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Category: engineering – Page 11

Researchers from the National University of Singapore (NUS) and University of New South Wales (UNSW) Sydney have proven that a spinning atomic nucleus really is fundamentally a quantum resource. The teams were led respectively by Professor Valerio Scarani, from NUS Department of Physics, and Scientia Professor Andrea Morello from UNSW Engineering. The paper was published in the journal Newton on 14 February 2025.

It has long been inferred that tiny particles such as electrons or protons are indeed quantum due to the way they get deflected in a magnetic field. However, when left to spin freely, they appear to behave in exactly the same way as a classical spinning item, such as a Wheel of Fortune turning on its axis. For more than half a century, experts in spin resonance have taken this fact as a universal truth.

For the same reason, a technician or a doctor operating a (MRI) machine at the hospital never needed to understand quantum mechanics—the spinning of the protons inside the patient’s body produces the same kind of magnetic field that would be created by attaching a fridge magnet to a spinning wheel.

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Researchers at NIMTE have turned metal corrosion into a tool for efficient biomass upgrading, achieving high HMF-to-BHMF conversion rates with a CoCuMW/CF electrode. Their findings offer a low-cost, sustainable solution for bio-based chemical production.

A research team led by Prof. Jian Zhang from the Ningbo Institute of Materials Technology and Engineering (NIMTE) of the Chinese Academy of Sciences (CAS) has harnessed metal corrosion to develop high-performance electrodes, facilitating the efficient and cost-effective upgrading of bio-based 5-hydroxymethylfurfural (HMF). Their findings were published in Chem Catalysis.

While corrosion is typically associated with material degradation and economic loss, researchers are now investigating its potential for advantageous applications, particularly in biomass upgrading.

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Engineers are renowned clock-problem solvers. They’re also notorious for treating every problem like a clock. Increasing specialization and cultural expectations play a role in this tendency. But so do engineers themselves, who are typically the ones who get to frame the problems they’re trying to solve in the first place.

In his latest book, Wicked Problems, Guru Madhavan argues that the growing number of cloudy problems in our world demands a broader, more civic-minded approach to engineering. “Wickedness” is Madhavan’s way of characterizing what he calls “the cloudiest of problems.” It’s a nod to a now-famous coinage by Horst Rittel and Melvin Webber, professors at the University of California, Berkeley, who used the term “wicked” to describe complex social problems that resisted the rote scientific and engineering-based (i.e., clock-like) approaches that were invading their fields of design and urban planning back in the 1970s.

Madhavan, who’s the senior director of programs at the National Academy of Engineering, is no stranger to wicked problems himself. He’s tackled such daunting examples as trying to make prescription drugs more affordable in the US and prioritizing development of new vaccines. But the book isn’t about his own work. Instead, Wicked Problems weaves together the story of a largely forgotten aviation engineer and inventor, Edwin A. Link, with case studies of man-made and natural disasters that Madhavan uses to explain how wicked problems take shape in society and how they might be tamed.

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A team of researchers has developed a “gut-on-chip” (a miniature model of the human intestine on a chip-sized device) capable of reproducing the main features of intestinal inflammation and of predicting the response of melanoma patients to immunotherapy treatment. The results have just been published in Nature Biomedical Engineering.

The interaction between microbiota and has long been known. It is the result of both systemic effects, i.e., the elicited in the entire body by immunotherapy, and local processes, especially in the gut, where most of the bacteria that populate our body live. However, the latter can only be studied in animal models, with all their limitations.

Indeed, there is no clinical reason to subject a patient receiving immunotherapy for melanoma to colonoscopy and colon biopsy. Yet intestinal inflammation is one of the main side effects of this treatment, often forcing the therapy to be discontinued.

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To test this new system, the team executed what is known as Grover’s search algorithm—first described by Indian-American computer scientist Lov Grover in 1996. This search looks for a particular item in a large, unstructured dataset using superposition and entanglement in parallel. The search algorithm also exhibits a quadratic speedup, meaning a quantum computer can solve a problem with the square root of the input rather than just a linear increase. The authors report that the system achieved a 71 percent success rate.

While operating a successful distributed system is a big step forward for quantum computing, the team reiterates that the engineering challenges remain daunting. However, networking together quantum processors into a distributed network using quantum teleportation provides a small glimmer of light at the end of a long, dark quantum computing development tunnel.

“Scaling up quantum computers remains a formidable technical challenge that will likely require new physics insights as well as intensive engineering effort over the coming years,” David Lucas, principal investigator of the study from Oxford University, said in a press statement. “Our experiment demonstrates that network-distributed quantum information processing is feasible with current technology.”

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From punch card-operated looms in the 1800s to modern cellphones, if an object has an “on” and an “off” state, it can be used to store information.

In a computer laptop, the binary ones and zeroes are transistors either running at low or high voltage. On a compact disc, the one is a spot where a tiny indented “pit” turns to a flat “land” or vice versa, while a zero is when there’s no change.

Historically, the size of the object making the “ones” and “zeroes” has put a limit on the size of the storage device. But now, University of Chicago Pritzker School of Molecular Engineering (UChicago PME) researchers have explored a technique to make ones and zeroes out of crystal defects, each the size of an individual atom for classical computer memory applications.

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Researchers from Mass General Brigham and collaborating institutions have developed a non-invasive approach to manipulate cardiac tissue activity by using light to stimulate an innovative ink incorporated into bioprinted tissue. Their goal is to develop a technique that can be used to repair the heart. Their findings in preclinical models, published in Science Advances, show the transformative potential of non-invasive therapeutic methods to control electrically active tissues.

“We showed for the first time that with this optoelectronically active ink, we can print scaffolds that allow remote control of engineered heart tissues,” said co-corresponding author Y. Shrike Zhang, Ph.D., of the Division of Engineering in Medicine at Brigham and Women’s Hospital, a founding member of the Mass General Brigham health care system. “This approach paves the way for non-invasive light stimulation, tissue regeneration, and host integration capabilities in cardiac therapy and beyond.”

Three-dimensional bioprinted tissues composed of cells and other body-compatible materials are a powerful emerging tool to repair damaged heart tissue. But most bioprinted tissues cannot generate the necessary electrical activity for cellular function. They must instead rely on invasive wire and electrode placement to control heart activity, which can damage body tissues.

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Ripples, like ones produced by raindrops falling in a puddle, are also called capillary waves. Studied since antiquity, they have garnered considerable interest in modern science due to their ability to reveal information about the medium on which they travel. This makes them particularly valuable for studying soft and biological matter in microfluidic applications, which focus on how fluids behave in microscopic environments.

Now physicists and from Aalto University’s Department of Neuroscience and Biomedical Engineering and Department of Applied Physics have unearthed new characteristics of capillary waves, setting a record for their speed while doing so.

The paper is published in Nature Communications.

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Entanglement—linking distant particles or groups of particles so that one cannot be described without the other—is at the core of the quantum revolution changing the face of modern technology.

While entanglement has been demonstrated in very small particles, new research from the lab of University of Chicago Pritzker School of Molecular Engineering (UChicago PME) Prof. Andrew Cleland is thinking big, demonstrating high-fidelity entanglement between two acoustic wave resonators.

The paper is published in Nature Communications.

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Altilium has filed a patent application for its proprietary EcoCathode™ recycling process, underlining its technical leadership in the UK and its commitment to establishing a national champion for EV battery recycling.

The patent provides a process, apparatus and system for recovering battery metals (such as cobalt, manganese, nickel and lithium) and graphite, and the production of battery precursors and battery-ready cathode active materials (CAM), from black mass (comprising a mixed feed of critical compounds or elements).

Through microstructure reengineering, Altilium’s EcoCathode™ process represents a significant stride in clean technology and sustainable EV battery recycling in the UK. Recovering over 95% of crucial metals from old EV batteries, the technology will contribute to a sustainable domestic supply of battery raw materials, reducing carbon emissions by over 50% and reducing the cost of CAM by more than 20% compared to conventional virgin mining practices.

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