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Category: energy

Ultrasound propagation in porous rocks: Theory identifies three distinct wave modes

Ultrasound-based irradiation of rock formations has attracted considerable attention as a technique for enhancing heavy-oil (high-viscosity crude oil) recovery from deep underground reservoirs. However, a unified theoretical framework for wave propagation and energy dissipation in these formations remains lacking because water coexists with heavy oil within rock pores, and gas bubbles in the water respond dynamically to ultrasonic excitation, thereby creating a complex system.

Conventional theories typically treat oil as a purely viscous (Newtonian) fluid or assume frequency ranges markedly below the ultrasonic regime. Consequently, these theories inadequately capture oil viscoelasticity and the influence of bubble oscillations in the ultrasonic regime.

Researchers at University of Tsukuba have developed a theoretical framework to clarify the propagation of ultrasonic waves through complex materials such as rocks containing mixtures of oil, water, and gas bubbles. The work extends previous low-frequency models and constructs a theoretical framework applicable to ultrasonic frequencies by incorporating three notable elements into a unified system of equations: (i) heavy-oil viscoelasticity, (ii) dynamic capillary pressure at fluid-fluid interfaces, and (iii) oscillations of gas bubbles dispersed in water induced by ultrasonic pressure fluctuations.

Circular polarization could cut laser backscatter in fusion experiments

Experiments at Lawrence Livermore National Laboratory’s National Ignition Facility (NIF) require breathtaking precision. Each of the 192 lasers is focused to a width of a few millimeters to enter a 3-millimeter hole at the top or bottom of a 2-centimeter (0.8-inch) gold canister known as a hohlraum.

As they enter, the beams intersect in plasma and transfer power, a process known as crossed-beam energy transfer (CBET). In designing a NIF inertial confinement fusion (ICF) experiment, scientists precisely tune the beams’ wavelengths to balance power via CBET and achieve better symmetry.

Small changes in wavelength have delivered big results—CBET is one key factor in achieving ignition on NIF. But what would be the effect of a more significant change in the laser architecture, namely its polarization state? LLNL scientists have calculated that this change would make the optics more resilient to filamentation damage.

New hydrogen breakthrough turns waste heat into clean fuel

Researchers at the University of Birmingham have developed a new low-temperature approach to hydrogen production that could make the clean fuel cheaper and more practical to generate. The technique could be used both in large centralized facilities and in smaller local systems that take advantage of waste heat from major industrial operations.

Hydrogen is the most abundant element in the universe and is widely viewed as an important clean energy source. When used as a fuel, it produces only water and heat rather than carbon dioxide and other pollutants associated with fossil fuels. Hydrogen can also power fuel cells that generate electricity. Despite these advantages, around 95% of hydrogen production today still depends on fossil fuels.

New ammonia-making method could upend one of industry’s dirtiest processes

As our world’s population grows, so does the demand for ammonia—a key ingredient in fertilizer. The International Renewable Energy Agency estimates that ammonia production must quadruple by 2050 to feed the increase in global population.

The current gold standard process for producing ammonia is energy-intensive and a major contributor to global greenhouse gas emissions. Invented in the early 1900s, the Haber-Bosch method requires mixing hydrogen and nitrogen gas at 400–500 degrees Celsius. It’s responsible for nearly 2% of global carbon dioxide emissions and accounts for 2% of fossil energy use.

Researchers from McMaster University have developed a process that is green and faster, generates ammonia more efficiently from nitrate—a common water pollutant—and is “cleaner” because it uses renewable electricity rather than fossil fuel.

E= mc^2

Einstein’s famous equation has grown into one of the great symbols of the 20th century. It is the one equation in science that people recognize, if any is. It has a kind of iconic status and dual connotations: the brilliance and insight of Einstein and the darkness of atomic bombs. Images.

The basic idea behind the formula E=mc2 is easy to state. Mass and energy are really just the same thing. At first that seems impossible.

• Mass is a measure of the quantity of stuff and manifests as a resistance to acceleration. A body with little mass, like a pebble, is easy to set in motion.

Cosmic dawn fuel discovery unlocks early galaxy growth secrets

Astronomers have discovered a huge reservoir of cold molecular gas, the direct fuel for star formation, in REBELS-25, a massive, star-forming galaxy. The team, led from Leiden University, focused on REBELS-25, seen when the universe was only about 700 million years old, around 5% of its current age. The research is published in the journal Monthly Notices of the Royal Astronomical Society.

Astronomers use “redshift” to describe this distance, which measures how much the universe’s expansion has stretched a galaxy’s light to redder wavelengths. The higher the redshift, the farther back in time we look. REBELS-25 sits at redshift z = 7.3, deep in the Epoch of Reionization, a key era in which the first stars and galaxies transformed the dark, neutral universe into the universe we see around us today.

Galaxies grow by turning gas into stars, and cold molecular gas is the primary fuel. Until now, astronomers suspected early bright, massive galaxies had huge gas supplies, but no one had directly detected them at these distances.

New cavity control strategy improves performance of blue vertical-cavity surface-emitting lasers

GaN-based vertical-cavity surface-emitting lasers (VCSELs) are promising for displays, sensing and optical communication, but improving efficiency remains challenging. Researchers have now shown that “cavity tuning,” which controls resonance wavelength, strongly affects laser performance. By analyzing variations across a VCSEL wafer, the team identified optimal mirror loss conditions and extracted device parameters. Their approach achieved 26.4% wall plug efficiency, offering guidance for next-generation high-efficiency visible-light semiconductor lasers.

Gallium nitride (GaN)-based vertical-cavity surface-emitting lasers, or VCSELs, are attracting increasing attention as compact and energy-efficient light sources for future technologies. These semiconductor lasers are considered promising for applications such as next-generation displays, biometric sensing, environmental monitoring and short-range optical communication. However, improving their efficiency has remained a major challenge because laser performance depends strongly on precise optical design and cavity control.

Addressing this challenge, a research team led by Professor Tetsuya Takeuchi, Professor Satoshi Kamiyama and Professor Motoaki Iwaya from the Department of Materials Science and Engineering, Meijo University, Japan, along with Mr. Naoki Shibahara, first author and graduate student at the Graduate School of Science and Technology, Meijo University, Japan, investigated how “cavity tuning” influences the lasing characteristics of GaN-based VCSELs. While conventional studies mainly focused on gain tuning, also known as detuning, the researchers demonstrated that resonance wavelength alignment relative to the distributed Bragg reflector center wavelength critically affects laser operation.

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Water locked in 1-nanometer channels could enable safer energy storage

Can pure water store electrical energy? A research team led by Dr. Vasily Artemov within the Cluster of Excellence “BlueMat—Water-Driven Materials” at Hamburg University of Technology has now shown that it can. By confining water within nanometer-sized channels in clay minerals, the researchers created a supercapacitor capable of efficiently storing and transporting electrical charge.

What makes the finding unusual is that it uses pure water as its electrolyte—the medium that transports electrical charge. Today’s batteries and supercapacitors typically rely on added salts, acids, or other chemical electrolytes. In contrast, the new system works without such additives and is based solely on abundant, naturally occurring materials: water, clay, and carbon.

“Our goal is to develop safer and more sustainable energy-storage technologies based on abundant materials rather than complex chemical compounds,” says Artemov, lead author of the paper published in Nature Communications. “The device stores and releases energy efficiently, operates at a comparatively high voltage for a water-based system, and remains stable over tens of thousands of charging cycles.”

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