## RESEARCH INTERESTS ##

Research Interests: Galaxy Formation and Evolution Progenitors of Type Ia Supernovae (SNe Ia) NOT the double-degenerate but the single-degenerate scenario, where the progenitor is a pair of white dwarf and normal star. In terms of the evolution of the binary system, metallicity effect is important on the occurrence of SNe Ia (Kobayashi et al. 1998). The observed scatter of the SNIa luminosity can be explained (Umeda et al. 1999). The dust effect on the SNIa cosmology can be estimated (Totani & Kobayashi 1999). The cosmic SN Ia rate will show a decrease from z~1.5 (Kobayashi et al. 98, 00) The bimodarity in lifetime distribution has been prediced (Kobayashi & Nomoto 2008). Galactic and Cosmic Chemical Evolution Chemical abundances are fossils to tell us the star formation history of galaxies and the universe; Stars formed from gas clouds in a galaxy, eject heavy elements into the interstellar medium via supernovae. Different heavy elements are produced from different types of supernovae (SN Ia, II, and HN) with different timescales. Computed with one zone-models, with which I can make a galaxy in 2 minutes:) (Kobayashi, Tsujimoto, Nomoto 00) Computed with SPH simulations, which takes 2 weeks for a galaxy, 2 months for the Universe... (Kobayashi, Springel, White 06) Spatial Distribution of Heavy Elements in galaxies and the Universe The formation history of the galaxy is imprinted in such internal structure of the galaxy, which will be obtained with the Integral Field Spectrographs and Adaptive Optics. Metallicity gradients of nearby elliptical galaxies observed (Kobayashi & Arimoto 99). Color gradients of distant (z<1) elliptical galaxies observed (Tamura, Kobayashi, et al. 00). GRAPE-SPH Chemodynamical Simulation I've simulated the formation and evolution of more than a hundred elliptical galaxies from the CDM initial fluctuation. GRAPE is a Japan-made special computer to calculate gravity. By reproducing the observed variety of radial metallicity gradients, I conclude that not all ellipticals formed by major mergers, but some of them formed monolithically (Kobayashi 2004). The observed scaling relations and fundamental plane can be reproduced (Kobayashi 2005). Chemodynamical evolution of the Milky Way Galaxy for the Galactic Archaeology (Kobayashi, Nakasato, in prep.). Cosmic Chemical Enrichment with GADGET I've introduced my schemes of feedback and chemical enrichment into GADGET, which is widely used parallel SPH code, German-made. I succeed in blowing the galactic winds from a small disk galaxy, not by hand but by supernova thermal feedback. Cosmic SFRs, chemical evolution, mass-dependent galactic winds, and the mass-metallicity relation of galaxies are reproduced (Kobayashi, Springel, White 06). Origin of Galactic Morphology How did spiral and elliptical galaxies form? What are dwarf galaxies? What are DLA, LBG, ERO, DRG, BzK,... Environmental Effects Galaxy formation in fields vs clusters? Elemental abundance patterns of ICM? Hypernovae nucleosynthesis (Kobayashi, Umeda, Tominaga, et al. 06) Gamma-ray burst rates (Kobayashi, Maeda, in prep.)