大域的トロイダル系における電磁的な微視的不安定性と乱流輸送に対する磁気シアと加熱の効果

京都大学新制・課程博士博士(エネルギー科学)甲第23537号エネ博第428号新制||エネ||82(附属図書館)京都大学大学院エネルギー科学研究科エネルギー基礎科学専攻(主査)教授 岸本 泰明, 教授 中村 祐司, 教授 田中 仁学位規則第4条第1項該当Doctor of Energy ScienceKyoto UniversityDFA

Classical and Quantum Mechanical Models of Many-Particle Systems

This workshop was dedicated to the presentation of recent results in the field of the mathematical study of kinetic theory and its naturalextensions (statistical physics and fluid mechanics). The main models are the Vlasov(-Poisson) equation and the Boltzmann equation, which are obtainedas limits of many-body equations (Newton’s equations in the classical case and Schrödinger’s equation in the quantum case) thanks to the mean-field and Boltzmann-Grad scalings. Numerical aspects and applications to mechanics, physics, engineering and biology were also discussed

Recent Advances in Industrial and Applied Mathematics

This open access book contains review papers authored by thirteen plenary invited speakers to the 9th International Congress on Industrial and Applied Mathematics (Valencia, July 15-19, 2019). Written by top-level scientists recognized worldwide, the scientific contributions cover a wide range of cutting-edge topics of industrial and applied mathematics: mathematical modeling, industrial and environmental mathematics, mathematical biology and medicine, reduced-order modeling and cryptography. The book also includes an introductory chapter summarizing the main features of the congress. This is the first volume of a thematic series dedicated to research results presented at ICIAM 2019-Valencia Congress

Generalized averaged Gaussian quadrature and applications

A simple numerical method for constructing the optimal generalized averaged Gaussian quadrature formulas will be presented. These formulas exist in many cases in which real positive GaussKronrod formulas do not exist, and can be used as an adequate alternative in order to estimate the error of a Gaussian rule. We also investigate the conditions under which the optimal averaged Gaussian quadrature formulas and their truncated variants are internal

MS FT-2-2 7 Orthogonal polynomials and quadrature: Theory, computation, and applications

Quadrature rules find many applications in science and engineering. Their analysis is a classical area of applied mathematics and continues to attract considerable attention. This seminar brings together speakers with expertise in a large variety of quadrature rules. It is the aim of the seminar to provide an overview of recent developments in the analysis of quadrature rules. The computation of error estimates and novel applications also are described

Laskennallisten avaruussäämallien kehittäminen, validointi ja käyttö

Currently the majority of space-based assets are located inside the Earth's magnetosphere where they must endure the effects of the near-Earth space environment, i.e. space weather, which is driven by the supersonic flow of plasma from the Sun. Space weather refers to the day-to-day changes in the temperature, magnetic field and other parameters of the near-Earth space, similarly to ordinary weather which refers to changes in the atmosphere above ground level. Space weather can also cause adverse effects on the ground, for example, by inducing large direct currents in power transmission systems. The performance of computers has been growing exponentially for many decades and as a result the importance of numerical modeling in science has also increased rapidly. Numerical modeling is especially important in space plasma physics because there are no in-situ observations of space plasmas outside of the heliosphere and it is not feasible to study all aspects of space plasmas in a terrestrial laboratory. With the increasing number of computational cores in supercomputers, the parallel performance of numerical models on distributed memory hardware is also becoming crucial. This thesis consists of an introduction, four peer reviewed articles and describes the process of developing numerical space environment/weather models and the use of such models to study the near-Earth space. A complete model development chain is presented starting from initial planning and design to distributed memory parallelization and optimization, and finally testing, verification and validation of numerical models. A grid library that provides good parallel scalability on distributed memory hardware and several novel features, the distributed cartesian cell-refinable grid (DCCRG), is designed and developed. DCCRG is presently used in two numerical space weather models being developed at the Finnish Meteorological Institute. The first global magnetospheric test particle simulation based on the Vlasov description of plasma is carried out using the Vlasiator model. The test shows that the Vlasov equation for plasma in six-dimensionsional phase space is solved correctly by Vlasiator, that results are obtained beyond those of the magnetohydrodynamic (MHD) description of plasma and that global magnetospheric simulations using a hybrid-Vlasov model are feasible on current hardware. For the first time four global magnetospheric models using the MHD description of plasma (BATS-R-US, GUMICS, OpenGGCM, LFM) are run with identical solar wind input and the results compared to observations in the ionosphere and outer magnetosphere. Based on the results of the global magnetospheric MHD model GUMICS a hypothesis is formulated for a new mechanism of plasmoid formation in the Earth's magnetotail.Avaruuteen lähetetyistä laitteista suurin osa sijaitsee Maan magnetosfäärissä, missä ne altistuvat avaruussäälle. Avaruussäällä tarkoitetaan Maan lähiavaruuden läpötilan, magneettikentän ja muiden ominaisuuksien päivittäistä vaihtelua auringosta jatkuvasti virtaavan plasman - aurinkotuulen - vuoksi. Avaruussäällä voi olla haitallisia vaikutuksia myön Maan pinnalla, esimerkkinä sähkönsiirtoverkkoihin indusoituvat suuret tasavirrat. Tietokoneiden laskentateho on kasvanut eksponentiaalisesti jo vuosikymmenien ajan, minkä seurauksena myös laskennallisen mallinnuksen merkitys tieteelle on kasvanut huomattavasti. Laskennallinen mallintaminen on erityisen tärkeää avaruusplasmafysiikassa, sillä aurinkokunnan ulkopuolelta ei ole suoria mittauksia, eikä kaikkia avaruusplasman ominaisuuksia voida tutkia maanpäällisissä laboratorioissa. Supertietokoneiden laskentaytimien määrän kasvaessa myös laskennallisten mallien rinnakkaisesta suorituskyvystä on tullut ratkaisevan tärkeää. Väitöskirja koostuu johdannosta ja neljästä vertaisarvioidusta julkaisusta joissa kuvataan laskennallisten avaruussäämallien kehittämistä ja käyttöä Maan lähiavaruuden tutkimiseen. Avaruussäämallien kaikki kehittämisaskeleet käydään läpi alkaen alustavasta suunnittelusta ja toteutuksesta, jaetun muistin rinnakkaistuksesta ja laskentanopeuden optimoinnista aina testaukseen ja validointiin asti. Väitöskirjan yhteydessä on suunniteltu ja toteutettu rinnakkainen hila jota käytetään tällä hetkellä kahdessa Ilmatieteen laitoksella kehitettävässä avaruussäämallissa. Näistä toisen, Vlasovin yhtälöllä plasmaa mallintavan Vlasiatorin, täyden kuusiulotteisen faasiavaruuden (kolme paikka- ja kolme nopeusulottuvuutta) käsittävällä magnetosfääritestillä on osoitettu mallin toimivuus ja soveltuvuus Maapallon koko magnetosfäärin mallintamiseen nykyisillä supertietokoneilla. Ensimmäistä kertaa on myös vertailtu neljän eri avaruussäämallin (BATS-R-US, GUMICS, OpenGGCM, LFM) tuottamia ennusteita Maan lähiavaruudesta käyttäen samaa aurinkotuulisyötettä