membrane

More efficient cooling for data centers

July 22, 2025 By EarthWise Leave a Comment

Increasing reliance on digital technologies in general and artificial intelligence in particular are dramatically increasing the energy consumption of data centers. Data centers consume far more energy per square foot than other commercial buildings. By the year 2030, data center energy consumption in the US is projected to reach 9% of the country’s electricity generation.

Computing hardware consumes large amounts of energy and generates large amounts of heat in the process. Currently, cooling the equipment so it doesn’t burn out accounts for as much as 40% of a data center’s total energy use.

Engineers at the University of California San Diego have developed a new cooling technology that could significantly improve the energy efficiency of data centers. The technology makes use of a specially engineered fiber membrane that passively removes heat through evaporation.

The membrane has a network of tiny, interconnected pores that draw cooling liquid across the membrane surface using capillary action. As the liquid evaporates, it removes heat from the electronics underneath. No extra energy is required.

Tests of the membrane demonstrated record-breaking performance in removing heat from electronics and being able to withstand very high levels of heat flux.

The researchers say that the technology is still operating well below its theoretical limit, and with additional work, can lead to optimized performance. The membranes will be integrated into cold plates, which are components that attach to power-hungry computing components to dissipate heat. The team is also launching a startup company to commercialize the new cooling technology.

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New Cooling Tech Could Curb Data Centers’ Rising Energy Demands

Photo, posted January 23, 2023, courtesy of Jefferson Lab via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

A biostimulant for wheat

May 28, 2025 By EarthWise Leave a Comment

Feeding a global population projected to reach nearly 10 billion by mid-century is a massive challenge. Wheat provides a fifth of the calories in the global human diet and is a significant source of protein, minerals, vitamins, and fiber. Finding ways to increase the yield of wheat crops has great value. However, wheat has complex genetics, which makes it difficult to improve yields by traditional breeding methods or even by genetic engineering.

Researchers at Oxford University and the nearby Rosalind Franklin Institute have developed a biostimulant that can deliver increased wheat yields of up to 12%. It is applied as a spray and a four-year study in Argentina and Mexico demonstrated that it delivers major yield improvements irrespective of weather conditions.

The biostimulant is based on trehalose 6-phosphate (T6P), which is a natural molecule that regulates the plant equivalent of blood sugar. T6P prompts plants to produce more starch and increases the rate of photosynthesis.

Naturally occurring T6P cannot be applied topically because it cannot cross cell membranes. The researchers developed a membrane-permeable precursor of T6P that releases T6P into a plant in the presence of sunlight.

The biostimulant can be manufactured on an industrial scale and would be inexpensive to use.

The researchers have created SugaROx, a spinout company whose mission is “to increase the productivity, resilience, sustainability, and profitability of crop production” using active ingredients inspired by powerful natural plant molecules.

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New biostimulant treatment significantly boosts wheat yields, field studies confirm

Photo, posted July 28, 2014, courtesy of Brad Higham via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

A better way to extract lithium

December 10, 2024 By EarthWise Leave a Comment

Lithium is the critical component in the batteries that power phones and computers, electric cars, and the systems that store energy generated by solar and wind farms. Lithium is not particularly rare, but it is difficult and often environmentally harmful to extract from where it is found.

Traditional ore sources are increasingly difficult and expensive to mine. The largest known deposits of lithium are in natural brines – the salty water found in geothermal environments. These brines also contain other ions like sodium, potassium, magnesium, and calcium, and efficiently separating out the lithium is extremely challenging.

Traditional separation techniques consume large amounts of energy and produce chemical waste, particularly hazardous chlorine gas. These techniques typically suffer from poor selectivity; that is, the process is interfered with by the other ions present in natural brines.

A team of researchers at Rice University has developed a three-chamber electrochemical reactor that improves the selectivity and efficiency of lithium extraction from brines. The middle chamber of the reactor contains a specialized membrane that acts as a barrier to chloride ions, preventing them from getting to the electrode area where they can form chlorine gas.

The new reactor has achieved a lithium purity rate of 97.5%, which means the setup can effectively separate lithium from other ions in the brine and allow the production of high-quality lithium hydroxide, the key material for battery manufacturing.

The Rice University reactor design has the potential to be a game changer for lithium extraction from geothermal brines.

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‘Game changer’ in lithium extraction: Rice researchers develop novel electrochemical reactor

Photo, posted October 21, 2023, courtesy of Simaron via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio

Nanotech Water Purification | Earth Wise

July 14, 2020 By EarthWise Leave a Comment

We have occasionally talked about metal-organic frameworks, which are organic-inorganic hybrid crystalline structures that have a microscopic cage-like structure. MOFs have been under development for a diverse set of applications including gas storage and separation, liquid purification, energy storage, catalysis, and sensing.

For the first time, an international research team, led by researchers from Monash University in Australia, has created an ultrathin porous membrane based on MOF technology that can completely separate potentially harmful ions, such as lead and mercury, from water.

This innovation could enhance water desalination and transform even the dirtiest water into something potable for millions of people around the world. The new membrane performed steadily in tests for more than 750 hours using only limited energy.

The technology uses water-stable monolayer aluminum-based MOFs just a millionth of a millimeter in thickness. These are essentially two-dimensional structures. The ultrathin membrane is permeable to water – it achieves maximum porosity – but rejects nearly 100 percent of ions. It has been a daunting challenge to fabricate ultra-thin MOFs for water-based processing. Most previous membranes were too thick and unstable in water.

Most existing ion separation membrane technologies are based on polymers and have the limitation that they have limited selectivity. They don’t reject all unwanted ions.

The new membrane technology has great potential based on its precise and fast ion separation and could be ideal for a variety of filtration applications such as gas separation and separation of organic solvents such as paint. Such membranes might also be used to remove harmful carcinogens from the atmosphere.

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Ultrathin nanosheets separate ions from water

Photo courtesy of Monash University.

Earth Wise is a production of WAMC Northeast Public Radio.

Harvesting Blue Energy | Earth Wise

February 7, 2020 By EarthWise Leave a Comment

There are various ways to generate renewable energy from the world’s oceans, most obviously from the power of tides and waves. But there is also an oceanic energy source called osmotic or “blue” energy. Osmotic energy uses the differences in pressure and salinity between freshwater and saltwater to generate electricity.

When freshwater and saltwater are mixed together, large amounts of energy are released. If the freshwater and seawater are then separated via a semi-permeable membrane, the freshwater will pass through the membrane and dilute the saltwater due to the chemical potential difference. This process is called osmosis. If the salt ions are captured completely by the membrane, the passing of water through the membrane will create a pressure known as osmotic pressure. This pressure can be used to generate electricity by using it to drive a turbine. This has been demonstrated to work as far back as the 1970s, but the materials we have to use are not adequate to withstand ocean conditions over the long term and tend to break down quickly in the water.

New research, published in the journal Joule, looked to living organisms for inspiration to develop an improved osmotic energy system. Scientists from the U.S. and Australia combined multiple materials to mimic the kind of high-performance membranes that are found in living organisms. They created a hybrid membrane made from aramid microfibers (like those used in Kevlar) and boron nitride. The new material provides both the flexibility of cartilage and the strength and stability of bone.

The researchers believe that the low cost and high stability of the new hybrid membrane will allow it to succeed in volatile marine environments. They also expect the technology will be both efficient and scalable.

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Inspired by the Tissues of Living Organisms, Researchers Take One Step Closer to Harvesting “Blue Energy”

Photo, posted February 14, 2017, courtesy of Marian May via Flickr.

Earth Wise is a production of WAMC Northeast Public Radio.