Volume 260

iTHEMS Weekly News Letter

Seminar Report

DMWG Seminar by Slivia Manconi on July 10, 2023

2023-07-20

As a nature of dark matter that feels gravity, dark matter in our Universe forms halos, which are gravitationally-bounded macroscopic structures. The halo structure is highly hierarchical and the halo of our Milky Way, for example, hosts many subhalos inside. However, smaller halos below a certain scale could not be visible because they cannot host galaxies.

If we look at the sky in gamma-ray wavelength, there are lots numbers of bright sources. Most of them are so-called active galactic nuclei (AGN), which are related to the powerful jet activities of black holes. A certain portion of point sources are not categorized yet. They could be AGNs, while it is also possible that they are bright due to DM annihilation occurring in compact and small subhalos in our Galaxy.

Neural networks, which are tools we have obtained in this era, powerfully help us to obtain insights into the properties of unknown gamma-ray sources. Properties of known sources such as spectrum and population serve as data for the supervision of the neural network. The trained network is used to look for outliers in the gamma-ray unknown sources which can be candidates for subhalos emitting gamma-rays by DM annihilations. In this way, a conservative upper limit on the annihilation cross-section of DM is derived.
The scheme is highly flexible and has many possibilities for extensions. In the near future, a huge amount of data, which is far beyond human ability to analyze all, from experiments in multiple wavelengths and probes should appear. The future of DM study assisted with machine learning should be bright.

Reported by Nagisa Hiroshima

Upcoming Events

Seminar

Quantum Matter Seminar

Electronic instabilities emerging from higher-order van Hove singularities

July 24 (Mon) at 17:00 - 18:15, 2023

Xinloong Han (Postdoctoral Fellow, Kavli Institute for Theoretical Sciences, University of Chinese Academy of Sciences, China)

Time: 5pm ~ 6:15pm (JST); 10am ~ 11:15am (CET); 4pm ~ 5:15pm (Taiwan)

Field: condensed matter physics
Keywords: topological superconductor, Van Hove singularity, Hubbard model, Kagome lattices

Abstract: Competing correlated electronic states are a central topic in condensed matter physics. A typical example is the close competition between spin density wave and d-wave superconductivity in the Hubbard model on the square lattice near half filling where the band structures have saddle points at which the Fermi surface topology changes from hole type to electron type. The saddle points are called van Hove singularity (VHS) points, and host diverging density of states with power-law behavior in the two dimensions. Recently, another type of VHS, namely the higher-order VHS was investigated in ABC-stacked trilayer graphene and twisted bilayer graphene. In this talk, I will first introduce the higher-order VHS, and make comparisons to the conventional VHS. Then I will discuss the enhanced nematicity driven by large flavor number with higher-order VHSs on the square and Kagome lattices. Finally, I will show that robust topological superconductivity can emerge on the square lattice due to interplay of spin-orbital coupling and higher-order VHSs.

Venue: Hybrid Format (Common Room 246-248 and Zoom)

Event Official Language: English

Lecture

3rd QGG Intensive Lectures: Spinfoam path integrals for Quantum Gravity

July 26 (Wed) - 28 (Fri), 2023

Etera Livine (Research Director CNRS, Ecole Normale Supérieure de Lyon, France)

At the crossroads of several approaches to quantum gravity, Spinfoams propose a discrete path integral for quantum general relativity built from topological field theory. With the spectrum of geometric operators directly read from the representation theory of the local symmetry group, they can be interpreted as a quantized version of Regge calculus and can be understood as implementing the dynamics of quantum states geometry in loop quantum gravity. I will explain the basics of the formalism, the motivations, the mathematical framework and the main tools. In three space-time dimensions, the spinfoam quantization of 3d gravity is given by the Turaev-Viro topological invariant, which is intimately related to the quantization of Chern-Simons theory. I will explain in particular how the spinfoam amplitudes solve the Wheeler-de Witt equation, implement the invariance under 3d diffeomorphisms (despite being formulated in a discretized space-time) and lead to a quasi-local version of holography. In four space-time dimensions, general relativity can be formulated as an almost-topological theory and I will explain how the existing spinfoam models introduce a sea of topological defects to re-create the gravitational degrees of freedom from a topological path integral. Finally, I will show how spinfoams are naturally defined in terms of group field theory, which are generalized tensor models, and the prospects that this opens. I will conclude with the main challenges and open lines of research of the field.

Program:

July 26
10:00 - 10:15 Registration and reception
10:15 - 11:45 Lecture 1
11:45 - 13:30 Lunch & coffee break
13:30 - 15:00 Lecture 2
15:00 - 16:00 Coffee break
16:00 - 17:00 Lecture 3
17:10 - 18:30 Short talk session

July 27
10:00 - 11:45 Lecture 4
11:45 - 13:30 Lunch & coffee break
13:30 - 15:00 Lecture 5
15:00 - 16:00 Coffee break
16:00 - 17:00 Lecture 6
17:30 - 20:00 Banquet

July 28
10:00 - 11:45 Lecture 7
11:45 - 13:30 Lunch & coffee break
13:30 - 15:00 Lecture 8
15:00 - 16:00 Coffee break
16:00 - 17:30 Lecture 9 & Closing

Venue: #435-437, 4F, Main Research Building, RIKEN

Event Official Language: English

Lecture

Higher Algebra in Geometry

July 31 (Mon) - August 10 (Thu), 2023

Hiro Lee Tanaka (Assistant Professor, Department of Mathematics, Texas State University, USA)

In these lectures, we will shed light on modern tools of higher algebra, where the traditional structures of algebra yield themselves only after controlled deformations. We will introduce infinity-categories, spectra, operads, and other standard tools of the last decade. The main applications will be to encode various higher-algebraic structures that inevitably arise in, and shed light on, geometry and topology. If time permits, we will illustrate how spectra naturally arise in geometric invariants.

The audience is imagined to consist of mathematicians interested in applications of infinity-categorical tools -- so a broad range of geometers (including topologists) and algebraists. From Lecture Two onward, I will assume basic knowledge of algebraic topology (e.g., the material of Hatcher) and homological algebra.

These lectures will be held between July 31 and August 10, each from 10:30 to 12:00, for a total of 8 lectures.

1st Week: Jul 31(mon), Aug 1(tue) - 3(thu)
- Introduction to ideas of higher algebra in geometry, for a general audience.
- Introduction to infinity-categories and to spectra.

2nd Week: Aug 7(mon) - 10(thu)
- Examples in geometry and topology, including invariants of Legendrian links and generating functions.
- Future Directions.

Profile:
Hiro Lee Tanaka is an assistant professor in the Department of Mathematics. After receiving his Ph.D. from Northwestern University and completing postdoctoral work at Harvard University, he conducted research at the Mathematical Sciences Research Institute in Berkeley, California, and at the Isaac Newton Institute in Cambridge, England. His research aims to fuse the higher structures in modern algebra with geometries emerging from both classical mechanics and supersymmetric field theories. Beyond research, Tanaka engages in efforts to create more equitable and supportive environments throughout the mathematics community.

References

  1. Jacob Lurie, Higher Topos Theory (PDF 4.8MB), doi: 10.1515/9781400830558
  2. Jacob Lurie, Higher Algebra (PDF 6.9MB)
  3. Kerodon - an online resource for homotopy-coherent mathematics
  4. Jacob Lurie, Hiro Lee Tanaka, Associative algebras and broken lines, arXiv: 1805.09587
  5. Jacob Lurie, On the Classification of Topological Field Theories, arXiv: 0905.0465
  6. Oleg Lazarev, Zachary Sylvan, Hiro Lee Tanaka, The infinity-category of stabilized Liouville sectors, arXiv: 2110.11754
  7. Araminta Amabel, Artem Kalmykov, Lukas Müller, Hiro Lee Tanaka, Lectures on Factorization Homology, Infinity-Categories, and Topological Field Theories, arXiv: 1907.00066
  8. David Ayala, John Francis, Hiro Lee Tanaka, Factorization homology of stratified spaces, arXiv: 1409.0848
  9. David Nadler, Hiro Lee Tanaka, A stable infinity-category of Lagrangian cobordisms, arXiv: 1109.4835
  10. David Gepner, An Introduction to Higher Categorical Algebra, arXiv: 1907.02904

Venue: #435-437, Main Research Building, RIKEN / via Zoom

Event Official Language: English

Seminar

Clifford Group and Unitary Designs under Symmetry

July 31 (Mon) at 14:00 - 15:30, 2023

Yosuke Mitsuhashi (Ph.D. Student, Department of Applied Physics, Graduate School of Engineering, The University of Tokyo)

We have generalized the well-known statement that the Clifford group is a unitary 3-design into symmetric cases by extending the notion of unitary design. Concretely, we have proven that a symmetric Clifford group is a symmetric unitary 3-design if and only if the symmetry constraint is described by some Pauli subgroup. We have also found a complete and unique construction method of symmetric Clifford groups with simple quantum gates for Pauli symmetries. For the overall understanding, we have also considered physically relevant U(1) and SU(2) symmetry constraints, which cannot be described by a Pauli subgroup, and have proven that the symmetric Clifford group is a symmetric unitary 1-design but not a 2-design under those symmetries. Our findings are numerically verified by computing the frame potentials, which measure the difference in randomness between the uniform ensemble on the symmetric group of interest and the symmetric unitary group. This work will open a new perspective into quantum information processing such as randomized benchmarking, and give a deep understanding to many-body systems such as monitored random circuits.

Venue: #345-347, Main Research Building, RIKEN Wako Campus / via Zoom

Event Official Language: English

Seminar

ABBL-iTHEMS Joint Astro Seminar

Evidence against a strong first-order phase transition in neutron star cores: impact of new data

August 1 (Tue) at 13:30 - 15:00, 2023

Len Brandes (Ph.D. Student, Technical University of Munich, Germany)

Information on the phase structure of strongly interacting matter at high baryon densities can be gained from observations of neutron stars and their detailed analysis. Bayesian inference methods are used to set constraints on the speed of sound in the interior of neutron stars, based on recent multimessenger data in combination with low-density constraints based on chiral effective field theory and perturbative QCD constraints at asymptotically high densities.
A detailed re-analysis is performed in order to clarify the influence of the latter constraints on the inference procedure. The impact of the recent new heavy (2.35 M_sol) black widow pulsar PSR J0952-0607 and of the unusually light supernova remnant HESS J1731-347 is inspected. One of the consequences of including PSR J0952-0607 in the database is a further stiffening of the equation-of-state, resulting in a 2.1 solar-mass neutron star in a reduced central density of less than five times the equilibrium density of normal nuclear matter.
A systematic Bayes factor assessment quantifies the evidence (or non-evidence) for small sound speeds, necessary for a strong first-order phase transition, within the range of densities realized in the core of neutron stars. Given the presently existing database, it can be concluded that the occurrence of a strong first-order phase transition in the core of even a 2.1 solar-mass neutron star is unlikely, while a continuous crossover cannot be ruled out.

Reference

  1. Len Brandes, Wolfram Weise, Norbert Kaiser, Evidence against a first-order phase transition in neutron star cores: impact of new data, (2023), arXiv: 2306.06218

Venue: via Zoom / Seminar Room #132, 1F Main Research Building, RIKEN

Event Official Language: English

Seminar

Quantum Gravity Gatherings

Quasi-local holography in 3d quantum gravity

August 4 (Fri) at 14:00 - 15:30, 2023

Etera Livine (Research Director CNRS, Ecole Normale Supérieure de Lyon, France)

Since the idea appeared in black hole physics, the concept of holography has become a guiding principle for quantum gravity. It is the notion that the dynamics of the geometry of a region of space-time can be entirely encoded in a theory living on its boundary. Although such holographic dualities have been well-developed in an asymptotical context, it remains a challenge to realize it exactly at finite distances. I will draw a possible route in 3d quantum gravity, by showing a duality between the Ponzano-Regge path integral for 3d quantum gravity as a topological field theory and the 2d (inhomogeneous) Ising model. This leads to an intriguing geometrical interpretation of the Ising critical couplings and opens the door to a possibly rich interplay between 3d quantum gravity and 2d condensed matter built out of holographic dualities.

Venue: Seminar Room #359, 3F Main Research Building, RIKEN / via Zoom

Event Official Language: English

Seminar

iTHEMS Theoretical Physics Seminar

Dark matter heating vs vortex creep heating in old neutron stars

August 7 (Mon) at 13:30 - 15:00, 2023

Motoko Fujiwara (Postdoctoral Researcher, Theoretical Particle Physics Group, Technical University of Munich, Germany)

Old isolated neutron stars have been gathering attention as targets to probe Dark Matter (DM) through temperature observations. DM will anomalously heat neutron stars through its gravitational capture and annihilation process, which predicts surface temperature as T_s ~ (1 − 3) × 10^3 K for t > 10^6 years. We may put constraints on DM-nucleon scattering cross section by finding even colder neutron stars.
This story, however, assumed that there is no relevant heating source for old neutron stars. In this talk, we discuss the creep motion of vortex lines in the neutron superfluid of the inner crust as the heating mechanism. This creep mechanism is inherent in the structure of neutron stars. The heating luminosity is proportional to the time derivative of the angular velocity of the pulsar rotation, and the proportional constant J has an approximately universal value for each neutron star. If this vortex creep heating is quantitatively relevant against DM heating, this mechanism may cause a serious background to probe DM.
The J parameter can be determined from the temperature observation of old neutron stars because the heating luminosity is balanced with the photon emission in the late time. We study the latest data of neutron star temperature observation and find that these data indeed give similar values of J, in favor of the assumption that these neutron stars are heated by the frictional motion of vortex lines. Besides, these values turn out to be consistent with the theoretical calculations of the vortex-nuclear interaction. Integarting all the results, we evaluate the vortex creep heating and conclude its significance against DM heating.

Venue: Seminar Room #359, 3F Main Research Building, RIKEN / via Zoom

Event Official Language: English

Seminar

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ABBL-iTHEMS Joint Astro Seminar

Early Formation of Dark Matter Halos

November 24 (Fri) at 14:00 - 15:15, 2023

Derek Beattie Inman (Research Scientist, iTHEMS)

Cosmological observations have led to an extremely precise understanding of the large-scale structure of the Universe. A common assumption is to extrapolate large-scale properties to smaller scales; however, whether this is correct or not is unknown and many well-motivated early Universe scenarios predict substantially different structure formation histories. In this seminar I will discuss two scenarios where nonlinear structures form much earlier than is typically assumed. In the first case, the initial fluctuations are enhanced on small scales leading to either primordial black holes clusters or WIMP minihalos right after matter-radiation equality. In the second, I will show that an additional attractive dark force leads to structure formation even in the radiation dominated Universe. I will furthermore discuss possible observations of such early structure formation including changes to the cosmic microwave background, dark matter annihilation, and when the first galaxies form.

Venue: Seminar Room #359, 3F Main Research Building, RIKEN / via Zoom

Event Official Language: English

Upcoming Visitors

July 22 (Sat) - August 21 (Mon), 2023

Etera Livine

Research Director CNRS, Ecole Normale Supérieure de Lyon, France

Visiting Place: RIKEN Wako Campus

July 24 (Mon) - 28 (Fri), 2023

Yasufumi Kojima

Emeritus Professor, Hiroshima University

Visiting Place: RIKEN Wako Campus

Paper of the Week

Week 4, July 2023

2023-07-20

Title: Numerical simulation of photospheric emission in long gamma-ray bursts: prompt correlations, spectral shapes, and polarizations
Author: Hirotaka Ito, Jin Matsumoto, Shigehiro Nagataki, Donald C. Warren, Maxim V. Barkov, Daisuke Yonetoku
arXiv: http://arxiv.org/abs/2307.10023v1

Title: Continuum limit for Laplace and Elliptic operators on lattices
Author: Keita Mikami, Shu Nakamura, Yukihide Tadano
arXiv: http://arxiv.org/abs/2307.08894v1

Title: 4D Weyl Anomaly and Diversity of the Interior Structure of Quantum Black Hole
Author: Pei-Ming Ho, Hikaru Kawai, Henry Liao, Yuki Yokokura
arXiv: http://arxiv.org/abs/2307.08569v1

Title: Quasinormal modes of black holes encircled by a gravitating thin disk
Author: Che-Yu Chen, Petr Kotlařík
arXiv: http://arxiv.org/abs/2307.07360v1

Title: Complete characterization of robust perfect adaptation in biochemical reaction networks
Author: Yuji Hirono, Ankit Gupta, Mustafa Khammash
arXiv: http://arxiv.org/abs/2307.07444v1

Title: Cosmic ray processes in galactic ecosystems
Author: Ellis R. Owen, Kinwah Wu, Yoshiyuki Inoue, H. -Y. Karen Yang, Alison M. W. Mitchell
arXiv: http://arxiv.org/abs/2306.09924v2

Title: SVD Entanglement Entropy
Author: Arthur J. Parzygnat, Tadashi Takayanagi, Yusuke Taki, Zixia Wei
arXiv: http://arxiv.org/abs/2307.06531v1

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