Great loss.

My first paper was based on the work he did in 1993 showing that black strings and branes are unstable [Gregory–Laflamme instability]

Now, having moved to quantum computing, his work is even more relevant especially KLM protocol and Knill-Laflamme QEC conditions.

Fascinating article by Feynman (1987). He discusses three issues in the article: 1) sensitivity, 2) extensivity, and 3) computability.

In 1956, it was found for the first time that there are fundamental interactions in nature (weak interactions) that violate parity symmetry (left and right are not alike). Curiously enough, it was only today that I found out that Dirac had this sentence in his July 1949 RMP article.

Long live Verschränkung
Great finish to the talk by John @preskill.bsky.social

#APSSummit25

At the #APS today.

Wishing everyone a very happy and prosperous new year 2025 🎉

Facts about 2025:

1) It is square of 45
2) It is product of two squares: 9² x 5² = 2025
3) It is the sum of three squares: 40²+ 20²+5²= 2025
4) It is the sum of cubes of natural numbers from 1 to 9: 1³+2³+3³+4³+5³+6³+7³+8³+9³= 2025

First page of the book - "Notes on quantum mechanics" by E. Fermi published by Chicago U Press.

Thanks to @thriftbooks.bsky.social for a great deal :-)

Louis de Broglie's quantum leap that changed physics forever • RFI English YouTube video by RFI English

led to the seminal works of Bohm, now known as 'Bohmian mechanics', in 1952, and served as the inspiration for Bell's theorem. He won the Nobel Prize in 1929 following the experimental demonstration of the wave-like character of electrons by Davisson & Germer. 

www.youtube.com/watch?v=1dhe...

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100 years ago, in November 1924, de Broglie became the first physicist to deduce that all matter has wave properties. A year later, in 1925, he developed the first hidden-variable theory (pilot-wave theory), which inspired Schrodinger to write down his famous equation. This theory eventually

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Sorry for the late reply. Just saw this comment. Thank you @cosmicobserver.bsky.social

Real-Time Scattering in Ising Field Theory using Matrix Product States We study scattering in Ising Field Theory (IFT) using matrix product states and the time-dependent variational principle. IFT is a one-parameter family of strongly coupled non-integrable quantum field...

I am very proud of our new paper on simulations of scattering processes in (1+1)-dimensional quantum field theory. All the hard work was done by my co-authors Raghav Jha, Ash Milsted, Dominik Neuenfeld, and Pedro Vieira.
arxiv.org/abs/2411.13645

Happy to announce that our paper on real-time scattering in Ising field theory using tensor networks is now on arXiv.

Great working and learning with Ashley Milsted, Dominik Neuenfeld, John Preskill (@preskill.bsky.social), and Pedro Vieira. We had great fun!

arxiv.org/abs/2411.13645