Preface

The following set of papers describe in detail the science goals of the future Space Infrared telescope for Cosmology and Astrophysics (SPICA). The SPICA satellite will employ a 2.5-m telescope, actively cooled to around 6K, and a suite of mid- to far-IR spectrometers and photometric cameras, equipped with state of the art detectors. In particular, the SPICA Far-Infrared Instrument (SAFARI) will be a grating spectrograph with low (R = 300) and medium (R ≃ 3000–11000) resolution observing modes instantaneously covering the 35–230μm wavelength range. The SPICA Mid-Infrared instrument (SMI) will have three operating modes: a large field of view (12arcmin × 10 arcmin) low-resolution (LR) 17–36μm spectroscopic (R ~ 50–120) and photometric camera at 34μm, a medium resolution (R ≃ 2000) grating spectrometer covering wavelengths of 17–36μm, and a high-resolution echelle module (R ≃ 28000) for the 12–18μm domain. A large field of view (80arcsec × 80 arcsec), three channel (110, 220, and 350μm) polarimetric camera will also be part of the instrument complement. These articles will focus on some of the major scientific questions that the SPICA mission aims to address, more details about the mission and instruments can be found in Roelfsema et al. (Reference Roelfsema2017).

2.1. The assembly of galaxies

Current models of galaxy formation predict that galaxy discs form through accretion of matter in an inside-out growth, with a combination of inflow and outflow events regulating the process of metal enrichment (Fu et al. Reference Fu, Hou, Yin and Chang2009; Davé et al. Reference Davé, Finlator and Oppenheimer2012; Anglés-Alcázar et al. Reference Anglés-Alcázar, Davé, Özel and Oppenheimer2014). The accreted gas reaches higher densities in the interior of the galaxy, leading to higher star-formation rates and a faster reprocessing of gas, which results in higher metallicities in the bulge and in the inner part of discs. This is followed by a decreasing metallicity towards outer regions populated by younger stars formed from poorly enriched material (e.g. González Delgado et al. Reference González Delgado2015). While outflow activity is potentially capable of transferring the high abundance of metals to the halo or even the IGM (Oppenheimer & Davé Reference Oppenheimer and Davé2006), and subsequent inflows can further recycle them, observations have to be performed to ascertain the history of chemical evolution and the way in which outflows and inflows have shaped it (see also González-Alfonso et al. Reference González-Alfonso2017). Since the spatial distribution contain the imprint of gas inflow and outflow episodes throughout the lifetime of these galaxies, tracing the spatial gradients of heavy element abundances in present day galaxies provides a unique insight into their evolutionary history.

2.2. The evolution of metallicity in galaxies

The ISM of massive galaxies shows a higher content of heavy elements when compared to less massive ones, as was discovered early by Lequeux et al. (Reference Lequeux, Peimbert, Rayo, Serrano and Torres-Peimbert1979). Later, Mannucci et al. (Reference Mannucci, Cresci, Maiolino, Marconi and Gnerucci2010) and Lara-López et al. (Reference Lara-López2010) incorporated and additional dependency on the SFR required to describe the evolution of galaxies up to z ~ 3.7. Thus, the impact of the baryon cycle determines the relation among fundamental properties of galaxies such as the gas metallicity, the stellar mass, and the SFR. This is illustrated in Figure 1, where the mass–metallicity relation is obtained for galaxies in different bins of SFR (Andrews & Martini Reference Andrews and Martini2013). The metallicities in Figure 1 are based on the direct method, i.e. using the weak auroral lines to determine the gas temperature, the latter is one of the main uncertainties of the strong-line method based on the calibration of bright emission lines sensitive to the metallicity (e.g. Tremonti et al. Reference Tremonti2004, see Section 3 for further details). Thereafter, Bothwell et al. (Reference Bothwell, Maiolino, Kennicutt, Cresci, Mannucci, Marconi and Cicone2013) interpreted the dependence on the SFR as a by-product of the molecular gas content, via the Schmidt–Kennicutt relation (Schmidt Reference Schmidt1959; Kennicutt Reference Kennicutt1998). In this scenario, the chemical enrichment is driven by the increase of the specific SFR due to the larger disc gas fractions in galaxies at high-z (Bothwell et al. Reference Bothwell, Maiolino, Peng, Cicone, Griffith and Wagg2016a, Reference Bothwell, Maiolino, Cicone, Peng and Wagg2016b), and can be triggered by the accretion of pristine gas from the cosmic web and/or mergers with metal-poor companions (Hunt et al. Reference Hunt, Dayal, Magrini and Ferrara2016a, Reference Hunt, Dayal, Magrini and Ferrara2016b). On the other hand, outflows of enriched material dominate at low redshift, explaining the correlation with the stellar mass (e.g. Peeples & Shankar Reference Peeples and Shankar2011; Davé, Finlator, & Oppenheimer Reference Davé, Finlator and Oppenheimer2011; Somerville & Davé Reference Somerville and Davé2015).

Figure 1. The mass–metallicity relation determined from direct abundance measurements based on optical fine-structure lines for ~200000 star-forming galaxies selected from the Sloan Digital Sky Survey (0.027 < z < 0.25) grouped in different bins of SFR. The colour-coded circles correspond to stacks of galaxies for each bin in SFR (mean error is indicated in the lower right). The coloured solid lines show asymptotic logarithmic fits to this relation for each bin in SFR, and the black-solid line in the centre of the figure shows the global fit. These are compared with the mass–metallicity relation from Tremonti et al. (Reference Tremonti2004), based on the strong-line method (the solid, dashed, and dotted grey lines correspond to the median, 68 and 95% contour of the relation, respectively). Figure adapted from Andrews & Martini (Reference Andrews and Martini2013).

In the present-day picture, the relation between galaxy mass and gas metallicity is a by-product of the internal cycle of matter in galaxies during their evolution with cosmic time (Davé et al. Reference Davé, Finlator and Oppenheimer2012), and it is due to several reasons: (i) starburst wind outflows in low-mass galaxies eject the metal-enriched material to the halo and the IGM due to the shallow gravitational potential well, resulting in a less efficient enrichment compared to massive galaxies (Tremonti et al. Reference Tremonti2004); (ii) the ‘galaxy downsizing’ scenario, i.e. low-metallicity galaxies in the Local Universe are associated with a high specific SFR and are found in low-mass systems, which are still in an early evolutionary stage because they have converted only a small fraction of their gas mass into stars (e.g. Brooks et al. Reference Brooks, Governato, Booth, Willman, Gardner, Wadsley, Stinson and Quinn2007); (iii) dependence of the shape of the initial mass function (IMF) with the galaxy mass (Köppen, Weidner, & Kroupa Reference Köppen, Weidner and Kroupa2007); and (iv) infall of metal-poor gas from the halo and/or the IGM (Finlator & Davé Reference Finlator and Davé2008; Brooks et al. Reference Brooks, Governato, Quinn, Brook and Wadsley2009).

If the same physical processes are in place in the Local Universe and at high-z, then the chemical evolution of galaxies should be governed by a reduced number of fundamental properties. Diverse models of galaxy formation and evolution predict manifold evolutionary patterns of the mass–metallicity relation as a function of redshift. These patterns lead to different properties in the modelled galaxies such as the slope of the mass–metallicity relation and its scaling with redshift, scatter around the mass–metallicity relation due to fluctuations in the baryon cycle activity, and the mass fraction of atomic and molecular gas (e.g. Davé et al. Reference Davé, Rafieferantsoa, Thompson and Hopkins2017). So far, most of the models reproduce the growth of the stellar mass in galaxies over cosmic time, but the global content of heavy elements and the gas fraction are largely unconstrained. Therefore, observational data of galaxies from high-z to the Local Universe are required to test these properties, discriminate among the different cosmological simulations, and understand the physical processes driving the chemical evolution in galaxies.

2.3. The build-up of cosmic dust

Heavy elements produced in the baryon cycle are partially locked into dust grains, and constitute the solid-phase of the ISM (Draine Reference Draine2003; Peimbert & Peimbert Reference Peimbert and Peimbert2010). The dust has a strong influence on the observational properties of galaxies, with a main role in the heating and cooling processes (Spitzer Reference Spitzer1948; Borkowski & Harrington Reference Borkowski and Harrington1991; van Hoof et al. Reference van Hoof, Weingartner, Martin, Volk, Ferland, Ferland and Savin2001), and as catalyst of chemical processes in the ISM (e.g. the formation of H₂ driving the molecular chemistry). Dust grains absorb the UV light and re-radiate it in the IR, shielding the dense gas, and by these means triggering the formation of molecular clouds where new stars are born. The grain surfaces and the polycyclic aromatic hydrocarbons (PAHs) participate in a large number of chemical reaction networks in different phases of the ISM (Bakes & Tielens Reference Bakes and Tielens1998), and also provide photoelectric heating of gas in photo-dissociation regions (Draine Reference Draine2011; Bakes & Tielens Reference Bakes and Tielens1994). Moreover, dust cooling is able to alter the shape of the IMF by favouring the cloud fragmentation, thus inhibiting the formation of massive stars and fostering the creation of low-mass stars (Omukai et al. Reference Omukai, Tsuribe, Schneider and Ferrara2005). On the other hand, dust grains suffer from processing and destruction due to intense radiation fields, sputtering (impacts with gas ions), shattering (grain–grain collisions), shocks due to SNe explosions, astration into newly formed stars, and photo-processing by cosmic rays and UV/X-ray fields in the vicinity of AGN.

Little is known on the dust chemistry and its evolution over cosmic time. Even in the Milky Way and its neighbourhood, fundamental aspects in the astrochemistry of dust are not well understood: the dust composition in star-forming regions (Peimbert & Peimbert Reference Peimbert and Peimbert2010), the ISM (e.g. Nieva & Przybilla Reference Nieva and Przybilla2012), and planetary nebulae (PNe; Clegg & Harrington Reference Clegg and Harrington1989; Bernard-Salas et al. Reference Bernard-Salas, Peeters, Sloan, Gutenkunst, Matsuura, Tielens, Zijlstra and Houck2009b); the depletion of elements onto dust grains (e.g. Delgado Inglada et al. Reference Delgado Inglada, Rodríguez, Mampaso and Viironen2009; Simón-Díaz & Stasińska Reference Simón-Díaz and Stasińska2011); the dust-to-gas ratios, grain size distribution, and dust destruction (Mallik & Peimbert Reference Mallik and Peimbert1988; Stasińska & Szczerba Reference Stasińska and Szczerba1999; van Hoof et al. Reference van Hoof2013; Asano et al. Reference Asano, Takeuchi, Hirashita and Nozawa2013b); the physical mechanisms involved in the dust-phase catalysis within the ISM and subsequent enrichment of the gas phase (Dulieu et al. Reference Dulieu, Congiu, Noble, Baouche, Chaabouni, Moudens, Minissale and Cazaux2013). Nevertheless, the dust composition and its properties are critical ingredients to describe the evolution of galaxies (Rémy-Ruyer et al. Reference Rémy-Ruyer2014), while the uncertainties mentioned above escalate significantly for studies of galaxies at high-z (e.g. Popping, Somerville, & Galametz Reference Popping, Somerville and Galametz2017). Currently, models describing the chemical evolution in galaxies (e.g. Asano et al. Reference Asano, Takeuchi, Hirashita and Inoue2013a) rely on dust studies in local metal-poor dwarfs (e.g. Rémy-Ruyer et al. Reference Rémy-Ruyer2015), which are usually adopted as a benchmark case for the ISM in galaxies at high-z. However, there is firm observational evidence suggesting that the dust properties are not universal, e.g. chemical composition, gas-to-dust and dust-to-metal ratios, and grain size distribution (see Zhukovska et al. Reference Zhukovska, Dobbs, Jenkins and Klessen2016, and references therein). The characteristics of dust in the early Universe may be quite different from those seen in local metal-poor dwarfs, thus probing the dust properties in galaxies at high-z is the only way to constrain the solid phase of the ISM in chemical evolution models.

3.1. Why IR tracers?

The use of robust metallicity tracers almost independent of the dust extinction, radiation field, and of the gas density are crucial to study the chemical evolution of galaxies. For instance, the metallicity inferred from the dust content of high-z sub-millimetre galaxies (SMG), determined with Herschel far-IR photometry, is more than an order of magnitude higher when compared to gas metallicity measurements based on optical nebular lines (Santini et al. Reference Santini2010). This discrepancy is most probably caused by dust obscuration. Since SMG are compact and dust-rich, most of the ISM is optically thick at visual wavelengths. Thus, the optical nebular lines only probe the outer parts of the star-forming regions, which are probably hardly enriched with heavy elements.

Abundance determinations based on mid- and far-IR lines offer two great advantages when compared to those derived from UV and optical lines: (i) IR lines are almost free from dust extinction; and (ii) they have a small dependency on the electron temperature (e.g. Bernard Salas et al. Reference Bernard-Salas, Pottasch, Beintema and Wesselius2001). The latter could be the origin of a known discrepancy between optical and IR tracers, where IR-based abundances tend to be higher when compared to those obtained using optical tracers (see Vermeij & van der Hulst Reference Vermeij and van der Hulst2002; Dors et al. Reference Dors2013). A comprehensive explanation of this discordance is still lacking, and therefore there is not a consensus in the field on what tracer (optical or IR) is more reliable. However, a possible explanation is given in Dors et al. (Reference Dors2013): temperature variations within the nebula that not resolved spatially in the spectra—e.g. produced by spatial variations in the chemical abundances—can lead to a systematic underestimation of the abundances derived from optical lines using the direct method by a factor ≲ 4 (0.6dex). For instance, this is the case of integrated spectra in galaxies. If confirmed, this result implies that tracers based on IR lines can be much more accurate, since their dependency on the electron temperature is feeble. Unfortunately, there are few galaxies where both methods can be applied and compared. Sensitive IR observations with the SPICA observatory for a sample of galaxies with available optical metallicity estimates would be essential to shed light on this issue and develop new and reliable abundance tracers.

In the Local Universe, SPICA would have access to several ionic fine-structure lines in the rest-frame mid- and far-IR spectra of galaxies. Thus, abundance diagnostics for heavy elements will be mainly based on ratios of these lines, which can be calibrated using photoionisation models such as Cloudy (Ferland et al. Reference Ferland2017) and Mappings Footnote ² . The weak dependence with density can be easily constrained using density-sensitive ratios such as [Nii]_122μm to [Nii]_205μm, [Oiii]_52μm to [Oiii]_88μm, [Siii]_18.7μm to [Siii]_33.5μm, [Neiii]_15.6μm to [Neiii]_36.0μm, and [Nev]_14.3μm to [Nev]_24.3μm (Croxall et al. Reference Croxall2013). Furthermore, the hardness of the radiation field can also be constrained using the line ratios of [Niii]_57μm to [Nii]_{122, 205μm}, [Neiii]_15.6μm to [Neii]_12.8μm, and [Oiv]_25.9μm to [Oiii]_{52, 88μm}. On the other hand, the effects on the fine-structure lines produced by the combination of high far-IR optical depths and high ionisation parameters found in luminous and ultraluminous IR galaxies (LIRGs and ULIRGs, respectively; Graciá-Carpio et al. Reference Graciá-Carpio2011, Fischer et al. Reference Fischer, Abel, González-Alfonso, Dudley, Satyapal and van Hoof2014, González-Alfonso et al. Reference González-Alfonso2015) can also be calibrated with photoionisation models (e.g. Abel et al. Reference Abel, Dudley, Fischer, Satyapal and van Hoof2009, Graciá-Carpio et al. Reference Graciá-Carpio2011, Fischer et al. Reference Fischer, Abel, González-Alfonso, Dudley, Satyapal and van Hoof2014).

Besides the gas-phase abundances, a sensitive telescope in the mid- to far-IR range would be able to probe the composition of dust in galaxies at high-z through several solid-state features in the spectrum, such as forsterite (Mg₂SiO₄; 23, 33, 69μm), water ice at 44 and 62μm, MgS and FeS at ~ 30μm, FeO and SiO₂ at around 21μm, iron-bearing crystalline silicates at ~ 55μm (Koike et al. Reference Koike, Chihara, Tsuchiyama, Suto, Sogawa and Okuda2003), fullerenes (C₆₀ and C₇₀), and PAHs (see the companion paper by Kaneda et al. Reference Kaneda2017 in this issue).

So far, the use of IR tracers based on mid- to far-IR spectroscopic observations with Spitzer and Herschel to study the chemical evolution of galaxies was restricted only to very luminous sources, due to sensitivity issues (e.g. Ruiz et al. Reference Ruiz, Risaliti, Nardini, Panessa and Carrera2013; Brisbin et al. Reference Brisbin, Ferkinhoff, Nikola, Parshley, Stacey, Spoon, Hailey-Dunsheath and Verma2015). Future facilities planned for the next decade will not cover this key spectral range. Therefore, their study of the chemical evolution in galaxies will be limited to unobscured regions in galaxies, and will rely on tracers with a strong dependency on the gas temperature (see Section 5).

The unique sensitivity of an IR observatory with the characteristics of SPICA would enable the study of key processes in the baryon cycle that are hidden to optical wavelengths. A description of the SPICA spectrometers, SMI and SAFARI, is given in Roelfsema et al. (Reference Roelfsema2017). Figure 2 shows the predicted spectra for starburst galaxies and AGN out to z = 4, assuming the spectral characteristics of a local starburst galaxy, and an AGN. The simulated spectra in this figure are based on the ISO/SWS + LWS and Spitzer/IRS observations of the starburst galaxy M82 and the Seyfert 2 galaxy NGC 1068. These galaxies were selected due to the availability of high S/N ISO-SWS and -LWS spectra which, combined with the high-spectral resolution Spitzer/IRS observations, allowed us to build spectral templates with a wide coverage in wavelength from 10 to 250μm, similar to the rest-frame range that would be accessible to SPICA. The spectra of both galaxies were scaled to a luminosity of 2 × 10¹²L_⊙, and located at z = 1, 2, 3, and 4 (from top to bottom). The different observational modes of SMI and SAFARI would be sensitive enough to provide access to a unique suite of IR lines in the mid- to far-IR rest-frame spectra of starburst galaxies and AGN at the knee of the luminosity function up to z ~ 3.

Figure 2. Simulated spectra for a starburst galaxy (left) and an AGN (right) with a luminosity of 2 × 10¹²L_⊙ in the z = 1–4 range, assuming the spectral characteristics of M82 and NGC 1068, respectively, observed with ISO/SWS + LWS and Spitzer/IRS. The spectra are simulated at z = 1, 2, 3, and 4, from top to bottom. In each case, white noise was added to the spectra with an amplitude of $1 \sigma / \sqrt{t}$ , t being the exposure time assumed (indicated in the upper-left corner of each panel). Finally, the SMI and SAFARI spectral ranges were binned to the spectral resolution values indicated in each frame. The SPICA 5σ sensitivities for SMI (MR mode in blue, R ~ 1500; LR mode in red, R ~ 100) and SAFARI (in green, HR mode in the upper panels at z = 0.7; LR mode, R ~ 300, in the lower panels) are indicated for integration times of 1 h (dotted lines) and 10 h (solid lines). The Pfund-α would be detected in the 1.5 < z ≲ 3 range (see inset on the left panel at z = 3).

In the following sections, we will focus on the observational strategies that SPICA could implement to determine heavy element abundances of galaxies from high-z to the Local Universe. First, we will describe the direct abundance determinations in Section 3.2, followed by the indirect methods in Sections 3.3 and 3.4. The main diagnostics are summarised in Table 1.

Table 1. Direct (upper rows) and indirect (lower rows) metallicity tracers based on the mid- to far-IR lines that could be exploited by SPICA. In the table, ‘[X]’ refers to any of the fine-structure lines found in the range accessible to SPICA (e.g. [S iii]_18.7μm, [Ar ii]_6.99μm, [Ne ii]_12.8μm) whose corresponding ionic stage abundance can be determined from the flux ratio of the [X] line to any of the hydrogen recombination lines. The Huα line is relatively weak and thus is expected to be detected only in nearby galaxies (z ~ 0).

3.2. Direct abundance determinations

A direct determination for the abundances of the main ionic stages of several heavy elements could be obtained using ratios of IR fine-structure lines to hydrogen recombination lines. In the case of SPICA, this would be possible using Pfund-α—at 7.46μm in the rest frame—or Humphreys-α—Hi (7–6) or Huα at 12.37μm. At 1.5 < z ≲ 3, the medium-resolution mode (MR, R ~ 1500) of SMI would be able to cover simultaneously Pfund-α and the argon lines [Arii]_6.99μm and [Ariii]_8.99μm. For instance, Pfund-α could be detected by SMI/MR in a starburst galaxy with similar spectral characteristics to M82, scaled to 2 × 10¹²L_⊙, as shown by the inset in Figure 2 (left panel, at z = 3). Then, the gas metallicity could be estimated from the ratio of argon to hydrogen lines, since argon does not suffer from depletion (Verma et al. Reference Verma, Lutz, Sturm, Sternberg, Genzel and Vacca2003). Since the ionisation potentials of Ar⁰ and Ar²⁺ are 15.8eV (> 13.6eV) and 40.7eV (< 54.4eV), respectively, the presence of Ar⁰ and Ar³⁺ could be expected. In the case of neutral argon, observations of star-forming regions do not show a significant contribution from this species, suggesting that most of the argon in the nebula is ionised (e.g. Lebouteiller et al. Reference Lebouteiller, Kunth, Lequeux, Lecavelier des Etangs, Désert, Hébrard and Vidal-Madjar2004, Reference Lebouteiller, Kunth, Lequeux, Aloisi, Désert, Hébrard, Lecavelier Des Étangs and Vidal-Madjar2006). This could be explained by a high photoionisation cross-section in the neutral argon (Sofia & Jenkins Reference Sofia and Jenkins1998). On the other hand, Ar²⁺ has a relatively low photoionisation cross-section for energies below 70eV (Verner et al. Reference Verner, Ferland, Korista and Yakovlev1996), and thus Ar³⁺ has a minor contribution for most Hii regions (≲ 3%, e.g. Peimbert Reference Peimbert2003; Tsamis et al. Reference Tsamis, Barlow, Liu, Danziger and Storey2003; García-Rojas et al. Reference García-Rojas, Esteban, Peimbert, Costado, Rodríguez, Peimbert and Ruiz2006; Lebouteiller et al. Reference Lebouteiller, Bernard-Salas, Brandl, Whelan, Wu, Charmandaris, Devost and Houck2008), although this could increase significantly when exposed to harder radiation fields in low-metallicity environments (~20%, Peimbert, Peimbert, & Ruiz Reference Peimbert, Peimbert and Ruiz2000). Therefore, the total argon abundance could be derived using an ionisation correction factor to account for the contribution of Ar³⁺ (e.g. Vermeij & van der Hulst Reference Vermeij and van der Hulst2002; Pérez-Montero et al. Reference Pérez-Montero, Hägele, Contini and Díaz2007; Hägele et al. Reference Hägele, Díaz, Terlevich, Terlevich, Pérez-Montero and Cardaci2008).

In combination with the LR (R ~ 300) of SAFARI, it would be also possible to obtain a direct determination of the neon abundance for star-forming galaxies up to z ~ 3, based on the [Neii]_12.8μm and [Neiii]_15.6μm lines. Ne²⁺ has a high ionisation potential (63.5eV) above the helium absorption edge in stars (54.4eV), and consequently Ne³⁺ does not exist in significant amounts (Bernard-Salas et al. Reference Bernard-Salas2009a; Hägele et al. Reference Hägele, Díaz, Terlevich, Terlevich, Pérez-Montero and Cardaci2008; Dors et al. Reference Dors2013). At the lower end, neutral neon could exist within the Strömgren radius due to its relatively high ionisation potential (21.6eV). However, a further investigation using photoionisation models proved that the expected amount of Ne⁰ within the nebula is negligible, with an ionisation correction factor below ≲ 1.05 for a wide range of ionisation parameter values (Martín-Hernández et al. Reference Martín-Hernández2002). In the case of sulphur, a minor contribution of S⁴⁺ is expected due to the high ionisation potential of S³⁺ (47.3eV), however S⁺ has an ionisation potential of 23.3eV and thus it could be present in the nebula. Based on measurements of the sulphur abundance in nearby star-forming regions (Peimbert Reference Peimbert2003; Vermeij & van der Hulst Reference Vermeij and van der Hulst2002; García-Rojas et al. Reference García-Rojas, Esteban, Peimbert, Costado, Rodríguez, Peimbert and Ruiz2006) and photoionisation models (Tsamis & Péquignot Reference Tsamis and Péquignot2005), the expected amount of S⁺ is less than ~10% of the total sulphur abundance (Lebouteiller et al. Reference Lebouteiller, Bernard-Salas, Brandl, Whelan, Wu, Charmandaris, Devost and Houck2008; Bernard-Salas et al. Reference Bernard-Salas2009a). As in the case of argon, the gas-phase abundance of sulphur could be derived from the [Siii]_18.7μm and [Siv]_10.5μm lines and the hydrogen recombination lines detected by SMI and SAFARI, using a relatively small ionisation correction factor.

In nearby galaxies, direct abundances could be determined using the Huα line (e.g. Bernard-Salas et al. Reference Bernard-Salas2009a), covered by SMI at high-spectral resolution (HR, R ~ 28000). As mentioned earlier, the weak dependence of the IR lines with the density and the effect of the radiation field hardness could be constrained using the corresponding diagnostics based on ratios of mid- and far-IR lines (e.g. Croxall et al. Reference Croxall2013). Besides argon, neon, and sulphur, we would be able to provide abundances for the dominant ionic species of nitrogen (N⁺ and N²⁺) and help in the determination of direct abundances for oxygen (O⁰, O²⁺, and O³⁺), iron (Fe⁺ and Fe²⁺), and carbon (C⁺), based on the spectral range covered by SMI and SAFARI ([Nii]_122μm and [Niii]_57μm; [Oi]_{63, 145μm}, [Oiii]_{52, 88μm}, and [Oiv]_25.9μm; [Feii]_{17.9, 26.0μm} and [Feiii]_22.9μm; [Cii]_158μm).

3.3. The O₃N₃ index

One of the main IR diagnostics to measure the metallicity of galaxies is based on the ratio of the [Oiii]_{52, 88μm} to [Niii]_57μm lines. These are two key elements in the gas chemistry: oxygen is an alpha-capture primary element produced by massive stars, whereas nitrogen behaves as both a primary and a secondary nucleosynthetic element. As a result, the N/O relative abundance shows a dependence with the star-formation history of the galaxy, and the subsequent global metallicity (Liang et al. Reference Liang, Yin, Hammer, Deng, Flores and Zhang2006; Pilyugin, Grebel, & Kniazev Reference Pilyugin, Grebel and Kniazev2014; Vincenzo et al. Reference Vincenzo, Belfiore, Maiolino, Matteucci and Ventura2016), which could be determined by SPICA (Nagao et al. Reference Nagao, Maiolino, Marconi and Matsuhara2011; Pereira-Santaella et al. Reference Pereira-Santaella, Rigopoulou, Farrah, Lebouteiller and Li2017). O and N have similar ionisation potentials for their first five ionisation stages and, thus, both have very similar ionisation structures almost independent of the ionisation parameter and hardness of the radiation field. Therefore, although ratios of [Oiii] to [Niii] lines only trace the relative abundance of O²⁺ to N²⁺, this ratio serves as a very good proxy for the global N/O abundance ratio (see Pérez-Montero & Contini Reference Pérez-Montero and Contini2009 for a calibration using the optical [Nii]λ6584/[Oii]λ3727 line ratio. The [Oiii] lines at 52 and 88μm, whose ratio can be used as a density tracer for the ionised gas in the ~10²–10³cm⁻³ range, are combined to produce a tracer for the gas metallicity with a weak dependency on the density. This tracer is based on the ratio of (2.2 ×[Oiii]_88μm + [Oiii]_52μm) to [Niii]_57μm (hereafter the O₃N₃ index), as shown by the top panel in Figure 3, it can be applied to both starburst galaxies and AGN, almost unaffected by the temperature, the extinction, the density, and the hardness of the radiation field (for further details, see Pereira-Santaella et al. Reference Pereira-Santaella, Rigopoulou, Farrah, Lebouteiller and Li2017).

Figure 3. Top: AGN and starburst models for the metallicity sensitive (2.2 ×[Oiii]_88μm+[Oiii]_52μm)/[Niii]_57μm line ratio as a function of the gas-phase metallicity. For each metallicity bin, those models with the same ionisation parameter but different densities are grouped and their median ratio is indicated by a circle (square) for the starburst (AGN) models. The shaded area represents the scatter due to the gas density dependence of this ratio for a given ionisation parameter. Figure from Pereira-Santaella et al. (Reference Pereira-Santaella, Rigopoulou, Farrah, Lebouteiller and Li2017). Bottom: the ([Neii]_12.8μm + [Neiii]_15.6μm) to ([Siii]_18.7μm + [Siv]_10.5μm) line ratio (i.e. the Ne₂₃S₃₄ index) from Spitzer/IRS observations of starburst galaxies in the Local Universe vs. indirect gas-phase metallicity determined from strong optical lines (Moustakas et al. Reference Moustakas, Kennicutt, Tremonti, Dale, Smith and Calzetti2010; Pilyugin et al. Reference Pilyugin, Grebel and Kniazev2014). The Cloudy simulations including sulphur stagnation above Z > 1/5Z_⊙ are in agreement with the observed increase of the line ratio with increasing metallicity for Z ≳ 0.2Z_⊙ (figure adapted from Fernández-Ontiveros et al. Reference Fernández-Ontiveros, Spinoglio, Pereira-Santaella, Malkan, Andreani and Dasyra2016). Below ≲ 0.2Z_⊙, direct abundances can be estimated using, e.g. the ratio of [Arii]_6.99μm and [Ariii]_8.99μm to the Pfund-α line for galaxies at 1.5 < z ≲ 3 (see Section 3.2).

Gas metallicities can be determined using the diagnostic shown in Figure 3 up to z ~ 1.6, where the [Oiii]_88μm line would still fall within the spectral range of SAFARI (34–230μm). A diagnostic based on the [Oiii]_52μm/[Niii]_57μm ratio (see Nagao et al. Reference Nagao, Maiolino, Marconi and Matsuhara2011) is also a metallicity tracer up to z ~ 3 if the density is constrained through other line ratios, e.g. from the [Siii]_{18.7, 33.5μm} or the [Neiii]_{15.6, 36.0μm} lines. As shown in Figure 2, a telescope like SPICA would be sensitive enough to detect these lines in a few hours of observing time in typical starburst galaxies and AGN with luminosities close to the knee of the luminosity function at z ~ 3.

3.4. The Ne₂₃S₃₄ index

Above z ≳ 0.15 and 0.7, the [Siv]_10.5μm line would enter in the SMI/HR and MR ranges, respectively, enabling an additional indirect abundance diagnostic—based on the calibration of metallicity-sensitive line ratios—using the ([Neii]_12.8μm + [Neiii]_15.6μm) to ([Siii]_18.7μm + [Siv]_10.5μm) line ratio (hereafter the Ne₂₃S₃₄ index; lower panel in Figure 3; see Fernández-Ontiveros et al. Reference Fernández-Ontiveros, Spinoglio, Pereira-Santaella, Malkan, Andreani and Dasyra2016 for further details). The chemical species of Ne⁺ and Ne²⁺ on one hand, and S²⁺ and S³⁺ on the other, are the most important stages of ionisation for neon and sulphur, respectively, in starburst galaxies and AGN. However, the stagnation of the sulphur abundance, possibly caused by depletion of sulphur onto dust grains (Verma et al. Reference Verma, Lutz, Sturm, Sternberg, Genzel and Vacca2003; Dors et al. Reference Dors, Pérez-Montero, Hägele, Cardaci and Krabbe2016; Vidal et al. Reference Vidal, Loison, Jaziri, Ruaud, Gratier and Wakelam2017), prevent the rise of the sulphur line intensities with increasing metallicity. Thus, the total [Siv]_10.5μm + [Siii]_18.7μm remains almost constant, while the [Neiii]_15.6μm + [Neii]_12.8μm increases with the neon abundance, which is not depleted onto dust grains.

The bottom panel in Figure 3 shows a calibration of this metallicity sensitive ratio obtained from Spitzer/IRS spectra in the high-resolution mode (R ~ 600) vs. gas-metallicities obtained from indirect optical tracers for a sample of unobscured local starburst and dwarf galaxies (Moustakas et al. Reference Moustakas, Kennicutt, Tremonti, Dale, Smith and Calzetti2010, Pilyugin et al. Reference Pilyugin, Grebel and Kniazev2014). The blue shaded area corresponds to photoionisation models obtained with Cloudy simulations (Ferland et al. Reference Ferland2017) for a starburst galaxy, assuming a constant sulphur abundance above Z = 0.2Z_⊙, while the neon abundance increases linearly with the overall gas metallicity (see Fernández-Ontiveros et al. Reference Fernández-Ontiveros, Spinoglio, Pereira-Santaella, Malkan, Andreani and Dasyra2016 for a full description of these models). Both the theoretical predictions and the measurements of unobscured starburst and dwarf galaxies are in agreement, since the trend shown by the models with sulphur abundance stagnation reproduces the behaviour of the observed line ratios. Since [Neiii] and [Neii] are the most important stages of ionisation, the neon abundances determined with this method will be almost independent of ionisation correction factors.

All the lines used in this diagnostic would be covered by SMI and SAFARI for galaxies at 0.15 < z < 3. The weakest line in starburst galaxies with solar metallicities is [Siv]_10.5μm (left panel in Figure 2), although it is expected to become stronger with decreasing metallicity, as shown by the mid-IR spectra of low-metallicity dwarf galaxies in the Local Universe (e.g. Madden et al. Reference Madden, Galliano, Jones and Sauvage2006, Cormier et al. Reference Cormier2015). Therefore, high-z galaxies with sub-solar metallicities are expected to show stronger [Siv]_10.5μm relative to other mid-IR fine-structure lines when compared to the spectrum of the starburst galaxy in Figure 2. A different depletion pattern as that implied by Figure 3 is not expected at high-z, since the range of metallicities probed by this diagram covers the range of values expected for galaxies at z ≲ 4 (e.g. Davé et al. Reference Davé, Rafieferantsoa, Thompson and Hopkins2017). Still, this scenario could be explored using observations of the dust spectral features in the mid- to far-IR spectra of galaxies at high-z (see Section 4.3). At very low metallicities, studies based on galaxies in the Local Universe predict a constant N/O abundance ratio due to the primary origin of nitrogen in massive stars (van Zee, Salzer, & Haynes Reference van Zee, Salzer and Haynes1998), while sulphur does not show a significant abundance stagnation (Dors et al. Reference Dors, Pérez-Montero, Hägele, Cardaci and Krabbe2016). Thus, both indirect tracers O₃N₃ and Ne₂₃S₃₄ show a flat behaviour below ≲ 0.2Z_⊙ in Figure 3. SPICA would be able to probe if this scenario holds at high-z. For instance, enhanced N/O abundances have been reported at z ~ 2 with regard to those of Local galaxies at similar gas-phase metallicities, possibly due to the high specific SFR at high-z (see discussion in Masters et al. Reference Masters2014; Masters, Faisst, & Capak Reference Masters, Faisst and Capak2016). On the other hand, direct abundance estimates for several ionic species can be obtained for neon, sulphur, oxygen, nitrogen, iron, and carbon below 0.2Z_⊙ in galaxies at 1.5 < z ≲ 3, from ratios of the mid- and far-IR fine-structure lines of these elements to the Pfund-α line, covered by SMI/MR and SAFARI/LR (see Section 3.2; Figure 2).

4.1. The assembly of galaxies

The potential of an observatory like SPICA to provide high-sensitivity IR spectral mapping of galaxies in the Local Universe, able to peer into their most obscured regions, would play an essential role to understand how galaxies were assembled. In the low-resolution mode, SPICA would be an extremely efficient mapping machine, reaching line luminosity noise levels of a few 10⁻¹⁹Wm⁻² over a square arcmin in less than a minute of observing time and over the entire wavelength range. Moreover, the 2.5m mirror of SPICA would provide a diffraction-limited angular resolution of ~2 to 32 arcsec in the 20–350μm range, which corresponds to 100pc–1.5kpc at 10Mpc, respectively. For example, this angular resolution would be sufficient to resolve individual molecular clouds throughout galaxies in the Local Group (Milky Way, M31, M33, IC10, LMC, NGC 6822, SMC, and WLM, in order of decreasing metallicity). Metallicity determinations based on the O₃N₃ index could be obtained at ~7 arcsec resolution (~ 0.3kpc at 10Mpc), i.e. a fraction of about 1/100 of the diameter for a galaxy located at 10Mpc with the size of the Milky Way. SPICA would be able to map a typical nearby spiral galaxy (~ 25arcmin²) with both SMI and SAFARI at medium to high-spectral resolution in about ~20 h (see van der Tak et al. Reference van der Tak2017).

The sensitivity and efficiency of an observatory like SPICA would allow us to quickly map large areas of nearby objects at the diffraction limit of the 2.5-m mirror above ≳ 20μm. For instance, when compared with the Herschel/PACS spectral maps for NGC 891 (at 9.6Mpc Hughes et al. Reference Hughes2015), SPICA would provide (i) about 100 times better sensitivity, thus revealing the outer galaxy regions with lower surface brightness (~ 10⁻¹¹Wm⁻²sr⁻¹, 5σ, 1h. compared to ~ 5 × 10⁻⁹Wm⁻²sr⁻¹ for the [Oiii]_88μm line with PACS); (ii) better spatial sampling (~ 0.5kpc/pixel in PACS); and (iii) with a much larger efficiency to cover the full extension of NGC 891 (~ 7.7arcmin²) for the whole 12–230μm spectral range in about 8h. PACS measured small spectral windows centred on the [Oi]_{63, 145μm}, [Oiii]_88μm, [Nii]_122μm, and [Cii]_158μm lines, covering half of this galaxy in a total of ~12 h.

These capabilities would allow SPICA to trace the spatial distribution of heavy elements in ISM of nearby galaxies. The metal budget at different radii would be compared to the stellar metallicities, which can be derived from optical and near-IR spectroscopic studies (e.g. Coccato et al. Reference Coccato, Morelli, Pizzella, Corsini, Buson and Dalla Bontà2013; Belfiore, Maiolino, & Bothwell Reference Belfiore, Maiolino and Bothwell2016), and chemical evolution models. This approach would allow to estimate the average outflow loading factors over the galaxies lifetime—i.e. the ratio between the star formation and the mass outflow rates—which is an essential step to constrain the episodes of matter cycling, and ultimately to understand how nearby galaxies were assembled (see Belfiore et al. Reference Belfiore, Maiolino and Bothwell2016; González-Alfonso et al. Reference González-Alfonso2017). Therefore, a detailed study of the spatial distribution of heavy element abundances in nearby galaxies would be a unique probe of the past history in the evolution of these galaxies.

4.2. The evolution of metallicity in galaxies

SPICA would be able to trace the global content of metals in galaxies from z ~ 3 till the present time. To accomplish this, future studies based on SPICA observations would dispose of heavy element abundances for galaxies up to z ~ 3, obtained from tracers with a feeble response to both extinction and temperature; e.g. using direct measurements of the main ionic species based on ratios of IR fine-structure lines to Pfund-α or Huα and ionisation correction factors (see Section 3.2; Figure 2); and/or indirect methods based on ratios of strong IR fine-structure lines such as those involved in the O₃N₃ and the Ne₂₃S₃₄ indices (Sections 3.3 and 3.4, respectively; Figure 3). A spectroscopic survey designed to observe thousands of galaxies at z < 3—e.g. covering a wide range in luminosity, galaxy type—would allow to obtain a statistically valid assessment of the metallicity evolution in galaxies. SPICA would be able to accomplish such a survey in ~4000 h of observing time.

Once the metallicities are measured using IR tracers, a global view of the baryon cycle could be derived by including the two remaining ingredients, i.e. the stellar mass and the total gas content of these galaxies. The latter would rely mainly on future and present facilities. For instance, the stellar mass can be obtained from near- and mid-IR photometric surveys available nowadays (e.g. with AKARI, Ishihara et al. Reference Ishihara2010; WISE, Wright et al. Reference Wright2010; Spitzer, Ashby et al. Reference Ashby2013), plus future catalogues assembled by the extremely large telescopes (ELTs)—the European-ELTFootnote ³ , the Thirty Meter Telescope (Sanders Reference Sanders2013), and the Giant Magellan Telescope (Shectman & Johns Reference Shectman, Johns, Stepp, Gilmozzi and Hall2010), Euclid (Maciaszek et al. Reference Maciaszek, MacEwen, Fazio, Lystrup, Batalha, Siegler and Tong2016), the Wide Field Infrared Survey Telescope (WFIRST; Spergel et al. Reference Spergel2013), and available James Webb Space Telescope (JWST; Gardner et al. Reference Gardner2006) observations at the time. On the other hand, the molecular gas content can be derived from follow-up observations of these sources with the Atacama Large Millimeter/submillimeter Array (ALMA; Wootten & Thompson Reference Wootten and Thompson2009) and the NOrthern Extended Millimeter Array (NOEMAFootnote ⁴ ) in the CO and [Ci]_{371, 609μm} transitions, assuming a conversion factorFootnote ⁵ from CO or Ci to H₂ (e.g. Papadopoulos & Greve Reference Papadopoulos and Greve2004). Alternatively, a proxy for the molecular gas content could be inferred from the SPICA spectra using IR transitions sensitive to the SFR such as the neon lines (Ho & Keto Reference Ho and Keto2007), or from the modelling of the 24–60μm rest-frame continuum which is also sensitive to the SFR (Ciesla et al. Reference Ciesla2014; van der Tak et al. Reference van der Tak2017). To remove the possible AGN contamination, the relative AGN/starburst contribution could be derived from the ratio of [Oiv]_25.9μm to either [Oiii]_{52, 88μm} or the total [Neii]_12.8μm + [Neiii]_15.6μm (Spinoglio et al. Reference Spinoglio, Pereira-Santaella, Dasyra, Calzoletti, Malkan, Tommasin and Busquet2015; Fernández-Ontiveros et al. Reference Fernández-Ontiveros, Spinoglio, Pereira-Santaella, Malkan, Andreani and Dasyra2016). Finally, the atomic gas content could be estimated from observations in the Hi line, e.g. using the Square Kilometer Array (SKA; Dewdney et al. Reference Dewdney, Hall, Schilizzi and Lazio2009), which will be already operational by the mid-2020s, though fully developed at the end of the decade.

4.3. The build-up of cosmic dust

The unique sensitivity of a cryogenic telescope with the characteristics of SPICA would enable the study of the dust composition based on several spectral features in the mid- to far-IR range (Section 3.1; van der Tak et al. Reference van der Tak2017), largely improving the work based on Spitzer and Herschel spectroscopic observations (e.g. Spoon et al. Reference Spoon2006; Matsuura et al. Reference Matsuura2015). A whole new suite of solid-state features can be used to investigate the main sources of dust in the ISM of galaxies at high-z. Among the different sources that contribute to the dust reservoir in galaxies one can find: evolved stars, producing crystalline silicates (Molster et al. Reference Molster1999; Molster, Waters, & Tielens Reference Molster, Waters and Tielens2002), dolomite and calcite (Kemper et al. Reference Kemper, Jäger, Waters, Henning, Molster, Barlow, Lim and de Koter2002), and complex carbon molecules such as C₆₀ and C₇₀ (Cami et al. Reference Cami, Bernard-Salas, Peeters and Malek2010); post-AGB stars show a rich IR spectrum, as shown by Matsuura et al. (Reference Matsuura2014), with features at 15.8 and 21μm (associated with PAHs), and 30μm (ascribed to MgS); supernovae remnants (SNR) may also be a significant source of dust at high-z, e.g. Cassiopeia A shows a prominent 21μm feature associated with FeO and possibly SiO₂ (Rho et al. Reference Rho2008).

In nearby galaxies, medium and high-resolution spectroscopy with SMI and SAFARI would be able to resolve the emission of SNR from the surrounding ISM at ~ 1Mpc (assuming a SNR size of ~ 60pc; Elwood, Murphy, & Diaz Reference Elwood, Murphy and Diaz2017) and investigate the properties and composition of the surviving dust after the pass of the reverse shock. Only far-IR follow-up observations of SNR in the Local Universe can probe the dust composition and size distribution produced by these sources. Specifically, future observations of SN 1987A would be of particular interest to constrain current models of dust condensation efficiency after the passage of the reverse shock. A detailed discussion on the role of SPICA in the study of dust properties in nearby galaxies can be found in the companion paper by van der Tak et al. (Reference van der Tak2017).

Focusing on studies at high-z, a cryogenic IR observatory like SPICA would be sensitive enough to distinguish among different shapes in the rest-frame mid-IR spectrum of galaxies associated with differences in the chemical composition of dust. The predicted shape of the mid- to far-IR spectra for three quasars with different dust compositions, from the results of Xie et al. (Reference Xie, Li and Hao2017), are shown in Figure 4 scaled to a luminosity of 2 × 10¹²L_⊙. The dust composition determines the central wavelength, width, and relative intensity of the two silicate bands at 9.7 and 18μm. Thus, a detailed modelling of the continuum emission and the dust emission and absorption features in this range is able to probe the dust composition (e.g. Spoon et al. Reference Spoon2006). The quasar spectra shown in Figure 4 are dominated by astronomical silicate (PG 1004+130, in red), amorphous olivine (PG 1351+640, in yellow), and amorphous pyroxene (PG 2214+139, in pink). Therefore, the access to dust features in the rest-frame mid- to far-IR range with SPICA would allow us to explore, for the first time, the composition of dust in galaxies at the peak of the star formation and SMBH accretion activity (1 < z < 3). At farther distances, z ≳ 4, very little is known on the dust produced by metal-free SNe (Nozawa et al. Reference Nozawa, Kozasa, Umeda, Maeda and Nomoto2003; Schneider, Ferrara, & Salvaterra Reference Schneider, Ferrara and Salvaterra2004), which could be investigated through mid-IR bands such as those produced by magnetite (Fe₃O₄), as discussed in a forthcoming study by Egami et al. (in preparation).

Figure 4. Differences in the Spitzer/IRS spectrum of three quasars associated to different silicate compositions (see Xie, Li, & Hao Reference Xie, Li and Hao2017): PG 1004+130 (astronomical silicate, in red colour), PG 1351+640 (amorphous olivine, in yellow), and PG 2214+139 (amorphous pyroxene, in pink). In this simulation, the spectra have been scaled to a luminosity of 10¹²L_⊙, and located at z = 2 (top panel, 2 h of integration time), z = 3 (central panel, 8 h), and z = 4 (bottom panel). The SPICA 5σ sensitivities for SMI/MR (in blue) and SAFARI/LR (in green) are indicated for integration times of 1 h (dotted lines) and 10 h (solid lines).

Finally, other agents involved in the baryon cycle can have a strong influence in the dust content and composition. For instance, outflows originated by AGN and star-formation activity can remove dust from the ISM, while inflows from the halo and the IGM surrounding the galaxy can alter the dust content and composition (Ciesla et al. Reference Ciesla2015; González-Alfonso et al. Reference González-Alfonso2017). Only an IR observatory with the characteristics of SPICA could determine the impact of these processes in the ISM chemistry.