簡易檢索 / 詳目顯示

研究生: 王康華
Wang, Kong-Hua
論文名稱: 早期型星系演化與基本性質之研究
Investigating fundamental properties and evolution of early type galaxies
指導教授: 陳林文
Chen, Lin-Wen
學位類別: 碩士
Master
系所名稱: 地球科學系
Department of Earth Sciences
論文出版年: 2018
畢業學年度: 106
語文別: 英文
論文頁數: 54
中文關鍵詞: 早期型星系 (ETGs)基本面 (FP)均功基本面 (vFP)均功能量密度(VED)星系性質性質面
英文關鍵詞: ETGs, fundamental plane (FP), vFP, VED, galaxy properties, property surface
DOI URL: http://doi.org/10.6345/THE.NTNU.DES.014.2018.B07
論文種類: 學術論文
相關次數: 點閱:119下載:16
分享至:
查詢本校圖書館目錄 查詢臺灣博碩士論文知識加值系統 勘誤回報
  • 早期型星系之尺度關係 (scaling relations) 可用來連接星系的各種性質,其中又以基本面 (fundamental plane) 為最早的一個應用實例,它藉由有效半徑Re、速度瀰散σ和平均表面亮度三者的關聯性,來估算星系的距離 (Dressler 1987; Djorgovski and Davis 1987)。後續的相關研究也經常地應用這種尺度關係技術,找出早期型星系各種性質間的關聯性。本論文,是以能量的觀點建構一個均功基本面 (virial Fundamental Plane, vFP), 它以質量密度 (ρ ~ M/V) 和均功能量密度 (VED ~ M2/ReV) 兩個變數去建立與其他早期型星系性質之間的關聯性,如質量M,光度L, Re, σ 和年齡Age。本研究使用兩組樣本 --- 核心樣本和延伸樣本:核心樣本包括258個早期型星系 (z < 0.011), 採自ATLAS3D觀測計劃 (Cappellari et al. 2011, 2013b); 延伸樣本包括3,128個早期型星系 (0.01< z < 0.1), 選自SDSS Data Release 4 中有較精準星系形態資訊的14,034個星系 (Nair and Abraham 2010)。

    本研究結果顯示:可與ρ -VED vFP構建出性質面的早期型星系性質包括σRe, σRe/8, Vcirc, L, E/L和Age。並且,由vFP建構的MDM面,可用來估計早期型星系在一個Re範圍內的暗物質質量,而這估算出來的暗物質質量可將 Mstar和 Mtotal 數據點由隨機散佈的形態轉變成平面的分佈形態。本研究於分析計算星系體積V時,已將星系橢圓度ε考量進去,並獲得關係式 Mstar ~ Mtotal(1−ε)0.5 和 MDM ~ Re Mtotal0.5 (1−ε)0.75。同時,研究所得數據揭示:質量愈大的早期型星系具有較小的質量密度,這表示,若早期型星系藉由多次星系合併而演化,且其最後總質量為各合併星系質量之和,則其總體積卻大於原各合併星系個別體積之和。另一方面,由獲得結果得知質光比和星系演化年齡有著Mstar ⁄L ~ Age 1/(0.93~0.96) 和Mtotal ⁄L ~ Age 1/(1.00~1.02) 的關係。
    關鍵詞: 早期型星系 (ETGs), 基本面 (FP), 均功基本面 (vFP), 均功能量密度(VED), 星系性質, 性質面

    Scaling relations of early-type galaxies (ETGs) connect galaxy properties. The ETG fundamental plane is one of the earliest examples that correlates effective radius Re with velocity dispersion σ. and surface brightness and is applied to estimate distance (Dressler 1987; Djorgovski and Davis 1987). Follow-up studies frequently utilize this scaling technique to find correlations among different properties of ETGs. In this study, based on the energy point of view, we construct our virial Fundamental Plane (vFP) with two variables of total mass density (ρ ~ M/V) and Virial Energy Density (VED ~ M2/ReV) to correlate properties of early-type galaxies, such as mass M, luminosity L, Re, σ and Age. Two sets of sample, core sample and extended sample, are included. The core sample includes 258 ETGs (z < 0.011), which are adopted from the ATLAS3D project (Cappellari et al. 2011, 2013b). The extended sample includes 3,128 ETGs (0.01< z < 0.1), which are selected from 14,034 galaxies (Nair and Abraham 2010), a subset of SDSS Data Release 4 (DR4).

    The results show that the properties of ETGs can be well constrained by the ρ -VED vFP, which could construct surfaces of σRe, σRe/8, Vcirc, L, E/L and Age. The vFP can define the MDM –surface, which offers a good solution to estimate the DM masses within one Re of ETGs. Simultaneously, the obtained DM masses could transform the distribution of Mstar –surface and the Mtotal –surface from a random type to a flat type with small thicknesses. We also note that both the stellar mass and dark matter mass are significantly correlated with ETG ellipticity ε, if it is not ignored in the galaxy volume estimate. The connections are Mstar ~ Mtotal(1−ε)0.5 and MDM ~ Re Mtotal0.5 (1−ε)0.75. Our results also reveal that the more massive ETGs are, the lower their mass density, which means if an ETG grows via multiple -merging evolution and keeps the original masses of the mergers, its volume becomes larger than the sum of the individual volumes of the mergers. On the other hand, the mass-to-light ratio and the stellar-to-dynamical mass ratio also evolve during the lifetime of ETGs, as our obtained correlations suggest Mstar ⁄L ~ Age (1/0.93~0.96) and Mtotal ⁄L ~ Age (1/1.00~1.02).
    Keywords: ETGs, fundamental plane (FP), vFP, VED, galaxy properties, property surface

    ABSTRACT.................i ACKNOWLEDGEMENTS.........iii TABLE OF CONTENTS........iv LIST OF FIGURES..........v LIST OF TABLES...........vi CHAPTER 1: Introduction.........1 CHAPTER 2: Methods and samples....................6 2.1 Three-dimensional coordinate system for FPs...6 2.2 Virial Fundamental Plane......................7 2.3 Sample selection..............................11 CHAPTER 3: Results.....................................15 3.1 Core sample........................................16 (a) Velocity dispersion at one effective radius........16 (b) Velocity dispersion at one-eighth effective radius.20 (c) Circular velocity..................................22 (d) Remaj-surface, Mtotal-surface and MDM-surface......24 (e) L-surface, E/L-surface and Lx-surface..............26 (f) Appropriateness and application of E⁄L-surface.....29 3.2 Extended sample....................................31 (a) Estimating DM mass of each ETG of the extended sample .......................................................31 (b) Other property surfaces............................35 CHAPTER 4: Discussions......................40 4.1 From FP and MP to vFP...................40 4.2 The confinement of the Mstar –surface...41 4.3 The E/L -surface and its application....44 CHAPTER 5: Conclusions.......50 CHAPTER 6: Future work.......52 REFERENCES:..................53

    Auger, M., Treu, T., & Bolton, A., 2010, ApJ, 724, 511
    Bertin, G., Ciotti, L., & Del Principe, M., 2002, A&A, 386 1 149-168
    Blanton, M.R., Hogg, D. W., & NBahcall, . A., 2003, ApJ, 594:186–207
    Blanton, M.R., and Moustakas, J., 2009, ARAA, 47, 1, 159-210
    Blanton, M. R., Schlegel, D. J., & Strauss, M. A., et al. 2005, ApJ 129, 2562–2578
    Boroson, B., Kim, D. W., & Fabbiano G., 2011, ApJ, 729, 12
    Borriello A., Salucci P., & Danese L., 2003, MNRAS, 341, 1109
    Braun, E., and Dekel, A., 1989, ApJ 345:31-38
    Cappellari, M., 2016, Annu. Rev. Astron. Astrophys, 54:597–665
    Cappellari, M., Emsellem, E., & Krajnovi´c,D., et al. 2011, MNRAS 413, 813–836
    Cappellari, M., McDermid, R. M., & Alatalo, K., et al. 2012, Nature, 484, 485-488
    Cappellari, M., Scott, N., & Alatalo, K., et al. 2013a, MNRAS 432, 1709–1741
    Cappellari, M., McDermid, R., & Alatalo, K., et al. 2013b, MNRAS 432, 1862–1893
    Cappellari, M., http://www-astro.physics.ox.ac.uk/~mxc/software/
    Davies, R., Efstathiou, R., & Fall, M., et al, 1983, ApJ, 266, 41-57
    Deur, A., 2014, MNRAS 438, 1535–1551
    Djorgovski, S., 1986, IAU symposium 127, 79-90
    Djorgovski, S., Davis M., 1987, ApJ, 313, 59
    Djorgovski, S., Pahre, M., and Carvalho, R., 1996, ASP Conference Series, 86, 129-138
    D’Onofrio, M., Fasano, G., & Moretti, A., et al. 2013, MNRAS 435, 45–63
    Dressler, A., Lynden-Bell, D., & Burstein, D., et al. 1987, ApJ, 313, 42
    Gavrilovic, N., Mickaelian, A., & Petit, C., et al. 2006, Proceedings IAU Symposium, 238
    Graham, A., and Colless, M., 1997, MNRAS, 287, 221-239
    Graves, G. J., Faber, S. M., & Schiavon, R. P., 2009, ApJ, 698, 1590
    Hyde J. B., Bernardi M., 2009, MNRAS, 396, 1171
    Jorgensen I., Franx M., Kjaergaard P., 1996, MNRAS, 280, 167
    Kauffmann, G., Heckman, T. M., & White, S. D. M., et al. 2003, MNRAS 341, 33-53
    Kim, D., & Pellegrini, S., 2008, Hot Interstellar Matter in Elliptical Galaxies, 7-11
    Lima Neto, G., Gerbal, D., & M’arquez, I., 1999 MNRAS, 000, 2-17
    M´arquez1, M., Lima Neto, G., & Capelato, H., et al. 2001, A&A 379, 767–780
    Nair, P. B., & Abraham, R. G., 2010, ApJS, 186, 427-456
    Novak, G., Jonsson, P., Primack, J., et al. 2012, MNRAS, 424, 635–648
    O’Sullivan E., Forbes D. A., & Ponman T. J., 2001, MNRAS, 328, 461
    Pahre M. A., Djorgovski S. G., & de Carvalho R. R., 1998, ApJ, 116, 1591
    Poci1, A., Cappellari, M., & McDermid, R. M., 2017, MNRAS, 467, 1397
    Press W. H., Teukolsky S. A., Vetterling W. T., Flannery B. P., 2007, Numerical recipes: The Art of Scientific Computing, 3rd edn. Cambridge, Univ. Press, Cambridge
    Prugniel, Ph., & Simien F., 1997, A&A 321, 111–122
    Ravikumar, C., Barway, S., & Kembhavi, A., et al. 2006, A&A 446, 827–838
    Renzini A., Ciotti L., 1993, ApJ, 416, L49
    Sarzi, M., Alatalo, K., & Blitz, L., et al. 2013, MNRAS 432, 1845–1861
    Saulder, C., Mieske, S., and Zeilinger2, W., et al. 2013, A&A 557, A21
    Skrutskie M. F. et al., 2006, AJ, 131, 1163
    Tortora,C., Napolitano, N. R., & Romanowsky, A. J., et al. 2009, MNRAS 396, 1132–1150

    下載圖示
    QR CODE