Lifeboat Foundation: Safeguarding Humanity
Toggle light / dark theme

Blog – Page 11537

A walk down memory lane: I thought it would be fun to revisit an article from 1998 about Los Alamos’ announcement about their move to Quantum Computing which we found out later they expanded it to include a Quantum Network which they announced in 2009 their success in that launch. Times certainly have changed.

LOS ALAMOS, N.M., March 17, 1998 — Researchers at the Department of Energy’s Los Alamos National Laboratory have answered several key questions required to construct powerful quantum computers fundamentally different from today’s computers, they announced today at the annual meeting of the American Physical Society.

“Based on these recent experiments and theoretical work, it appears the barriers to constructing a working quantum computer will be technical, rather than fundamental to the laws of physics,” said Richard Hughes of Los Alamos’ Neutron Science and Technology Group.

Hughes also said that a quantum computer like the one Los Alamos is building, in which single ionized atoms act like a computer memory, could be capable of performing small computations within three years.

Read more

Great writeup and goes well with the other posting on DiAmanti’s new perfected synthetic diamonds.

Scientists in Japan have successfully recorded the atomic bonds between diamond and cubic boron nitride: the hardest known materials on earth. This feat could ultimately lead to the design of new types of semiconductors.

Diamond is the in existence but is useless for cutting steel because it reacts with iron, from which steel is made, at . Cubic , a synthetic material, is the second hardest substance after diamond but is chemically stable against iron at high temperatures. If desirable composites of diamond and cubic boron nitride crystals could be obtained, a unique machining tool could be developed for work on hard rock and substances that contain iron. Also, a better understanding of the bonds formed between these two unique semiconducting could lead to the development of new types of semiconductors. The nature of these bonds was previously unknown.

Reporting their findings in Nature Communications, a team of researchers at Tohoku University, the National Institute for Materials Science and the Japan Fine Ceramics Center imaged bonded diamond and boron nitride, both crystalline materials, using a super-high-resolution scanning electron microscope. The team then subjected those observations to extensive theoretical calculations.

Continue reading “Map of diamond-boron bond paves way for new materials” | >

A new article considering chip implants:

Among other tragedies in Florida recently gripping America’s attention, a 2-year-old boy was snatched away from its parents by an alligator at Walt Disney World on Wednesday. I have a similar-aged toddler myself, and I followed this heartbreaking story closely. Unfortunately, it ended as horribly as it began, with the recovery of a dead child.

My presidential campaign with the Transhumanist Party is based on advocating for radical science and technology to make the world a better place for humans. As a result, for nearly two years I have been advocating for using chip implants in people to help keep them safer. Chip implants are often just the size of a grain of rice and can be injected by a needle in a nearly pain-free 60-second procedure. The implants can do a multiple array of things depending on the type. And much of the technology has been used in pets for over a decade, so it’s already been shown to be relatively safe.

I have a RFID NFC chip in my hand that is programmed to send a text saying “Win in 2016” to people who have the right type of phone. To get the text, all you have to do is put your phone by my hand. My chip can also start a car with the right software, hand out a business card electronically, or give out my medical information.

Continue reading “Could an implant have saved the life of the toddler attacked by an alligator?” | >

A microchip containing 1,000 independent programmable processors has been designed by a team at the University of California, Davis, Department of Electrical and Computer Engineering. The energy-efficient “KiloCore” chip has a maximum computation rate of 1.78 trillion instructions per second and contains 621 million transistors. The KiloCore was presented at the 2016 Symposium on VLSI Technology and Circuits in Honolulu on June 16.

“To the best of our knowledge, it is the world’s first 1,000-processor chip and it is the highest clock-rate processor ever designed in a university,” said Bevan Baas, professor of electrical and computer engineering, who led the team that designed the . While other multiple-processor chips have been created, none exceed about 300 , according to an analysis by Baas’ team. Most were created for research purposes and few are sold commercially. The KiloCore chip was fabricated by IBM using their 32 nm CMOS technology.

Each processor core can run its own small program independently of the others, which is a fundamentally more flexible approach than so-called Single-Instruction-Multiple-Data approaches utilized by processors such as GPUs; the idea is to break an application up into many small pieces, each of which can run in parallel on different processors, enabling high throughput with lower energy use, Baas said.

Read more

Einstein called it “spooky action at a distance.”

That’s because entanglement, a voodoo-like phenomenon in quantum physics linking particles that once interacted, seems to surpass the speed of light, violating the cosmic speed limit.

Because of this, it doesn’t fit in with Einstein’s theory of relativity, so he concluded that it was too ludicrous to be real.

Read more