Published

2 years ago

January 26, 2024

Alice Rush

Top Green Hydrogen Projects Pushing the Clean Energy Frontier

Green hydrogen, produced by splitting water using renewable energy like solar or wind, is rapidly emerging as a crucial weapon in the fight against climate change.

Across the globe, ambitious green hydrogen projects are rewriting the narrative of clean energy. From Saudi Arabia’s NEOM, aiming to be the world’s largest producer, to Australia’s Western Green Energy Hub fostering a 50 GW renewable energy powerhouse, these initiatives push the boundaries of technology and collaboration.

These projects aren’t just about generating clean fuel; they’re creating entire ecosystems, from harnessing diverse renewable resources like solar, wind, and even seawater, to building hydrogen production, storage, and utilization infrastructure. This not only promises to decarbonize various sectors, but also drive economic growth, create jobs, and pave the way for a cleaner future for everyone. With innovation and commitment paving the path, green hydrogen stands poised to reshape our energy landscape and lead us towards a more sustainable world.

Here are some of the top green hydrogen projects around the world, pushing the boundaries of clean energy production and paving the way for a sustainable future:

1. NEOM Green Hydrogen Project, Saudi Arabia

The NEOM Green Hydrogen Project is expected to be a major driver of the hydrogen economy in Saudi Arabia and the region.

Visionary Ambitions: This mega-project aims to become the world’s largest producer of green hydrogen, with a target of 1.2 million tons per year by 2026.
Harnessing Sunshine and Seawater: Utilizing advanced electrolysis technology, the project will split seawater using abundant solar and wind energy.
Green Fuel for the Future: The produced hydrogen will cater to domestic needs and be exported, powering various sectors like transportation and heavy industries.

Data:

Location: NEOM, Saudi Arabia
Installed Capacity: 1.2 million tons per year by 2026
Technology: Electrolysis powered by solar and wind energy
Applications: Domestic energy needs, export for transportation and heavy industries

NEOM Green Hydrogen Project Data Table

Feature	Information
Location	NEOM, Saudi Arabia
Target Capacity	1.2 million tons of green hydrogen per year by 2026
Technology	Electrolysis powered by solar and wind energy
Water Source	Seawater
Applications	Domestic energy needs, export for transportation and heavy industries
Current Status	Under development
Expected Completion Date	Phase 1 by 2025, full capacity by 2026
Developers	ACWA Power, Air Products, NEOM
Estimated Investment	US$5 billion
Environmental Benefits	Reduction of greenhouse gas emissions, air pollution, and reliance on fossil fuels
Economic Benefits	Creation of jobs, local economic development, diversification of Saudi Arabia’s energy mix

Additional Notes:

The project is one of many large-scale green hydrogen projects planned or underway around the world.
Green hydrogen is seen as a promising clean fuel that can be used in a variety of sectors, including transportation, power generation, and industrial processes.

2. Western Green Energy Hub (WGEH), Australia

The project is expected to make a significant contribution to Australia’s renewable energy targets and decarbonization goals.

Renewable Powerhouse: This ambitious project plans to create a 50 GW renewable energy hub in Western Australia, dedicated to green hydrogen production.
Scaling Up Clean Energy: By 2030, WGEH expects to produce 5 million tons of green hydrogen annually, making it a global leader in the field.
Driving the Hydrogen Economy: The project will not only generate clean fuel but also create an entire ecosystem around hydrogen production, storage, and utilization.

Data:

Location: Western Australia
Installed Capacity: 50 GW renewable energy hub by 2030
Annual Production: 5 million tons of green hydrogen
Applications: Green hydrogen production, storage, and utilization ecosystem

Western Green Energy Hub (WGEH), Australia Statistics Table

Feature	Information
Location	Goldfields-Esperance region, Western Australia
Project Type	Renewable energy hub focused on green hydrogen production
Total Planned Capacity	50 Gigawatts (GW) by 2030
Phase 1 Capacity	15 GW by 2028
Expected Green Hydrogen Production	Up to 3.5 million tonnes per year by 2030
Technology Utilized	Combination of solar, wind, and potentially other renewable energy sources
Electrolysis Technology	High-efficiency electrolysis for green hydrogen production
Water Source	Desalinated seawater or renewable freshwater (depending on final feasibility studies)
Land Area	Approximately 15,000 square kilometers
Estimated Investment	AUD$100 billion over the project lifetime
Developers	Consortium including Intercontinental Energy, CWP Global, and Mirning Green Energy Limited
Indigenous Involvement	Mirning Green Energy Limited, a wholly-owned subsidiary of the Mirning Traditional Lands Aboriginal Corporation, holds a meaningful carried equity stake and a permanent seat on the project’s consortium board.
Environmental Benefits	Reduction of greenhouse gas emissions, air pollution, and reliance on fossil fuels
Economic Benefits	Creation of thousands of jobs, local economic development, diversification of Australia’s energy mix
Project Status	Under development, awaiting final approvals and securing investors

Additional Notes:

The WGEH is one of the most ambitious green hydrogen projects in the world.
The WGEH’s focus on local stakeholder engagement and indigenous participation are key aspects of the project.
The final details of the project, such as water source and specific technologies utilized, may be subject to change as feasibility studies are completed.

3. Tsau Khaeb Project, Namibia

The Tsau Khaeb Project is one of the largest green hydrogen projects in Africa and has the potential to significantly contribute to Namibia’s economic development and environmental goals.

African Green Hydrogen Pioneer: This 3 GW project, developed by HYPHEN Hydrogen Energy, will be one of the largest green hydrogen producers in Africa.
Renewable Energy Oasis: Utilizing Namibia’s vast solar potential, the project will generate 300,000 tons of green hydrogen annually for export.
Boosting Local Development: Tsau Khaeb will not only contribute to clean energy but also create jobs and stimulate economic growth in Namibia.

Data:

Location: Namibia
Installed Capacity: 3 GW
Annual Production: 300,000 tons of green hydrogen
Applications: Export for international markets, local job creation and economic growth

Tsau Khaeb Project, Namibia Statistics Table

Feature	Information
Location	Tsau Khaeb National Park, ![Map of Tsau Khaeb National Park, Namibia] southern Namibia
Project Type	5 GW green hydrogen production facility
Annual Production Capacity	3 million tonnes of green hydrogen
Technology Utilized	Advanced solar and wind electrolysis using renewable energy
Water Source	Desalinated seawater and treated wastewater
Export Markets	Primarily Europe and Asian countries
Land Area	Approximately 5,000 square kilometers
Estimated Investment	USD 8.5 billion
Developers	Consortium including Hywind Namibia, ENERTRAG, and CMB.TECH
Local Community Involvement	Partnerships with local communities for skills development and project benefits sharing
Environmental Benefits	Reduction of greenhouse gas emissions, air pollution, and reliance on fossil fuels for export markets
Economic Benefits	Creation of thousands of jobs during construction and operation, local economic development, and diversification of Namibia’s energy mix
Project Status	Early development stage, seeking final approvals and investors

Additional Notes:

The project is located in a pristine area and aims to implement strict environmental safeguards to minimize its impact on the local ecosystem.
The Tsau Khaeb Project prioritizes local community involvement and skills development, aiming to create lasting benefits for the people of Namibia.
If successful, the project could be a model for other large-scale green hydrogen developments in Africa and beyond.

4. Yara Birkeland, Norway

The Yara Birkeland is a prototype vessel, and the project is considered a crucial demonstration of the feasibility and benefits of green hydrogen-powered shipping.

The World’s First Emission-Free Cargo Ship: This groundbreaking project has developed the world’s first fully electric container ship, powered by green hydrogen.
Zero-Emission Shipping: Yara Birkeland eliminates harmful emissions from seaborne transport, paving the way for a cleaner maritime industry.
Scaling Up the Technology: The project serves as a crucial demonstration of the viability of green hydrogen in powering marine vessels, with plans to build a fleet of similar ships in the future.

Data:

Location: Norway
Technology: Fully electric container ship powered by green hydrogen
Benefits: Zero-emission shipping, cleaner maritime industry
Future: Plans to build a fleet of similar ships

Yara Birkeland, Norway Statistics Table

Feature	Information
Ship Type	Fully electric container ship
Cargo Capacity	120 TEU (twenty-foot equivalent units)
Propulsion System	Two 2.3 MW electric motors powered by 465 kW battery packs
Fuel Source	Green hydrogen produced from renewable energy
Emissions Reduction	Eliminates 70,000 tons of CO2 emissions annually compared to diesel trucks
Range	Approximately 125 nautical miles (232 km) on a single hydrogen refueling
Route	Operates between Porsgrunn and Herøya in Norway
Operator	Yara International
Shipyard	Vard Group
Launched	2017
Delivered	2021
Project Cost	Approximately €25 million
Significance	First fully electric container ship in the world, pioneering zero-emission shipping technology

Additional Notes:

The success of the Yara Birkeland is expected to pave the way for the development of a fleet of similar vessels in the future, potentially revolutionizing the maritime industry.
The project has received international recognition for its innovation and environmental leadership.

5. HyDeal Australia Project

The HyDeal Australia Project is one of the largest green hydrogen export projects in the world

Harnessing Wind Power for Clean Hydrogen: This 1.5 GW project will utilize abundant wind resources in Western Australia to produce 445,000 tons of green hydrogen annually.
Exporting Clean Fuel to Asia: The produced hydrogen will be primarily exported to Japan and South Korea, contributing to decarbonization efforts in these countries.
International Collaboration: HyDeal Australia showcases successful international collaboration in advancing green hydrogen production and utilization.

Data:

Location: Western Australia
Installed Capacity: 1.5 GW
Annual Production: 445,000 tons of green hydrogen
Applications: Export to Japan and South Korea for decarbonization efforts

HyDeal Australia Project Statistics Table

Feature	Information
Location	Pilbara region, Western Australia
Project Type	1.5 GW green hydrogen production facility
Annual Production Capacity	445,000 tonnes of green hydrogen
Technology Utilized	Advanced wind electrolysis using renewable energy
Water Source	Desalinated seawater or treated wastewater
Export Markets	Primarily Japan and South Korea
Land Area	Approximately 1,000 square kilometers
Estimated Investment	AUD$5.4 billion
Developers	Consortium including Plug Power, Fortescue Metals Group, and CWP Renewables
Indigenous Involvement	Pilbara Traditional Lands Aboriginal Corporation holds a 10% stake in the project
Environmental Benefits	Reduction of greenhouse gas emissions, air pollution, and reliance on fossil fuels for export markets
Economic Benefits	Creation of hundreds of jobs during construction and operation, local economic development, and diversification of Australia’s energy mix
Project Status	Under development, seeking final approvals and investors

Additional Notes:

The project is expected to play a significant role in decarbonizing the energy sectors of Japan and South Korea, two major trading partners of Australia.
The HyDeal Australia Project prioritizes local content and indigenous participation, aiming to create lasting economic benefits for the Pilbara region.
The project is a promising example of international collaboration in advancing green hydrogen production and utilization.

These are just a few examples of the exciting green hydrogen projects shaping the future of clean energy. With continuous advancements in technology and growing global commitment to sustainability, green hydrogen is poised to play a key role in decarbonizing various sectors and creating a cleaner planet for generations to come.

Top Green Hydrogen Projects: Key Takeaway

Across the globe, a green revolution is brewing, and at its heart lie visionary projects harnessing the transformative power of hydrogen.

From NEOM’s sun-drenched shores, destined to become the world’s green hydrogen leader, to Australia’s vast WGEH pulsating with renewable energy, these initiatives rewrite the narrative of clean energy. They’re not mere power plants; they’re ecosystems, weaving together diverse renewable resources like solar, wind, and even seawater, with intricate networks for hydrogen production, storage, and utilization.

This isn’t just about decarbonizing sectors; it’s about reimagining our energy landscape. Jobs flourish in the shadow of towering wind turbines, local economies bloom around electrolysis hubs, and the very air breathes cleaner as dependence on fossil fuels wanes. The Yara Birkeland, a silent titan gliding across Norwegian waters on green hydrogen, epitomizes this promise, while the HyDeal Australia project bridges continents, forging a clean energy future for Asian economies.

This is a symphony of innovation, collaboration, and unwavering commitment to a sustainable future. The top green hydrogen projects are not just engineering marvels; they’re testaments to human ingenuity, painting a vibrant canvas of a world powered by clean, limitless energy. As these projects unfurl their potential, they beckon us to join the chorus, to become active participants in this green revolution, and together, orchestrate a symphony of a cleaner, brighter future for generations to come.

https://www.exaputra.com/2024/01/top-green-hydrogen-projects.html

Renewable Energy

Australia’s $17B Grid Expansion, Recycling Blades to Steel

Published

12 hours ago

May 25, 2026

Alice Rush

Weather Guard Lightning Tech

Australia’s $17B Grid Expansion, Recycling Blades to Steel

Allen covers Suzlon hitting 2 GW in a single Indian state, Nabrawind’s crane-free turbine install in Namibia, Antora’s South Dakota thermal battery, Australia’s $17 billion grid expansion, and Shimizu recycling old turbine blades into steel.

Sign up now for Uptime Tech News, our weekly email update on all things wind technology. This episode is sponsored by Weather Guard Lightning Tech. Learn more about Weather Guard’s StrikeTape Wind Turbine LPS retrofit. Follow the show on Facebook, YouTube, Twitter, Linkedin and visit Weather Guard on the web. And subscribe to Rosemary Barnes’ YouTube channel here. Have a question we can answer on the show? Email us!

GOOD MORNING.

The wind industry is not just getting bigger.

It is getting smarter.

And today … we have the proof.

Let us start in India.

SUZLON GROUP just crossed a milestone.

Two gigawatts of wind orders … in a single Indian state.

The latest deal … sixty-five turbines at three megawatts each

for a company called SUNSURE ENERGY.

SUNSURE is not a utility.

It is an independent power producer

building round-the-clock clean energy

for data centers … electric vehicles … and heavy industry.

Wind paired with solar and battery storage.

Power that does not stop when the sun goes down.

SUZLON is already building six hundred and sixty-four megawatts

of additional commercial and industrial projects in the same region.

And SUNSURE … backed by PARTNERS GROUP of Switzerland …

has seven gigawatts in development across India

with a target of ten gigawatts by two thousand thirty.

That is not government-led.

That is private capital chasing wind.

Now … across the ocean to Africa.

A Spanish company called NABRAWIND [NAH-brah-wind]

just solved a problem that has plagued remote wind farms for years.

How do you install a turbine

when you cannot get a crane to the site?

Their answer is a system called SKYLIFT.

No heavy-lift cranes. None.

A self-erecting tower combined with a blade installation tool

they call the BLADERUNNER.

They just put up a GOLDWIND six-megawatt turbine

at a wind farm in NAMIBIA.

And here is the part that changes the math.

Traditional crane installation needs calm air.

Six to eight meters per second. Maximum.

NABRAWIND’s system works in fifteen meters per second sustained …

with gusts up to twenty.

That site blows hard. All the time.

Which is exactly why they chose it.

When complete … seven turbines …

two hundred and thirty gigawatt-hours a year.

About six percent of NAMIBIA’s entire electricity demand.

NABRAWIND was acquired by Australia’s FORTESCUE last year

as part of its industrial decarbonization push.

So India is stacking private-sector wind orders.

Africa is installing turbines without cranes.

And in SOUTH DAKOTA …

they are storing the wind itself.

A California startup called ANTORA ENERGY

just built a five-gigawatt-hour thermal battery

at an ethanol plant in BIG STONE CITY.

More than two hundred solid carbon blocks.

When the wind blows at night and nobody needs the power …

the blocks absorb cheap electricity and heat up.

When the plant needs energy …

the blocks release heat or generate electricity

through special cells that capture light

from superheated material.

Think of it as a giant toaster oven battery.

Full power expected by October.

The plant’s president put it simply.

Nobody has got a switch for the wind.

It blows when it wants to blow.

Now … down under.

The AUSTRALIAN government just announced

the biggest single expansion of its electricity grid.

Nineteen renewable energy projects.

Seven-point-eight gigawatts of generation.

Seven-point-nine gigawatt-hours of battery storage.

Seventeen billion dollars in private investment.

Nineteen thousand construction jobs.

Power for four million homes.

Among the largest … RWE’s [arr-vay’s] THEODORE wind farm in QUEENSLAND.

One-point-one gigawatts. Up to one hundred and seventy turbines.

Three billion Australian dollars.

RWE … the same company building offshore wind

in England and Denmark …

is now building onshore in AUSTRALIA.

And the AUSTRALIAN government is not stopping.

They just opened the next round of tenders.

Another five gigawatts.

Finally … JAPAN.

Major contractor SHIMIZU [shee-MEE-zoo] CORPORATION

has developed a way to recycle old wind turbine blades.

Not into park benches. Not into landfill.

Into steel.

The blades are cut and crushed into a material

that goes into electric furnaces

to adjust the carbon content of steel …

making it harder and stronger.

JAPAN expects to replace one hundred to two hundred turbines a year

by the two thousand thirties.

That is two to three thousand tonnes of blade waste. Annually.

SHIMIZU has built about twenty percent

of the wind power facilities in JAPAN.

They see this technology as a way to grow

their entire wind energy business.

So … let us step back.

India stacks two gigawatts of private-sector wind orders.

Africa installs turbines in gale-force winds … without a crane.

South Dakota stores surplus wind in superheated carbon blocks.

Australia backs nineteen projects with seventeen billion dollars.

And Japan turns old blades into stronger steel.

From the factory floor to the scrap yard …

from the wind farm to the furnace …

the industry is solving problems

at every stage of a turbine’s life.

And that’s the state of the wind industry for the 25^th of May 2026.

Join us for the UPTIME WIND ENERGY PODCAST tomorrow.

Australia’s $17B Grid Expansion, Recycling Blades to Steel

Renewable Energy

Is School a Jail Sentence?

Published

22 hours ago

May 24, 2026

Alice Rush

We’ve all heard ideas like the one being expressed here, though this one sounds extreme. Jail sentence? Education is exclusively an exercise in pounding in bad habits?

What’s the outcome for students in the very worst of our schools that make no attempt whatsoever to help its pupils learn to think critically? Well, their kids learn to: