Unlock the secrets of fungal computing! Discover the mind-boggling potential of fungi as living computers. From the wood-wide web to the Unconventional Computing Lab, witness the evolution of mushroom technology.
Got a beard? Good. I’ve got something for you: http://beardblaze.com.
Simon’s Social Media:
Twitter: / simonwhistler.
Instagram: / simonwhistler.
Love content? Check out Simon’s other YouTube Channels:
Inspired by the “Harry Potter” stories and the Disney Channel show “Wizards of Waverly Place,” 7-year-old Sabrina Corsetti emphatically declared to her parents one afternoon that she was, in fact, a wizard.
“My dad turned to me and said that, if I really wanted to be a wizard, then I should become a physicist. Physicists are the real wizards of the world,” she recalls.
That conversation stuck with Corsetti throughout her childhood, all the way up to her decision to double-major in physics and math in college, which set her on a path to MIT, where she is now a graduate student in the Department of Electrical Engineering and Computer Science.
While her work may not involve incantations or magic wands, Corsetti’s research centers on an area that often produces astonishing results: integrated photonics. A relatively young field, integrated photonics involves building computer chips that route light instead of electricity, enabling compact and scalable solutions for applications ranging from communications to sensing.
MIT graduate student Sabrina Corsetti is exploring the cutting edge of integrated photonics, which involves building computer chips that route light instead of electricity. Her projects have included a chip-sized 3D printer and miniaturized optical systems for quantum computing.
Understanding randomness is crucial in many fields. From computer science and engineering to cryptography and weather forecasting, studying and interpreting randomness helps us simulate real-world phenomena, design algorithms and predict outcomes in uncertain situations.
Randomness is also important in quantum computing, but generating it typically involves a large number of operations. However, Thomas Schuster and colleagues at the California Institute of Technology have demonstrated that quantum computers can produce randomness much more easily than previously thought.
And that’s good news because the research could pave the way for faster and more efficient quantum computers.
Check out the free AMD loaner offer. Test the Ryzen PRO laptops yourself and experience the benefits they can bring to your business:
https://tinyurl.com/4zwaxnfm.
Timestamps:
00:00 — New Technology.
10:57 — How It Works & Applications.
15:10 — Challenges.
GIVEAWAY form: https://docs.google.com/forms/d/e/1FA… with me on LinkedIn ➜ / anastasiintech Connect with me on Instagram ➜
/ anastasi.in.tech Subscribe to My Deep In Tech Newsletter ➜ https://anastasiintech.substack.com Support me at Patreon ➜
/ anastasiintech #AMD #RYZENPRO
Connect with me on LinkedIn ➜ / anastasiintech.
Connect with me on Instagram ➜ / anastasi.in.tech.
Support me at Patreon ➜ / anastasiintech.
#AMD #RYZENPRO
Modern low-power solutions to computer memory rely heavily on the manipulation of the magnetic properties of materials. Understanding the influence of the chemical properties of these materials on their magnetization ability is of key importance in developing the field.
A study published in Applied Physics Letters, led by researchers from SANKEN at The University of Osaka, has revealed a technique for recovering magnetism in a degraded spintronics device. This method can be applied to improve the robustness of next-generation semiconductor memory.
Spintronics exploits the spin (and charge) of electrons to process and store memory, and this is achieved practically by stacking layers of thin material films that behave differently under the influence of a magnetic field.
The first results of the ETH Zurich and ANSTO collaboration focused on silicon carbide (SiC) devices have been reported in two publications.
Dr. Corinna Martinella, formerly a senior scientist at ETH Zurich, said in a LinkedIn post that the research advances an understanding of the basic mechanisms of radiation damage in SiC power devices exposed to heavy ions.
An article in IEEE Transactions on Nuclear Science describes the testing of how commercial silicon carbide (SiC) power devices, including MOSFETs and Junction Barrier Schottky (JBS) diodes, respond to space-like radiation at a microscopic level.
