HPCS News picks up researchers who conduct their advanced scientific research leveraging large-scale computer in the Cybermedia Center.



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vol.11 Molecular simulation on water and ions in the self-assembled membranes - Prediction of molecular properties by using computer simulation -

Researcher : Yoshiki Ishii
Affiliation : Specially Appointed Lecturer, Graduate School of Information Science, University of Hyogo

Specially Appointed Lecturer, Graduate School of Information Science, University of Hyogo
Abstract: The water-treatment membrane is a key issue to keep the safe and secure environments for water supply toward the sustainable development goals. In order to understand the nature of molecular transport in the membrane, we’re challenging the computational observation of water and ion dynamics in the nanomaterial by using the supercomputer. In this study, the reason why water molecules move fast inside the nanoconfinement is clarified with the simulation methods of quantum chemistry and classical molecular dynamics.

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vol.10 Field-induced chiral transition and paramagnetic current in superconductivity ~Chiral phenomena generated by paramagnetic coupling of orbital magnetization to magnetic field~

Researcher : Hirono Kaneyasu
Affiliation : Assistant Professor, Department of Material Science, Graduate School of Engineering, University of Hyogo

Electrons are pairing in the superconducting state, and various superconducting phenomena occur as features of spin and orbital of electron pairs. One of the phenomena is the chiral state with intrinsic orbital magnetization which generates the spontaneous field. It is not clarified why the chiral superconducting state yields. We study the nature of chiral state by simulation based on the Ginzburg-Landau equation. The numerical analysis clarifies the field-induced chiral transition, paramagnetic supercurrent, and the inversion of chirality. These phenomena are caused by the paramagnetic coupling between the orbital magnetization and the external magnetic fields when the superconducting state varies depending on the distance. The vector parallelization is useful for analyzing the dependence of chiral superconducting state, and it is performed by the SX-Aurora TSUBASA at the Cybermedia Center.

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vol.09 Numerical simulation of cavitating turbulent flow

Researcher : Kie Okabayashi
Affiliation : Assistant Professor, Department of Mechanical Engineering, Graduate School of Engineering, Osaka University

When the pressure drops below the saturated vapor pressure in liquid flows, bubbles appear and disappear in a short time. This phenomenon is called cavitation, and it has various harmful effects on fluid machinery such as pumps and marine propellers. In Japan, numerical methods of cavitating flow have been developed, especially in response to the demand for flow analysis in liquid hydrogen turbopumps of rocket engines. However, the quantitative reproducibility of the lift coefficient is still not sufficient even flows around basic hydrofoils. In this study, the reproducibility of lift of cavitating flow around a hydrofoil was improved by resolving fine turbulent vortices. The computation to capture the fine-scale turbulence vortices tends to be large scale. Supercomputer SX-ACE can execute such computation in a high speed.

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vol.08 Analysis of time-course single-cell data for identifying genes that control disease

Researcher : Yuki Kato
Affiliation : Assistant Professor, Department of RNA Biology and Neuroscience, Graduate School of Medicine, Osaka University

Organs and tissues consist of cell populations, and genes expressed in these cells can be investigated at a single-cell level. A cell changes from a stem cell into a mature specialized cell, which is called cellular differentiation. It is important to trace changes of gene expression levels during cellular differentiation. For instance, comparing time-course single-cell data of a normal mouse with those of a diseased one by a computational method will reveal which genes can control the disease. In this study, we develop a computational tool for efficiently comparing differentiation trajectories derived from single-cell data for two related experimental conditions. https://github.com/ykat0/capital

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vol.07 Towards high performance data analytics to provide practical solutions to real world problems

Researcher : Chonho LEE
Affiliation : Specially Appointed Associate Professor, Advanced High-Performance Computing System Architecture Joint Research Division, Cybermedia Center, Osaka University

With the experience of Cybermedia Center accumulated through the operation and use of large-scale computer systems, we are conducting research to build computing platform that enables high-performance big data analysis, and to produce practical and beneficial solutions to solve real world problems from the user’s perspective. In this video, we introduce a wide variety of applications leveraging machine learning and AI technology as practical examples using a large-scale computer system, which include (i) periodontal disease diagnosis and cephalometric landmark detection in dental clinical practice, (ii) individual identification of coconut crab in ecological research, (iii) colorization of black and white images after the atomic bombing in Hiroshima. (https://www.aca.cmc.osaka-u.ac.jp/)

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vol.06 Real-Scale Social Simulations

Researcher : Tadahiko MURATA1, Takuya HARADA2
Affiliation : 1Professor, Department of Informatics, Kansai University, 2Graduate School of Informatics, Kansai University

Social simulations are attracting attentions since one of them is awarded the Novel Memorial Prize in Economic Sciences. However, many social simulations are regarded too abstract. We are developing nation-wide synthetic populations in order to implement real-scale social simulations. We synthesize populations using available statistics in finer districts in cities, towns or villages.

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vol.05 Simulation of electrical excitation propagation in human heart

Researcher : Shin Inada
Affiliation : Professor, Department of Medical Engineering, Faculty of Health Sciences, Morinomiya University of Medical Sciences

Cardiac arrhythmias are related to abnormal electrical excitation propagation in the heart. Especially, ventricular arrhythmia may lead to sudden cardiac death. However, it is not fully understood how abnormal electrical excitation propagation affects and contributes to initiate and maintenance of ventricular arrhythmias. One of the methods to investigate the mechanisms of initiation and maintenance of the arrhythmia is to simulate electrophysiological phenomena in the heart. In our study, we constructed large scale and anatomically-detailed heart models including approximately 20 million units. Simulations are conducted with SX-ACE supercomputer at the Cybermedia Center. Our simulations suggest that abnormality of electrical excitation propagation in the right ventricular outflow tract contribute to develop and maintenance of ventricular arrhythmia. We believe that computer simulation is one of the powerful tools to analyze complicated electrical activity of the heart and find new method to treat heart diseases such as arrhythmias.

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vol.04 Numerical simulation of supersonic streamwise vortices induced by a strut injector

Researcher : Hiejima Toshihiko
Affiliation : Osaka Prefecture University, Graduate School of Engineering, Aerospace and Marine-System Engineering, Aerospace Engineering, Assistant Professor

The key to airbreathing hypersonic aircrafts, supersonic airplane and spaceplane, is to realize supersonic combustion ramjet (scramjet) engines. However, the residence time of air in combustor is supposed to be the order of milliseconds in terms of the length of the combustor. Under the condition, the main issue to address is effective fuel-oxidizer mixing in the engine over the short time scale of combustion. We challenge the issue using streamwise vortices induced by a strut injector, which are effective in supersonic mixing and combustion. To clarify physics and chemistry in the extreme environments (i.e., high speed, high temperature, and high pressure), supercomputers are very useful because experimental studies of supersonic combustion are difficult and expensive.

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vol.03 Numerical simulation of flow and water quality in Osaka Bay

Researcher : Yusuke Nakatani
Affiliation : Osaka University, Division of Global Architecture, Graduate School of Engineering, Assistant Professor

Water pollution is a social problem in an enclosed bay with a large city, such as Osaka Bay. However, there are a lot of uncertain points in the pollution mechanism. To clarify the mechanism of water environmental degradation by reclamation, numerical analysis have conducted using a 3-D flow and water-quality model. The results indicated that coastal landform change could influence the currents and water quality not only around the reclaimed land but also in the entire bay and the adjacent seas by weakening the anticyclonic circulation flow in the bay head.

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vol.02 Cosmology with Numerical Simulations

Researcher : Kentaro Nagamine
Affiliation : Osaka University, Department of Earth and Space Science, Graduate School of Science, Professor

Thanks to the explosive astronomical observations over the past two decades, humankind has obtained the expanding Big Bang Universe as a standard cosmological model. However, does such a model really reproduce the large-scale structure and galaxies that we see in the sky? Our goal is to reveal the secrets of cosmological structure formation using supercomputers in the Universe dominated by dark matter and dark energy. Our research is gradually revealing how large-scale structures, galaxies and supermassive black holes form in this Universe.

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vol.01 Air flow analysis on speech production

Researcher : Kazunori Nozaki
Affiliation : Osaka University Dental Hospital, Assistant Professor

Speech is physically classified as aerodynamic acoustics, and the sound generated from the turbulence that is uttered in the oral cavity of the speaker propagates to the eardrum of the listener. This phenomenon can be visualized by using the supercomputer. In this research, as a first step, using the state-of-the-art medical imaging diagnostic apparatus, the airway shape at the time of utterance was measured and fluid simulation was carried out. In the future, by combining it with medical information, we plan to link speech information to medical information which is information of individual patients.