Forcing them to become servants could have a bad outcome. See the latest episode of The Orville, “From Unknown Graves”. https://www.imdb.com/title/tt12037520
Ron HelwigThe Orville keeps getting better. It’s already the best Trek.
Continue reading “SpaceX Starship: Where is Musk’s mega rocket now?” »
Breaking the previous record by 60 percent.
The team behind the first Chinese X-ray astronomy satellite, Insight-HXMT, has discovered the strongest magnetic field directly measured in the universe hitherto.
It is a known fact that neutron stars generate the strongest magnetic fields in the universe. These magnetic fields, close to a neutron star’s surface, can only be measured accurately and directly by looking for cyclon resonance scattering features (CRSF). The Insight-HXMT team discovered a cyclotron absorption line with an energy of 146 keV in the neutron star X-ray binary Swift J0243.6+6124, which translates to a surface magnetic field of more than 1.6 billion Tesla.
Lasers normally use mirrors to create laser light, but a new kind uses clumps of moving particles. The result is a laser that is more programmable and could generate extra-sharp visual displays.
Surveillance, Preparedness & Health Security In Critical Disease Emergencies — Dr. Rosamund Lewis, MD, Head, WHO Smallpox Secretariat, Technical Lead for Monkeypox.
Dr. Rosamund Lewis, MD, is Head, WHO Smallpox Secretariat, Emerging Diseases and Zoonoses Unit, World Health Emergencies Programme, at the World Health Organization in Geneva, Switzerland, leading on emergency preparedness and advising on health security for the agency in this very critical domain, including as technical lead for Monkeypox. She also holds an appointment as Adjunct Professor in the School of Epidemiology and Public Health, University of Ottawa.
TRISO particles cannot melt in a reactor and can withstand extreme temperatures well beyond the threshold of current nuclear fuels.
There’s a lot of buzz around advanced nuclear.
These technologies are going to completely change the way we think about nuclear reactors.
Continue reading “TRISO Particles: The Most Robust Nuclear Fuel on Earth” »
Biological synapses are known to store multiple memories on top of each other at different time scales, much like representations of the early techniques of manuscript writing known as “palimpsest,” where annotations can be superimposed alongside traces of earlier writing.
Biological palimpsest consolidation occurs via hidden biochemical processes that govern synaptic efficacy at varying lifetimes. The arrangement can facilitate idle memories to be overwritten without forgetting them, while using previously unseen memories short-term. Embedded artificial intelligence can significantly benefit from such functionality; however, the hardware has yet to be demonstrated in practice.
In a new report, now published in Science Advances, Christos Giotis and a team of scientists in Electronics and Computer Science at the University of Southampton and the University of Edinburgh, U.K., showed how the intrinsic properties of metal-oxide volatile memristors mimicked the process of biological palimpsest consolidation.
Moore’s law has driven the semiconductor industry to continue downscaling the critical size of transistors to improve device density. At the beginning of this century, traditional scaling started to encounter bottlenecks. The industry has successively developed strained Si/Ge, high-K/metal gate, and Fin-FETs, enabling Moore’s Law to continue.
Now, the critical size of FETs is down to 7 nm, which means there are almost 7 billion transistors per square centimeter on one chip, which brings huge challenges for fin-type structure and nanomanufacturing methods. Up to now, extreme ultraviolet lithography has been used in some critical steps, and it is facing alignment precision and high costs for high-volume manufacturing.
Meanwhile, the introduction of new materials and 3D complex structures brings serious challenges for top-down methods. Newly developed bottom-up manufacturing serves as a good complementary method and provides technical driving force for nanomanufacturing.
In cancer research, it all comes down to a single cell.
Over the last decade, cancer researchers have homed in on the fact that an individual cell from a tumor can be used to perform molecular analyses that reveal important clues about how the cancer developed, how it spreads and how it may be targeted.
With this in mind, a team of researchers at Brown University has developed an advanced way to isolate single cells from complex tissues. In a study published in Scientific Reports, they show how the approach not only results in high-quality, intact single cells, but is also superior to standard isolation methods in terms of labor, cost and efficiency.
