​(2024-12-28/29) 2024 SEUYC Forum for Young Scholars in Mathematical Physics

发布者:杨璐发布时间:2024-12-17浏览次数:128

2024年东南大学丘成桐中心数学物理青年学者论坛



On behalf of Shing-Tung Yau Center and School of Physics, Southeast University, we are pleased to announce Forum for Young Scholars in Mathematical Physics at the end of 2024. The purpose of this forum is to promote interaction among young theoretical physicists, and to give participants an opportunity to get to know our Center at the center of Nanjing city, China. We also encourage participants to apply for faculty positions, including tenured and tenure-track positions, in our center.

Most of the forum is broadcasted by Zoom, according to China Standard Time (UTC+8). The details are:



Schedule

Day 1: December 28 (Saturday)

TimeSpeaker and AffiliationTitle
15:30-15:45Opening remarks
15:45-16:30Sunjin Choi, IPMU, Japan--
16:30-17:15Xi Tong, Cambridge, UKThere and Back Again: Mapping and Factorising Cosmological Observables
17:15-17:30Break
17:30-18:15Manki Kim, Stanford, USA*--
18:15-19:00Yao Ma, ETH, Switzerland*Regions in Asymptotic Expansions of Amplitudes
19:00-20:00Break
20:00-20:45Hao Zhang, IPMU, JapanAtomic Higgsing of 6D SCFTs
20:45-21:30Ho Tat Lam, MIT, USA--

Day 2: December 29 (Sunday)

TimeSpeaker and AffiliationTitle
9:00-9:45Zixia Wei, Harvard, USA--
9:45-10:30Yuezhou Li, Princeton, USACausality constraints on effective field theories
10:30-10:45Break
10:45-11:30Han Ma, Perimeter, Canada--
11:30-12:15Yijian Zou, Perimeter, CanadaMixed-state phases and quantum error correction
12:15-13:15Break
13:15-14:00Zhenghao Zhong, Oxford, UK*A Radioactive Higgs Mechanism

The duration of each talk is 40 minutes plus 5 minutes for questions. Offline speakers are marked by *.

Abstract

[Sunjin Choi]

[Xi Tong] There and Back Again: Mapping and Factorising Cosmological Observables
Observables in cosmology consist of correlation functions of various cosmological fields. These correlators encode invaluable information about the wavefunction that characterizes the state of the primordial universe. In this talk I will present a simple yet novel duality between correlators and wavefunction coefficients. The duality manifests itself as a non-perturbative Z4 symmetry in the dictionary of correlators and the modulus parts of wavefunction coefficients, and maps any equation in the dictionary involving the two to another equation in the dictionary. To demonstrate the power of the duality already at tree-level, we derive a correlator-to-correlator factorisation formula for the parity-odd part of cosmological correlators which relates n-point observables to lower-point ones via a series of diagrammatic cuts. These relations are in principle testable as they involve observables defined for arbitrary physical kinematics (i.e. without any analytic continuation). For n = 4, the factorization formula provides a relation between the parity-odd curvature trispectrum and the mixed bispectra involving two curvature modes and an additional light state.

[Manki Kim]

[Hao Zhang] Atomic Higgsing of 6D SCFTs
In this talk, we present a procedure to characterize a full Higgs branch Hasse diagram for any given 6d N=(1,0) SCFT constructed via F-theory. This can be done by a procedure of determining all the atomic (i.e., minimal) Higgsings on the generalized quiver description on the tensor branch of the 6d SCFT. We call this procedure the atomic Higgsing and we explain how to implement it iteratively. We present our general algorithms with many concrete examples of Hasse diagrams. We also compare our algorithm with the Higgsings determined by the 3d N=4 magnetic quivers. For the cases where the magnetic quivers are unitary, we can reproduce the full Hasse diagrams. We also construct the orthosymplectic magnetic quivers from the Type IIA brane systems for some new examples. Our approach, based on F-theory, applies to the known and new orthosymplectic cases, as well as theories that do not have known descriptions in terms of magnetic quivers. We expect our geometry-based approach to help extend the horizon of the RG flows of the 6d SCFTs.

[Ho Tat Lam]


[Zixia Wei]

[Yao Ma] Regions in Asymptotic Expansions of Amplitudes
The method of regions, a systematic approach to the asymptotic expansions of Feynman integrals, suggests that a Feynman integral can be reconstructed by summing over integrals expanded in certain regions. This technique not only facilitates the computation of Feynman integrals but also provides valuable insights for formulating an EFT, such as the Soft-Collinear Effective Theory (SCET).
However, a fundamental question remains unanswered for most cases: how does one systematically determine the complete list of regions?
This talk aims to address this question to all orders by drawing from some recent research works. This talk addresses this question to all orders, drawing from recent research. The results presented focus on generic massless scattering, with potential generalization to massive cases. Additionally, these findings have important implications for other topics, including infrared subtraction, factorization breaking, and Landau singularities, which will be discussed during the presentation.

[Yuezhou Li] Causality constraints on effective field theories
We will review the bootstrap method for constraining low-energy effective field theories (EFT) using causality and unitarity. This method provides a systematic approach to sharpening our understanding of a variety of EFTs. Our focus will be on applying this bootstrap method to sharply constrain the polynomial modified gravity as gravitational EFTs, where we show that the Wilson coefficients are rigorously bounded uniformly by the Newton constant and the scale of new physics or the mass of higher-spin states. Such bounds can be uplifted to Anti-de Sitter space, providing sharp constraints on holographic conformal field theories. By coupling gravitons to a large number of matter fields, we also clarify what happens to the universal scale at which gravitational field theories break down and signals the necessity of an underlying non-field-theoretic description of gravity, which we refer to as the high-spin onset.

[Han Ma]

[Yijian Zou] Mixed-state phases and quantum error correction
Quantum phases of matter are characterized by patterns of long-range entanglement. In recent years, it has been demonstrated that mixed states can exhibit a rich phase diagram that goes beyond pure states. I will overview the study of mixed-state phases and emphasize its connection with quantum error correction codes. We give a precise definition of mixed-state phases using local channel transformations. We define renormalization group (RG) transformations on mixed states which establish the phase equivalence. We study the RG in several examples and show that they are related to error correctability in quantum error correction codes.

[Zhenghao Zhong] A Radioactive Higgs Mechanism
The Higgs mechanism is a well known process in quantum field theory where scalar fields gain VEVs and gauge groups are broken to subgroups. Today, I will talk about the Higgs mechanism in superconformal field theories (SCFTs) with eight supercharges. Due to a lack of Lagrangian description in much of the SCFTs in the literature, Higgsing is not easy. Using magnetic quivers, we introduce a new algorithm called Decay and Fission which performs Higgs mechanism for SCFTs regardless whether it has a Lagrangian description. I will demonstrate this with various examples in spacetime dimensions d=4,5,6. Finally, I will use the algorithm to arrive at a bound on the landscape of 3d mirror pairs that have quiver gauge theory descriptions.


Registration

This forum is open to all young theoretical physicists, and no registration is needed.


Organizers

Please contact Qiang Wen or Ryo Suzuki for any queries regarding this forum. We hope you will join us for this exciting event.



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