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Category: engineering

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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Science fiction writers have long featured terraforming, the process of creating an Earth-like or habitable environment on another planet, in their stories. Scientists themselves have proposed terraforming to enable the long-term colonization of Mars. A solution common to both groups is to release carbon dioxide gas trapped in the Martian surface to thicken the atmosphere and act as a blanket to warm the planet.

However, Mars does not retain enough carbon dioxide that could practically be put back into the atmosphere to warm Mars, according to a new NASA-sponsored study. Transforming the inhospitable Martian environment into a place astronauts could explore without life support is not possible without technology well beyond today’s capabilities.

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Environmental Gerontology & Vulnerability Science For Health And Well-Being — Dr. Amir Baniassadi, Ph.D. — Marcus Institute for Aging Research, Hebrew SeniorLife / Harvard Medical School.

Dr. Amir Baniassadi, Ph.D. is an Instructor of Medicine at Harvard Medical School and an Assistant Scientist in Marcus Institute for Aging Research (https://www.marcusinstituteforaging.o… where he works on environmental impacts on health and well-being of older populations.

Dr. Baniassadi works on the impacts of ambient air temperature and air quality (both indoors and outdoors) on outcomes related to the health and well-being of physiologically and socioeconomically vulnerable populations. His research applies novel environmental modeling and measurement techniques along with remote and long-term physiological and functional monitoring of individuals to establish relationships between exposure and outcome variables of interest outside clinical lab settings. The ultimate goal of his research is to develop environmental interventions that optimize the environment for health and longevity of older adults.

Continue reading “Dr. Amir Baniassadi, Ph.D. — Marcus Institute for Aging Research — Environmental Gerontology” | >

Estimating spectral features of quantum many-body systems has attracted great attention in condensed matter physics and quantum chemistry. To achieve this task, various experimental and theoretical techniques have been developed, such as spectroscopy techniques1,2,3,4,5,6,7 and quantum simulation either by engineering controlled quantum devices8,9,10,11,12,13,14,15,16 or executing quantum algorithms17,18,19,20 such as quantum phase estimation and variational algorithms. However, probing the behaviour of complex quantum many-body systems remains a challenge, which demands substantial resources for both approaches. For instance, a real probe by neutron spectroscopy requires access to large-scale facilities with high-intensity neutron beams, while quantum computation of eigenenergies typically requires controlled operations with a long coherence time17,18. Efficient estimation of spectral properties has become a topic of increasing interest in this noisy intermediate-scale quantum era21.

A potential solution to efficient spectral property estimation is to extract the spectral information from the dynamics of observables, rather than relying on real probes such as scattering spectroscopy, or direct computation of eigenenergies. This approach capitalises on the basics in quantum mechanics that spectral information is naturally carried by the observable’s dynamics10,20,22,23,24,25,26. In a solid system with translation invariance, for instance, the dynamic structure factor, which can be probed in spectroscopy experiments7,26, reaches its local maximum when both the energy and momentum selection rules are satisfied. Therefore, the energy dispersion can be inferred by tracking the peak of intensities in the energy excitation spectrum.

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Engineering researchers at Lawrence Livermore National Laboratory (LLNL) have achieved breakthroughs in multi-material 3D printing through the power of capillary action. The LLNL team printed lattice structures with a series of custom-designed unit cells to selectively absorb fluid materials and precisely direct them into patterns – making it possible to fabricate complex structures with unprintable materials or materials with vastly different properties.

According to the researchers, the technique, featured in Advanced Materials Technologies, would help engineers design and optimize structures for properties like extreme strength-to-weight ratios, large surface areas, or precision deformation.

“By decoupling some of the printing and patterning techniques, you could achieve some complex multi-material structures, and you wouldn’t always have to be able to print the material,” said Hawi Gemeda, Materials Engineering Division (MED) staff engineer at LLNL and the paper’s lead author.

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Discover the incredible engineering and visionary potential of Bernal Spheres, futuristic space habitats designed to sustain human life in the stars.

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The ideal material for interfacing electronics with living tissue is soft, stretchable, and just as water-loving as the tissue itself—in short, a hydrogel. Semiconductors, the key materials for bioelectronics such as pacemakers, biosensors, and drug delivery devices, on the other hand, are rigid, brittle, and water-hating, impossible to dissolve in the way hydrogels have traditionally been built.

A paper published today in Science from the UChicago Pritzker School of Molecular Engineering (PME) has solved this challenge that has long stymied researchers, reimagining the process of creating hydrogels to build a powerful semiconductor in hydrogel form. Led by Asst. Prof. Sihong Wang’s research group, the result is a bluish gel that flutters like a sea jelly in water but retains the immense semiconductive ability needed to transmit information between living tissue and machine.

New material from the UChicago Pritzker School of Molecular Engineering can create better brain-machine interfaces, biosensors, and pacemakers.

Continue reading “A new hydrogel semiconductor represents a breakthrough for tissue-interfaced bioelectronics” | >

For the first time, a team of researchers at Lawrence Livermore National Laboratory (LLNL) quantified and rigorously studied the effect of metal strength on accurately modeling coupled metal/high explosive (HE) experiments, shedding light on an elusive variable in an important model for national security and defense applications.

The team used a Bayesian approach to quantify with tantalum and two common explosive materials and integrated it into a coupled metal/HE . Their findings could lead to more accurate models for equation-of-state-studies, which assess the state of matter a material exists in under different conditions. Their paper —featured as an editor’s pick in the Journal of Applied Physics —also suggested that metal strength uncertainty may have an insignificant effect on result.

“There has been a long-standing field lore that HE model calibrations are sensitive to the metal strength,” said Matt Nelms, the paper’s first author and a group leader in LLNL’s Computational Engineering Division (CED). “By using a rigorous Bayesian approach, we found that this is not the case, at least when using tantalum.”

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