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Sains Malaysiana 51(9)(2022):
http://doi.org/10.17576/jsm-2022-5109-25
Star Formation Rates for Elliptical
Galaxies Derived from the WISE 12- and 22- µm Emission
(Kadar Penghasilan Bintang untuk Terbitan Galaksi Elips Terbitan daripada Gelombang 12- dan 22- µm
WISE)
NUR HIDAYAH MOHD ALI1, ZAMRI
ZAINAL ABIDIN1,* & CHORNG-YUAN HWANG2
1Physics
Department, Universiti Malaya, 50603 Kuala Lumpur, Federal Territory,
Malaysia
2Graduate
Institute of Astronomy, National Central University, Zhong-Li, Taoyuan
32001,
Taiwan
Diserahkan: 13 Februari 2022/Diterima: 22 April 2022
Abstract
We investigated the star formation rates (SFRs) of
selected elliptical galaxies using the infrared data from the Wide-field
Infrared Survey Explorer (WISE). The elliptical galaxies were selected from the Sloan Digital Sky Survey (SDSS) MPA-JHU catalog and morphology classified by Galaxy Zoo catalog. We used the 3.4-µm emission (W1) of WISE to
represent the stellar mass of the galaxies and the 12- and 22-µm emission (W3
and W4) of WISE to represent the star formation activity of the galaxies. The
W3- and W4-based star formation rates are usually overestimated due to the star
emission in low star-forming galaxies. Stellar continuum emission could
contribute to MIR fluxes of elliptical galaxies with an average overestimation
of ~ 13.95 and ~ 0.77% from the observed fluxes of WISE W3 and W4-bands, which
determined by using the estimated WISE W3 and W4 flux correction factors.
Better SFRs can be obtained by subtracting the stellar contribution of the
sources. Our result highlights the possibility of the existence of unknown
mechanisms triggering the continuous star formation activities in elliptical
galaxies.
Keywords: Galaxies; IR sources; star formation
Abstrak
Kami mengkaji kadar penghasilan bintang dalam galaksi elips terpilih menggunakan data inframerah daripada Wide-field Infrared Survey Explorer (WISE). Galaksi dipilih daripada katalog Sloan Digital
Sky Survey (SDSS) MPA-JHU dan disaring mengikut bentuk berdasarkan katalog Galaxy Zoo. Gelombang 3.4-µm (W1) daripada WISE digunakan bagi mewakili jisim bintang galaksi dan gelombang 12- and 22-µm (W3 dan W4) mewakili aktiviti penghasilan bintang. Kadar penghasilan bintang berdasarkan W3 dan W4 seringkali dianggarkan lebih tinggi disebabkan isyarat daripada bintang dalam galaksi yang kadar penghasilan bintangnya adalah rendah. Purata lebihan anggaran daripada WISE W3 adalah ~ 13.95
dan W4 adalah ~ 0.77% bagi galaksi elips, diukur berdasarkan agnggaran daripada faktor pembetulan untuk WISE W3 dan W4. Kadar penghasilan binatang yang lebih tepat diperoleh dengan menolak sumbangan daripada bintang tersebut. Keputusan kami menunjukkan bahawa tidak mustahil wujudnya satu mekanisme yang menghasilkan bintang secara berterusan dalam galaksi elips.
Kata kunci: Galaksi; pembentukan bintang; punca inframerah
RUJUKAN
Baldwin, J.A., Phillips,
M.M. & Terlevich, R. 1981. Classification
parameters for the emission-line spectra of extragalactic objects. Publications
of the Astronomical Society of the Pacific 93(551): 5.
Balogh, M.L., Morris, S.L.,
Yee, H.K.C., Carlberg, R.G. & Ellingson, E. 1999. Differential galaxy
evolution in cluster and field galaxies at z≈0.3. The Astrophysical
Journal 527(1): 54.
Boselli, A., Sauvage, M., Lequeux, J., Donati, A. & Gavazzi, G. 2003. Mid-IR emission of
galaxies in the Virgo cluster III. The data. Astronomy & Astrophysics 406(3): 867-877.
Bressan, A., Granato, G.L. &
Silva, L. 1998. Modelling intermediate age and old stellar populations in the
infrared. Astronomy and Astrophysics 332: 135-148.
Brinchmann, J., Charlot, S., White,
S.D.M., Tremonti, C., Kauffman, G., Heckman, T. &
Brinkmann, J. 2004. The physical
properties of star-forming galaxies in the low-redshift Universe. Monthly
Notices of the Royal Astronomical Society 351(4): 1151-1179.
Caccianiga, A., Antón, S., Ballo, L.,
Foschini, L., Maccacaro, T., Ceca, R.D., Severgnini, P., Marchã, M.J., Mateos, S. & Sani, E. 2015. WISE colours and star
formation in the host galaxies of radio-loud narrow-line Seyfert 1. Monthly Notices of the Royal Astronomical Society 451(2): 1795-1805.
Calzetti, D., Kennicutt, R.C., Engelbracht, C.W., Leitherer, C., Draine, B.T., Kewley, L.,
Moustakas, J., Sosey, M., Dale, D.A., Gordon, K.D.
& Helou, G.X. 2007. The calibration of
mid-infrared star formation rate indicators. The Astrophysical Journal 666(2): 870.
Calzetti, D., Kennicutt Jr., R.C.,
Bianchi, L., Thilker, D.A., Dale, D.A., Engelbracht, C.W., Leitherer, C.,
Meyer, M.J., Sosey, M.L., Mutchler, M. & Regan,
M.W. 2005. Star formation in NGC 5194 (M51a): The panchromatic view from GALEX
to Spitzer. The Astrophysical Journal 633(2): 871.
Chang, Y., van der Wel, A., da Cunha, E. & Rix, H. 2015. Stellar masses
and star formation rates for 1 m galaxies from sdss+
wise. The Astrophysical Journal Supplement Series 219(1): 8.
Condon, J.J. 1992. Radio
emission from normal galaxies. Annual Review of Astronomy and Astrophysics 30(1): 575-611.
Contursi, A., Lequeux, J. & Cesatsky, C. 2000. Mid-infrared imaging and
spectrophotometry of N 66 in the SMC with ISOCAM. Astronomy and Astrophysics 362: 310-324.
Da Cunha, E., Charlot, S. & Elbaz, D. 2008. A simple model to
interpret the ultraviolet, optical and infrared emission from galaxies. Monthly
Notices of the Royal Astronomical Society 388(4): 1595-1617.
Davis, T.A., Young, L.M.,
Crocker, A.F., Bureau, M., Blitz, L., Alatalo, K., Emsellem, E., Naab, T., Bayet,
E., Bois, M. & Bournaud, F. 2014. The ATLAS3D
Project–XXVIII. Dynamically driven star formation suppression in early-type
galaxies. Monthly Notices of the Royal Astronomical Society 444(4):
3427-3445.
Donoso, E., Yan, L., Tsai, C., Eisenhardt, P., Stern, D.,
Assef, R.J., Leisawitz, D., Jarrett, T.H. &
Stanford, S.A. 2012. Origin of 12 μm emission
across galaxy populations from WISE and SDSS surveys. The Astrophysical
Journal 748(2): 80.
Draine, B.T. & Li, A. 2007. Infrared emission from
interstellar dust. IV. The silicate-graphite-PAH model in the post-Spitzer era. The Astrophysical Journal 657(2): 810.
Hayward, C.C., Lanz, L., Ashby, M.L.N., Fazio, G., Hernquist,
L., Martínez-Galarza, J.R., Noeske, K., Smith, H.A., Wuyts, S. & Zezas, A. 2014.
The total infrared luminosity may significantly overestimate the star formation
rate of quenching and recently quenched galaxies. Monthly Notices of the
Royal Astronomical Society 445(2): 1598-1604.
Helou, G., Roussel, H., Appleton, P., Frayer, D., Stolovy, S., Storrie-Lombardi,
L., Hurt, R., Lowrance, P., Makovoz, D., Masci, F. & Surace, J. 2004.
The anatomy of star formation in NGC 300. The Astrophysical Journal
Supplement Series 154(1): 253.
Jarrett, T.H., Masci, F., Tsai, C.W., Petty, S., Cluver,
M.E., Assef, R.J., Benford, D., Blain, A., Bridge,
C., Donoso, E. & Eisenhardt, P. 2012. Extending
the nearby galaxy heritage with wise: First results from the wise enhanced
resolution galaxy atlas. The Astronomical Journal 145(1): 6.
Kauffmann, G., Heckman,
T.M., White, S.D., Charlot, S., Tremonti,
C., Peng, E.W., Seibert, M., Brinkmann, J., Nichol, R.C., SubbaRao,
M. & York, D. 2003. The dependence of star formation history and internal
structure on stellar mass for 105 low-redshift galaxies. Monthly Notices of
the Royal Astronomical Society 341(1): 54-69.
Kennicutt, R.C. 1998. The global Schmidt law in star-forming
galaxies. The Astrophysical Journal 498(2): 541.
Kennicutt, R.C. & Evans, N.J. 2012. Star formation in the
milky way and nearby galaxies. Annual Review of Astronomy and Astrophysics 50: 531-608.
Kennicutt, R.C. & Kent, S.M. 1983. A survey of H-alpha
emission in normal galaxies. The Astronomical Journal 88: 1094-1107.
Lee, J.C., Ho, S.H. &
Ko, J. 2013. The calibration of star formation rate indicators for WISE 22 μm-selected galaxies in the Sloan Digital Sky Survey. The
Astrophysical Journal 774(1): 62.
Li, A. & Draine, B.T. 2001. Infrared emission from interstellar
dust. II. The diffuse interstellar medium. The Astrophysical Journal 554(2): 778.
Lintott, C.J., Schawinski, K., Slosar, A., Land,
K., Bamford, S., Thomas, D., Raddick, M.J., Nichol,
R.C., Szalay, A., Andreescu,
D. & Murray, P. 2008. Galaxy zoo: Morphologies derived from visual
inspection of galaxies from the Sloan Digital Sky Survey. Monthly Notices of
the Royal Astronomical Society 389(3): 1179-1189.
Lintott, C., Schawinski, K., Bamford, S., Slosar,
A., Land, K., Thomas, D., Edmondson, E., Masters, K., Nichol, R.C., Raddick, M.J. & Szalay, A.
2011. Galaxy Zoo 1: Data release of morphological classifications for nearly
900 000 galaxies. Monthly Notices of the Royal Astronomical Society 410(1): 166-178.
Mullaney, J.R., Alexander, D.M., Goulding, A.D. & Hickox, R.C. 2011. Defining the intrinsic AGN infrared spectral energy distribution and measuring its contribution to the infrared output of composite galaxies. Monthly Notices of the Royal Astronomical Society 414(2): 1082-1110. Murphy, E.J., Chary, R.R., Dickinson, M., Pope, A., Frayer, D.T. & Lin, L. 2011. An accounting of the dust-obscured star formation and accretion histories over the last∼ 11 billion
years. The Astrophysical Journal 732(2): 126.
Netzer, H., Lutz, D., Schweitzer, M., Contursi,
A., Sturm, E., Tacconi, L.J., Veilleux, S., Kim,
D.C., Rupke, D., Baker, A.J. & Dasyra, K. 2007. Spitzer quasar and ULIRG evolution study
(QUEST). II. The spectral energy distributions of palomar-green
quasars. The Astrophysical Journal 666(2): 806.
Panuzzo, P., Rampazzo, R., Bressan, A., Vega, O., Annibali,
F., Buson, L.M., Clemens, M.S. & Zeilinger,
W.W. 2011. Nearby early-type galaxies with ionized gas-VI. The Spitzer-IRS
view. Basic data set analysis and empirical spectral classification. Astronomy
& Astrophysics 528: A10.
Piovan, L., Tantalo, R. & Chiosi, C. 2003. Shells of dust around AGB stars: Effects
on the integrated spectrum of single stellar populations. Astronomy &
Astrophysics 408(2): 559-579.
Rieke, G.H.,
Alonso-Herrero, Weiner, B.J., Pérez-González, P.G., Blaylock, M., Donley, J.L.
& Marcillac, D. 2009. Determining star formation
rates for infrared galaxies. The Astrophysical Journal 692(1): 556.
Schreiber, N.M.F., Roussel,
H., Sauvage, M. & Charmandaris,
V. 2004. Warm dust and aromatic bands as quantitative probes of star-formation
activity. Astronomy & Astrophysics 419(2): 501-516.
Schmitt, H.R., Calzetti, D., Armus, L., Giavalisco, M., Heckman, T.M., Kennicutt,
R.C., Leitherer, C. & Meurer,
G.R. 2006. Ultraviolet-to-far-infrared properties of local star-forming
galaxies. The Astrophysical Journal 643(1): 173.
Shi, F., Kong, X., Wicker,
J., Chen, Y., Gong, Z.Q. & Fan, D.X. 2012. Star formation rate indicators
in Wide-Field Infrared Survey preliminary release. Journal of Astrophysics
and Astronomy 33(2): 213-220.
Simonian, G.V. &
Martini, P. 2017. Circumstellar dust, PAHs and stellar populations in
early-type galaxies: Insights from GALEX and WISE. Monthly Notices of the
Royal Astronomical Society 464(4): 3920-3936.
Smith, J.D.T., Draine, B.T., Dale, D.A., Moustakas, J., Kennicutt Jr., R.C., Helou, G., Armus, L., Roussel, H., Sheth,
K., Bendo, G.J. & Buckalew,
B.A. 2007. The mid-infrared spectrum of star-forming galaxies: Global
properties of polycyclic aromatic hydrocarbon emission. The Astrophysical
Journal 656(2): 770.
Stern, D., Eisenhardt, P., Gorjian, V., Kochanek, C.S.,
Caldwell, N., Eisenstein, D., Brodwin, M., Brown, M.J., Cool, R., Dey, A. &
Green, P. 2005. Mid-infrared selection of active galaxies. The Astrophysical
Journal 631(1): 163.
Temi, P., Brighenti, F. &
Mathews, W.G. 2007. Far-infrared spitzer observations of elliptical galaxies:
Evidence for extended diffuse dust. The Astrophysical Journal 660(2):
1215.
Tremonti, C.A., Heckman, T.M., Kauffmann, G., Brinchmann, J., Charlot, S.,
White, S.D., Seibert, M., Peng, E.W., Schlegel, D.J., Uomoto,
A. & Fukugita, M. 2004. The origin of the
mass-metallicity relation: Insights from 53,000 star-forming galaxies in the
Sloan Digital Sky Survey. The Astrophysical Journal 613(2): 898.
Villaume, A., Conroy, C.
& Johnson, B.D. 2015. Circumstellar dust around AGB stars and implications
for infrared emission from galaxies. The Astrophysical Journal 806(1):
82.
Westra, E., Geller, M.J., Kurtz, M.J., Fabricant, D.G. & Dell'Antonio, I. 2009. Evolution of the Hα
luminosity function. The Astrophysical Journal 708(1): 534.
Wright, E.L., Eisenhardt,
P.R., Mainzer, A.K., Ressler, M.E., Cutri, R.M., Jarrett, T., Kirkpatrick, J.D., Padgett, D.,
McMillan, R.S., Skrutskie, M. & Stanford, S.A.
2010. The Wide-Field Infrared Survey Explorer (WISE): Mission description and
initial on-orbit performance. The Astronomical Journal 140(6): 1868.
Wu, H., Cao, C., Hao, C.,
Liu, F., Wang, J., Xia, X., Deng, Z. & Young, C.K. 2005. PAH and
mid-infrared luminosities as measures of star formation rate in Spitzer first
look survey galaxies. The Astrophysical Journal Letters 632(2): L79.
Zaritsky, D., Zabludoff, A.I. & Willick, J.A. 1995. Spectral classification of galaxies
along the hubble sequence. Astronomical Journal 110: 1602.
Zhu, Y., Wu, H., Cao, C. & Li, H. 2008. Correlations between mid-infrared, far-infrared, Hα, and FUV luminosities for Spitzer SWIRE field galaxies. The Astrophysical Journal 686(1): 155.
*Corresponding author email: zzaa@um.edu.my
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