April 10, 2024, 7:30 p.m.
Sitterzaal

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Repainting Quantum Mechanics on QBist Canvas

Christopher Fuchs

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QBism (pronounced cubism) is a foundational program for quantum mechanics premised on the idea that quantum probabilities should be understood as personalist Bayesian probabilities—that is, quantified degrees of belief or gambling attitudes. Philosophers hate it. “Wah, wah, wah, your quantum states aren't real; they have to be real because my philosophy says so!” What the philosophers have never appreciated (or perhaps cared about) is that this turn in thinking has motivated a significant number of theorems in quantum information science that might not have been discovered otherwise. In this talk, I will sketch QBism’s most ambitious project yet—rewriting the quantum formalism so to wear its Bayesian character on its sleeve. One of our key moves will be to replace the notion of Phasenraum (a notion first developed by Paul and Tatyana Ehrenfest, in fact) with the notion of a reference measurement. But which reference measurement is the most revealing of quantum theory’s essence? In trying to answer this question, we will see that it leads to a deep mathematical question related to Hilbert’s still-unsolved 12th problem and suggests a novel measurement (when it exists) with a growing number of applications in quantum information science.

Okay

May 8, 2024, 7:30 p.m.
Sitterzaal

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Quantum Gravity and Predictions for our Universe

Cumrun Vafa

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In this talk I provide an executive summary of some of the recent progress that has been made in understanding some key features of quantum gravitational theories. This is rooted in lessons learned from the landscape of consistent solutions to string theory and captured by the principles of the Swampland program. A key feature of this is the lack of decoupling between short and long distance descriptions of the theory leading to a radical revision of the notion of consistency of effective field theories. This opens up a new window into unresolved fine tuning problems for particle physics and cosmology. I will further explain how these ideas lead to concrete experimentally verifiable predictions for our universe.

Okay

May 29, 2024, 7:30 p.m.
Sitterzaal

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Physics for maggots

William Bialek

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The development of a single cell into a fully functional organism is one of Nature’s most extraordinary phenomena. In the case of a fruit fly, the larva—a maggot—can walk away from the discarded egg shell just 24 hours after the egg is laid. Even more strikingly, if we measure the concentrations of fewer than a dozen crucial molecules we can see a “blueprint” for the segmented body plan of the maggot after just three hours, and this happens before cells start to move. These patterns are the result of information flow through a network of interacting genes, and the fly embryo provides a laboratory for studying the physics of this information flow. It turns out that development is extraordinarily precise and reproducible despite the fact that relevant molecules are at low concentrations and hence signals must be noisy. This motivates a physical principle: the relevant network is tuned to extract as much information as possible from a limited number of molecules. We’ll see how this theory can be connected to experiments, generating quantitative and parameter-free predictions.

Okay

Sept. 25, 2024, 7:30 p.m.
GORLB CM 1.26

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TBA

Chiara Mariotti

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TBA

Okay
• Sept. 25, 2024, 7:30 p.m. CE Chiara Mariotti (CERN, INFN Turin) TBA

Oct. 16, 2024, 7:30 p.m.
GORLB CM 1.26

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TBA

Xiao-Gang Wen

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TBA

Okay
• Oct. 16, 2024, 7:30 p.m. CE Xiao-Gang Wen (MIT) TBA

Nov. 6, 2024, 7:30 p.m.
GORLB CM 1.26

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TBA

Viatcheslav Mukhanov

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TBA

Okay
• Nov. 6, 2024, 7:30 p.m. CE Viatcheslav Mukhanov (LMU Munich) TBA