Volume 224

iTHEMS Weekly News Letter

Hot Topic

Naritaka Oshita thumbnail

Naritaka Oshita presented his talk at the 12th Koshien of Science (Oita tournament) on November 3, 2022

2022-11-10

The 12th Koshien of Science (Oita tournament), a scientific competition for high school students in Oita prefecture, was held on 3rd November 2022 at Oita city. Naritaka Oshita from iTHEMS presented his talk on “Black Holes Veiled in Mystery” after the competition. More than 200 high school students from Oita prefecture attended. Oshita talked about the history of science, recent progress, and remaining mysteries of black holes. A student asked a unique question “What if we fall into a black hole? Can our consciousness be recovered from the hole?”. Another student asked, “How can it be possible to detect the signal from a ringing black hole?”. The audience enjoyed the stimulating talk and questions from the students.

During the competition, Oshita and an iTHEMS assistant Tomoko Iwanami observed the competition, where some students built their toy cars in each group and competed in a race.

Seminar Report

DMWG Seminar by Dr. Oscar Macias on October 28, 2022

2022-11-07

Dark matter (DM) is only a part of the mysterious phenomena in our Universe. As our exploration of the Universe proceeds, we frequently meet new mysteries. The Fermi bubble is such an example. Fermi-LAT founds extended gamma-ray emissions in the vertical direction from the Galactic Center and the origin is still unknown.

Observations in other wavelengths could give some hints about its interpretation. The Saggitarius stellar stream, which is believed to be a dwarf spheroidal galaxy (dSph) being disrupted, seems to overlap with the Fermi Bubble region. Old star populations including milli-second pulsars, which are famous gamma-ray emitters, can be expected in dSphs. However, the spectrum of milli-second pulsars is different from that of the Fermi Bubble and the interpretation cannot be possible in a straightforward way.
Another key ingredient for this consideration is the gas component of the Saggitarius stream. In such environments, inverse Compton emission should contribute to the high-energy regime and gamma-ray emission should be interpreted with two components. The prediction of this two-component model fairly matches the observed properties of the Fermi Bubble.

This fact, at this stage, leads to another hint to DM study.
Currently, one of the tightest constraints of the DM annihilation cross-section is obtained from gamma-ray observations of dSphs. When we consider such investigations, usually it is assumed that astrophysical gamma-rays are subtle enough. However, regarding the fact that the tidally disrupted dSph of Saggitarius emits gamma rays from interactions of baryonic components, we must be careful about the target selection of dSphs for future observations. It is suggested in the talk that the ordering of the promising dSphs for the future gamma-ray search of DM could be different.

Interaction between visible and invisible sectors in our Universe always brings us fruitful insights. We will meet further indications in this era by boosting astrophysical studies.

Reported by Nagisa Hiroshima

Upcoming Events

Seminar

iTHEMS Theoretical Physics Seminar

Expanding Edges of Quantum Hall Systems in a Cosmology Language - Hawking Radiation from de Sitter Horizon in Edge Modes

November 11 (Fri) at 16:00 - 17:30, 2022

Masahiro Hotta (Assistant Professor, Department of Physics, Graduate School of Science, Tohoku University)

Expanding edge experiments are promising to open new physics windows of quantum Hall systems. In a static edge, the edge excitation, which is described by free fields decoupled with the bulk dynamics, is gapless, and the dynamics preserve conformal symmetry. When the edge expands, such properties need not be preserved. We formulate a quantum field theory in 1+1 dimensional curved spacetimes to analyze the edge dynamics. We propose methods to address the following questions using edge waveforms from the expanding region: Does the conformal symmetry survive? Is the nonlinear interaction of the edge excitations induced by edge expansion? Do the edge excitations interact with the bulk excitations? We additionally show that the expanding edges can be regarded as expanding universe simulators of two-dimensional dilaton-gravity models, including the Jackiw-Teitelboim gravity model. As an application, we point out that our theoretical setup might simulate emission of analog Hawking radiation with the Gibbons-Hawking temperature from the future de Sitter horizon formed in the expanding edge region.

Venue: #345-347, 3F, Main Research Building, RIKEN / via Zoom

Event Official Language: English

Seminar

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iTHEMS Theoretical Physics Seminar

Merger and post-merger of binary neutron stars with a quark-hadron crossover equation of state

November 15 (Tue) at 15:00 - 17:01, 2022

Yongjia Huang (Ph.D. Student, University of Science and Technology of China, China)

The state of the ultra-dense matter remains one of the long-standing open questions. Neutron star (NS), as it cools down the eons ahead after the birth in the supernova explosion, provides an astrophysical laboratory to investigate the dense, strongly interacting nuclear matter at zero temperature. On the other hand, the most intense gravitational wave(GW) radiation is produced in regions of the strong gravitational field by coherent movements of masses with large compactness. Therefore, GW from binary neutron star(BNS) merger naturally contains the information from the ultra-dense matter.

In this talk, I will introduce our recent work, "Merger and post-merger of binary neutron stars with a quark-hadron crossover equation of state ."Quark-hadron crossover(QHC) is one way of hadron-quark transition, which generally predicts a peak in sound speed vs. density, and so releases more pressure during the hadron-quark transition. I will first briefly summarize the features of QHC EOS and the BNS merger. I will then focus on how information on the hadron-quark transition shows in the GW and its spectrum during the BNS merger.

Venue: via Zoom

Event Official Language: English

Conference

MCME SYMPOSIUM 2022 thumbnail

Co-hosted by iTHEMS

MCME SYMPOSIUM 2022

November 16 (Wed) - 17 (Thu), 2022

Takemasa Miyoshi (Team Leader, Data Assimilation Research Team, RIKEN Center for Computational Science (R-CCS))
Hidetoshi Taya (Special Postdoctoral Researcher, iTHEMS)
Hidetoshi Nishimori (Specially Appointed Professor, Tokyo Institute of Technology)

"MCME SYMPOSIUM 2022" will be held at the Musashino Center of Mathematical Engineering (MCME), Musashino University. This symposium is free of charge and open to everyone.
Colleagues of iTHEMS will also be speaking. Below is an excerpt from the program.

Wednesday, November 16, 13:30 - 14:40 Takemasa Miyoshi
Thursday, November 17, 10:00 - 11:10 Hidetoshi Taya
Thursday, November 17, 14:50 - 16:00 Hidetoshi Nishimori

Registration is open until November 14. Please register from the related links below.

Organized by Musashino Center of Mathematical Engineering (MCME), Musashino University
Co-organized by RIKEN Interdisciplinary Theoretical and Mathematical Sciences Program (iTHEMS)

Venue: Hybrid Format (Room 301, Building 5, Ariake Campus, Musashino University and Zoom)

Seminar

iTHEMS Biology Seminar

Emergence of growth and dormancy from a kinetic model of the Escherichia coli central carbon metabolism

November 17 (Thu) at 18:00 - 19:00, 2022

Yusuke Himeoka (Assistant Professor, Universal Biology Institute, The University of Tokyo)

Physiological states of bacterial cells exhibit a wide spectrum of timescale. Under nutrient-rich conditions, most of the cells in an isogenic bacterial population grow at certain rates, while a small subpopulation sometimes stays in a dormant state where the growth rates slow down by orders of magnitude. For revealing the origins of such heterogeneity of timescales, we studied the kinetic model of Escherichia coli central carbon metabolism. We found that the model robustly exhibits both the growing- and the dormant state. Performing the model reduction, we have revealed the necessary conditions for the distinct behaviour, namely, the depletion of energy due to the futile cycle and its non-uniform impact on the kinetics because of the coexistence of the energy currency-coupled and uncoupled reactions as well as branching of the network.

Venue: via Zoom

Event Official Language: English

Seminar

iTHEMS Math Seminar

Mathematics of Post-Quantum Cryptography

November 18 (Fri) at 14:00 - 16:30, 2022

Yusuke Aikawa (Researcher, Information Technology R&D Center, Mitsubishi Electric Corporation)

Cryptography keeps our everyday information communications secure.
Cryptography based on key sharing have been used mainly for military purposes since ancient times in human history, but with the advent of the Internet, cryptography that does not require key sharing has become necessary.
In 1976, Diffie and Hellman proposed the concept of public key cryptography, which does not require key sharing among communicators. Since then, research on public key cryptography has progressed, involving not only computer science but also mathematics, and has become an essential technology for the society we live in.

The security of public key cryptography is supported by computational hardness of problems derived from mathematics. For example, the integer factoring problem is a basis for the security of RSA cryptography, and the discrete logarithm problem is for elliptic curve cryptography.
However, in 1994, Shor proposed an efficient quantum algorithm that solves these problems. This means that emergence of large-scale quantum computers will break RSA and elliptic curve cryptography we use today.

For this reason, research on next-generation cryptography, so-called Post-Quantum Cryptography (PQC for short), is currently underway to prepare for a future in which quantum computers will emerge. In this talk, without assuming any knowledge of cryptography, I will give a brief overview of cryptography and the progress of PQC. The first half of the talk will mainly outline the relationship between mathematics and cryptography, while the second half will discuss isogeny-based cryptography, one of the promising PQC, with our recent results.

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

Event Official Language: English

Seminar

iTHEMS Math Seminar

Tropical methods in Enumerative Geometry and Mirror Symmetry

November 25 (Fri) at 14:00 - 16:00, 2022

Michel Van Garrel (Assistant Professor, School of Mathematics, University of Birmingham, UK)

Abstract for the 1st hour: Enumerative Geometry has been a feature of mathematics from its beginnings, just think about the number of lines in the plane passing through 2 points. I will take you on a history of the subject and its relationship to other areas of mathematics and physics.

Abstract for the 2nd hour: Many problems in mathematics are solved by taking a limit and solving the limiting problem. Tropical geometry is a key technique that allows us to do this systematically. I will talk about the following problem. Take the complex projective plane S and an elliptic curve E in S. Count algebraic maps from the affine line into the complement S \ E. This counting problem is solved via tropical geometry as I will describe in this talk.

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

Event Official Language: English

Seminar

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iTHEMS Seminar

Efficient encoding of the Schrodinger equation on quantum computers

December 5 (Mon) at 14:00 - 15:30, 2022

Ermal Rrapaj (Postdoctoral Researcher, iTHEMS)

The continuous space Schrödinger equation is reformulated in terms of spin Hamiltonians. For the kinetic energy operator, the critical concept facilitating the reduction in model complexity is the idea of position encoding. A binary encoding of position produces a spin-1/2 Heisenberg-like model and yields exponential improvement in space complexity when compared to classical computing. Encoding with a binary reflected Gray code (BRGC), and a Hamming distance 2 Gray code (H2GC) reduces the model complexity down to the XZ and transverse Ising model respectively. Any real potential is mapped to a series of k-local Ising models through the fast Walsh transform. As a first step, the encoded Hamiltonian is simulated for quantum adiabatic evolution. As a second step, the time evolution is discretized, resulting in a quantum circuit with a gate cost that is better than the Quantum Fourier transform. Finally, a simple application on an ion-based quantum computer is provided as proof of concept.

References

  1. Improving Schrödinger Equation Implementations with Gray Code for Adiabatic Quantum Computers, Chia Cheng Chang, Kenneth S. McElvain, Ermal Rrapaj, and Yantao Wu, PRX Quantum 3, 020356, doi: 10.1103/PRXQuantum.3.020356
  2. Ermal Rrapaj, Kenneth S. McElvain, Chia Cheng Chang, Yantao Wu, André Walker-Loud, Gate Based Implementation of the Laplacian with BRGC Code for Universal Quantum Computers, doi: 10.48550/arXiv.2207.11647

Venue: Common Room #246-248, 2F Main Research Building, RIKEN / via Zoom

Event Official Language: English

Colloquium

iTHEMS Colloquium

The Epidemiology and Economics of Physical Distancing during Infectious Disease Outbreaks

December 14 (Wed) at 11:00 - 12:30, 2022

Troy Day (Professor, Head of Department, Department of Mathematics and Statistics, Queen's University, Canada)

People's incentives during an infectious disease outbreak influence their behaviour, and this behaviour can impact how the outbreak unfolds. Early on during an outbreak, people are at little personal risk of infection and hence may be unwilling to change their lifestyle to slow the spread of disease. As the number of cases grows, however, people may then voluntarily take extreme measures to limit their exposure. Political leaders also respond to the welfare and changing desires of their constituents, through public health policies that themselves shape the course of the epidemic and its ultimate health and economic repercussions. In this talk I will use ideas from the study of differential games to model how individuals’ and politicians’ incentives change during an outbreak, and the epidemiological and economic consequences that ensue when these incentives are acted upon. Motivated by the COVID-19 pandemic, I focus on physical distancing behaviour and the imposition of stay-at-home orders by politicians. I show that there is a fundamental difference in the political, economic, and health consequences of an infectious disease outbreak depending on the degree of asymptomatic transmission. If transmission occurs primarily by asymptomatic carriers, then politicians will be incentivized to impose stay-at-home orders earlier and for longer than individuals would like. Despite such orders being unpopular, however, they ultimately benefit all individuals. On the other hand, if the disease is transmitted primarily by symptomatic infections, then individuals are incentivized to stay at home earlier and for longer than politicians would like. In this case, politicians will be incentivized to impose back-to-work orders that, despite being unpopular, will again ultimately be to the benefit of all individuals.

This is joint work with David McAdams, Fuqua School of Business and Economics Department, Duke University.

Venue: via Zoom

Event Official Language: English

Seminar

iTHEMS Seminar

Lattice gauge theory in curved spacetimes

December 15 (Thu) at 14:00 - 15:30, 2022

Arata Yamamoto (Assistant Professor, Department of Physics, Graduate School of Science, The University of Tokyo)

Lattice gauge theory is a powerful computational approach in quantum field theory. It is also utilizable for investigating quantum phenomena in curved spacetimes, such as rotating frame, torsion, and gravitational backgrounds. In this talk, I would like to overview the formulation and results of lattice simulations in curved spacetimes.

References

  1. A. Yamamoto and Y. Hirono, Lattice QCD in Rotating Frames, Phys. Rev. Lett. 111, 081601 (2013), doi: 10.1103/PhysRevLett.111.081601
  2. A. Yamamoto, Lattice QCD in curved spacetimes, Phys. Rev. D 90, 054510 (2014), doi: 10.1103/PhysRevD.90.054510
  3. S. Benic and A. Yamamoto, Quantum Monte Carlo simulation with a black hole, Phys. Rev. D 93, 094505 (2016), doi: 10.1103/PhysRevD.93.094505
  4. S. Imaki and A. Yamamoto, Lattice field theory with torsion, Phys. Rev. D 100, 054509 (2019), doi: 10.1103/PhysRevD.100.054509

Venue: Common Room #246-248, 2F Main Research Building, RIKEN / via Zoom

Event Official Language: English

Paper of the Week

Week 2, November 2022

2022-11-10

Title: Entanglement Dynamics of the Non-Unitary Holographic Channel
Author: Kanato Goto, Masahiro Nozaki, Kotaro Tamaoka, Mao Tian Tan
arXiv: http://arxiv.org/abs/2211.03944v1

Title: Projecting XRP price burst by correlation tensor spectra of transaction networks
Author: Abhijit Chakraborty, Tetsuo Hatsuda, Yuichi Ikeda
arXiv: http://arxiv.org/abs/2211.03002v1

Title: Homological instability for moduli spaces of smooth 4-manifolds
Author: Hokuto Konno, Jianfeng Lin
arXiv: http://arxiv.org/abs/2211.03043v1

Title: A family of slice-torus invariants from the divisibility of reduced Lee classes
Author: Taketo Sano, Kouki Sato
arXiv: http://arxiv.org/abs/2211.02494v1

Title: Probing hadron mass spectrum in dense two-color QCD with linear sigma model
Author: Daiki Suenaga, Kotaro Murakami, Etsuko Itou, Kei Iida
arXiv: http://arxiv.org/abs/2211.01789v1

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