銀河と共に進化する超大質量ブラックホール

谷口義明

• 日本物理学会誌　2014-11

http://www.jps.or.jp/books/gakkaishi/2014/11/69-11.html 


ブラックホール，中国語では，
黒洞

大栗先生の超弦理論入門

2014-11

とても不思議な「超弦理論」がどことなく理解できたような気がする。

The Perfect Wave

http://www.hup.harvard.edu/catalog.php?isbn=9780674725010 

Heinrich Pes

include many interesting stories related to neutrino.

good for scientists and students

Author:
http://www.physik.uni-dortmund.de/~paes/

Head First Java 第2版――頭とからだで覚えるJavaの基本

http://www.oreilly.co.jp/books/4873112796/

(2014-11-19) Javaの勉強。for ASTRO-H

Go Vietnam for Soken-dai

2014-11-13 -> 11-17
Hanoi and HCMC

http://www.jasso.go.jp/study_j/info_fair_vietnam_2014.html
に総研大として参加。

同行者：
田村理事
http://www.minpaku.ac.jp/aboutus/pe/tamura/index

三原教授 (KEK)

総研大の担当者３人。

通訳の大西さん。

訪問先：

VNUHCM, University of Science

James Webb Space Telescope: The First Light Machine

ISAS

　　　　　  Space Science Seminar
Date:       15:30-16:30, 6th of November (Thu), 2014
Place:      Bldg-newA 2F Meeting room A
Speaker:    H. Philip Stahl (NASA/MSFC, USA)
Title:      James Webb Space Telescope:  The First Light Machine

Abstract:
Scheduled to begin its 10 year mission after 2018, the James Webb Space
Telescope (JWST) will search for the first luminous objects of the
Universe to help answer fundamental questions about how the Universe
came to look like it does today.  At 6.5 meters in diameter, JWST will
be the world’s largest space telescope.  This talk reviews science
objectives for JWST and how they drive the JWST architecture, e.g.
aperture, wavelength range and operating temperature.  Additionally, the
talk provides an overview of the JWST primary mirror technology
development and fabrication status.

The Power of Topology in Superstring Theory

ISAS

　　　　　  Space Science Colloquium
Date:       16:30-17:30, 5th of November (Wed), 2014
Place:      Conference room (Main building 2F)
Speaker:    Hiroshi Oguri (Caltech, USA)
Title:      The Power of Topology in Superstring Theory


Abstract:
Superstring theory is the leading candidate for the ultimate unified
theory of all the matters and forces in nature. It postulates that
fundamental building blocks are not point particles but strings, and it
is defined in (9+1)-dimensional spacetime. The rich structure in
particle physics in our (3+1) dimensions, such as quark and lepton
flavors, gauge forces, and the Higgs boson to break the gauge symmetry,
is expected to emerge from the geometry of the extra 6 (= 9 - 3)
dimensions, called a Calabi-Yau space. We want to derive quantitative
predictions on our universe from the geometry of the Calabi-Yau space.
However, the Calabi-Yau space is so complicated that we do not even know
an expression for its metric, namely how to measure the distance between
two points on the space. Given this limitation, what can we do? In this
talk, I will describe techniques we have developed to overcome this
difficulty and applications of these techniques to problems in physics
and mathematics.