OCI broke ground on the project in 2022. Photo via oci-global.com

Woodside Energy has announced its acquiring a Beaumont, Texas, clean ammonia project that's slated to deliver its first ammonia by 2025 and lower carbon ammonia by 2026.

The agreement is for Woodside to acquire 100 percent of OCI Clean Ammonia Holding and its lower carbon ammonia project in Beaumont in an all-cash deal of approximately $2.35 billion. According to Woodside CEO Meg O’Neill, the acquisition positions Woodside as an early mover in clean ammonia within the energy transition.

“This transaction positions Woodside in the growing lower carbon ammonia market," O’Neill says in a news release. "The potential applications for lower carbon ammonia are in power generation, marine fuels and as an industrial feedstock, as it displaces higher-emitting fuels.

“Global ammonia demand is forecast to double by 2050, with lower carbon ammonia making up nearly two-thirds of total demand," she continues. “This Project exceeds our capital allocation framework targets for new energy projects. Both phases are expected to achieve an internal rate of return above 10 percent and payback of less than 10 years."

OCI broke ground on the project in 2022. It's reportedly the world’s first ammonia plant paired with auto thermal reforming with over 95 percent carbon dioxide capture.

Phase 1 of the project will have a capacity of 1.1 million tonnes per annum and is currently under construction. The first ammonia production will be derived from natural gas and is slated for 2025, with lower carbon ammonia production — derived from natural gas paired with carbon sequestration — is expected in in 2026 following commencement of CCS operations

According to the release, Phase 2 will have the capacity to abate 3.2 million tonnes per annum CO2-e, "or over 60 percent of our Scope 3 abatement target,” O’Neill explains.

Linde will source the nitrogen and lower carbon hydrogen feedstock from its feedstock facility, which is currently under construction with a targeted completion in early 2026. In the meantime, early supply of feedstock for the project will come from various suppliers including Linde. Per the release, CCS services will be provided to Linde by ExxonMobil and are expected to be available in 2026.

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Houston-based co. closes acquisition of 50 percent stake in Texas cogeneration facility

M&A Moves

Fengate Asset Management announced the financial close on the acquisition of a 50 percent interest in Freeport Power Limited, which owns a 440-megawatt cogeneration facility in Freeport, Texas.

FPL is located near the Freeport Energy Center, which is a 260-megawatt cogeneration facility that is currently owned and managed by Fengate. The two facilities work to provide cost-effective power and steam to Dow’s Freeport site, which is the largest integrated chemical manufacturing complex in the Western Hemisphere.

“We are thrilled to have closed this acquisition, which aligns with our strategy of acquiring behind-the-meter cogeneration projects with strong industrial partners like Dow,” Greg Calhoun, managing director of Infrastructure Investments at Fengate, says in a news release.

Fengate was able to acquire interest in FPL under a strategic operating partnership with asset manager Ironclad Energy. The partnership with Ironclad was established in 2022 to acquire and operate cogeneration, district energy and other power generation projects throughout North America.

“This is our second acquisition with Fengate, and we look forward to continuing our partnership to optimize and expand the portfolio,” Christopher Fanella, president and CFO of Ironclad Energy, says in the release.

Fengate opened its first U.S. office in 2017 in Houston.

“Combined heat and power projects like FPL will continue to play an important role in the U.S. power industry – especially for hard-to-abate industrial sectors – to ensure reliability, efficiency and affordability,” adds in the release.

Houston energy leader on why the future of fuels is more than electric vehicles

guest column

Gasoline, diesel, bunker fuel, and jet fuel. Four liquid hydrocarbons that have been powering transportation for the last 100-plus years.

Gas stations, truck stops, ports, and airport fuel terminals have been built up over the last century to make transportation easy and reliable.

These conventional fuels release Greenhouse Gases (GHG) when they are used, and governments all over the world are working on plans to shift towards cleaner fuels in an effort to lower emissions and minimize the effects of climate change.

For passenger cars, it’s clear that electricity will be the cleaner fuel type, with most countries adopting electric vehicles (EVs), and in some cases, providing their citizens with incentives to make the switch.

While many articles have been written about EVs and the benefits that come along with them, they fail to look at the transportation system as a whole.

Trucks, cargo ships, and airplanes are modes of transportation that are used every day, but they don’t often get the spotlight like EVs do.

For governments to be effective in curbing transportation-related greenhouse emissions, they must consider all forms of transportation and cleaner fuel options for them as well.

43 percent of GHG emissions comes from these modes of transportation. Therefore, using electricity to reduce GHG emissions in light duty vehicles only accounts for part of the total transportation emissions equation.

The path to cleaner fuels for these transportation modes has its challenges.

According to Ed Emmett, Fellow in Energy and Transportation Policy at the Baker Institute Center for Energy Studies (CES);

  • "Airplanes cannot be realistically powered by electricity, at least not currently, and handle the same requisite freight and passenger loads"
  • "The long-haul trucking industry [...] pushed back against electrification as being impractical due to the size and weight of batteries, their limited range, and the cost of adoption"
  • "Shipowners have expressed reluctance to scrap existing bunker fueled ships for newer, more expensive ships, especially when other fueling options, e.g. biofuels and hydrocarbon derivatives-for fleets can be made available"

Finding low-cost, reliable, and environmentally sound fuels for the various segments of transportation is complex. As Emmett suggests in his latest article;

"Hovering over the transition to other fuels for almost every transportation mode is the question of dependability of supply. For the trucking industry, the truck stop industry must be able to adapt to new fuel requirements. For ocean shipping, ports must be able to meet the fuel needs of new ships. Airlines, air cargo carriers and airports need to be on the same page when it comes to aviation fuels. In other words, the adoption equation in transitions in transportation is not only a function of the availability and cost of the new technology but also a function of the cost of the full supply chain needed to support fuel production and delivery to the point of use. Going forward, the transportation industry is facing a dilemma: How are environmental concerns addressed while simultaneously maintaining operational efficiency and avoiding unnecessary upward cost shifts for moving goods and people? In answering that question, for the first time in history, modes of transportation may end up going in multiple different directions when it comes to the fuels each mode ultimately chooses."

This is why many forecasts predict that hydrocarbon demand will continue through 2050, despite ambitious aspirations of achieving net zero emissions by that year. The McKinsey "slow evolution" scenario has global liquid hydrocarbon demand in 2050 at 92mmb/d versus 103 mmb/d in 2023. With their "continued momentum" scenario, oil demand is 75 mmb/d. Proportionally, global oil demand related to GHG emissions from transportation would decline 11-27 percent. The global uptake of EVs is the primary driver of uncertainty around future oil demand. In all the McKinsey scenarios, the share of EVs in passenger cars sales is expected to be above 90 percent by 2050.

The Good News

Despite the relatively slow progress expected for reducing GHG emissions in the global transportation sector, there are solutions emerging that lower the carbon footprint tied to traditional petroleum-based fuels. Emmett highlights some of the methods under study, noting that "sustainable biofuels sourced from cooking oils, animal fats, and agriculture products, as well as hydrogen, methanol, ammonia, and various e-fuels are among the options being tested. Some ocean carriers are already ordering ships powered by liquified natural gas, bio-e-methanol, bio/e-methane, ammonia, and hydrogen. Airlines are already using sustainable aviation fuel as a supplement to basic aviation fuel. Railroads are testing hydrogen locomotives. The trucking industry is decarbonizing local delivery by using vehicles powered by electricity, compressed natural gas, and sustainable diesel. Long-haul trucking companies are considering sustainable diesel as a drop-in fuel for existing equipment, and fuel suppliers are researching new engines fueled by hydrogen and other alternative fuels."

Most of these options will require a combination of increased government incentives, along with advancements in technology and cost reductions.

McKinsey's "sustainable transformation" scenario, which considers potential shifts in government regulations as well as advancements in technology and cost, suggests there is moderate growth in alternative fuels alongside growth in EVs. Mckinsey projects;

  • EV demand could grow to over 90 percent of total passenger car sales by 2050
  • EVs to make up around 80 percent of commercial truck sales by 2050
  • In aviation, low carbon fuels such as biofuels, synfuels, hydrogen and electricity are projected to grow to 49 percent by 2050.

According to McKinsey, the combination of these alternatives along with demand changes in power and chemicals could reduce global oil demand to 60 mmb/d in 2050. The shift to cleaner fuels, for modes of transportation other than EVs, is underway but the progress and adoption will take decades to achieve according to McKinsey’s forecasts.

Looking more closely at EVs, the story may not be as dire globally as it seems to be in the West. While the U.S. appears to be losing momentum on electric vehicle adoption, China is roaring ahead. New electric car registrations in China reached 8.1 million in 2023, increasing by 35 percent relative to 2022. McKinsey’s forecasts have underestimated global EV sales in the past, with China surpassing their estimates, while the U.S. lags behind. It’s clear that China is the winner in EV adoption; could they also lead the way to adopt cleaner fuels for other modes of transport? That is something governments and the transportation industry will be watching in the years ahead.

Conclusion

While we are not on a trajectory to meet the aspirations to reduce global GHG emissions in the transportation sector, there are emerging solutions that could be adopted should governments around the world decide to put in place the incentives to get there. Moving forward, the future of transportation fuels will be shaped by a mix of innovation, government policies, and what consumers want. The focus will be on ensuring that the transportation sector remains reliable, secure, and economically robust, while also reducing GHG emissions. But, decarbonizing the transportation sector is much more than just EV's – it's a broader effort that will require continued global progress in each of the multiple transportation segments.

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Scott Nyquist is a senior advisor at McKinsey & Company and vice chairman, Houston Energy Transition Initiative of the Greater Houston Partnership. The views expressed herein are Nyquist's own and not those of McKinsey & Company or of the Greater Houston Partnership. This article originally ran on LinkedIn on October 9, 2024.

Houston company secures $10M contract to deliver subsea well decommissioning solution

big deal

Houston energy services provider Expro was awarded a contract valued at over $10 million for the provision of a well decommissioning solution.

The solution will combine subsea safety systems and surface processing design that can enable safe entry to the well and management of well fluids.

“The contract reinforces our reputation as the leading provider of subsea safety systems and surface well test equipment, including within the P&A sector,” Iain Farley, Expro’s regional vice president for Europe and Sub-Saharan Africa, says in a news release. "It demonstrates our commitment to delivering best-in-class equipment, allied with the highest standards of safety and service quality that Expro is renowned for.”

Expro will provide from its global support hub in Aberdeen, a surface fluid management package and a market-leading 7-3/8 inch large-bore subsea test tree assembly (SSTTA). This will include surface tree and controls that can provide dual barrier and disconnect capability to facilitate re-entry into the subsea wells.

Expro has been supplying its subsea safety systems and well test equipment to the construction of many of the 52 wells now being plugged and abandoned.

“Having been involved in the development phase for many of these fields, we have gained a life of well experience that will be invaluable for this P&A campaign,” Farley adds. “Our expertise and know-how will help deliver key technical and commercial benefits for the client across the project.”