Plasma treatment enhances electrode material for fuel cells in industry, homes and vehicles

 

Researchers from Skoltech and their colleagues have improved the properties of a carbon-based electrode material by exposing it to air plasma. Such treatment turned out to enhance electrode performance, which is the limiting factor for high-tech energy sources—particularly fuel cells.

These are a promising technology for cleaner and more efficient electrical power generation. Published in the Journal of Electroanalytical Chemistry, the study even shows that the cheaper-to-make air plasma is better-suited for processing the carbon material than pure nitrogen or oxygen plasma.

One way to make burning natural gas cleaner is to use fuel cells. These are devices that technically do not burn the fuel but rather oxidize it in a different manner. That process is friendlier to the environment, because it produces more useful power, less greenhouse gases and emits no pollutants such as nitrogen oxides, sulfur dioxide, and aerosol particles.

Fuel cells are used to power industrial facilities and homes, particularly in remote off-grid locations and where backup power is needed. Another application is generating electricity for space probes, submarines, industrial trucks operating in refrigerated spaces, and the more conventional vehicles such as cars, buses, trains, and boats. The main advantages of the technology are its efficiency, resilience, and sustainability.

The biggest challenges are coping with the high operating temperature of fuel cells and refining the advanced materials used in their three principal components: the positive and negative electrodes and the ceramic electrolyte layer between them, which facilitates the chemical reaction that yields useful energy. Previously, Skoltech researchers manufactured an intricately shaped electrolytic component for solid-oxide fuel cells. The new study tinkers with one of the common anode materials to improve it.

"Anodes in solid-oxide fuel cells are made of various forms of carbon, and the catalytic activity of those materials puts a limitation on the rate of the reaction in the cell that supplies power. We seek ways to boost catalytic activity by incorporating foreign atoms, called defects, into the carbon electrode. This is referred to as defect engineering," says the lead author of the study, Assistant Professor Stanislav Evlashin of Skoltech Materials.

"In this study, we introduce oxygen and nitrogen atoms in various proportions into highly oriented pyrolytic graphite and one other carbon-based material by exposing them to plasma of distinct compositions."

To modify the electrode material, the team subjected it to a direct current discharge that formed plasma in a chamber filled alternately with pure nitrogen, pure oxygen, and ordinary air. The latter of the three performed the best, which is good news because the pure gases are obviously more expensive.

In general, this defect engineering approach is more economical than the existing alternatives: carbon doped with ruthenium oxide or with platinum. The new technique is also handy in that the oxygen and nitrogen inclusions can be introduced during the original material's manufacture, without the need for an additional post-processing stage, which is necessary for ruthenium oxide and platinum doping.

As far as the effect on catalytic activity goes, plasma treatment improved the material's properties enough to put electrodes made of it fairly close to those using noble metals.

The findings show that the defect engineering approach can significantly improve the resulting electrochemical characteristics of the material without incorporating additional materials or steps of production. Once the researchers learn to insert defects during the process of material synthesis in a controlled manner, the produced materials can immediately be used in the manufacture of current sources.

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Tribology is the study of interacting surfaces in motion and the measurement of properties such as friction, wear and abrasion. When designing nanoscale devices the consideration of tribology is particularly important because the high surface area ratio enhances problems with friction and wear.

Understanding nanoscale surface changes of tribological properties will also allow for either increased or decreased friction at a greater scale than currently provided by macroscopic lubrication and adhesion. Scanning probe microscopy techniques such as the atomic force microscope are being utilized to assess tribological properties at the nanoscale. The tip of the atomic force microscope provides contact with a solid or lubricated surface in order to study properties such as adhesion, friction and wear. The information provided can be used to further the understanding of nanotribology and predict how this affects nanomaterial surface interactions. Current nanotechnology applications of tribology are leading to the development of new drug delivery techniques, biosensors, data recording systems and microprojectors.

Nanotechnology Applications of Tribology for Biosensors and Drug Delivery

Biosensors for determining the presence and concentration of biomolecules have increased in accuracy through the greater surface area provided by nanotechnology for the immobilization of enzymes used to detect biological analytes. Glucose biosensors are a prominent example; they utilize nanoparticles over a carbon nanotube sheet for immobilizing the enzyme glucose oxidase. Biosensors are developed with nanoelectrochemical systems (NEMS) meaning they integrate electrical, mechanical, fluidic and thermal properties at the nanoscale. By implementing NEMS, tribological properties such as friction, adhesion and cohesive forces can be controlled to model and improve the biochemical reactions necessary for biosensing.

Because the high surface area of nanoscale devices increase tribological problems of friction and wear, further understanding of these issues is important for improving biosensing technologies. Moreover, strengthening the ability to control these properties will also increase the likelihood of providing enhanced drug delivery systems through nanotechnology. Drug delivery of molecules at the nanoscale or for drugs that are transported via nanovectors requires adhesion between biological molecular layers and the substrate. Understanding how friction and wear affects this adhesion is important and extensive measurements of tribological properties for nanomaterial is currently being implemented through the use of atomic force microscopes.

 
Nanotechnology Applications of Tribology for Data Storage

Nanotechnology is supplying new techniques for nonvolatile digital data storage systems. Magnetic hard disks have a high storage capacity and data is extracted from the physical movement of the recording medium or reading head. Scanning probe microscopy provides the technology for probe based data storage which employs an atomic force microscope tip for scanning at speeds of up to 100 millimeters per second. The technology also has the ability to utilize a multiple probe array for a high data rate.

An obvious limitation to this data storage methodology is wear to the atomic force microscope tip, and the damage produced from the high velocities and temperature required for high data rate recording. Therefore, nanotribological experiments are important for improving the technology. Studies have found differences in the friction properties of storage devices with unlubricated and lubricated film surfaces. As expected, significant probe tip wear is produced from the unlubricated film surface sample but future technology may utilize lubricated surface coatings to the probe to reduce abrasion during data recording.

Nanotechnology Application of Tribology for Microprojectors

The development of handheld electronic devices has produced the requirement for microprojectors to avoid the limitations of smaller screen displays. Adaptive optic components are used to align optics and maintain power output which can be misaligned due to the high temperatures produced from small optic lenses and nanoscale light beams. Enhancing the technology for microprojectors requires the tribological analysis of the lubricant used in the adaptive optics component. In the development of one microprojector patent, tribology tests found that there was a trade-off between the thickness of lubricant film and surface roughness required for optimum friction, adhesive force and durability.

This is because as lubricant thickness increases, the distribution on the optics component improves leading to stable and reliable operation; however, adhesive forces increase because of the lubrication within the connecting areas of the material. Therefore, the lubrication film thickness to sample roughness ratio should be assessed dependent on the level of use and functionality of the microprojector device.

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Nanotechnology promises improved energy storage, solar conversion

 

The emergent field of nanotechnology offers “extraordinary possibilities in the area of sustainable energy, providing innovative solutions for improving green energy,” says the World Nano Foundation.

The Foundation is a globally recognised not-for-profit membership organisation at the forefront of nanoscale technology advancement.

Its recently released white paper, Unleashing the Potential of Nanotechnology for Superior Energy Storage and Solar Conversion Solutions delves into the possibilities of nanotechnology in reshaping energy storage and solar conversion.

The Foundation said this field offers “innovative solutions to drive sustainable energy practices.”

The white paper investigates the most recent breakthroughs in nanotechnology that pave the way for more effective and efficient energy storage and solar conversion.

“The global challenge of transitioning from fossil fuels to sustainable energy sources necessitates advanced technology, and nanotechnology offers a promising solution in this area,” said the Foundation.

Working at the nanoscale level, scientists and engineers have “significantly improved” energy storage and solar conversion technologies’ performance and efficiency.



Exploring the impact on renewable energy

“Nanoscale innovations have improved energy storage, creating advanced batteries with higher energy density and faster charging. Nanomaterials like carbon nanotubes enhance battery stability and lifespan through nanoscale coatings, facilitating quicker ion diffusion,” said the Foundation.

It said that nanotechnology has also boosted solar cell efficiency by incorporating nanoscale structures like quantum dots and perovskite materials.

This leads to improved light absorption, better charge separation, and minimised energy losses, enabling more efficient conversion of sunlight into electricity.

“Moreover, nanotechnology enables compact and efficient energy conversion and storage systems.

“Hybrid solar cells using nanomaterials generate electricity and store energy simultaneously, ensuring uninterrupted power supply even in low-light conditions.

“Nanoscale supercapacitors offer high power density and rapid energy discharge, ideal for energy storage applications.”

But there are potential barriers to entry in energy storage and conversion, the Foundation pointed out.

These include:Exorbitant expenditure for research and development: Delving into nanotechnology for energy storage and conversion necessitates substantial funding, posing a financial challenge for emerging companies or researchers in the sector.
Lengthy development process: Creating new and innovative nanomaterials for energy purposes can be a drawn-out process, contributing to the hurdles faced by novices in the field.
Regulatory barriers: Before new nanomaterials are given the green light for energy storage or solar conversion, they must surmount numerous regulatory obstacles, further complicating the market penetration pathway.

Push for renewable energy sources drives nanotechnology research

“Despite the obstacles, the energy storage and conversion market is experiencing swift growth. It is expected to grow to $17 billion by 2028, according to the report from Markets and Markets, which said: ‘The ongoing revolution in renewable energy is contributing to this market growth.’”

The increasing demand for renewable energy and the transition towards electric transportation create substantial market opportunities for advanced batteries and nanotechnology-enabled solar cells, the Foundation said.

“Esteemed organisations such as the United States Department of Energy (DOE), and the Japan Science and Technology Agency (JST) have been pioneering this movement with substantial expenditure on research and development of advanced nanotechnologies, which are aimed at enhancing the efficiency of energy systems and curbing costs.

“In particular, the DOE has played a pivotal role in nurturing innovation in nanotechnology-enabled energy solutions, which are poised to revolutionise various facets of energy storage and conversion.”

A  Nanotechnology critical for the future of the energy landscape

Paul Stannard, World Nano Foundation Chairman and Founder, said: ”Utilising the unique power of nanoscale innovation in energy storage and solar conversion is a critical leap forward for the future of sustainable energy.

“Its ability to augment efficiency and diminish costs is transformative and delivers commercial scalability. Indeed, it’s not just an enhancement; it’s the cornerstone of constructing a future of sustainable energy.”

A spokesperson for the American Association for the Advancement of Science said that “nanostructured materials and nanoarchitectured electrodes can provide solutions for designing and realising high-energy, high-power, and long-lasting energy storage devices.”

The Foundation said that advancements in energy storage and conversion depend heavily on material science.

Nanotechnology serves as a pivotal component in this progress, particularly in the realm of advanced batteries and solar cells.

“Despite the existing hurdles, the advanced energy storage and conversion solutions market is on a growth trajectory.

“Nanomaterials possess the potential to greatly enhance ion transportation and electron conductivity, which could be the solution to advancing this field.”

Access the World Nano Foundation’s white paper Unleashing the Potential of Nanotechnology for Superior Energy Storage and Solar Conversion Solutions.

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'Stunning' discovery: Metals can heal themselves

Scientists for the first time have witnessed pieces of metal crack, then fuse back together without any human intervention, overturning fundamental scientific theories in the process. If the newly discovered phenomenon can be harnessed, it could usher in an engineering revolution—one in which self-healing engines, bridges and airplanes could reverse damage caused by wear and tear, making them safer and longer-lasting.



The research team from Sandia National Laboratories and Texas A&M University described their findings today in the journal Nature.

"This was absolutely stunning to watch first-hand," said Sandia materials scientist Brad Boyce.

"What we have confirmed is that metals have their own intrinsic, natural ability to heal themselves, at least in the case of fatigue damage at the nanoscale," Boyce said.

Fatigue damage is one way machines wear out and eventually break. Repeated stress or motion causes microscopic cracks to form. Over time, these cracks grow and spread until—snap! The whole device breaks, or in the scientific lingo, it fails.

The fissure Boyce and his team saw disappear was one of these tiny but consequential fractures—measured in nanometers.

"From solder joints in our electronic devices to our vehicle's engines to the bridges that we drive over, these structures often fail unpredictably due to cyclic loading that leads to crack initiation and eventual fracture," Boyce said. "When they do fail, we have to contend with replacement costs, lost time and, in some cases, even injuries or loss of life. The economic impact of these failures is measured in hundreds of billions of dollars every year for the U.S."

Although scientists have created some self-healing materials, mostly plastics, the notion of a self-healing metal has largely been the domain of science fiction.

"Cracks in metals were only ever expected to get bigger, not smaller. Even some of the basic equations we use to describe crack growth preclude the possibility of such healing processes," Boyce said.

Unexpected discovery confirmed by theory's originator

In 2013, Michael Demkowicz—then an assistant professor at the Massachusetts Institute of Technology's department of materials science and engineering, now a full professor at Texas A&M—began chipping away at conventional materials theory. He published a new theory, based on findings in computer simulations, that under certain conditions metal should be able to weld shut cracks formed by wear and tear.

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Plasmonics

Plasmonics

A plasmon is defined as a quantum oscillation of the free electron cloud with respect to the fixed positive ions in a metal and those that are confined on surfaces and strongly interacting with light are called surface plasmons.

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Nanofabrication

 

Nanofabrication is the manufacture of materials with nanometer dimensions. Nanofabrication helps with the processing of material on a large scale. The purpose of nanofabrication is to produce nanoscale structures that form part of a system, device, or component in large quantities and at a very low cost.

Nanomanufacturing is both the production of nanoscaled materials, which can be powders or fluids, and the manufacturing of parts "bottom up" from nanoscaled materials or "top down" in smallest steps for high precision, used in several technologies such as laser ablation, etching and others.

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Nanomaterials are substances that are, or have been, reduced in size to the range from 1 nm to ~ 100 nm (i.e. 1 to ~ 100 nanometers, or 1 to ~ 100 × 10-9 meters). Nanotechnology is the science and applications of nano-materials, and is growing at an ever increasing pace.

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