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Posted on 11/20/2025 6:20:42 AM PST by Red Badger
Scientists at the University of Santiago de Compostela have unveiled a new photocatalytic method that converts methane and other natural gas components directly into versatile chemical building blocks.
Researchers have created an iron-based catalyst that controls methane’s extreme reactivity, opening the door for natural gas to serve as a sustainable feedstock for high-value chemicals, including pharmaceuticals.
Natural gas, one of the most plentiful energy resources on Earth, consists mainly of methane, ethane, and propane. Although it is commonly burned for power and contributes to greenhouse gas emissions, researchers have long looked for ways to convert these stable hydrocarbons into useful chemicals instead. Their low reactivity has made this goal difficult, limiting natural gas as a sustainable starting point for chemical manufacturing.
A research group led by Martín Fañanás at the Centre for Research in Biological Chemistry and Molecular Materials (CiQUS) at the University of Santiago de Compostela has now introduced a method that overcomes this barrier. Their approach converts methane and other components of natural gas into flexible chemical “building blocks” that can be used to create high-value products, including pharmaceuticals. The work, published in Science Advances, marks an important step toward a more efficient and environmentally responsible chemical industry.
In a key demonstration, the CiQUS team produced the bioactive compound dimestrol, a non-steroidal estrogen used in hormone therapy, directly from methane. This milestone shows how their technique can generate complex and valuable molecules from a simple and inexpensive resource.
Taming Free Radicals to Unlock New Chemical Pathways
The researchers focused their approach on a reaction known as allylation, which adds a small chemical “handle” (an allyl group) to the gas molecule. This added group acts as a flexible anchor that allows many different products to be built in later steps, including pharmaceutical ingredients and common industrial chemicals. Until now, a major obstacle was that the catalytic system often generated unwanted chlorinated byproducts, which disrupted the entire process.
To overcome this obstacle, the team engineered a tailor-made supramolecular catalyst. “The core of this breakthrough lies in designing a catalyst based on a tetrachloroferrate anion stabilized by collidinium cations, which effectively modulates the reactivity of the radical species generated in the reaction medium,” explains Prof. Fañanás. “The formation of an intricate network of hydrogen bonds around the iron atom sustains the photocatalytic reactivity required to activate the alkane, while simultaneously suppressing the catalyst’s tendency to undergo competing chlorination reactions. This creates an optimal environment for the selective allylation reaction to proceed.”
Beyond its effectiveness, the method stands out for its sustainability. It uses iron—a cheap, abundant, and far less toxic metal than the precious metals typically used in catalysis—and operates under mild temperature and pressure conditions, powered by LED light. This significantly reduces both environmental impact and energy costs.
This work is part of a broader research line funded by the European Research Council (ERC), focused on upgrading the main components of natural gas. In a complementary advance published in Cell Reports Physical Science, the same team presented a method to directly couple these gases with acid chlorides, yielding industrially relevant ketones in a single step. Both studies, based on photocatalytic strategies, position CiQUS as a leader in developing innovative chemical solutions to harness abundant raw materials.
Transforming Natural Gas into Versatile Chemical Intermediates
The ability to convert natural gas into versatile chemical intermediates opens up new possibilities for industry, laying the foundation to gradually replace petrochemical sources with more sustainable alternatives.
Reference:
“Attenuated LMCT photocatalysis enables C─H allylation of methane and other gaseous alkanes”
by Andrés M. Álvarez-Constantino, Pol Martínez-Balart, Sergio Barbeira-Arán, Álvaro Velasco-Rubio and Martín Fañanás-Mastral, 7 November 2025, Science Advances.
DOI: 10.1126/sciadv.aea0783
This cutting-edge research is made possible by the excellence environment at CiQUS, which holds the CIGUS accreditation from the Galician government, recognizing the quality and impact of its research.
The center receives crucial financial support from the European Union through the Galicia FEDER 2021-2027 Program, enabling scientific advances with potential for transfer and socioeconomic impact.
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“yielding industrially relevant ketones in a single step”
Although it is commonly burned for power and contributes to greenhouse gas emissions, researchers have long looked for ways to convert these stable hydrocarbons into useful chemicals instead.
It uses iron—a cheap, abundant, and far less toxic metal than the precious metals typically used in catalysis
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Where to begin?
At the beginning is a good place....................
This once again brings up risk reduction methods for vast fields of Methane ice (Methane clathrate) under the sea floor.
This is potentially a very valuable invention.
The reaction requires LED light as a trigger; as such it will be difficult to scale commercially.
But might have value as new route for niche drugs.
Can you convert sunlight into LED light?
I saved a post here on how to create methane gas from sunlight and water. Then groked the below .01@kwh solar early stage solar companies. I got one. Then I found some government owned land with brackish water beneath them. Then I found some materials that would cause water to flow along the surface for collection. You would need a large shaped bomb to blast a hole for an upside down water tower to collect water. That would yield about 350 acre feet on 7 inches of annual rainfall spread over a square mile solar farm with a 500 megawatt output. Desalinated water would cover any remaining water needs. So you would have a square mile facility that produces both water and electricity. The two together could be used to either produce the worlds cheapest methane or support a data center with the world’s cheapest electricity, interestingly the demand for power is so high rhe government will fund these kinds of projects.
I doubt there’s anything special about LED, other than it’s efficient to produce from electricity. So solar panels would get you going.
Natural gas in west Texas and New Mexico is very cheap and sometimes negative. The low pricing is due to rapid oil production growth, without pipelines to take associated gas to market. It’s why Chevron announced last week they were planning to generate up to 5,000 megawatts power for data centers. There’s another dozen companies looking to do similar projects.
https://finance.yahoo.com/news/chevron-picks-west-texas-first-103423266.html
As to fresh water, there would be interest in better conversion methods from brackish or salt water. Tehran is a water shortage crisis.
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