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Category: engineering – Page 31

Artificial photosynthesis learned from nature: New solar hydrogen production technology developed

Researchers have successfully developed a supramolecular fluorophore nanocomposite fabrication technology using nanomaterials and constructed a sustainable solar organic biohydrogen production system.

The research team used the good nanosurface adsorption properties of tannic acid-based metal-polyphenol polymers to control the and optical properties of fluorescent dyes while also identifying the photoexcitation and electron transfer mechanisms. Based on these findings, he implemented a solar-based biohydrogen production system using bacteria with hydrogenase enzymes.

The findings are published in the journal Angewandte Chemie International Edition. The joint research was led by Professor Hyojung Cha at the Department of Hydrogen and Renewable Energy, Kyungpook National University and Professor Chiyoung Park at the Department of Energy Science and Engineering, Daegu Gyeongbuk Institute of Science & Technology.

Strain engineering approach enhances performance of 2D semiconductor-based transistors

The manipulation of mechanical strain in materials, also known as strain engineering, has allowed engineers to advance electronics over the past decades, for instance enhancing the mobility of charge carriers in devices. Over the past few years, some studies have tried to devise effective strategies to manipulate strain in two-dimensional (2D) semiconductors that are compatible with existing industrial processes.

Researchers at Stanford University recently introduced a CMOS-compatible approach to engineer the (i.e., stretchiness) in monolayer semiconductor transistors.

This approach, outlined in a paper published in Nature Electronics, relies on the use of silicon nitride capping layers that can impart strain on monolayer molybdenum disulfide (MoS2) transistors integrated on silicon substrates.

Tiny rotating particles create vorticity in viscous fluids, yielding fascinating new behaviors

Vorticity, a measure of the local rotation or swirling motion in a fluid, has long been studied by physicists and mathematicians. The dynamics of vorticity is governed by the famed Navier-Stokes equations, which tell us that vorticity is produced by the passage of fluid past walls. Moreover, due to their internal resistance to being sheared, viscous fluids will diffuse the vorticity within them and so any persistent swirling motions will require a constant resupply of vorticity.

Physicists at the University of Chicago and applied mathematicians at the Flatiron Institute recently carried out a study exploring the behavior of viscous fluids in which tiny rotating particles were suspended, acting as local, mobile sources of vorticity. Their paper, published in Nature Physics, outlines fluid behaviors that were never observed before, characterized by self-propulsion, flocking and the emergence of chiral active phases.

“This experiment was a confluence of three curiosities,” William T.M. Irvine, a corresponding author of the paper, told Phys.org. “We had been studying and engineering parity-breaking meta-fluids with fundamentally new properties in 2D and were interested to see how a three-dimensional analog would behave.

Smart Materials and Nanotechnology Engineering conf. kicks off

Dr Mehdi Ghommem said that the AUS was happy to host and organise the eighth edition of the International Conference on Smart Materials and Nanotechnology, and to host more than 100 participants from 15 different countries.

Ghommem added that the social programme of the conference included plenary lectures, keynote lectures, parallel technical sessions with more than 70 presentations.

Dr Mehdi Ghommem also explained that the social programme which came in parallel with the technical programme included dinner, a visit of iconic landmark in Sharjah. He stressed that it was a great opportunity for participants not only to interact and talk about scientific topics, but also to get to know about the local culture and also, to get good exposure to the main monuments of Sharjah.

Strange Engineering Hiding in Plain Sight

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This video explores fascinating engineering solutions hiding in plain sight — ingenious designs that solve complex problems through elegant simplicity. From shoes that expand when stretched to windshields with hidden patterns, discover how everyday objects incorporate remarkable engineering innovations.

AUXETICS
These metamaterials that defy conventional physics by getting thicker when stretched. Follow their evolution from theoretical designs in 1978 to modern applications in athletic footwear and medical devices, and discover how precise geometric patterns create extraordinary properties that could revolutionize everything from prosthetics to architecture, despite challenging manufacturing requirements.

WINDSHIELD DOTS
The black dots on car windshields serve a dual purpose that revolutionized the automotive industry in the 1950s. This pattern manages extreme thermal stress during glass tempering while protecting crucial adhesive bonds. The precise ceramic frit application process has evolved to support modern safety systems and sensor integration, making these simple dots essential to modern vehicle design.

CURIE POINT HEATERS
Curie point heaters achieve temperature control through magnetic properties alone, eliminating complex control systems. These heaters maintain precise temperatures by becoming “magnetically invisible” at specific points. Modern implementations use sophisticated alloy combinations and multi-layer designs for unprecedented temperature control in medical sterilization and semiconductor processing.

TRIBOELECTRIC GENERATORS

Continue reading “Strange Engineering Hiding in Plain Sight” | >

Nanopesticide delivery system made with neem seed extract improves pesticide effectiveness

Pesticides can be made more effective and environmentally friendly by improving how they stick to plant surfaces, thanks to new research led by Dr. Mustafa Akbulut, professor of chemical engineering at Texas A&M University.

Akbulut and his research group have developed an innovative pesticide delivery system called nanopesticides. These tiny technologies, developed through a collaboration between Texas A&M University’s engineering and agricultural colleges, Dr. Luis Cisneros-Zevallo, professor of Horticultural Science and Dr. Younjin Min, professor of Chemical Environ Engineering at University of California, Riverside, could change how we use pesticides.

“The U.S. is a world leader in , feeding not just our nation but much of the world. Yet we are using pesticides in a way that is simply not sustainable—with a substantial fraction not reaching its intended target,” said Akbulut. “Our research shows that by optimizing the surface chemistry of pesticide carriers, we can make these essential crop protection tools more efficient.”

Q&A — Information, Evolution, and intelligent Design — With Daniel Dennett

How long until humans are made redundant by the evolution of technology? Is there an inherent difference between men and women’s intelligence? Daniel Dennett answers questions from the audience following his talk. Watch the main event here: • Information, Evolution, and intellige…
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The concept of information is fundamental to all areas of science, and ubiquitous in daily life in the Internet Age. However, it is still not well understood despite being recognised for more than 40 years. In this talk, Daniel Dennett explored steps towards a unified theory of information, through common threads in evolution, learning, and engineering.

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How tiny droplets can deform ice: Findings show potential for cryopreservation and food engineering

When water freezes slowly, the location where water turns into ice—known as the freezing front—forms a straight line. Researchers from the University of Twente showed how droplets that interact with such a freezing front cause surprising deformations of this front. These new insights were published in Physical Review Letters and show potential for applications in cryopreservation and food engineering techniques.

When water freezes, it is often thought of as a predictable, solid block forming layer by layer. But what happens if the progressing freezing front encounters or ? Researchers from the University of Twente have explored this question, discovering that droplets can cause surprising deformations in the way ice forms.