Carl Sagan liked to smoke weed. His essay on why is fascinating.
Aug. 27 (UPI) — Built-in night vision may not be far off. Scientists have developed nanoparticles that allow mice to see near-infrared light.
Researchers are scheduled to describe the technological breakthrough on Tuesday at 12:30 p.m. ET at the American Chemical Society’s fall meeting, held this week in San Diego. Their presentation will be streamed live online.
“When we look at the universe, we see only visible light,” lead researcher Gang Han, a material scientists and biochemist at the University of Massachusetts Medical School, said in a news release. “But if we had near-infrared vision, we could see the universe in a whole new way. We might be able to do infrared astronomy with the naked eye, or have night vision without bulky equipment.”
One way that scientists can non-invasively study the human brain is by growing “mini-brains,” clusters of brain cells each about the size of a pea, in the lab. In a fascinating progression of this line of research, a team this week reports that they observed human-like brainwaves from these organoids.
Previous studies of mini-brains have demonstrated movement and nerve tract development, but the new study from researchers at the University of California San Diego, led by biologist Alysson Muotri, is the first to record human-like neural activity. In their paper, published in Cell Stem Cell on Thursday, the researchers write that they observed brain wave patterns resembling those of a developing human. This sophistication in the in vitro model is a step to enable scientists to use mini-brains to study brain development, model diseases, and learn about the evolution of brains, according to Muotri.
Scientists have created miniature brains from stem cells that developed functional neural networks. Despite being a million times smaller than human brains, these lab-grown brains are the first observed to produce brain waves that resemble those of preterm babies. The study, published August 29 in the journal Cell Stem Cell, could help scientists better understand human brain development.
“The level of neural activity we are seeing is unprecedented in vitro,” says Alysson Muotri, a biologist at the University of California, San Diego. “We are one step closer to have a model that can actually generate these early stages of a sophisticated neural network.”
The pea-sized brains, called cerebral organoids, are derived from human pluripotent stem cells. By putting them in culture that mimics the environment of brain development, the stem cells differentiate into different types of brain cells and self-organize into a 3D structure resembling the developing human brain.
Carbon isn’t just the stuff life is made of—it’s also the stuff our future is being built on.
Carbon—a versatile element that frequently trades off its electrons to create various forms of itself—has been gaining an exciting reputation in tech thanks to the successful exfoliation of graphene, a sheet of carbon that’s just one atom thick and has remarkable chemical properties.
But carbon nanotubes, a sort of cousin to graphene, has been quietly staking out its own place in the world of materials science.
Astronauts would have to fly their rocket into the Spaceline, attach to a solar-powered shuttle and be dragged up to the Moon.
Carbon nanotubes will need to be built on a large scale for the design.
Zephyr Penoyre, one of the Columbia astronomy graduate students behind the Spaceline, told Futurism: The line becomes a piece of infrastructure, much like an early railroad.
Alibaba Group chairman Jack Ma told the World Artificial Intelligence Conference in Shanghai Thursday that artificial intelligence should enable people to work 4 hours a day, 3 days a week, Bloomberg reports.
Why it matters: It’s a remarkable demonstration of Ma’s faith in AI, given he’s endorsed the Chinese tech sector’s standard “996” schedule, which consists of a 72-hour workweek: 9am to 9pm, 6 days a week.
Apple’s update to macOS for 2019 will be known as Catalina and will bring many third-party iOS apps to the Mac, new Music and TV apps, as well as lots of other exciting features. Find out what else we expect from the new macOS Catalina update.
Hinted at in a brief tweet on August 28th, SpaceX CEO Elon Musk says that SpaceX’s massive Starship and Super Heavy launch vehicle – set to be the most powerful rocket ever built upon completion – could eventually be followed by a rocket multiple times larger.
SpaceX is currently in the process of assembling the first full-fidelity prototypes of Starship, a 9m (30 ft) diameter, 55m (180 ft) tall reusable spacecraft and upper stage. Two prototypes – Mk1 and Mk2 – are simultaneously being built in Texas and Florida, respectively, while the beginnings of the first Super Heavy prototype has visibly begun to take shape at SpaceX’s Florida campus.
Once complete, Starship’s Super Heavy booster will be the single most powerful rocket booster ever built, standing at least 70m (230 ft) tall on its own and capable of producing as much as ~90,000 kN (19,600,000 lbf) of thrust with 30 250-ton-thrust and 7 200-ton-thrust Raptor engines installed. Assuming 31 throttleable 200-ton Raptors, Super Heavy’s minimum max thrust is a still record-breaking ~62,000 kN (13.7 million lbf).
Fusion energy startup First Light Fusion is working towards demonstrating “first fusion” before the end of the year, in their Oxford-based laboratory. If they succeed, they join only a few companies and research groups on the path to demonstrating “gain,” where the energy created outstrips the energy required to start the reaction, which they hope to do by 2024.
Demonstrating gain is the key marker of success and the proof required for the industry to start building the commercial infrastructure to scale the technology, but no company or research group has managed it yet. The history of fusion is littered with a few high-profile failures, prompting many to believe the “it’s always 30 years away” narrative, but with investment in the space heating up with more private investors starting to see the potential in recently-formed startups, belief in fusion is growing again.
In the fusion energy race, it’s arguably anybody’s game among the few key global leaders of both startups and publicly-funded research efforts. There’s the huge international research effort in the south of France, ITER, looking to demonstrate first plasma–not gain–at the end of 2025. And there’s the various startups with their different technological approaches attracting private funding worldwide, such as TAE with $600 million funding in Los Angeles, Boston-based Commonwealth Fusion Systems with $115 million raised in June and General Fusion with over $100 million based in British Columbia. In the U.K., Tokamak Energy has raised over $50 million.