Diagnostics for Physical Processes of X-ray Plasma in Supernova Remnants / 超新星残骸のX線プラズマにおける物理過程の診断

Amano, Yuki

23 May 2023

京都大学 / 新制・課程博士 / 博士(理学) / 甲第24777号 / 理博第4971号 / 新制||理||1710(附属図書館) / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 鶴 剛, 准教授 細川 隆史, 教授 田島 治 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM

X-ray

Supernova remnant

High energy astrophysics

Atomic process

400

Atomic processes in gaseous nebulae

Prozesky, Andri

05 1900

The atomic physics relevant to gaseous nebulae is critically examined using modelling software with particular emphasis on radio recombination lines (RRLs). The theoretical spectral line intensities can be deduced if we know the population structure of the bound electrons in the gas under non-thermal equilibrium conditions. The population structure of hydrogen is solved for various environments using a capture-collision-cascade model that incorporates an ambient radiation eld. The validity of assuming Case B (Baker & Menzel, 1938) for nebulae is investigated. It is known that Case B is appropriate for levels with small principal quantum numbers (n < 40), but this assumption is re-examined for high levels which are relevant to RRLs. E ects of an ambient radiation eld on the population structure is examined and processes that are stimulated by a radiation eld are included in the model. This is done as a preliminary investigation to extend the model to a photoionization code. / Physics / (M. Sc. (Astronomy)

Atomic data

Atomic process

Plasmas

ISM atoms

530.11350113

Atoms -- Computer simulation

Radiative transfer

Nebulae -- Computer simulation

Astrophysics -- Computer simulation

Radio recombination lines

Atomic processes in gaseous nebulae

Prozesky, Andri

05 1900

The atomic physics relevant to gaseous nebulae is critically examined using modelling software with particular emphasis on radio recombination lines (RRLs). The theoretical spectral line intensities can be deduced if we know the population structure of the bound electrons in the gas under non-thermal equilibrium conditions. The population structure of hydrogen is solved for various environments using a capture-collision-cascade model that incorporates an ambient radiation eld. The validity of assuming Case B (Baker & Menzel, 1938) for nebulae is investigated. It is known that Case B is appropriate for levels with small principal quantum numbers (n < 40), but this assumption is re-examined for high levels which are relevant to RRLs. E ects of an ambient radiation eld on the population structure is examined and processes that are stimulated by a radiation eld are included in the model. This is done as a preliminary investigation to extend the model to a photoionization code. / Physics / (M. Sc. (Astronomy)

Atomic data

Atomic process

Plasmas

ISM atoms

530.11350113

Atoms -- Computer simulation

Radiative transfer

Nebulae -- Computer simulation

Astrophysics -- Computer simulation

Radio recombination lines