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Saturday, December 25, 2021

What is green hydrogen and why do we need it? An expert explains



Green Hydrogen might be the fuel of the future

Image: REUTERS/ Jane Barlow
21 Dec 2021
Abhinav Chugh
Acting Content and Partnerships Lead,
 World Economic Forum
Head of the Power Sector Transformation Strategies, 
International Renewable Energy Agency


The world's progress on transitioning to sustainable energy has stalled. Here’s how to fix it.


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Hydrogen

Explore the latest strategic trends, research and analysis

Green hydrogen could be a critical enabler of the global transition to sustainable energy and net zero emissions economies.

There is unprecedented momentum around the world to fulfil hydrogen’s longstanding potential as a clean energy solution.

Dr Emanuele Taibi lays out where things with hydrogen stand now and how it can help to achieve a clean, secure and affordable energy future.

The time is right to tap into hydrogen’s potential to play a key role in tackling critical energy challenges. The recent successes of renewable energy technologies and electric vehicles have shown that policy and technology innovation have the power to build global clean energy industries.

Hydrogen is emerging as one of the leading options for storing energy from renewables with hydrogen-based fuels potentially transporting energy from renewables over long distances – from regions with abundant energy resources, to energy-hungry areas thousands of kilometers away.

Green hydrogen featured in a number of emissions reduction pledges at the UN Climate Conference, COP26, as a means to decarbonize heavy industry, long haul freight, shipping, and aviation. Governments and industry have both acknowledged hydrogen as an important pillar of a net zero economy.

The Green Hydrogen Catapult, a United Nations initiative to bring down the cost of green hydrogen announced that it is almost doubling its goal for green electrolysers from 25 gigawatts set last year, to 45 gigawatts by 2027. The European Commission has adopted a set of legislative proposals to decarbonize the EU gas market by facilitating the uptake of renewable and low carbon gases, including hydrogen, and to ensure energy security for all citizens in Europe. The United Arab Emirates is also raising ambition, with the country’s new hydrogen strategy aiming to hold a fourth of the global low-carbon hydrogen market by 2030 and Japan recently announced it will invest $3.4 billion from its green innovation fund to accelerate research and development and promotion of hydrogen use over the next 10 years.

You might encounter the terms ‘grey’, ‘blue’, ‘green’ being associated when describing hydrogen technologies. It all comes down to the way it is produced. Hydrogen emits only water when burned but creating it can be carbon intensive. Depending on production methods, hydrogen can be grey, blue or green – and sometimes even pink, yellow or turquoise. However, green hydrogen is the only type produced in a climate-neutral manner making it critical to reach net zero by 2050.

We asked Dr Emanuele Taibi, Head of the Power Sector Transformation Strategies, International Renewable Energy Agency (IRENA) to explain what green hydrogen is and how it could pave the way towards net zero emissions. He is currently based with the IRENA Innovation and Technology Center in Bonn, Germany, where he is responsible for assisting Member Countries in devising strategies for the transformation of the power sector, and currently managing the work on power system flexibility, hydrogen and storage as key enablers for the energy transition. Dr Taibi is also a co curator for the World Economic Forum’s Strategic Intelligence platform, where his team developed the transformation map on Hydrogen.

Green hydrogen technologies


What motivated you to develop your expertise in energy technologies and how does your work at IRENA contribute to it?


It was during my Master’s thesis. I did an internship in the Italian National Agency for Energy and Environment (ENEA), where I learnt about sustainable development and energy, and the nexus between the two. I wrote my thesis in management engineering about it and decided this was the area where I wanted to focus my working life. Fast forward almost 20 years of experience in energy and international cooperation, a PhD in Energy Technology and time spent in private sector, research and intergovernmental agencies, I currently lead the power sector transformation team at IRENA since 2017.


My work at IRENA is to contribute, with my team and in close cooperation with colleagues across the agency and external partners such as the World Economic Forum, in supporting our 166 Member Countries in the energy transition, with a focus on renewable electricity supply and its use to decarbonize the energy sector through green electrons as well as green molecules like hydrogen and its derivatives.


What is green hydrogen? How does it differ from traditional emissions-intensive ‘grey’ hydrogen and blue hydrogen?


Hydrogen is the simplest and smallest element in the periodic table. No matter how it is produced, it ends up with the same carbon-free molecule. However, the pathways to produce it are very diverse, and so are the emissions of greenhouse gases like carbon dioxide (CO2) and methane (CH4).


Green hydrogen is defined as hydrogen produced by splitting water into hydrogen and oxygen using renewable electricity. This is a very different pathway compared to both grey and blue.


Grey hydrogen is traditionally produced from methane (CH4), split with steam into CO2 – the main culprit for climate change – and H2, hydrogen. Grey hydrogen has increasingly been produced also from coal, with significantly higher CO2 emissions per unit of hydrogen produced, so much that is often called brown or black hydrogen instead of grey. It is produced at industrial scale today, with associated emissions comparable to the combined emissions of UK and Indonesia. It has no energy transition value, quite the opposite.


Blue hydrogen follows the same process as grey, with the additional technologies necessary to capture the CO2 produced when hydrogen is split from methane (or from coal) and store it for long term. It is not one colour but rather a very broad gradation, as not 100% of the CO2 produced can be captured, and not all means of storing it are equally effective in the long term. The main point is that capturing large part of the CO2, the climate impact of hydrogen production can be reduced significantly.

Depending on production methods, hydrogen can be grey, blue or green – and sometimes even pink, yellow or turquoise
Image: International Renewable Energy Agency


There are technologies (i.e. methane pyrolysis) that hold a promise for high capture rates (90-95%) and effective longterm storage of the CO2 in solid form, potentially so much better than blue that they deserve their own colour in the “hydrogen taxonomy rainbow”, turquoise hydrogen. However, methane pyrolysis is still at pilot stage, while green hydrogen is rapidly scaling up based on two key technologies - renewable power (in particular from solar PV and wind, but not only) and electrolysis.


Unlike renewable power, which is the cheapest source of electricity in most countries and region today, electrolysis for green hydrogen production needs to significantly scale-up and reduce its cost by at least three times over the next decade or two. However, unlike CCS and methane pyrolysis, electrolysis is commercially available today and can be procured from multiple international suppliers right now.
Green hydrogen energy solutions


What are the merits of energy transition solutions towards a ‘green’ hydrogen economy? How could we transition to a green hydrogen economy from where we are currently with grey hydrogen?


Green hydrogen is an important piece of the energy transition. It is not the next immediate step, as we first need to further accelerate the deployment of renewable electricity to decarbonize existing power systems, accelerate electrification of the energy sector to leverage low-cost renewable electricity, before finally decarbonize sectors that are difficult to electrify – like heavy industry, shipping and aviation – through green hydrogen.


It is important to note that today we produce significant amount of grey hydrogen, with high CO2 (and methane) emissions: priority would be to start decarbonizing existing hydrogen demand, for example by replacing ammonia from natural gas with green ammonia.


Recent studies have sparked a debate about the concept of blue hydrogen as a transition fuel till green hydrogen becomes cost-competitive. How would green hydrogen become cost competitive vis-à-vis blue hydrogen? What sort of strategic investments need to occur in the technology development process?


The first step is to provide a signal for blue hydrogen to replace grey, as without a price for emitting CO2, there is no business case for companies to invest in complex and costly carbon capture system (CCS) and geological storages of CO2. Once the framework is such that low-carbon hydrogen (blue, green, turquoise) is competitive with grey hydrogen, then the question becomes: should we invest in CCS if the risk is to have stranded assets, and how soon will green become cheaper than blue.


The answer will of course differ depending on the region. In a net zero world, an objective that more and more countries are committing to, the remaining emissions from blue hydrogen would have to be offset with negative emissions. This will come at a cost. In parallel, gas prices have been very volatile lately, leaving blue hydrogen price highly correlated to gas price, and exposed not only to CO2 price uncertainty, but also to natural gas price volatility.


For green hydrogen, however, we might witness a similar story to that of solar PV. It is capital intensive, therefore we need to reduce investment cost as well as the cost of investment, through scaling up manufacturing of renewable technologies and electrolysers, while creating a low-risk offtake to reduce the cost of capital for green hydrogen investments. This will lead to a stable, decreasing cost of green hydrogen, as opposed to a volatile and potentially increasing cost of blue hydrogen.


Renewable energy technologies reached a level of maturity already today that allows competitive renewable electricity generation all around the world, a prerequisite for competitive green hydrogen production. Electrolysers though are still deployed at very small scale, needing a scale up of three orders of magnitude in the next three decades to reduce their cost threefold.


Today the pipeline for green hydrogen projects is on track for a halving of electrolyser cost before 2030. This, combined with large projects located where the best renewable resources are, can lead to competitive green hydrogen to be available at scale in the next 5-10 years. This does not leave much time for blue hydrogen – still at pilot stage today – to scale up from pilot to commercial scale, deploy complex projects (e.g. the longterm geological CO2 storage) at commercial scale and competitive cost, and recover the investments made in the next 10-15 years.


Several governments have now included hydrogen fuel technologies in their national strategies. Given the rising demands to transition towards decarbonization of the economy and enabling technologies with higher carbon capture rates, what would be your advice to policymakers and decisionmakers who are evaluating the pros and cons of green hydrogen?


We will need green hydrogen to reach net zero emissions, in particular for industry, shipping and aviation. However, what we need most urgently is:


1) energy efficiency;


2) electrification;


3) accelerated growth of renewable power generation.


Once this is achieved, we are left with ca. 40% of demand to be decarbonised, and this is where we need green hydrogen, modern bioenergy and direct use of renewables. Once we further scale up renewable power to decarbonise electricity, we will be in a position to further expand renewable power capacity to produce competitive green hydrogen and decarbonise hard-to-abate sectors at minimal extra cost.

How green hydrogen can be produced, converted and used across the energy system.
Image: International Renewable Energy Agency
The future of green hydrogen


Where do you see energy technologies relating to hydrogen evolving by 2030? Could we anticipate hydrogen-powered commercial vehicles?


We see the opportunity for rapid uptake of green hydrogen in the next decade where hydrogen demand already exists: decarbonising ammonia, iron and other existing commodities. Many industrial processes that use hydrogen can replace grey with green or blue, provided CO2 is adequately priced or other mechanisms for the decarbonisation of those sectors are put in place.


For shipping and aviation, the situation is slightly different. Drop-in fuels, based on green hydrogen but essentially identical to jet fuel and methanol produced from oil, can be used in existing planes and ships, with minimal to no adjustments. However, those fuels contain CO2, which has to be captured from somewhere and added to the hydrogen, to be released again during combustion: this reduces but does not solve the problem of CO2 emissions. Synthetic fuels can be deployed before 2030, if the right incentives are in place to justify the extra cost of reduced (not eliminated) emissions.


In the coming years, ships can switch to green ammonia, a fuel produced from green hydrogen and nitrogen from the air, which does not contain CO2, but investments will be needed to replace engines and tanks, and green ammonia is currently much more expensive than fuel oil.


Hydrogen (or ammonia) planes are further away, and these will be essentially new planes that have to be designed, built and sold to airlines to replace existing jet-fuel-powered planes – clearly not feasible by 2030: in this sense, green jet fuel – produced with a combination of green hydrogen and sustainable bioenergy – is a solutions that can be deployed in the near term.


In conclusion, the main actions to accelerate decarbonisation between now and 2030 are 1) energy efficiency 2) electrification with renewables 3) rapid acceleration of renewable power generation (which will further reduce the already low cost of renewable electricity) 4) scale up of sustainable, modern bioenergy, needed - among others - to produce green fuels that require CO2 5) decarbonisation of grey hydrogen with green hydrogen, which would bring scale and reduce the cost of electrolysis, making green hydrogen competitive and ready for a further scale up in the 2030s, towards the objective of reaching net zero emissions by 2050.


The World Economic Forum is a longstanding supporter of the clean hydrogen agenda since 2017, having helped -inter alia- with the creation of the Hydrogen Council, the establishment of a hydrogen Innovation Challenge in partnership with Mission Innovation, and the creation, together with the Energy Transitions Commission, of the Mission Possible platform to help transition hard-to-abate sectors to net zero emissions by 2050. Read more on the Accelerating Clean Hydrogen Initiative here.
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Written by

Abhinav Chugh, Acting Content and Partnerships Lead, World Economic Forum

Emanuele Taibi, Head of the Power Sector Transformation Strategies, International Renewable Energy Agency

The views expressed in this article are those of the author alone and not the World Economic Forum.





CleanTechnica
~0.03% Of Hydrogen Is Green Hydrogen




CLEAN POWER
By Zachary Shahan
Published3 days ago

It seems that 95% of headlines and stories about hydrogen focus on green hydrogen, yet green hydrogen is barely present here on planet Earth. So, how much of a disservice is being done to society by all of these headlines and articles implying that hydrogen is clean?

When Mike Barnard interviewed Paul Martin for CleanTech Talk a few months ago, one stat caught my attention above all else — that 0.1% of global hydrogen production came from “green hydrogen” (hydrogen produced by splitting water using electricity produced by clean, renewable power). The focus of their discussion was the “Hydrogen Ladder.” (Read about part one and part two for more commentary, or listen to the podcasts — embedded below.)

While I knew that “green hydrogen” was mostly hype, small science projects, and a dream for the future, I didn’t realize it was just 0.1% of global hydrogen production. That stunningly low figure makes the hydrogen hype all the more irritating. You can listen to the full, super informative interview here:

Looking around the internet (thanks, Google), I couldn’t find much reference to this figure of 0.1% (or actually less than 0.1%) of global hydrogen production being green hydrogen production (ugh, Google). I did find a CNBC article from a year ago citing an International Energy Agency (IEA) report and saying, “less than 0.1% of hydrogen today is produced through water electrolysis.” That led me to this report from June 2019. It stated, “While less than 0.1% of global dedicated hydrogen production today comes from water electrolysis, with declining costs for renewable electricity, in particular from solar PV and wind, there is growing interest in electrolytic hydrogen.” Ah, yes, interest.

Luckily, Google did swiftly show me that there’s an updated report published in October 2021 and revised in November 2021, Global Hydrogen Review 2021. So, with all of this interest in green hydrogen in the past few years, where are we at?

The new report indicates that “water electrolysis made up ~0.03%” of global hydrogen production last year. That’s right — not even 0.3%, but a lowly 0.03%! It doesn’t show up on a pie chart of hydrogen sources, of course. (See image at top.) Nonetheless, headline after headline is about “green hydrogen.” Is the hype around green hydrogen doing more damage than good, or is it spurring on a yet-to-sprout green industry?

If you want to count carbon capture, utilization, and storage (CCUS), it provided another 0.7% of global hydrogen supply in 2020. However, that’s from 16 fossil fuel plants, and the CCUS components of the plants are surely heavily subsidized and are quite expensive methods of getting hydrogen. Many experts argue this can never be cost-competitive.

At the end of the day, the following chart shows three things: “green hydrogen” expectations from projects under construction or planned, the amount of it that is in country pledges by 2030, and the amount needed for an IEA net zero emissions scenario.



As it stands, despite all of the hype, the green hydrogen market is looking a bit anemic, and the 2030 projections based on plans or even pledges are not where the world needs it to be. Green hydrogen proponents will say that means that more money needs to be tossed at green hydrogen. Critics will say that we are throwing our money away on many of these green hydrogen projects and programs, money that could be used to fund more capital-efficient decarbonization tech.

The two bottom lines of this matter, in my opinion, are: 1) any funding for green hydrogen needs to be focused on solutions that have a serious chance at becoming cost competitive and thus truly useful in the effort to decarbonize, and 2) any coverage of green hydrogen needs to put this industry in context, should explain where 99.97% of hydrogen comes from, and should at least bring to mind why it is that fossil fuel companies are so keen on hyping the green hydrogen dream.
 CleanTechnica.com


Namibia eyeing emerging market for green hydrogen: WSJ



https://arab.news/nqvz4
Updated 25 December 2021
ARAB NEWS

RIYADH: Namibia is one of many countries seeking to cash in on the green energy rush and it is positioning itself as a leader in the emerging market for green hydrogen, The Wall Street Journal reported.

Many experts agree that “green” hydrogen, a carbon-friendly nontoxic gas produced using renewable energy, can play a significant role in achieving a green gas-neutral economy by 2050, helping to combat global warming.

The southwest African nation is already “putting up to €40 million ($45.3 million) from Germany to use on on feasibility studies and pilot projects related to so-called green hydrogen.”

“Germany’s government says Namibia’s natural advantages could help it produce the world’s cheapest green hydrogen — a crucial ingredient in policies hoping to cut carbon emissions to the net-zero benchmark by 2050,” the WSJ reported.

“The list is quite short of those new potential large renewable capable countries and Namibia is there,” the reported quoted Noel Tomnay, global head of hydrogen consulting at Wood Mackenzie, as saying. But he also pointed to significant challenges. “Infrastructure, suitable water and just the uncertainty associated with someone who’s not been doing that in the past on a large scale,” he said.

According to the report, several global players expressed interest after Namibia’s government put out a request for proposals to develop two separate but adjacent sites, where it envisions massive desalination plants.

The sites would also include wind and solar farms as well as electrolysers — systems that use electricity to split water into hydrogen and oxygen—which would be used to produce green hydrogen and ammonia for export.

Namibia received nine bids from six developers for the two sites, including South Africa’s Sasol Ltd., Australia’s Fortescue Metals Group Ltd. and Germany’s Enertrag AG—a shareholder in Hyphen Hydrogen Energy (Pty) Ltd., which has been awarded both sites.

In the global race for green hydrogen, Namibia is the latest sub-Saharan African country with major natural assets to position itself as a potential green energy hub.

The Hydrogen Stream: Storing hydrogen in offshore caverns

The European Commission has approved, under EU state aid rules, a €900 million German scheme to support investment in the production of renewable hydrogen in non-EU countries, which will be then imported to the EU. “The scheme, called H2Global, aims at meeting the EU demand for renewable hydrogen that is expected to significantly increase in the coming years, by supporting the development of the unexploited renewable resource potential outside the EU,” wrote the commission yesterday. The ten-year project will be managed by special-purpose entity Hint.co. “This intermediary will conclude long-term purchase contracts on the supply side ([for] green hydrogen production) and short-term resale contracts on the demand side (green hydrogen usage),” said the commission. Prices will be determined via a double-auction model, where the lowest bid price for hydrogen production and the highest selling price for hydrogen consumption will each be awarded contracts.

Spanish company H2B2 Electrolysis Technologies is developing a project to generate up to 1,000kg per day of solar-powered emission-free hydrogen in California. The SoHyCal project, in Fresno County, consists of the construction, financing and operation of a renewable hydrogen production plant using polymer electrolyte membrane (PEM) technology, and with a nameplate capacity of up to 3,000kg per day.

The government of Western Australia is backing its hydrogen industry with three projects set to receive support from its lead agency services. Province Resources' HyEnergy Project will harness 8 GW of solar and wind power generation capacity to produce around 550,000 tons of hydrogen per year. The Murchison Hydrogen Renewables facility will use solar and wind to produce 5.2 GW of electricity to power the production of hydrogen which will be converted into 2 million tons of green ammonia annually. It is expected InterContinental Energy's Western Green Energy Hub will use up to 50 GW of solar and wind capacity to produce up to 3.5 million tons of hydrogen or 20 million tons of green ammonia per year.

Hydrogen-powered equipment was mentioned as part of Hyundai Construction Equipment‘s plan to invest €150 million into its Ulsan production plant, in South Korea, to increase capacity by 50% to more than 15,000 machines per year. “The move will support Hyundai’s growing presence in the booming global construction equipment market while providing a manufacturing base for a new generation of electric and hydrogen-powered equipment,” the company wrote yesterday.

Sweden has shown it has the potential to become a pioneer in green steel production, according to a note released today by U.S.-owned analyst Wood Mackenzie. The Nordic nation produces 3.2% of the crude steel made in the EU and U.K. Sweden's steelmakers expected to bank on the cost reductions offered by alkaline electrolysis technology, as well as benefiting from the declining cost of renewables and rising carbon prices, according to WoodMac. “At a levelized cost of electricity at $30/MWh, wind power is a highly economical source of power generation in Sweden today,” wrote the analyst. “Further cost reductions are expected, with better financing structures for onshore wind, lower capex [capital expenditure levels] for onshore and offshore installations, technological optimization for asset management, and state support for offshore grid infrastructure.” WoodMac added, the combination of hydrogen from alkaline electrolysis and energy from onshore wind is the most cost-effective option for green crude steel production in Sweden. “Assuming a carbon price of $100/ton, green steel producers could benefit from $85/ton of carbon credits,” wrote the analyst. “Better financing models for onshore wind and 48% lower capex for alkaline technology in 2025, yield [a] steel cost of $360-390/ton in carbon price scenarios ranging between $50/ton and $150/ton.”

This copy was amended on 21/12/21 to add details of the SoHyCal project.

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Tuesday, August 17, 2021

UK Government reveals plans for £4bn hydrogen investment by 2030

Low-carbon hydrogen economy could also create thousands of jobs


Hydrogen could cover 20-35% of the UK’s energy consumption by 2050, providing a cleaner alternative to fossil fuels. Photograph: Alamy


Jillian Ambrose 
Energy correspondent
THE GUARDIAN
Tue 17 Aug 2021 

The government hopes to attract at least £4bn of investment to the hydrogen economy by 2030 under plans to produce the equivalent of enough hydrogen to replace fossil fuel gas for heating and cooking in about 3m households in the UK.

The government has published its long-awaited plans for a UK-wide hydrogen economy, which it says could be worth £900m and create more than 9,000 high-quality jobs by the end of the decade, rising to £13bn and 100,000 new jobs by 2050.

The strategy document lays out its efforts to attract investment in 5 gigawatts of hydrogen production by 2030, which would mostly power heavy industry, as well as transport and up to 70,000 homes. It suggests hydrogen could cover 20-35% of the UK’s energy consumption by 2050, providing a clean alternative to oil and gas in energy-intensive industries, power and transport

It proposes a series of industry consultations to help establish a subsidy system to support large hydrogen projects to decarbonise areas that cannot run on electricity.

However, the plans remain dogged by uncertainty over how the government will determine a fair subsidy for the multibillion-pound projects and whether the cost will be shouldered through household bills or by the Treasury. The government has promised more clarity after an industry consultation later this year.

Matthew Fell, the chief UK policy director at the CBI, said the strategy included important steps for the economy-wide hydrogen sector.

“However, to truly capitalise on those large-scale economic opportunities, and unlock the private sector finance needed, firms will now be looking for the government to provide detailed policies and standards for hydrogen production and application,” he said.

The hydrogen projects under development include “green hydrogen” schemes, which extract hydrogen from water, leaving only oxygen as a byproduct, and “blue hydrogen”, which extracts hydrogen from fossil fuel gas before trapping the greenhouse gas emissions that are left behind.

However, last week a study by academics at Cornell and Stanford universities in the US, warned that blue hydrogen could be up to 20% worse for the climate than fossil gas owing to the emissions that escape during its production, multiplied by the amount of gas required to make the equivalent amount of energy from hydrogen.

The government says it will set out emissions standards for blue hydrogen projects to ensure they capture enough greenhouse gas emissions during hydrogen production to qualify as “low carbon”, but many environmentalists and green energy producers have put pressure on the government to drop its support for blue hydrogen altogether.

The strategy paper does not set out a vision for the balance of blue and green hydrogen in the future, despite a clear instruction from its official climate advisers at the Committee on Climate Change (CCC) to include a pathway for each to 2035.


The CCC has supported plans for a “blue hydrogen bridge” to play a role in supplementing green hydrogen over the near-term because it could begin displacing fossil fuels sooner and at a greater scale than green hydrogen projects. However, critics of blue hydrogen fear a long-term commitment could extend the UK’s reliance on fossil fuels.

Doug Parr, the chief scientist for Greenpeace UK, warned that producing large quantities of hydrogen from fossil gas would lock the UK “into costly infrastructure that is expensive and … may be higher carbon than just burning the gas”.


Dan McGrail, the chief executive of RenewableUK, said the national strategy “doesn’t focus nearly enough on developing the UK’s world-leading green hydrogen industry” and should “set out a clear ambition for green hydrogen”.

“We’re urging the government to set a target of 5GW of renewable hydrogen electrolyser capacity by 2030 as well as setting out a roadmap to get us there, to show greater leadership on tackling climate change,” he said.

This article was amended on 17 August 2021. The government originally stated that the hydrogen production could replace fossil gas in about 3m UK households. It has since clarified that it was referring to the equivalent of current household fossil gas usage and that the hydrogen will predominantly be used by heavy industry.

UK plan to replace fossil gas with blue hydrogen ‘may backfire’



Academics warn ‘fugitive’ emissions from producing hydrogen could be 20% worse for climate than using gas

Whitelee windfarm in East Renfrewshire. Researchers recommended governments focus on green hydrogen made from wind and solar energy. Photograph: PA


Jillian Ambrose 
Energy correspondent
THE GUARDIAN
Thu 12 Aug 2021 

The government’s plan to replace fossil gas with “blue” hydrogen to help meet its climate targets could backfire after US academics found that it may lead to more emissions than using gas.

In some cases blue hydrogen, which is made from fossil gas, could be up to 20% worse for the climate than using gas in homes and heavy industry, owing to the emissions that escape when gas is extracted from the ground and split to produce hydrogen.

The process leaves a byproduct of carbon dioxide and methane, which fossil fuel companies plan to trap using carbon capture technology. However, even the most advanced schemes cannot capture all the emissions, leaving some to enter the atmosphere and contribute to global heating.

Professors from Cornell and Stanford universities calculated that these “fugitive” emissions from producing hydrogen could eclipse those associated with extracting and burning gas when multiplied by the amount of gas required to make an equivalent amount of energy from hydrogen.

Robert Howarth, a Cornell University professor and co-author of the study, said the research was the first to be published in a peer-reviewed journal to lay bare the “significant lifecycle emissions intensity of blue hydrogen”.

The paper, which will be published in Energy Science and Engineering, warned that blue hydrogen may be “a distraction” or “something that may delay needed action to truly decarbonise the global energy economy”.

The researchers recommended a focus on green hydrogen, which is made using renewable electricity to extract hydrogen from water, leaving only oxygen as a byproduct.

“This is a warning signal to governments that the only ‘clean’ hydrogen they should invest public funds in is truly net zero, green hydrogen made from wind and solar energy,” Howarth said.

A spokesperson for the UK government said hydrogen would be “essential for meeting our legally binding commitment to eliminating the UK’s contribution to climate change by 2050” and promised further details in the government’s forthcoming hydrogen strategy, which is expected next month.

“Independent reports, including that from the Climate Change Committee, show that a combination of blue and green hydrogen is consistent with reaching net zero but alongside the strategy, we will consult on a new UK standard for low-carbon hydrogen production to ensure the technologies we support make a real contribution to our goals,” the spokesperson said.


Hydrogen power offers jobs boost, says government

By Paul Rincon
Science editor, BBC News website
Published15 hours ago
Hydrogen fuel cells can power vehicles

Thousands of new jobs could be created by investing in low-carbon hydrogen fuel to power vehicles and heat homes, the government says.

Ministers have unveiled a strategy for kick-starting a hydrogen industry, which they say could attract billions of pounds in investment.

Business Secretary Kwasi Kwarteng said the fuel was also essential for UK efforts to reach net zero emissions.

He said it had the potential to provide a third of UK energy in future.

Because of the current higher cost involved in producing hydrogen compared to existing fuels, subsidies have been proposed to overcome the gap. The government has launched a consultation on this plan.

Labour also backs hydrogen's potential, but said the government had failed to invest as much as other countries.

Using hydrogen gas as a fuel produces no carbon dioxide (CO2) pollution. It can be used to power fuel cells - devices that generate electricity through an electrochemical reaction - used in a turbine for electricity or burned in a boiler and vehicle engine.

As such, it is a low-carbon, versatile fuel that can be used by cars, trucks and trains, heat our homes and generate the power needed for industrial processes such as steel production.

Is the hydrogen tech 'revolution' hope or hype?

Can hydrogen fuel help drive towards green future?

The government plans to deliver 5GW of hydrogen production capacity by 2030, estimating that the industry could be worth £900m and support more than 9,000 jobs by the same date.

Hydrogen-powered trains are undergoing tests
The Hydroflex made a 25-mile round-trip in Warwickshire, reaching speeds of up to 50 mph


"Today marks the start of the UK's hydrogen revolution. This home-grown clean energy source has the potential to transform the way we power our lives and will be essential to tackling climate change and reaching net zero," said Mr Kwarteng.

"Our strategy positions the UK as first in the global race to ramp up hydrogen technology and seize the thousands of jobs and private investment that come with it."

Reaching net zero by 2050 will involve cutting emissions as much as possible and then balancing out any remaining ones by planting trees or burying CO2 underground.

The potential role of hydrogen in achieving this target has been highlighted by a government analysis suggesting 20-35% of the UK's energy consumption by 2050 could be hydrogen-based.

A low-carbon hydrogen economy could deliver emissions savings equivalent to the carbon captured by 700 million trees by 2032, the government claims. It would help decarbonise polluting industries such as chemical production and oil refining and heavy transport such as shipping and rail.

Experts say there is an urgent need to reduce emissions from home heating

Alan Whitehead MP, Labour's shadow minister for energy and the green new deal, said hydrogen power had a "significant role" to play in decarbonising the economy.

But he added: "The belated publication of this hydrogen strategy needs to be followed up with urgent action. That is what we will judge the government on because too many of the Tories' warm words and targets on climate change have not been followed up with practical steps.

"It is regrettable that the Conservatives have failed to match the investment shown by other countries and key decisions have been delayed, such as mandating that all boilers must be hydrogen-ready."

The government is proposing subsidies for the hydrogen industry along the lines of those credited with driving down the cost of offshore wind power.

It will also review the infrastructure - thought by some to be very costly - needed to underpin hydrogen power in the UK.

Ministers want a twin-track approach to hydrogen production.

So-called blue hydrogen is made using fossil fuels, but its environmental impact can be mitigated by capturing and storing greenhouse emissions underground. Green hydrogen, meanwhile, is made using renewable energy.

Though blue hydrogen is not as clean as the green form, it is cheaper.


Environmental campaigners say there is too much focus in the strategy on blue hydrogen. Jess Ralston, an analyst at the Energy and Climate Intelligence Unit, said the government should "be alive to the risk of gas industry lobbying causing it to commit too heavily to blue hydrogen and so keeping the country locked into fossil fuel based technology". This, she added, would make reaching net zero more difficult and costly.

Philip Dunne MP, chair of the environmental audit committee, commented: "While the twin track approach proposed, supporting both green and blue hydrogen production, is positive, it is also important that substantial capacity for carbon capture is developed, so as to avert release of damaging emissions currently created in blue hydrogen production."

In fact, one study by researchers in the US has suggested that blue hydrogen could release more carbon than burning natural gas.

Dr Jan Rosenow, from the Regulatory Assistance Project, an organisation dedicated towards accelerating the transition to clean energy, said: "As the strategy admits, there won't be significant quantities of low-carbon hydrogen for some time. We need to use it where there are few alternatives and not as a like-for-like replacement of gas.

He said the plan confirmed that "hydrogen for heating our homes will not play a significant role before 2030. The government's strategy shows that less than 0.2% of all homes are expected to use hydrogen to keep warm in the next decade. This means that for reducing emissions this decade, hydrogen will play only a very marginal role.

"But we cannot wait until 2030 before bringing down emissions from heating. The urgency of the climate crisis requires bold policy action now."

Green hydrogen 'transitioning from a shed-based industry' says researcher as the UK hedges its H2 strategy

Am I blue? Am I green? Government report isn't quite transparent
THE REGISTER ®
Tue 17 Aug 2021 

The UK government has released its delayed hydrogen strategy which – in a strange move for a colourless gas – hedges its bets between green and blue.

The government claimed the UK-wide hydrogen economy could be worth £900m by 2030, potentially £13bn by 2050. In the next 10 years the universe's most abundant element could decarbonise energy-intensive industries like chemicals, oil refineries, power and heavy transport by helping these sectors move away from fossil fuels, it claimed.

Light, energy-intensive and carbon-free "hydrogen-based" solutions could make up to 35 per cent of the UK's energy consumption by 2050, helping the nation meet its target of net-zero emissions by 2050, according to the government paper.

But navigation from the current state of the hydrogen industry to that worthy destination might require some tricky manoeuvres. The vast majority of industrial hydrogen is extracted from natural gas [PDF] in a process that releases greenhouse gasses and requires energy, which often comes from carbon fuels.

In theory, the simplest way to overcome this problem is to use renewable electricity to extract hydrogen from water using electrolysis – so called green hydrogen. The problem is, although it works in the lab, the process has yet to be industrialised on a scale comparable with other fuels in the global energy supply chain. Green hydrogen received a fillip as researchers found methods to make electrolysis more efficient at lower capital costs.

An alternative is to continue to use natural gas as a source of hydrogen but to capture and store the methane and CO2 byproduct, and use renewable energy to power the process. But a recent study found making blue hydrogen was 20 per cent worse for the climate than just using fossil gas over its entire lifecycle.
Light on detail – and how are we producing it?

The UK government is hedging its bets, its strategy outlining a "twin track" approach to supporting multiple technologies including green and blue hydrogen production.

Critics have jumped on the plans for blue hydrogen. Doug Parr, the chief scientist for Greenpeace UK, told The Guardian that extracting large quantities of hydrogen from natural gas would lock the UK "into costly infrastructure that is expensive and … may be higher carbon than just burning the gas."

Speaking to The Register, Malte Jansen, Imperial College London research associate, said: "We may have reached a point in the battling climate change where I wouldn't want to be dogmatic about one or another. But if either technology delivers and fixes to climate problems by 2050, then that's good."

While blue hydrogen faced the challenge of capturing CO2 effectively and avoiding methane leakage, green hydrogen production was still maturing, he said.

"The industry is transitioning from a shed-based industry to a full-blown, highly automated one. I'm not dismissing the sort of level of technical intricacy, but there's still a lot of steps in the production of electrolysis that involve manual labour that could be automated."

While the UK government commitment could help the industry invest and raise capital, as other nations release hydrogen strategies – Germany already has one for example – the balance is likely to be in favour of green hydrogen, Malte said.

"I do not see the same level of push on blue hydrogen, people are talking about it but not just quite on the same global scale with that same level of excitement as green hydrogen," he said.

While it was a good start, the UK strategy needs more detail, Malte said.

But industries might have to wait a little longer for vital details. The strategy was already delayed because of Parliament's summer recess.

What the government has now published is a public consultation on a preferred hydrogen business model leaving many pieces of the jigsaw yet to find their places.

These include how it might build a system similar to the offshore wind industry's Contract for Difference, which gave investors confidence despite fluctuating energy prices. At the same time, the government is consulting on the design of the £240m Net Zero Hydrogen Fund, which aims to support the commercial deployment of new low carbon hydrogen production plants across the UK. Details on that and the blue and green hydrogen strategy would emerge in 2022 on the government's production strategy. ®



Hydrogen Strategy | Four key takeaways for civil engineers


17 AUG, 2021 BY CATHERINE KENNEDY

The UK’s first-ever Hydrogen Strategy has been released today.

The plan drives forward the commitments laid out in prime minister Boris Johnson’s ambitious 10 Point Plan for a green industrial revolution, setting the foundation for how the government will work with industry to meet its ambition for 5GW of low carbon hydrogen production capacity by 2030.

This could replace natural gas in powering around 3M UK homes each year as well as powering transport and businesses, particularly heavy industry.

Here are four key takeaways for civil engineers:

Technologies

The Hydrogen Strategy outlines a ‘twin track’ approach to supporting multiple technologies including ‘green’ electrolytic and ‘blue’ carbon capture-enabled hydrogen production, and committing to providing further detail in 2022 on the government’s production strategy
Infrastructure

A review will be undertaken to support the development of the necessary network and storage infrastructure to underpin a thriving hydrogen sector

Action plan


A hydrogen sector development action plan will be launched in early 2022 setting out how the government will support companies to secure supply chain opportunities, skills and jobs in hydrogen

Government support


The strategy also details further support the UK government is providing for hydrogen projects, including:

£240M Net Zero Hydrogen Fund to support new hydrogen production projects

Up to £60M through the Low Carbon Hydrogen Supply 2 competition to support innovative hydrogen production, transport and storage technologies

Up to £183M for transport decarbonisation, including trials and roll-outs of hydrogen technologies for buses, HGV lorries, shipping and aviation. This will include:

up to £120M this year through the Zero Emission Bus Regional Areas (ZEBRA) scheme towards 4,000 new zero emission buses, either hydrogen or battery electric, and infrastructure needed to support them

up to £20M this year to design trials for both electric road system and hydrogen long haul heavy road vehicles (HGVs) and to run a battery electric trial to establish the feasibility, deliverability, costs and benefits of each technology

up to £20M this year for the Clean Maritime Demonstration Competition
up to £15M this year for the ‘Green Fuels, Green Skies’ competition to support the production of first-of-a-kind sustainable aviation fuel plants in the UK

£3M this year to support the development of a Hydrogen Transport Hub in Tees Valley, and £4.8M (subject to business case) to support the development of a hydrogen hub in Holyhead, Wales

A booming, UK-wide hydrogen economy could be worth £900M and create over 9,000 high-quality jobs by 2030, potentially rising to 100,000 jobs and worth up to £13bn by 2050. By 2030, hydrogen could play an important role in decarbonising polluting, energy-intensive industries like chemicals, oil refineries, power and heavy transport like shipping, HGV lorries and trains, by helping these sectors move away from fossil fuels. Low-carbon hydrogen provides opportunities for UK companies and workers across our industrial heartlands.

With government analysis suggesting that 20-35% of the UK’s energy consumption by 2050 could be hydrogen-based, this new energy source could be critical to meet targets of net zero emissions by 2050 and cutting emissions by 78% by 2035.

The government has also launched a public consultation on a preferred hydrogen business model to overcome the cost gap between low carbon hydrogen and fossil fuels, helping the costs of low-carbon alternatives to fall quickly.

Business & energy secretary Kwasi Kwarteng said that today "marks the start of the UK's hydrogen revolution".

"This home-grown clean energy source has the potential to transform the way we power our lives and will be essential to tackling climate change and reaching net zero," he said.

"With the potential to provide a third of the UK’s energy in the future, our strategy positions the UK as first in the global race to ramp up hydrogen technology and seize the thousands of jobs and private investment that come with it."

Energy & climate change minister Anne-Marie Trevelyan added: "Today’s Hydrogen Strategy sends a strong signal globally that we are committed to building a thriving low carbon hydrogen economy that could deliver hundreds of thousands of high-quality green jobs, helps millions of homes transition to green energy, support our key industrial heartlands to move away from fossil fuels and bring in significant investment."

Reaction


Energy and Climate Intelligence Unit analyst Jess Ralston

“A strong hydrogen economy in the UK could cement our place as a green industrial leader if the right action is taken early. The fuel could be very valuable for cleaning up steel production and protecting jobs in this industry – crucial when Europe is already steaming ahead with 23 hydrogen steel plants when we have none. But some questions remain over whether the government has truly grasped which areas will be most suitable for hydrogen use and which will not.

“For example the case for hydrogen for home heating is far from proven, particularly hydrogen derived from fossil gas rather than from renewable energy. After all, any remaining fossil gas with a hydrogen blend in the grid is just not compatible with net zero and it’s not yet clear how effective hydrogen will be, nor how much it will cost.

“The government should also be alive to the risk of gas industry lobbying causing it to commit too heavily to blue hydrogen and so keeping the country locked into fossil fuel based technology, making reaching net zero more difficult and costly. Instead, focussing on green hydrogen could unlock the our full industrial potential, bringing with it lifelong jobs in places like the North East, supporting both the government’s climate goals and its levelling up ambitions.”

Ramboll UK energy market director John Mullen

“What this strategy will finally deliver, and what is really needed, is the business assurance that investment in hydrogen infrastructure and technology is a good bet. Hydrogen presents us with an excellent opportunity to repurpose and make use of existing infrastructure already in place for fossil fuels to support a burgeoning new frontier in the UK energy sector.

However as a developing market the government should be seizing the opportunity by providing investment and the development of a concrete action plan now, rather than making us wait until 2022. Transitioning away from gas will require investment, and we need to ensure the support is there for upskilling and learning if we are to reach their 2030 goals. Effective regulatory frameworks and financial incentives are also needed for hydrogen to work in synergy with existing technologies”

“Hydrogen is often presented as a silver-bullet solution to the UK’s carbon and climate concerns, but relying on it alone will not solve the UK’s challenge when it comes to the challenge of meeting Net Zero. Although a key part of the puzzle for parts of the energy industry, it will only hold around 5-10% of the UK’s energy mix and we cannot take our eye off broader investment and support for renewable energies.

“There are also still distinct challenges to overcome and the ‘twin track’ approach will need to be closely monitored as Blue Hydrogen and Carbon Capture are incredibly inefficient processes at present and the only justification for their use is to allow for the transition to a green hydrogen world. Blue hydrogen could be used to support business cases to implement new Hydrogen infrastructure, however the government needs to put a cap on the greenhouse gasses produced and place a deadline for the end of all blue hydrogen production in the next 10 to 15 years.”

Hydrogen Taskforce Secretariat co-lead Clare Jackson

“Today’s Hydrogen Strategy is a landmark moment for the sector. By setting clear direction for the development of the hydrogen sector, it offers a framework which will enable businesses to invest in hydrogen projects.

“This is a vital first step towards unlocking hydrogen’s huge potential for the UK but there is still much to be done to scale up hydrogen solutions. As our research has shown, hydrogen has a crucial role to play in decarbonising industry, generating power, transport and heating homes, while boosting job creation, sustaining local industries and supporting UK innovation in energy.

“We look forward to seeing further crucial steps towards this low carbon future, such as implementation of the Government’s proposed business models for hydrogen. The Taskforce and its members are ready to deliver the vision for a low carbon UK detailed in the Hydrogen Strategy.”

HyNet North West project director David Parkin

“Industry across the UK’s North West industrial heartland is crying out for low carbon hydrogen so we welcome the promise of more support. HyNet is driven by demand from organisations across the region who are committed to the decarbonisation of their processes. This includes over 20 major industrials, many of whom are households names, who have signed up to switch to HyNet hydrogen, replacing the natural gas fossil fuel they currently use to support the drive to net zero.

“We are working at pace. With initial engineering nearly completed on HyNet’s first hydrogen production plant at Essar’s Stanlow Manufacturing Complex, hydrogen production will begin as soon as 2025 and deliver up to 4GW of low carbon hydrogen by 2030 - nearly 80% of the UK target in the new hydrogen strategy. Large scale demonstrations of industrial fuel switching from natural gas will begin shortly with NSG Pilkington in the world’s first large scale glass manufacturing using hydrogen.

“The key now is for the government to build momentum by prioritising projects that are ready for development today. The sooner we get hydrogen to business, the better they can protect jobs and compete internationally while cutting emissions. The UK should seize the opportunity to lead the world in hydrogen as it did offshore wind.”

National Grid hydrogen director Antony Green

"The transition to a green economy will require a mix of technologies and hydrogen will play a vital role. This strategy signals the UK’s commitment to hydrogen and provides the certainty needed to boost consumer and investor confidence and support commercial solutions.

"Importantly, unlocking the potential of hydrogen as a clean energy solution requires significant pace and innovation to scale up production, and the guidance from government today will be key to triggering the investment and buy-in needed to achieve this."

Energy UK chief executive Emma Pinchbeck

"Hydrogen and CCUS are going to be incredibly valuable for sectors that will be difficult to decarbonise with electricity – and so we welcome that today’s Hydrogen Strategy takes an economy-wide approach to developing these innovative technologies.

"The UK has real potential for hydrogen and CCUS, both of which can deliver new skilled jobs, particularly in places where the UK already has a proud industrial and energy heritage."

National Infrastructure Commission chair Sir John Armitt

“This strategy provides a platform for hydrogen to take its place as part of the solution for decarbonising our economy. The proposed twin-track approach to both blue and green hydrogen development presents a realistic pathway to meet the breadth of potential uses across different parts of the economy including industry, transport and power. As recognised by government, it is vital that we concentrate on truly low carbon hydrogen production, and therefore the proposed development of technical standards is welcome.

“The big question is how to drive down the costs of hydrogen production, and its relationship with the low cost of natural gas. That will only happen by scaling up production, so alongside the positive measures to kick start the sector there needs to be a longer term funding model that provides investor confidence in the same way the UK has successfully achieved in the offshore wind sector. Government will also need to decide how best to ensure the cost of natural gas reflects the cost of carbon.

“Clarity on where the costs will fall in such a model, and how they will be distributed fairly, is needed soon in order to secure industry and public confidence and support.

“This strategy is an important milestone, and industry will now look forward to seeing details of the business model, funding mechanism and sector development plan in the coming months.”

Saturday, August 07, 2021

 HYDROGEN UPDATES

The weekend read: ‘Hydrogen is the flagship of the energy transition’

Ankica Kovač

From pv magazine 07/2021

Your laboratory at the University of Zagreb has its own solar power plant and green hydrogen production – what is the nature of your research there?

This solar power plant, which I am very proud of, is installed on the roof of the Power Engineering Laboratory and serves for green hydrogen production. The electrolyzer is installed in the first Croatian hydrogen refueling station, located in front of my lab. With a pressure of 30 bar, this HRS (Hydrogen Refueling Solution) serves the first Croatian hydrogen-powered bicycle, which was also developed in my lab.

At the moment I am working on improving the system of green hydrogen production via solar electrolysis. This implies both fundamental and development research in the new design of electrolyzer stack of improved efficiency, as well as applied research on commercially available system components such as PEM (polymer electrolyte membrane) electrolyzer stack, PEM fuel cell stack, and hydrogen storage tank. Also, a novel system component that attracted my attention recently is the electrochemical hydrogen compressor. It operates similarly to a PEM electrolyzer in the context of the membrane, but as the technology is so new, I am still learning. But novel innovation like this compressor is exactly why I am so passionate about hydrogen technology; it opens a large space for the realization of great research curiosity.

You’re a guest editor for the International Journal of Hydrogen Energy. In your recent “Hydrogen in energy transition: A review” article, you tracked the progress of green hydrogen. How would you say the technology and its applications currently stand? And where do you see it in the near future?

According to the EU hydrogen strategy, the key to an accelerated transition to renewable energy sources (RES) is energy storage, and especially green hydrogen storage. If hydrogen systems were built next to the systems that use RES, the surplus electricity from RES variability and intermittency could be stored. Future production, according to current projections, is still from solar and wind energy, but the compensation for variability goes to hydrogen. The energy transition to RES is urgently needed on a large scale due to the threat of climate change, and it can be accelerated by reliance on mass green hydrogen production.

In the near future I expect some expansion of green hydrogen-powered FCEVs, as well as the replacement of natural gas with green hydrogen in steel production, fertilizer production, and, in part, for heating buildings where justified. Green hydrogen will also be used in the production of synthetic fuels for aircraft and ships.

Hydro bike
Kovač’s lab developed Croatia’s first hydrogen-powered bicycle.Image: Ankica Kova

Croatia is in the process of implementing a national hydrogen strategy. What will the green hydrogen market look like in Croatia compared to other European nations?

The government established an expert working group of 11 members to draft a proposal for the Croatian Hydrogen Strategy.

The strategy will give a national vision of development, research, production, infrastructure, and the use of hydrogen and hydrogen technology, with the goal to contribute to climate neutrality by 2050, as well as national targets related to the development of infrastructure for alternative fuels. The goal of the strategy is the decarbonization of hydrogen production and the use of green hydrogen as a substitute for fossil fuels. Croatia’s hydrogen strategy will send a clear message to all those interested in investing in hydrogen technology that the state is on their side.

I believe that Croatia can find its place in the hydrogen energy economy in all four areas of hydrogen technology, from production, through storage to transport and the use of green hydrogen. I have stated many times and I repeat it now: The current situation is such that Croatian companies with investments in green hydrogen cannot make a mistake. Among other things, I would like to emphasize the possibility of involving Croatian companies in the equipment production sector (such as electrolyzers and fuel cells, valves, measuring and control equipment, sensors, etc.) which would ensure the rise of the Croatian economy on the European and world market stage. Here I would especially like to point out shipbuilding with hydrogen as a propellant and electric propulsion (hydrogen fuel cells plus electric motors) in maritime transport. It is still a relatively undeveloped area [hydrogen ships] and I am sure that Croatia has a lot to offer. Now we have an extraordinary opportunity to create a Croatian hydrogen brand. The only thing we have to do at this time is to be brave: dare to sail in these, for Croatian companies, slightly unknown waters, and the result will not be missed.

On the world stage, the demand for hydrogen systems is currently such that soon the existing production capacities will not be able to meet all the demand. If that’s not a good enough invitation for our companies, then I don’t know what is.


What do you see as the biggest challenge for the development of green hydrogen?

The biggest challenge I see is that the consequences of global temperature increase above 2°C have not been adequately presented to the public. Education at all levels should not be neglected. People need to know what is happening, why it is happening, and what the possible exits are. It must be explained how and why hydrogen technology is replacing fossil fuel-based technologies and what the price of hesitation is.

How do you currently see the green hydrogen economy? Will it be a case of countries like Saudi Arabia and Australia becoming export superpowers because of their solar advantage compared to countries in, say, Northeast Asia and Europe?

The key to establishing a green hydrogen economy is mass green hydrogen production. Mass production requires cost reduction, functionality and predictability for investment, and it requires a comprehensive regulatory framework. Of course, it also requires sufficient additional RES and the associated transmission infrastructure to the hydrogen production site. For the EU to compete it will need to implement the missing infrastructure as soon as possible.

According to some research, by 2050 RES could make up 100% of primary energy sources in the EU, of which green hydrogen could make up 20% to 30%. The current price is not attractive at all (€2.50–€5.50/kg), while the cost of producing hydrogen from fossil fuels is about €1.50/kg.

European production of green hydrogen may not in itself be sufficient to meet European demand because the decarbonization of some sectors will require large amounts of green hydrogen. We already have negotiations between countries such as Germany and Morocco, Portugal and the Netherlands, Australia with Asian countries, etc. In the meantime, Australia, Saudi Arabia, and Chile are aiming to become the world’s export superpowers of green hydrogen. Green hydrogen should become an integral part of EU international cooperation in general, including climate diplomacy.

You’re a great proponent of hydrogen transportation – I’m thinking of the H2LAB project. You were also part of the team that installed Croatia’s first hydrogen refueling station. How will green hydrogen change the transport industry?

Yes, I am the leader of several projects with an impact on the introduction of hydrogen technology on all levels. One of these is the H2LAB project that is funded by Croatian Science Foundation. It is focused on advanced methods of green hydrogen production and its transportation. Such projects include the first Croatian hydrogen-powered bicycle, the first Croatian hydrogen refueling station, and the Croatia Mirai Challenge, a road trip from Zagreb to Brussels to raise awareness about CO2-free transport. This was the first time that FCEV was driven on Croatian roads. I’m proud to have been behind the wheel.

Hydrogen propulsion is being introduced in all segments of transport, road, rail and sea, and hydrogen technology has gone so far that today there are also ultra-light fuel cells and hydrogen tanks used in aircraft and drones.

What’s next for green hydrogen?

If we look at the EU hydrogen strategy, it is mass production realized by electrolyzers utilizing RES. It is hydrogen storage realized in high-pressure tanks, and it is the conversion of hydrogen into electricity carried by fuel cells. Green hydrogen has the potential to be a great alternative especially since it can be stored in large quantities over a long period of time, and thus can bridge seasonal fluctuations in demand. Hydrogen can be transported by trucks, ships, or pipelines, allowing energy from RES to be stored where it is most efficient. Hydrogen also allows long-distance transportation and energy integration without overloading the power grid.

In order to reduce the cost of green hydrogen and for optimization purposes, research, development, and innovation are needed throughout the value chain. We also need industry-level demonstration projects to be able to apply hydrogen-based solutions to in-demand sectors. In the first period from 2020 to 2024, the strategic goal is to install at least 6 GW of electrolyzers in the EU to produce up to one million tons of green hydrogen. Given the extreme decline in electrolyzer prices, it is estimated that by 2030, green hydrogen will be price competitive to hydrogen produced from fossil fuels, and this is why hydrogen is the flagship of the energy transition.

Hydrogen-powered aviation will be tested on turboprops at new venture


Credit: Pixabay/CC0 Public Domain

The dream—and the hype—of hydrogen-powered, zero-emissions aviation will prepare for takeoff from Moses Lake in Central Washington.

An ambitious new project aims to modify small regional turboprop aircraft there to fly on hydrogen fuel, test and certify them to carry passengers, and potentially offer a long-term solution to aviation's carbon emissions by demonstrating that hydrogen aviation is economically viable.

Los Angeles-based startup Universal Hydrogen, led by Paul Eremenko, former chief technology officer and leading clean energy visionary at both Airbus and United Technologies, is developing the technology to retrofit mid-sized turboprop aircraft to run on hydrogen.

Partnering with Universal Hydrogen are aerospace engineering and certification firm AeroTEC of Seattle, electric motor company MagniX of Everett and New York-based Plug Power, which has a hydrogen fuel cell facility in Spokane.

"Our goal is to have butts in seats on commercial, revenue-generating flights as quickly as possible, said Eremenko in an interview, adding that he anticipates achieving Federal Aviation Administration certification in 2025.

Challenging technology

First up for retrofit is the De Havilland Canada DHC-8 turboprop, commonly known as the Dash 8.

The version that will be converted is not the larger model flown locally by Alaska Airlines but a smaller one that typically seats about 50 passengers.

The company plans to tear out 10 seats to accommodate the large capsules full of hydrogen that will be the plane's fuel, reducing the capacity to about 40 passengers.

Later, the project will do the same modification for the ATR 72 turboprop, with seating reduced to about 58 passengers post-conversion.

The technology that must be developed is complex and will require innovation.

Universal Hydrogen proposes to set up an extensive logistics infrastructure to deliver to airports twin packs of 7-foot-long, 3-foot-diameter capsules of hydrogen that can be loaded and unloaded quickly.

Plug Power, which currently builds ground-based  cells that generate electricity from hydrogen, will have to develop much lighter fuel cells that are certifiable to airplane safety standards.

MagniX will build the motors that use the electricity to turn the propellers. It has already built similar motors for battery-powered electric airplane prototypes.

Linking all this together, Universal Hydrogen must integrate all the ancillary equipment wrapped around the fuel cell and the electric motor, including the electronic control algorithms for the entire system as well as compressors, humidifiers and the cooling systems for the fuel cell and the motor.

Batteries will be added for reserve power.

AeroTEC's engineers, meanwhile, will have to modify the airframe—designing a new cargo door through which to load the hydrogen capsules and holding fixtures for all the equipment—and then shepherd the complete aircraft through the FAA certification process.

Roei Ganzarski, CEO of MagniX, which employs about 60 people in Everett, said this work represents the future of aerospace. Having it all here in Washington, he said, "puts the state in a position of leadership for all things electric aviation."

Eremenko attributed his choice of Moses Lake to the "tremendous aerospace and cleantech workforce" in the region.

Emily Wittman, CEO of the state trade group the Aerospace Futures Alliance, said "the possibilities for our state's aviation sector are enormous."

Lee Human, president of AeroTEC, which has a total workforce of about 250, said he expects about 30 people to work on the hydrogen project initially, expanding if it's successful and turns into a full modification line in Moses Lake for retrofitting multiple aircraft.

He said he expects to begin modifying an actual aircraft early next year. Testing will begin with one engine using hydrogen and the other conventional gas before both are converted. Certification will take several years.

Human sees a large market for zero-emissions aircraft, both passenger and cargo, that can fly out of small, underserved airports at very low cost.

"There are a lot of candidate aircraft that could be modified," he said. "Amazon just bought a bunch of ATR 72s."

Silicon Valley backing

Eremenko, a Ukrainian-American prodigy who worked at Google and Motorola and led the U.S. government's drone research unit at DARPA before joining Airbus, founded Universal Hydrogen last year, at the outset of the COVID-19 pandemic.

The startup secured $20 million in initial funding earlier this year, led by Silicon Valley venture fund Playground Global, with backers including Plug Power, Airbus, JetBlue, Toyota and New York-based hedge fund Coatue.

Its advisory board includes former Airbus CEO Tom Enders and the European giant's former head of sales, John Leahy.

Eremenko estimates it will take about $300 million to achieve certification of the regional planes.

The company was "born out of my frustration ... with the pace of decarbonization in aviation," Eremenko said. "Biofuels, synthetic fuels, batteries and various other options out there just aren't going to work on the timeframe that you need to make the Paris Agreement targets."

"The industry is too slow," he said. "We need to create an external sort of disrupter to get the industry to move."

Eremenko's brash plan is to demonstrate this decade that hydrogen aviation can work on the scale of small regional passenger planes so that Boeing and Airbus will also choose hydrogen in the 2030s when they design their next all-new single-aisle jets to replace the 737 MAX and the A320neo.

"I founded this company to create irrefutable proof of the fact that you can get affordable hydrogen, you can get it to airports, you can certify it, it can be safe and passengers will fly on hydrogen airplanes," he said.

Green hydrogen?

One issue is that although hydrogen-fueled planes will emit only water vapor, most hydrogen production currently comes from natural gas and is highly energy intensive.

For this technology to be truly sustainable, the world needs to produce so-called "green hydrogen" via water electrolysis. Today that's just 1% of the total hydrogen produced and most projections say green hydrogen may not be available on a large scale until the 2030s.

Eremenko believes in a kind of a Moore's Law for hydrogen technology, certain that it will accelerate as demand grows.

"Green hydrogen production is on an exponential trajectory," he said, projecting a decrease in cost and a rapid growth in capacity.

But both Airbus or Boeing envisage a much longer timeline for this hydrogen revolution.

"I just don't believe that is going to deliver anything for us between now and 2050," Boeing CEO Dave Calhoun told Aviation Week in June.

And though rival Airbus is actively pursuing hydrogen technology, in a leaked briefing to the European Commission in February it conceded that while it expects  may power regional and shorter range aircraft from 2035, traditional gas turbine engines will still be required for larger A320-size planes until close to 2050.

Eremenko is scornful of those conservative projections.

"That's why this company exists, to persuade and move the industry in a different direction," he said. "I didn't go into the aerospace business to be the laggard. ... I expect us to lead in this space as an industry, and make bold bets."

In doing so, Universal Hydrogen is a David stepping out to confront Goliath.

So far three regional airlines have signed letters of intent to buy its planes: Icelandair; Anchorage-based Ravn; and Valencia, Spain-based Air Nostrum.

In late June, Universal Hydrogen had only about 20 employees, though Eremenko said "we're scaling up to 40."

Airbus aims for hydrogen-powered plane by 2035

©2021 The Seattle Times.
Distributed by Tribune Content Agency, LLC.

Global green hydrogen supply is surging,


 but can demand keep pace?

Michael Mazengarb

6 August 2021 


Global green hydrogen production capacity is set to double in size over the next year, but analyst firm BloombergNEF has warned that governments will need to do more to boost the use of hydrogen, with fears that the world could be on track for a massive green hydrogen glut.

In its latest hydrogen market outlook, BloombergNEF forecasts that global shipments of hydrogen electrolyser technologies will double in 2021, and then quadruple in 2022 to 1.8GW. By 2040, the cumulative installations of electrolysers could be as high as 40GW.

“Nearly everything has doubled already this year in the world of clean hydrogen, and we expect the momentum to continue,” Tengler said.

“More than 40 countries have now published a hydrogen strategy or are developing one. More than 90 projects are being planned worldwide to use hydrogen in industry. Electricity generators have almost doubled their planned hydrogen-fired turbine capacity since January.”

China has emerged as a leading market for new electrolyser additions, with manufacturers being spurred into action by new carbon neutrality targets, and a goal to see its greenhouse gas emissions peak by 2030.

“What’s happening in China right now is revolutionary for clean hydrogen,” Tengler said.

“Chinese companies are racing to show their compliance with the country’s carbon neutrality target, pushing the market for electrolysers – the devices that produce hydrogen using water and electricity – to be at least nine times bigger in 2022 than in 2020.”

However, BloombergNEF warned that while there was strong growth amongst facilities manufacturing electrolysers to boost renewable hydrogen production, there needed to be increased investment in the demand-side of the hydrogen market to ensure the zero emissions fuel was being put to use.

Tengler said this would require stronger national climate change policies and a price on carbon emissions – possibly as high as $100 a tonne – to ensure green hydrogen is cost competitive with fossil fuels equivalents.

Further investments in hydrogen use, including in new transport technologies and the use of hydrogen in industrial processes, are likely to be necessary to ensure the use of hydrogen is able to keep up with the supply.


The analysis flags a potential future challenge for surging investment in global hydrogen production capacity, whereby surging supply is not matched by a corresponding increase in consumption.

“Hydrogen’s future as a major clean energy source is far from certain,” Tengler said. “Sustained, large-scale demand for clean hydrogen will need stronger demand-side incentives than what we are seeing now.”

“We’ll need to see CO2 prices of at least $100 per ton by 2030 to incentivize hydrogen adoption. No country has such carbon prices today, and we forecast only three markets to reach that level before 2030: Canada, the EU and the UK.”

“It is no surprise then that the vast majority of announced large-scale demand-side clean hydrogen projects come from these regions.”

BloombergNEF said that while direct government financial support for clean hydrogen technologies was continuing to grow – with more than US$11 billion (A$14.9 billion) set to be spent by governments each year between 2021 and 2030, the level of governments support is still well below the amount of early financial support provided to emerging solar technologies.

In Australia, the Morrison government has set itself a target of reducing the cost of hydrogen production to less than $2 per kilogram, a threshold it says will allow hydrogen to become cost competitive with fossil fuel alternatives.

However, the Morrison government has no plans to impose any form of price on carbon emissions.

Australia has seen its own surge in interest in new hydrogen production projects – including proposals for multi gigawatt scale renewable hydrogen projects using wind and solar – but the demand-side of the market has so far lagged with only limited investments being made in hydrogen transport and the blending of hydrogen in mains gas networks.


Michael Mazengarb  is a journalist with RenewEconomy, based in Sydney. Before joining RenewEconomy, Michael worked in the renewable energy sector for more than a decade.


China Makes a Hard Turn Towards Clean Hydrogen

gcl
Chinese solar power company GCL is pivoting to hydrogen (GCL)

PUBLISHED AUG 5, 2021 8:20 PM BY THE MARITIME EXECUTIVE

 

China is on track to become a powerhouse for the production of green hydrogen, one of the most promising alternative fuels for shipping, according to recent reports from BloombergNEF and Fitch. As the world's largest shipbuilder, largest exporter, largest port operator and third-largest shipowner, China's fuel policy choices will have a significant impact on the composition of the world fleet.

Hydrogen power is prominently included in the Chinese Communist Party's 14th Five-Year Plan. At present, most of China's hydrogen comes from coal gasification or steam reformation of methane, but green hydrogen (from renewable electricity) is a high priority as China takes aim at carbon neutrality by 2060. According to IEA data, China has 20 green hydrogen projects under development today.

As the cost of the electrolyzer units used to split water into hydrogen and oxygen comes down, the share of green hydrogen in China's economy is expected to rise. The Hydrogen Council predicts that electrolyzer prices are going to fall by 70-80 percent within ten years' time, dramatically lowering total cost of production. 

The prospect of a hydrogen value chain is attracting large Chinese companies, including solar manufacturer GCL, which is jettisoning its solar power station assets and investing in new hydrogen projects. It plans to build out about 400,000 tonnes of green hydrogen capacity in China, predominantly from solar power sources, and it is investing in a much larger conventional natural gas-to-hydrogen project in Ethiopia. "We are re-locating ourselves and focusing on a new racing track," GCL Chairman Zhu Gongshan told Reuters.

However, there may be a timeframe mismatch between when Chinese production of electrolyzers ramps up and when demand for electrolyzers materializes. BloombergNEF expects that next year, demand for electrolyzers will be in the range of 2 GW - an unprecedented number driven up by growth in China. The same year, electrolyzer manufacturing capacity will hit 10 GW, rising to 16 GW by 2024 - creating an oversupply that could drive down electrolyzer prices and prompt further uptake. 

“What's happening in China right now is revolutionary for clean hydrogen,” said Martin Tengler, lead hydrogen analyst at BNEF. "Chinese companies are racing to show their compliance with the country's carbon neutrality target, pushing the market for electrolyzers . . . to be at least nine times bigger in 2022 than in 2020."


Rotterdam Explores Importing Norwegian Blue Ammonia 

Rotterdam import blue ammona from Norway
Artist impressions of the Barents Blue facilities (Horisont Energi)

PUBLISHED AUG 5, 2021 5:57 PM BY THE MARITIME EXECUTIVE

 

The Port of Rotterdam is pushing forward aggressively to become a leader in the emerging hydrogen sector. Northwest Europe will have to import hydrogen on a large scale to achieve its goal of becoming net-zero on carbon emission and the Port of Rotterdam Authority is looking to create those supply chains for hydrogen and ammonia from countries where hydrogen can be produced and supplied cost-effectively. The port authority notes that already half of the Dutch projects developing hydrogen are centered in Rotterdam and their goal is to become the hub for northern Europe.

In the latest development to build that supply chain, the Port of Rotterdam will work with a Norwegian start-up, Horisont Energi, that provides clean energy and carbon storage services at an industrial scale. Together they will explore a collaboration to ship blue ammonia, produced in northern Norway, from natural gas with carbon capture and storage, to the port of Rotterdam. 

“There’s an important role for blue hydrogen if we want to realize the international climate ambitions,” said Nico van Dooren, director of New Business at the Port of Rotterdam.  In the coming years, he notes, “there will not be enough green hydrogen to meet the demand. We’ll need every possible solution. We, therefore, focus not only on green but also on blue, just as we don’t only look at local production but also at imports.”

Horisont is seeking to develop its production plant near Hammerfest in the northernmost part of Norway. The fully automated plant would draw gas from the nearby Melkøya LNG plant producing more than one million tons annual of ammonia. It would have a capacity to produce 600 tons per day of blue hydrogen and 3,000 tons per day of blue ammonia with the CO2 stored off Finmark, Norway. A final investment decision for the production of blue ammonia at the Barents Blue project is expected towards the end of 2022. 

Blue ammonia could be shipped to Rotterdam by 2025 and would be distributed to meet expected demand in Northwestern Europe. In addition to being a key industrial gas used in the fertilizer and chemical sector, ammonia is a very efficient hydrogen carrier. This makes net zero CO2 emission ammonia one of the most promising fuels for decarbonization of the shipping industry.

The port of Rotterdam is an energy hub port for western Europe, with some 13 percent of total energy demand in Europe entering the EU via Rotterdam. The port has the ambition to be net-zero CO2 emission in 2050 while at the same time maintaining its pivotal role in the European energy system. In addition to this effort with Norway, last week the port said it was also exploring hydrogen imports using chemical carriers. The demand in Rotterdam is expected to be up to 20 million tons of hydrogen, equivalent to 100 million tons of ammonia, in 2050, according to Port of Rotterdam estimates.


The hydrogen economy is about to get weird
Companies may be investing in production capacity that will outpace demand.

JOHN TIMMER - 
8/5/2021, 

Enlarge / A Coradia iLint hydrogen fuel-cell powered prototype railway train, manufactured by Alstom SA, travels in Salzgitter, Germany.

If you were paying attention at the start of this century, you might remember the phrase "hydrogen economy," which was shorthand for George W. Bush's single, abortive attempt to take climate change seriously. At the time, hydrogen was supposed to be a fuel for vehicular transport, an idea that still hasn't really caught on.

But hydrogen appears to be enjoying a revival of sorts, appearing in the climate plans of nations like the UK and Netherlands. The US government is investing in research on ways to produce hydrogen more cheaply. Are there reasons to think hydrogen power might be for real this time?

A new report by research service BloombergNEF suggests that hydrogen is set for growth—but not in transport. And the growth has some aspects that don't actually make sense given the current economics.

A gas that’s not really for cars


There are currently two primary ways of producing hydrogen. One involves stripping it from a hydrocarbon such as the methane in natural gas. CO2 is a byproduct of these reactions, and at present, it is typically just released into the atmosphere, so the process is anything but carbon neutral. That carbon can be captured and stored relatively easily, however, so the process could be clean if the capture and storage are done with renewable or nuclear power. The same caveat applies to producing hydrogen by water electrolysis: It needs to be done with low-carbon power to make sense for climate goals.


Until recently, very few countries have had enough renewables installed to regularly produce an excess of carbon-free electricity to power climate-friendly hydrogen production. That situation is now starting to change, so governments are beginning to include hydrogen in their climate plans.

But something else has changed since the early talk of a hydrogen economy: Battery prices have plunged, and widespread electric vehicle use is a viable option for decarbonizing a lot of transportation. There are still some types of vehicles, like trains, for which batteries aren't a great option and hydrogen could play a role. But looking out to the end of the decade, BloombergNEF sees transportation generating only about 10 percent of the total demand.

Instead, BloombergNEF foresees countries using hydrogen as part of a larger integrated plan to reach national climate goals. If things go according to these plans, carbon-neutral hydrogen will be used in segments of the economy that are difficult to decarbonize otherwise.

One option for hydrogen is to supplement renewable power during periods of low productivity. BloombergNEF suggests that fossil fuels will outcompete hydrogen economically unless there's a price on carbon high enough to drive capturing the emissions of fossil fuel plants. Batteries will also be cheaper for shorter periods (three hours or less). So while renewal power is expected to be a major source of demand, it will be heavily reliant on carbon pricing to make economic sense.

Perhaps more promising are industrial uses like oil refining and ammonia production, which already use a lot of hydrogen produced from fossil fuels. Some additional processes, like metal production, don't currently use hydrogen but could switch to it to decarbonize. Again, making hydrogen attractive at current hydrogen prices will require a price on carbon. Canada and EU members will likely implement these practices first, and EU countries have some of the most concrete roadmaps for hydrogen use.

Volume production


For many countries, economical hydrogen production depends on policies that aren't yet in place. However, BloombergNEF foresees a short-term boom in our ability to produce it. Based on announced plans, manufacturers of hydrogen-producing hardware will produce an additional 10 GW of hardware annually by the end of next year. (Hydrogen-producing equipment is rated based on the electricity it consumes.) In contrast, Bloomberg predicts a demand of under 2 GW of hardware at that time.

Some of the production expansion appears to be a response to China's announced plan to be carbon neutral by 2060. While China hasn't detailed its roadmap to get there, industries in the country seem to be acting in anticipation of what the pathway might look like. BloombergNEF also acknowledges that the plans of companies in China are often opaque, and they'll sometimes announce facility openings only as they are happening. So there's a chance that Bloomberg is underestimating demand.

Still (and this is our analysis, not BloombergNEF's), the situation echoes what happened with solar panels. China had invested in production capacity that outstripped the present demand, leading to low-priced exports that helped stimulate demand in a number of other countries and set off a cycle of price drops and demand expansion.

This could potentially work for hydrogen-production equipment as well, but there's a key difference here. While solar panels help offset carbon emissions whenever they're put to use, hydrogen production hardware will do so only when it's paired with renewable or nuclear power. And it's unlikely that there will be a lot of excess power in three years after all that equipment production is online. So while the expected overproduction could stimulate hydrogen production, it could also be meaningless before the end of the decade, when other pieces of policy are in place.


JOHN TIMMER
John became Ars Technica's science editor in 2007 after spending 15 years doing biology research at places like Berkeley and Cornell.

Japanese Engine Manufacturers Launch Hydrogen Marine Engine Company

Japan marine hydrogen engines
Kawassaki will cooperate building medium-speed 4-stroke engines (Kawasaki file photo)

PUBLISHED AUG 4, 2021 6:39 PM BY THE MARITIME EXECUTIVE

 

As a next step in the development of new, green propulsion systems for the maritime sector, three of Japan’s leading engine manufacturers announced the formation of a new company designed to develop and market hydrogen-fueled marine engines. With the establishment of HyEng Corporation, Kawasaki Heavy Industries, Yanmar Power Technology Co., and Japan Engine Corporation are seeking to accelerate their drive to develop new markets, realizing the opportunities for decarbonization in the maritime sector.

With the growing focus on reducing greenhouse gas emissions, the companies expect marine engines to transition to various alternative fuels in the coming years. Among the many alternatives, they highlighted that hydrogen is attracting global interest for its application in a wide range of energy and mobility industrial sectors as a fuel that offers zero emissions. In taking the step to form HyEng, the engine manufacturers are increased their focus with the goal of joint development of world-leading marine hydrogen-fueled engines.

The three companies announced in April 2021 that they were forming a consortium to pursue the joint development of hydrogen-fueled marine engines for ocean-going and coastal vessels. By cooperating on common fundamental technologies, such as basic experiments and analysis on hydrogen combustion, materials, and sealing techniques, as well as classification society requirements, each company aims to bring hydrogen-fueled engines to the market by 2025.

Kawasaki Heavy Industries will develop medium-speed 4-stroke engines, Yanmar Power Technology will focus on medium- and high-speed 4-stroke engines, and Japan Engine Corporation will embark on the development of low-speed 2-stroke engines. By pursuing a strategy of simultaneously developing the three sectors, the companies believe it will enhance the product lineup of propulsion and auxiliary (generator) engines for a wide range of vessels. In addition, a hydrogen fuel storage and supply system will be developed as part of the integrated hydrogen fuel system.

By developing advanced hydrogen marine engine technologies based on distinctive engines and quickly launching in the market, the consortium seeks to contribute to the Japanese shipbuilding industry. Furthermore, the companies aim to revitalize the Japanese maritime industry and realize a sustainable society by promoting the uptake of hydrogen-fueled engine technology for marine vessels.

Scottish Wind Project Seeks Advantage with Hydrogen Partnership

Scottland offshore wind hydrogen generation
Proposal to combine offshore wind with hydrogen generation (Simple Blue Group)

PUBLISHED AUG 4, 2021 8:16 PM BY THE MARITIME EXECUTIVE

 

Interest continues to grow for the potential of combining offshore wind projects with hydrogen to create a green process for the creation of the future fuel. In the latest development, the Salamander floating wind project in development for the northeast coast of Scotland near Aberdeen said it is pursuing the opportunity to become the world’s first combined floating wind and green hydrogen project putting it in competition with similar projects proposed for other areas in Europe.

The 200 MW Salamander floating wind project, developed by the Irish company Simply Blue Energy in partnership with Subsea 7, signed a memorandum of understanding with sustainability consultancy ERM for the potential use of the ERM Dolphyn hydrogen technology. The technology combines electrolysis, desalination, and hydrogen production on a floating wind platform. The hydrogen would be transported to shore through a pipeline. ERM Dolphyn aims to undertake a 10 MW demonstration project, which would produce green hydrogen offshore and provide the first step needed to scale up at Salamander. According to the companies, it is an economic and scalable solution, which produces green hydrogen with no carbon emissions at the point of use.

“When we started the Salamander project, we always envisioned a stepping-stone project and a catalyzer for future, bigger commercial opportunities,” said Adrian de Andres, Salamander Project Director. “Considering the rapidly approaching 2030 deadline for the floating wind and green hydrogen targets, we now think the Salamander project could act not only as a stepping-stone for floating wind but also potentially for green hydrogen production, paving the way for multi-GW green hydrogen developments in the 2030s.”

The Salamander project is targeting a lease under the upcoming Innovation & Decarbonization leasing process and now plans to put forward its ambitious green hydrogen plans to Crown Estate Scotland and Marine Scotland. The hope is that by incorporating hydrogen into their proposal it will provide them an advantage in the upcoming leasing process.

According to the companies, the proximity of the site for the Salamander project to St Fergus Gas Terminal along with the plans for a hydrogen infrastructure in the region around Aberdeenshire and Aberdeen City make their project ideally suited for the combination of offshore wind and hydrogen. They also noted that they are working closely with Scotland Gas Networks (SGN) to potentially integrate with and connect into future hydrogen infrastructure or as a blend with existing gas infrastructure, which SGN is aiming to develop.

The Salamander project they said has been investigating different routes to market since its inception and due to its advantageous location off Aberdeenshire, the project believes producing green hydrogen is a very interesting option. 

Scotland has become one of the emerging hotbeds for potential offshore wind projects with both major corporations and emerging companies all seeking to participate in the market. The Scottish government has set a target to reach 11 GW of offshore wind capacity in its waters by 2030. The next round of the leasing project is expected to be announced in early 2022.