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Fortescue Energy CEO says green hydrogen cost is key as demand drops

DAVOS, Switzerland, Jan 24 (Reuters) – Replacing fossil fuels with green hydrogen depends on creating demand by making it price competitive, as buyers are unwilling to pay “green premiums”, Fortescue Energy CEO Mark Hutchinson told Reuters in Davos.

Green hydrogen is created by splitting water into hydrogen and oxygen using renewable electricity. It can then be used as a power source itself or to make carbon-free ammonia, a major ingredient in agricultural fertilizers.

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Electrolyzers that split hydrogen are costly, and government subsidies to reduce these costs for companies have not come through as they were expected to, Hutchinson told the Reuters Global Markets Forum.

The CEO said on the sidelines of the World Economic Forum’s annual meeting in the Swiss resort on Thursday,

(The) green hydrogen, ammonia (sector) is not where we thought it would be,

He said,

The demand hasn’t emerged in the way it should, (but) over the next few years we’re hoping demand will (rise) as prices come down,

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He added,

If you’re waiting for someone to pay you extra because it’s green, forget it … at the end of the day, the economics have to work,

Fortescue Energy, the green energy arm of Australian iron ore miner Fortescue’s (FMG.AX), said in July that it was unlikely to meet its target of producing 15 million metric tons of green hydrogen by 2030.

A backlash against environmental-driven business decisions has been compounded by Donald Trump’s return to the White House, with the U.S. president declaring an energy emergency and rolling back green policies shortly after taking office.

Hutchinson said a push for green energy could take a back seat during Trump’s term, but it is up to the industry to make it an economic discussion, not just “about saving the planet”.

However, the company’s focus on “green iron” has risen significantly over the past year,despite the demand worries.

Green iron is produced by reducing iron ore using hydrogen gas, which is then converted into steel in an electric arc furnace.

The production of steel, a key material for infrastructure and the net-zero energy transition, currently contributes around 8% of global carbon emissions.

Hutchinson said final investment approvals were still pending for green hydrogen projects in Norway and Brazil, originally due in 2023, with Fortescue Energy waiting to bring in more investors.

Source:  Hydrogencentral

January 21, 2025, Shenzhen: The 300 kW Solid Oxide Fuel Cell (SOFC) demonstration project at the East Campus of Guangming People's Hospital, jointly constructed by Shenzhen Three-Circle (Group) and Shenzhen Gas Group Co., Ltd., was officially put into operation.

Panoramic View of the Project

This project is the first 300 kW SOFC commercial promotion demonstration project in the country and the promotion and application of the "First Set of Major Equipment in the Energy Field" products issued by the National Energy Administration. The project is composed of 6 power generation units with a power output of 50 kW each, which can provide stable power for the hospital.

Image: Three-Circle (Group)

As of now, the total power generation during the trial operation of the project has reached 110,000 kW-hours, and the average power generation efficiency is as high as 64.4%, which is at the global advanced level. It is expected that the annual power generation can reach 2.3 million kW-hours, and the annual carbon reduction can reach approximately 320 tons.

The SOFC technology is an efficient and clean power generation technology that directly converts chemical energy into electrical energy through electrochemical reactions. It has the characteristics of high-power generation efficiency and strong fuel adaptability.

In 2024, SOFC technology was included in the "Green Technology Promotion Catalogue (2024 Edition)" issued by eight departments including the National Development and Reform Commission.

Since 2004, Three-Circle (Group) has been focusing on the innovation and integration of production and research in SOFC/SOEC, continuously overcoming various key challenges. After more than 20 years of continuous investment and technological research, Three-Circle (Group) has now become one of the core links in the global SOFC/SOEC industry chain. It has mastered the R&D and mass production capabilities of the entire SOFC/SOEC technology chain, from single cells, stacks to systems. It holds more than 50 core invention patents and took the lead in launching the first domestic 35kW and 50kW high-power SOFC power generation systems. It also takes the lead in undertaking the key R&D programs during the "13th Five-Year Plan" and "14th Five-Year Plan" periods and is committed to providing safe and reliable new energy technology alternatives for the efficient utilization of renewable energy in the process of achieving the "carbon peak and carbon neutrality" goals.

As a subsidiary of Three-Circle (Group), Shenzhen Three-Circle has a group of high-level technical personnel covering various professional fields such as materials, electrochemistry, machinery, and mechanics. It also has testing equipment for material analysis, electrochemical analysis, etc.

In the future, Shenzhen Three-Circle will continue to cooperate closely with the Guangming District Government, Shenzhen Gas Group Co., Ltd. and other units, actively respond to the national carbon peak and carbon neutrality strategies. Starting from the SOFC demonstration project in the People's Hospital, it will explore the promotion and application in more scenarios and contribute to the construction of Shenzhen as a green and low-carbon city.

Source: GuanmingNews

A green fuels breakthrough: bio-engineering bacteria to become ‘hydrogen nanoreactors’

Researchers at the University of Oxford’s Department of Engineering Science have made major advances towards realising green hydrogen – the production of hydrogen by splitting water, powered by renewable energy. Their approach, which focuses on bio-engineering bacteria to become ‘hydrogen nanoreactors’, could open the way towards a cost-effective, zero carbon method of generating hydrogen fuels.

Hydrogen could play a key role in helping us achieve net-zero emissions, since this burns cleanly without releasing CO2. However, current industrial hydrogen production depends heavily on fossil fuels, generating approximately 11.5–13.6 kilograms of CO2 emissions per kilogram of hydrogen produced.

In the new study, the researchers used a synthetic biology approach to convert a species of bacteria into a cellular ‘bionanoreactor’ to split water and produce hydrogen using sunlight. By generating a highly-efficient, stable and cost-effective catalyst, this overcomes one of the critical challenges that has been holding back green hydrogen to date.

Lead author Professor Wei Huang (Department of Engineering Science, University of Oxford) said:

Currently, most commercially used catalysts for green hydrogen production rely on expensive metals.

“Our new study has provided a compelling alternative in the form of a robust and efficient biocatalyst. This has the advantages of greater safety, renewability, and lower production costs all of which can improve long-term economic viability.”

In nature, specific microorganisms can reduce protons (H+) to hydrogen (H2) using hydrogenase enzymes, however this is limited to low yields due to constraints, such as low electron transfer rate. Up to now, this has prevented microorganisms from being used as effective hydrogen catalysts.

To overcome this, the Oxford researchers engineered the bacterium Shewanella oneidensis to concentrate electrons, protons, and hydrogenase in the space between the inner and outer membrane (known as the periplasmic space, 20-30 nm wide). This species is ‘electroactive’, meaning that it can transfer electrons to or from solid surfaces outside their cells.

To enhance electron and proton transfer, the team engineered a light activated electron pump (called Gloeobacter rhodopsin) onto the inner membrane, newly enabling it to efficiently pump protons into the periplasm in the presence of light. The Gloeobacter rhodopsin itself was engineered by the introduction of the pigment canthaxanthin (which absorbs light energy) to boost proton pumping by harvesting extra photon energy from sunlight. Additionally, nanoparticles of reduced graphene oxide and ferric sulfate were introduced to enhance the electron transfer. Finally, the hydrogenase enzyme in the periplasmic space was also overexpressed.

When the engineered S. oneidensis strain was exposed to electrons from an electrode, this achieved a ten-fold increase in hydrogen yield compared to a control, non-engineered strain.

Professor Wei Huang and his group explain the concept of producing hydrogen using bacterial nanoreactors.

First author of the study Weiming Tu, a DPhil candidate in Oxford’s Department of Engineering Science, said,

The natural periplasm of S. oneidensis offers an optimal nano-environment for hydrogen production, as it effectively ‘squeezes’ protons and electrons, thereby increasing the likelihood of their interactions within nanoscale spaces.

“Thermodynamically, this design results in a lower energy requirement for hydrogen production. This work is a good demonstration of engineering biology.”

Co-author Professor Ian Thompson (Department of Engineering Science, University of Oxford) added:

Efficient, affordable, and safe green hydrogen production is a long-standing goal.

“Our bionanoreactor has suggested the potential of biocatalysts for clean energy production. The abiotic materials used in this work, including the graphene oxide and ferric sulfate nanoparticles, were synthesised by biological methods, making them more eco-friendly than traditional chemical approaches.”

According to the researchers, the system could be scaled up to produce ‘artificial leaves’, with the engineered cells printed onto carbon fibre cloth. When these artificial leaves are exposed to sunlight, they would immediately begin producing hydrogen. 

This work was published as the paper ‘Engineering bionanoreactor in bacteria for efficient hydrogen production’ in Proceedings of the National Academy of Science. 

This advance builds on the expertise Professor Huang’s lab group have developed in sustainable synthetic biology. In 2023, his group achieved a world-first in successfully bio-engineering a non-photosynthetic bacterium (called Ralstonia eutropha) to become photosynthetic – a pivotal proof-of-concept for the field. Similar to the Shewanella hydrogen nanoreactors, this system used rhodopsin, but this time as a replacement for the pigment chlorophyll (which normally powers photosynthesis).

Their achievement led to follow-on funding from UK Research and Innovation (UKRI) and the Science and Technology Agency (JST) in Japan to further develop new artificial photosynthetic cell systems to enhance green biotechnology. Alongside Professor Hiroyuki Noji (The University of Tokyo), Professor Wei Huang is leading a collaboration of eight UK and Japanese Universities to research new sustainable methods to convert carbon dioxide into useful bioproducts (such as biodegradable plastic). Ultimately, this could provide sustainable sources of important products for a diverse range of industries including healthcare, biomanufacturing, and agriculture.

Source: Hydrogencentral