotic systems must continuously operate, HDCs ensure the uninterrupted flow of electrical power and data signals.

Market Drivers

Expansion of Industrial Automation and Robotics

One of the primary drivers of the Global Heavy Duty Connector Market is the expansion of industrial automation. As factories and warehouses increasingly adopt automation technologies, the demand for connectors that can withstand the demanding environments of these industrial spaces has surged. In particular, the need for connectors in robotic systems and automated manufacturing equipment is pushing HDC manufacturers to innovate and create products that ensure uninterrupted power transmission and data communication.

Rising Demand for Renewable Energy Solutions

The ongoing transition to sustainable and renewable energy sources such as solar and wind power has created new demand for HDCs. In renewable energy applications, connectors are vital for ensuring secure electrical connections in energy storage and grid integration systems. HDCs play a crucial role in wind turbines, solar panels, and energy storage systems, where they ensure the efficient transfer of power while withstanding harsh weather conditions and environmental stress.

Growth of Electric Vehicle (EV) Infrastructure

The rapid growth of the electric vehicle (EV) market is another significant factor driving the HDC market. With the increasing adoption of electric vehicles, the need for robust connectors in EV charging stations has grown. These connectors must support high power loads and resist environmental stresses such as vibrations and temperature fluctuations, which makes HDCs an ideal choice for EV infrastructure.

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Market Restraints

High Initial Cost and Maintenance

While heavy-duty connectors offer unmatched durability and performance, their high initial cost can be a barrier for smaller businesses or industries operating on limited budgets. Additionally, maintaining these connectors, particularly in extreme environments, can be costly. Regular inspections and repairs can add to the total cost of ownership, potentially deterring some industries from fully adopting HDCs.

Complex Installation Process

The installation of heavy-duty connectors is not always straightforward. It requires specialized tools and skilled labor to ensure that the connectors are installed correctly and safely. The complexity of the installation process can be a deterrent for industries looking for simpler, more cost-effective solutions.

Market Opportunities

Advancements in Smart Grid Technology

As the world moves towards more intelligent energy systems, the demand for advanced smart grids has increased. These systems require high-performance connectors to transmit both power and data efficiently. HDCs with IoT capabilities are becoming a key component in smart grid applications, as they support real-time diagnostics and predictive maintenance, which enhance overall operational efficiency.

Growth in the Electric Vehicle (EV) Charging Infrastructure

The global shift towards electric vehicles is expected to continue, driving the need for connectors that support fast and reliable EV charging. Heavy-duty connectors that can handle high power and ensure secure, stable connections are in demand, making this a critical area of growth for HDC manufacturers.

Market Trends

Integration of IoT and Smart Connectivity

A notable trend in the Global Heavy Duty Connector Market is the integration of Internet of Things (IoT) functionality into connectors. IoT-enabled connectors can provide real-time data and diagnostics, which helps with predictive maintenance and reduces downtime. These advanced connectors are being used in industries where operational efficiency and real-time monitoring are key to success, such as in manufacturing and renewable energy.

Modular and Compact Designs

There is a growing demand for modular and compact HDC designs. These designs offer greater flexibility, allowing businesses to customize connectors to suit specific applications. Additionally, modular designs simplify installation, which reduces downtime and installation costs in industries where space is limited or constrained.

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Key Market Segments

By Component

The hood and housing segment is expected to dominate the heavy-duty connector market in 2024. These components form the main protective shell of the connector, shielding the electrical components from moisture, dust, and physical stress. As industries require highly durable connectors for harsh environments, this segment continues to grow in demand.

The insert and contact segment is also seeing significant growth due to its adaptability. Inserts allow connectors to be configured in various ways, offering flexibility for industries with specific needs, such as industrial automation or renewable energy applications.

By Material

In terms of material, metal connectors are expected to dominate the market in 2024 due to their superior strength, conductivity, and resistance to corrosion. Metal connectors ensure reliable electrical transmission and protection in extreme conditions, making them ideal for industries where durability is a top priority.

By Termination Style

The crimp termination style is expected to lead the market in 2024, as it provides a secure, stable connection and is easy to install without requiring soldering. This style of termination is particularly popular in industrial settings where time and precision are critical.

By Application

The manufacturing industry is projected to be the leading application area for heavy-duty connectors in 2024. HDCs are widely used in industrial machinery, automation systems, and control units. As manufacturing facilities increasingly rely on automated systems and robotics, the need for durable and reliable connectors is growing.

The power sector is also becoming a significant application for HDCs, particularly in the fields of solar energy, wind energy, and energy storage. These sectors require connectors that can handle high power loads and maintain performance even in challenging environmental conditions.

Regional Analysis

Asia-Pacific

The Asia-Pacific region is expected to hold 33.1% of the revenue share of the Global Heavy Duty Connector Market in 2024. Countries like China, India, and Japan are driving this growth, particularly due to rapid industrialization, increased manufacturing, and a strong presence in renewable energy and electric vehicle infrastructure. The region's growing demand for industrial automation and renewable energy solutions continues to boost the need for heavy-duty connectors.

North America

North America is expected to witness steady growth in the heavy-duty connector market, driven by the expansion of smart manufacturing, electric vehicle infrastructure, and renewable energy projects. The U.S. and Canada are particularly focused on developing clean energy solutions and expanding electric vehicle charging networks, which further contributes to the increasing demand for high-performance connectors.

FAQs

1. What are Heavy Duty Connectors?

Heavy Duty Connectors (HDCs) are industrial-grade connectors designed to provide secure and stable electrical connections in harsh environments. These connectors protect against dust, moisture, vibrations, and extreme temperatures, ensuring reliable power and data transmission in sectors like manufacturing, energy, and transportation.

2. Why are HDCs used in renewable energy applications?

HDCs are essential in renewable energy applications such as wind turbines and solar panels due to their ability to withstand harsh environmental conditions. They ensure secure power transmission and are built to handle high loads of electricity, making them ideal for use in energy storage systems and grid integration.

3. What factors are driving the growth of the HDC market?

Key factors driving the Global Heavy Duty Connector Market include the expansion of industrial automation, the growth of renewable energy projects, and the rise of electric vehicle infrastructure. These industries require reliable and durable connectors to ensure uninterrupted power and data transmission in challenging environments.

4. What challenges does the heavy-duty connector market face?

The market faces challenges such as high initial costs, which can deter small businesses from adopting HDCs. Additionally, the complex installation process and the need for skilled labor can be a barrier for some industries.

5. Which region is expected to dominate the Heavy Duty Connector Market?

The Asia-Pacific region is expected to hold the largest revenue share in the Global Heavy Duty Connector Market due to rapid industrialization and significant growth in manufacturing, renewable energy, and electric vehicle infrastructure.

Conclusion

The Global Heavy Duty Connector Market is on a strong upward trajectory, driven by advancements in industrial automation, renewable energy, and electric vehicle infrastructure. With growing demand for connectors that can withstand harsh environments and provide reliable, high-performance connections, manufacturers are focusing on innovation and smart connectivity to meet the evolving needs of industries. However, challenges such as high initial costs and complex installation processes remain. As industries continue to prioritize efficiency and sustainability, the demand for heavy-duty connectors will likely continue to rise, creating opportunities for market players to expand their reach and offerings.

Russia Intensifies Aerial Assault on Ukraine Amid Ongoing Conflict

Russia Launches Aerial Assault on Ukraine Amid Ongoing Conflict In a significant escalation of hostilities, Russia commenced a series of aerial attacks on Ukraine early Tuesday morning, targeting major urban centers including the capital, Kyiv. The assault involved a coordinated barrage of missiles and drones, intensifying the already perilous situation in the region. Ukraine’s air force raised a…

Kinder Morgan Stock Price Forecast: Long-Term Investment Potential

Over the long term, KMI’s stock has the potential to appreciate by approximately 15%, making it an attractive option for investors. #KinderMorgan #EnergyInfrastructure #StockMarket #FinancialHealth #DividendStocks #EnergySector #stockpriceforecast

Kinder Morgan, Inc. (KMI) is one of the largest energy infrastructure companies in North America. The company operates approximately 83 000 miles of pipelines and 141 terminals. These assets transport natural gas, refined petroleum products, crude oil, carbon dioxide (CO2), and more. Kinder Morgan’s extensive network plays a crucial role in the energy supply chain, ensuring the efficient and safe…

"People have been telling stories about renewable energy since the nineteen-seventies, when the first all-solar-powered house opened on the campus of the University of Delaware, drawing a hundred thousand visitors in 1973, its first year, to marvel at its early photovoltaic panels and its solar hot-water system, complete with salt tubs in the basement to store heat overnight. But, even though we’ve got used to seeing solar panels and wind turbines across the landscape in the intervening fifty years, we continue to think of what they produce as “alternative energy,” a supplement to the fossil-fuelled power that has run Western economies for more than two centuries. In the past two years, however, with surprisingly little notice, renewable energy has suddenly become the obvious, mainstream, cost-efficient choice around the world. Against all the big bad things happening on the planet (and despite all the best efforts of the Republican-led Congress in recent weeks), this is a very big and hopeful thing, which a short catalogue of recent numbers demonstrates:

It took from the invention of the photovoltaic solar cell, in 1954, until 2022 for the world to install a terawatt of solar power; the second terawatt came just two years later [in 2024], and the third will arrive either later this year or early next [in 2025 or early 2026].

That’s because people are now putting up a gigawatt’s worth of solar panels, the rough equivalent of the power generated by one coal-fired plant, every fifteen hours. Solar power is now growing faster than any power source in history, and it is closely followed by wind power—which is really another form of energy from the sun, since it is differential heating of the earth that produces the wind that turns the turbines.

Last year, ninety-six per cent of the global demand for new electricity was met by renewables, and in the United States ninety-three per cent of new generating capacity came from solar, wind, and an ever-increasing variety of batteries to store that power.

In March, for the first time, fossil fuels generated less than half the electricity in the U.S. In California, at one point on May 25th, renewables were producing a record hundred and fifty-eight per cent of the state’s power demand. Over the course of the entire day, they produced eighty-two per cent of the power in California, which, this spring, surpassed Japan to become the world’s fourth-largest economy.

Meanwhile, battery-storage capability has increased seventy-six per cent, based on this year’s projected estimates; at night, those batteries are often the main supplier of California’s electricity. As the director of reliability analysis at the North American Electric Reliability Corporation put it, in the CleanTechnica newsletter, “batteries can smooth out some of that variability from those times when the wind isn’t blowing or the sun isn’t shining.” As a result, California is so far using forty per cent less natural gas to generate electricity than it did in 2023, which is the single most hopeful statistic I’ve seen in four decades of writing about the climate crisis.

Texas is now installing renewable energy and batteries faster than California; in a single week in March, it set records for solar and wind production as well as for battery discharge. In May, when the state was hit by a near-record-breaking early-season heat wave, air-conditioners helped create a record demand on the grid, which didn’t blink—more than a quarter of the power came from the sun and wind. Last week’s flooding tragedy was a reminder of how vulnerable the state is to extreme weather, especially as water temperatures rise in the Gulf, producing more moisture in the air; in late June, the director of the state’s utility system said that the chances of emergency outages had dropped from sixteen per cent last summer to less than one per cent this year, mostly because the state had added ten thousand megawatts of solar power and battery storage. That, he said, “puts us in a better position.”

All this is dwarfed by what’s happening in China, which currently installs more than half the world’s renewable energy and storage within its own borders, and exports most of the solar panels and batteries used by the rest of the world. In May, according to government records, China had installed a record ninety-three gigawatts of solar power—amounting to a gigawatt every eight hours. The pace was apparently paying off—analysts reported that, in the first quarter of the year, total carbon emissions in China had actually decreased; emissions linked to producing electricity fell nearly six per cent, as solar and wind have replaced coal. In 2024, almost half the automobiles sold in China, which is the world’s largest car market, were full or hybrid electric vehicles. And China’s prowess at producing cheap solar panels (and E.V.s) means that nations with which it has strong trading links—in Asia, Africa, South America—are seeing their own surge of renewable power.

In South America, for example, where a decade ago there were plans to build fifteen new coal-fired power plants, as of this spring there are none. There’s better news yet from India, now the world’s fastest-growing major economy and most populous nation, where data last month showed that from January through April a surge in solar production kept the country’s coal use flat and also cut the amount of natural gas used during the same period in 2024 by a quarter. But even countries far from Beijing are making quick shifts. Poland—long a leading coal-mining nation—saw renewable power outstrip coal for electric generation in May, thanks to a remarkable surge in solar construction. In 2021, the country set a goal for photovoltaic power usage by 2030; it has already tripled that goal.

Over the past fifteen years, the Chinese became so skilled at building batteries—first for cellphones, then cars, and now for entire electric systems—that the cost of energy storage has dropped ninety-five per cent. On July 7th, a round of bidding between battery companies to provide storage for Chinese utilities showed another thirty per cent drop in price. Grid-scale batteries have become so large that they can power whole cities for hours at a time; in 2025, the world will add eighty gigawatts of grid-scale storage, an eightfold increase from 2021. The U.S. alone put up four gigawatts of storage in the first half of 2024.

There are lots of other technologies vying to replace fossil fuels or to reduce climate damage: nuclear power, hydrogen power, carbon capture and storage; along with renewables, all were boosted by spending provisions in Biden’s Inflation Reduction Act and will be hampered to varying degrees by congressional rollbacks. Some may prove useful in the long run and others illusory, but for now they are statistically swamped by the sheer amount of renewable power coming online. Globally, roughly a third more power is being generated from the sun this spring than last. If this exponential rate of growth can continue, we will soon live in a very different world.

All this suggests that there is a chance for a deep reordering of the earth’s power systems, in every sense of the word “power,” offering a plausible check to not only the climate crisis but to autocracy. Instead of relying on scattered deposits of fossil fuel—the control of which has largely defined geopolitics for more than a century—we are moving rapidly toward a reliance on diffuse but ubiquitous sources of supply. The sun and the wind are available everywhere, and they complement each other well; when sunlight diminishes in the northern latitudes at the approach of winter, the winds pick up. This energy is impossible to hoard and difficult to fight wars over. If you’re interested in abundance, the sun beams tens of thousands of times more energy at the earth than we currently need. Paradigm shifts like this don’t come along often: the Industrial Revolution, the computer revolution. But, when they do, they change the world in profound and unpredictable ways...

In retrospect, it’s reasonably easy to see how fast solar and wind power were coming. But, blinkered by the status quo, almost no one actually predicted it. In 2009, the International Energy Agency predicted that we would hit two hundred and forty-four gigawatts of solar capacity by 2030; we hit it by 2015. For most of the past decade, the I.E.A.’s five-year forecasts missed [underestimated the amount of renewables] by an average of two hundred and thirty-five per cent. The only group that came even remotely close to getting it right was not J. P. Morgan Chase or Dow Jones or BlackRock. It was Greenpeace, which estimated in 2009 that we’d hit nine hundred and twenty-one total gigawatts by 2030. We were more than fifty per cent above that by 2023. Last summer, Jenny Chase, who has been tracking the economics of solar power for more than two decades for Bloomberg, told the Times, “If you’d told me nearly 20 years ago what would be the case now, 20 years later, I would have just said you were crazy. I would have laughed in your face. There is genuinely a revolution happening.”

-via The New Yorker, July 9, 2025

Mission 300: Africa’s Bold Gamble to Power a Continent’s Future

In the vast expanse of Sub-Saharan Africa, as night falls, entire communities fade into darkness. Nearly 600 million people—more than half the region’s population—still live without electricity. But now, a sweeping and ambitious plan is taking shape to flip the switch for nearly half of them. It’s called Mission 300, and its goal is as bold as it is urgent: connect 300 million Africans to…