Ice mixed with amino acids stores methane in minutes

NUS researchers developed a reusable, biodegradable ice material that captures methane rapidly, paving the way for safer and cleaner storage of natural gas and biomethane.

National University of Singapore College of Design and Engineering

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Professor Praveen Linga and his research team, Yunhan Ma (left) and Dr Ye Zhang (middle), at their lab, where the amino-acid-modified ice technology was developed.

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Credit: College of Design and Engineering at NUS

If you have ever cooked on a gas stove or seen a flame flicker to life with the turn of a knob, you have seen natural gas in action. Supplying that energy at scale, however, is far more complicated. Today, natural gas is mostly stored under high pressure or cooled into liquid at -162 °C — both methods that are energy-intensive and costly. An alternative approach, called solidified natural gas, locks methane inside an ice-like cage known as a hydrate. But in practice, these hydrates usually form far too slowly to be practical on a larger scale.

Researchers led by Professor Praveen Linga from the Department of Chemical and Biomolecular Engineering at the College of Design and Engineering, National University of Singapore, have found a simple workaround by adding amino acids — the building blocks of proteins. In a new study ‘Rapid conversion of amino acid modified-ice to methane hydrate for sustainable energy storage’ published in Nature Communications, the researchers showed that freezing water with a small amount of these naturally occurring compounds produces an “amino-acid-modified ice” that locks in methane gas in minutes. In tests, the material reached 90 per cent of its storage capacity in just over two minutes, compared with hours for conventional systems.

The method also brings environmental benefits. Because amino acids are biodegradable, the method averts the environmental risks posed by surfactants often used to speed up hydrate formation. It also allows methane to be released on demand with gentle heating, after which the ice can be refrozen and reused, creating a closed-loop storage cycle. This combination of performance and sustainability makes the approach attractive for large-scale natural gas storage as well as for smaller, renewable sources of biomethane. The team also sees potential for adapting the technique to store other gas, including carbon dioxide and hydrogen.

Faster hydrates with a biological twist

The concept behind the new material is highly effective yet elegantly simple: mix water with amino acids, freeze it and then expose the ice to methane gas. In the lab, this amino-acid-modified ice quickly transformed into a white, expanded solid — evidence that methane had been locked inside as hydrate. Within just over two minutes, the material stored 30 times more methane than plain ice could hold.

This is possible because amino acids change the surface properties of the ice. Hydrophobic amino acids such as tryptophan encourage the formation of tiny liquid layers on the ice surface as methane is injected. These layers act as fertile ground for hydrate crystals to grow, producing a porous, sponge-like structure that speeds up gas capture. By contrast, plain ice tends to form a dense outer film that blocks further methane from diffusing inward, slowing the process dramatically.

To probe what was happening at the molecular level, the team turned to Raman spectroscopy, a technique that tracks how light scatters from vibrating molecules. These experiments showed methane rapidly filling two types of microscopic cages inside the hydrate structure, with occupancies above 90 per cent. “This gives us direct evidence that the amino acids are not only speeding up the process but also allowing methane to pack efficiently into the hydrate cages,” said Dr Ye Zhang, the lead author of the paper, a Research Fellow from the Department of Chemical and Biomolecular Engineering.

The team also tested different amino acids and found a clear pattern. Notably, hydrophobic ones like methionine and leucine worked well, while hydrophilic ones such as histidine and arginine did not. This “design rule,” Prof Linga said, could guide future efforts to tailor ice surfaces for gas storage.

From lab results to energy storage cycles

The researchers’ work is still at the proof-of-concept stage, but the performance of the modified ice is very promising. At near-freezing temperatures and moderate pressures, the amino acid ice outperformed some of the most advanced porous materials, including metal-organic frameworks and zeolites, used for storing natural gas — not only in how much methane it could hold, but also in how quickly it filled. And unlike surfactant-based systems, it did not produce foaming during gas release, which is a major hurdle for large-scale operation.

Equally important is the ability to empty and reuse the system. By gently warming the hydrate, the team could recover all the stored methane. The leftover solution could then be frozen again to form fresh amino acid modified ice, setting up a repeatable ‘charge–discharge’ cycle reminiscent of how batteries store and release energy.

Reusability and sustainability make the method appealing for handling smaller, distributed supplies of renewable biomethane, which are often too modest in scale to justify expensive liquefaction or high-pressure storage facilities. The team is also exploring how to scale up the process for larger systems, including reactor designs that maintain efficient gas–liquid–solid contact, as well as tests with natural gas mixtures containing methane, ethane and propane. Other directions include improving hydrate stability through amino acid-engineered composite systems, and eventually adapting the method for gases such as carbon dioxide and hydrogen.

“Natural gas and biomethane are important components in the energy mix today, but their storage and transport have long relied on methods that are either costly or carbon-intensive,” added Prof Linga. “What we are showing is a simple, biodegradable pathway that can both work quickly and be reused. It makes gas storage safer, greener and more adaptable.”

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Journal

Nature Communications

DOI

10.1038/s41467-025-63699-2 

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

Rapid conversion of amino acid modified-ice to methane hydrate for sustainable energy storage

Article Publication Date

30-Sep-2025

 

Passive silver-nanoring coating points to “self-regulating” smart windows — without power or tinting

Aarhus University team shows that thermoplasmonic nanorings can cut near-infrared heat while keeping windows clear, offering a passive route to lower cooling demand and CO₂ emissions.

Aarhus University

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Passive smart window: A thin layer of silver nanorings lets visible light pass while reducing near-infrared heat at high solar intensity—cutting cooling needs without power.

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Credit: Lise Refstrup Linnebjerg Pedersen, iNANO, Aarhus University

A passive, light-responsive material for intelligent windows
A new Danish breakthrough points to “smart” windows that work entirely without wiring, sensors or electronics. Scientists at Aarhus University’s Interdisciplinary Nanoscience Center (iNANO) have developed a transparent layer embedded with silver nanorings that automatically adapts to sunlight intensity and controls how much heat enters through the glass—without dimming the view or using any electricity.

How it works.
The silver nanorings act like microscopic antennas for near-infrared (NIR) light, which carries the majority of solar heat. When exposed to intense sunlight, they heat up via a thermoplasmonic effect and reduce NIR transmission. Because the mechanism is triggered directly by light, it self-regulates in real time: more sun means stronger response and less NIR gets through; less sun weakens the effect. Visible light passes largely unaffected, keeping interiors bright without the midday heat load.

What’s new.
Unlike electrochromic or mechanically adjustable smart windows, this passive solution needs no wiring, power supply, sensors, or control systems. The NIR-blocking effect intensifies with solar irradiance, while visible transmittance remains high—preserving both daylight and clarity. The response is reversible and has been demonstrated under controlled lab conditions.

Why it matters.
Modern buildings with large glass façades often consume more energy on cooling than heating. A window coating that selectively filters heat-producing radiation at peak times—without blocking light—could lower cooling demand and CO₂ emissions, contributing to energy-efficient architecture and improved indoor comfort.

“We have developed a combination of materials whose optical properties change in response to sunlight. It allows heat to enter when the sun is low, but reduces heat radiation at midday—exactly when the need for cooling otherwise increases. And it all happens without any electricity,”
— says PhD student Xavier Baami González, first author of the study.

“These types of solutions are crucial if we want to build in a more climate-friendly way without compromising on comfort and daylight. Our hope is that the hybrid material can eventually be integrated into smart window solutions and find its way into commercial use,”
— adds project lead Professor Duncan S. Sutherland.

The university has filed a patent application covering aspects of the technology.

Publication
Thermoplasmonic Nanorings for Passive Solar-Responsive Smart Windows in Energy-Efficient Building Applications, Advanced Functional Materials (2025).
Authors: Xavier Baami González and Duncan S. Sutherland, iNANO, Aarhus University.

Funding
Independent Research Fund Denmark

Media contact
Duncan S. Sutherland, Professor, iNANO, Aarhus University — duncan@inano.au.dk

Sun-Responsive Silver Nanorings [VIDEO] 

Animated explainer from iNANO, Aarhus University: an active layer of silver nanorings lets visible light pass while modulating near-infrared heat. At low sun, most NIR passes; at high sun, the rings heat and dissipate/scatter NIR, cutting heat gain without power—lower cooling and CO₂, better indoor comfort.

Credit

Lise Refstrup Linnebjerg Pedersen, iNANO, Aarhus Unviersity

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Journal

Advanced Functional Materials

DOI

10.1002/adfm.202518295 

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

Thermoplasmonic Nanorings for Passive Solar-Responsive Smart Windows in Energy-Efficient Building Applications

Article Publication Date

29-Sep-2025

 

Global wildfire disasters are growing in frequency and cost

Summary author: Walter Beckwith

American Association for the Advancement of Science (AAAS)

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Wildfire disasters worldwide are growing notably in frequency and cost, according to a new study, with nearly half of the most damaging events over the last 44 years occurring in just the past decade, driven largely by increasingly extreme fire weather in vulnerable, densely populated regions. The findings, informed by an analysis of global reinsurance data and international disaster reports, reveal a concerning trend and highlight the need to adapt for a more fire-prone world. Humans have coexisted with wildfires for millennia, but climate change, land mismanagement, and expansion into flammable landscapes have intensified risks. However, despite widespread concerns, the authors of this new study say there has been little systematic global evidence on whether societally disastrous wildfires – events with major social and economic consequences – are becoming more frequent or costly. This may be due, in part, to the lack of long-term, global data on the socioeconomic effects of wildfires, with many governments worldwide keeping such information inaccessible to the public. To address this gap, Calum Cunningham and colleagues compiled and harmonized two global disaster databases – Munich Re’s NatCatSERVICE, one of the most comprehensive proprietary reinsurance datasets, and the publicly available Emergency Events Database (EM-DAT) – to examine wildfire disasters from 1980 to 2023. These integrated datasets allowed the authors to evaluate, at a global scale, both societal impacts and financial losses from major wildfire disasters (i.e., those that caused 10 or more fatalities or were among the 200 largest wildfire-related economic losses relative to national GDP).

 

Cunningham et al. found that wildfire disasters have become markedly more burdensome worldwide over the last 40 years, with a pronounced acceleration beginning around 2015. Major economic disasters from wildfires have increased more than fourfold since 1980, with 43% of the 200 most damaging events occurring in just the past decade. Wildfire fatality events have also risen significantly, tripling in frequency since 1980. According to the findings, this escalation is driven by a combination of intensifying climate conditions that promote extreme fire weather and human factors such as expansion of the wildland–urban interface, land-use shifts, and long-term fire suppression policies. Although fire-prone biomes such as Mediterranean, temperate conifer, and boreal forests bear a disproportionate share of disasters, significant impacts are now also emerging in diverse regions, particularly along the margins of affluent urban areas where financial consequences are especially pronounced.

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Journal

Science

DOI

10.1126/science.adr5127 

Article Title

Climate-linked escalation of societally disastrous wildfires

Article Publication Date

2-Oct-2025

Wildfire management: Reactive response and recovery, or proactive mitigation and prevention

Summary author: Walter Beckwith

American Association for the Advancement of Science (AAAS)

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Catastrophic wildfires – those causing massive damage and soaring suppression costs – are increasing in frequency and intensity worldwide, a trend expected to worsen with climate change. In a Policy Forum, Robert Gray and colleagues use British Columbia (BC), Canada, as a case study of a government at a crossroads: continue reactive spending on suppression and recovery or invest in strategies to reduce future wildfire risk. “Although we focus on BC, this same tough question, along with lessons learned and our main recommendations, apply to regional and national governments in dozens of countries,” Gray et al. write. Over the past decade, BC has lost more than 7 million hectares to wildfire, with suppression and recovery costs topping $4.8 billion. Indirect costs, including health impacts and economic disruption, are far higher. Here, the authors argue that governments like BC are faced with an important policy choice; either continue to focus on response and recovery, or embrace proactive, long-term fire mitigation and prevention. Gray et al. highlight that scaling up wildfire mitigation requires public and political support for sustained, multidecade investments, along with cost-management strategies, yet governments continue to prioritize reactive spending despite evidence that prevention is far more cost-effective. They propose four recommendations: set clear resilience goals based on economic and risk analyses; foster public understanding and support for short-term sacrifices like prescribed burns; implement collaborative, hands-on landscape-scale interventions with scientists, Indigenous leaders, industry, and communities; and leverage public concern and scientific evidence to secure long-term political commitment and funding for preventive wildfire management.

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Journal

Science

DOI

10.1126/science.adx1230 

Article Title

Wildfire management at a crossroads: Mitigation and prevention or response and recovery?

Article Publication Date

2-Oct-2025