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A University of Texas at Dallas physicist has teamed with Texas Instruments Inc. to design a better way for electronics to convert waste heat into reusable energy.

The collaborative project demonstrated that silicon’s ability to harvest energy from heat can be greatly increased while remaining mass-producible.

Dr. Mark Lee, professor and head of the Department of Physics in the School of Natural Sciences and Mathematics, is the corresponding author of a study published July 15 in Nature Electronics that describes the results. The findings could greatly influence how circuits are cooled in electronics, as well as provide a method of powering the sensors used in the growing “internet of things.”

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But in many ways, the field of AI ethics remains limited. Researchers say they are blocked from investigating many systems thanks to trade secrecy protections and laws like the Computer Fraud and Abuse Act (CFAA). As interpreted by the courts, that law criminalizes breaking a website or platform’s terms of service, an often necessary step for researchers trying to audit online AI systems for unfair biases.

Whittaker acknowledges the potential for the AI ethics movement to be co-opted. But as someone who has fought for accountability from within Silicon Valley and outside it, Whittaker says she has seen the tech world begin to undergo a deep transformation in recent years. “You have thousands and thousands of workers across the industry who are recognizing the stakes of their work,” Whittaker explains. “We don’t want to be complicit in building things that do harm. We don’t want to be complicit in building things that benefit only a few and extract more and more from the many.”

It may be too soon to tell if that new consciousness will precipitate real systemic change. But facing academic, regulatory and internal scrutiny, it is at least safe to say that the industry won’t be going back to the adolescent, devil-may-care days of “move fast and break things” anytime soon.

“There has been a significant shift and it can’t be understated,” says Whittaker. “The cat is out of the box, and it’s not going back in.”

Continue reading “Meet the Researchers Fighting to Make Sure Artificial Intelligence Is a Force for Good” | >

The ability to edit genes in living organisms offers the opportunity to treat a plethora of inherited diseases. However, many types of gene-editing tools are unable to target critical areas of DNA, and creating such a technology has been difficult as living tissue contains diverse types of cells.

Now, Salk Institute researchers have developed a new tool—dubbed SATI—to edit the , enabling the team to target a broad range of mutations and cell types. The new genome-editing technology, described in Cell Research on August 23, 2019, could be expanded for use in a broad range of gene mutation conditions such as Huntington’s disease and the rare premature aging syndrome, progeria.

“This study has shown that SATI is a powerful tool for genome editing,” says Juan Carlos Izpisua Belmonte, a professor in Salk’s Gene Expression Laboratory and senior author of the paper. “It could prove instrumental in developing effective strategies for target-gene replacement of many different types of mutations, and opens the door for using genome-editing tools to possibly cure a broad range of genetic diseases.”

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In new research published in Psychoneuroendocrinology, scientists have shown that loving-kindness meditation has a positive impact at the cellular level. The study examined how different types of meditation influenced telomere length, an indicator of physiological aging.

Telomeres are the end caps of DNA on our chromosomes, which help in DNA replication and get shorter over time.

“Chronological age and biological age are not identical. The former is measured in years, whereas the latter is often indexed by telomere length,” the authors of the new study explained. “Telomeres progressively shorten with cell division (i.e., aging) in general, but may also be replenished, or lengthened, by the enzyme telomerase.”

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Inspired by the human eye, researchers at the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) have developed an adaptive metalens that is essentially a flat, electronically controlled artificial eye. The adaptive metalens simultaneously controls for three of the major contributors to blurry images: focus, astigmatism, and image shift.

The research is published in Science Advances.

“This research combines breakthroughs in artificial muscle technology with metalens technology to create a tunable metalens that can change its focus in real time, just like the human eye,” said Alan She, an SEAS graduate student at the Graduate School of Arts and Sciences, and first author of the paper. “We go one step further to build the capability of dynamically correcting for aberrations such as astigmatism and image shift, which the human eye cannot naturally do.”

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Science has officially broadened the blood supply:

Access to efficient enzymes that can convert A and B type red blood cells to ‘universal’ donor O would greatly increase the supply of blood for transfusions. Here we report the functional metagenomic screening of the human gut microbiome for enzymes that can remove the cognate A and B type sugar antigens. Among the genes encoded in our library of 19,500 expressed fosmids bearing gut bacterial DNA, we identify an enzyme pair from the obligate anaerobe Flavonifractor plautii that work in concert to efficiently convert the A antigen to the H antigen of O type blood, via a galactosamine intermediate. The X-ray structure of the N-acetylgalactosamine deacetylase reveals the active site and mechanism of the founding member of an esterase family. The galactosaminidase expands activities within the CAZy family GH36. Their ability to completely convert A to O of the same rhesus type at very low enzyme concentrations in whole blood will simplify their incorporation into blood transfusion practice, broadening blood supply.

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When energy is added to uranium under pressure, it creates a shock wave, and even a tiny sample will be vaporized like a small explosion. By using smaller, controlled explosions, physicists can test on a microscale in a safe laboratory environment what could previously be tested only in larger, more dangerous experiments with bombs.

“In our case, it’s the laser depositing energy into a target, but you get the same formation and time-dependent evolution of plasma,” author Patrick Skrodzki said. “With these small-scale explosions in the lab, we can understand similar physics.”

In a recent experiment, scientists working with Skrodzki used a laser to ablate atomic uranium, stealing its electrons until it ionized and turned to plasma, all while recording as the plasma cooled, oxidized and formed species of more complex uranium. Their work puts uranium species and the reaction pathways between them onto a map of space and time to discover how many nanoseconds they take to form and at which part of the plasma’s evolution.

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