No Arabic abstract
We present a rest-frame UV-optical stacked spectrum representative of quiescent galaxies at $1.0 < z < 1.3$ with log$(M_*/rm{M_odot}) > 10.8$. The stack is constructed using VANDELS survey data, combined with new KMOS observations. We apply two independent full-spectral-fitting approaches, obtaining consistent stellar ages and metallicities. We measure a total metallicity, [Z/H] = $-0.13pm0.08$, and an iron abundance, [Fe/H] = $-0.18pm0.08$, representing falls of $sim0.3$ dex and $sim0.15$ dex respectively compared with the local Universe. We also measure the alpha enhancement via the magnesium abundance, obtaining [Mg/Fe] = 0.23$pm$0.12, consistent with similar-mass galaxies in the local Universe, indicating no evolution in the average alpha enhancement of log$(M_*/rm{M_odot}) sim 11$ quiescent galaxies over the last 8 Gyr. This suggests the very high alpha enhancements recently reported for several very bright $zsim1-2$ quiescent galaxies are due to their extreme masses, in accordance with the well-known downsizing trend, rather than being typical of the $zgtrsim1$ population. The metallicity evolution we observe with redshift (falling [Z/H], [Fe/H], but constant [Mg/Fe]) is consistent with recent studies. We recover a mean stellar age of $2.5^{+0.6}_{-0.4}$ Gyr, corresponding to a formation redshift, $z_rm{form} = 2.4^{+0.6}_{-0.3}$. Recent studies have obtained varying average formation redshifts for $zgtrsim1$ massive quiescent galaxies, and, as these studies report consistent metallicities, we identify different star-formation-history models as the most likely cause. Larger spectroscopic samples from upcoming ground-based instruments will provide precise constraints on ages and metallicities at $zgtrsim1$. Combining these with precise $z>2$ quiescent-galaxy stellar-mass functions from JWST will provide an independent test of formation redshifts from spectral fitting.
We present a Bayesian full-spectral-fitting analysis of 75 massive ($M_* > 10^{10.3} M_odot$) UVJ-selected galaxies at redshifts of $1.0 < z < 1.3$, combining extremely deep rest-frame ultraviolet spectroscopy from VANDELS with multi-wavelength photometry. By the use of a sophisticated physical plus systematic uncertainties model, constructed within the Bagpipes code, we place strong constraints on the star-formation histories (SFHs) of individual objects. We firstly constrain the stellar mass vs stellar age relationship, finding a steep trend towards earlier average formation with increasing stellar mass of $1.48^{+0.34}_{-0.39}$ Gyr per decade in mass, although this shows signs of flattening at $M_* > 10^{11} M_odot$. We show that this is consistent with other spectroscopic studies from $0 < z < 2$. This relationship places strong constraints on the AGN-feedback models used in cosmological simulations. We demonstrate that, although the relationships predicted by Simba and IllustrisTNG agree well with observations at $z=0.1$, they are too shallow at $z=1$, predicting an evolution of $<0.5$ Gyr per decade in mass. Secondly, we consider the connections between green-valley, post-starburst and quiescent galaxies, using our inferred SFH shapes and the distributions of galaxy physical properties on the UVJ diagram. The majority of our lowest-mass galaxies ($M_* sim 10^{10.5} M_odot$) are consistent with formation in recent ($z<2$), intense starburst events, with timescales of $lesssim500$ Myr. A second class of objects experience extended star-formation epochs before rapidly quenching, passing through both green-valley and post-starburst phases. The most massive galaxies in our sample are extreme systems: already old by $z=1$, they formed at $zsim5$ and quenched by $z=3$. However, we find evidence for their continued evolution through both AGN and rejuvenated star-formation activity.
We present the results of a study utilising ultra-deep, rest-frame UV, spectroscopy to quantify the relationship between stellar mass and stellar metallicity for 681 star-forming galaxies at $2.5<z<5.0$ ($langle z rangle = 3.5 pm 0.6$) drawn from the VANDELS survey. Via a comparison with high-resolution stellar population models, we determine stellar metallicities for a set of composite spectra formed from subsamples selected by mass and redshift. Across the stellar mass range $8.5 < mathrm{log}(langle M_{ast} rangle/rm{M}_{odot}) < 10.2$ we find a strong correlation between stellar metallicity and stellar mass, with stellar metallicity monotonically increasing from $Z_{ast}/mathrm{Z}_{odot} < 0.09$ at $langle M_{ast} rangle = 3.2 times 10^{8} rm{M}_{odot}$ to $Z_{ast}/Z_{odot} = 0.27$ at $langle M_{ast} rangle = 1.7 times 10^{10} rm{M}_{odot}$. In contrast, at a given stellar mass, we find no evidence for significant metallicity evolution across the redshift range of our sample. However, comparing our results to the $z=0$ stellar mass-metallicity relation, we find that the $langle z rangle = 3.5$ relation is consistent with being shifted to lower metallicities by $simeq 0.6$ dex. Contrasting our derived stellar metallicities with estimates of gas-phase metallicities at similar redshifts, we find evidence for enhanced $rm{O}/rm{Fe}$ ratios of the order (O/Fe) $gtrsim 1.8$ $times$ (O/Fe)$_{odot}$. Finally, by comparing our results to simulation predictions, we find that the $langle z rangle = 3.5$ stellar mass-metallicity relation is consistent with current predictions for how outflow strength scales with galaxy mass. This conclusion is supported by an analysis of analytic models, and suggests that the mass loading parameter ($eta=dot{M}_{mathrm{outflow}}/M_{ast}$) scales as $eta propto M_{ast}^{beta}$ with $beta simeq -0.4$.
The chemical composition of galaxies has been measured out to z~4. However, nearly all studies beyond z~0.7 are based on strong-line emission from HII regions within star-forming galaxies. Measuring the chemical composition of distant quiescent galaxies is extremely challenging, as the required stellar absorption features are faint and shifted to near-infrared wavelengths. Here, we present ultra-deep rest-frame optical spectra of five massive quiescent galaxies at z~1.4, all of which show numerous stellar absorption lines. We derive the abundance ratios [Mg/Fe] and [Fe/H] for three out of five galaxies; the remaining two galaxies have too young luminosity-weighted ages to yield robust measurements. Similar to lower-redshift findings, [Mg/Fe] appears positively correlated with stellar mass, while [Fe/H] is approximately constant with mass. These results may imply that the stellar mass-metallicity relation was already in place at z~1.4. While the [Mg/Fe]-mass relation at z~1.4 is consistent with the z<0.7 relation, [Fe/H] at z~1.4 is ~0.2 dex lower than at z<0.7. With a [Mg/Fe] of 0.44(+0.08,-0.07) the most massive galaxy may be more alpha-enhanced than similar-mass galaxies at lower redshift, but the offset is less significant than the [Mg/Fe] of 0.6 previously found for a massive galaxy at z=2.1. Nonetheless, these results combined may suggest that [Mg/Fe] in the most massive galaxies decreases over time, possibly by accreting low-mass, less alpha-enhanced galaxies. A larger galaxy sample is needed to confirm this scenario. Finally, the abundance ratios indicate short star-formation timescales of 0.2-1.0 Gyr.
We investigate the stellar populations of 25 massive, galaxies ($log[M_ast/M_odot] geq 10.9$) at $1.5 < z < 2$ using data obtained with the K-band Multi-Object Spectrograph (KMOS) on the ESO VLT. Targets were selected to be quiescent based on their broadband colors and redshifts using data from the 3D-HST grism survey. The mean redshift of our sample is $bar{z} = 1.75$, where KMOS YJ-band data probe age- and metallicity-sensitive absorption features in the rest-frame optical, including the $G$ band, Fe I, and high-order Balmer lines. Fitting simple stellar population models to a stack of our KMOS spectra, we derive a mean age of $1.03^{+0.13}_{-0.08}$ Gyr. We confirm previous results suggesting a correlation between color and age for quiescent galaxies, finding mean ages of $1.22^{+0.56}_{-0.19}$ Gyr and $0.85^{+0.08}_{-0.05}$ Gyr for the reddest and bluest galaxies in our sample. Combining our KMOS measurements with those obtained from previous studies at $0.2 < z < 2$ we find evidence for a $2-3$ Gyr spread in the formation epoch of massive galaxies. At $z < 1$ the measured stellar ages are consistent with passive evolution, while at $1 < z lesssim2$ they appear to saturate at $sim$1 Gyr, which likely reflects changing demographics of the (mean) progenitor population. By comparing to star-formation histories inferred for normal star-forming galaxies, we show that the timescales required to form massive galaxies at $z gtrsim 1.5$ are consistent with the enhanced $alpha$-element abundances found in massive local early-type galaxies.
We use deep textit{Hubble Space Telescope} spectroscopy to constrain the metallicities and (editone{light-weighted}) ages of massive ($log M_ast/M_odotgtrsim10$) galaxies selected to have quiescent stellar populations at $1.0<z<1.8$. The data include 12--orbit depth coverage with the WFC3/G102 grism covering $sim$ $8,000<lambda<11,500$~AA, at a spectral resolution of $Rsim 210$ taken as part of the CANDELS Lyman-$alpha$ Emission at Reionization (CLEAR) survey. At $1.0<z<1.8$, the spectra cover important stellar population features in the rest-frame optical. We simulate a suite of stellar population models at the grism resolution, fit these to the data for each galaxy, and derive posterior likelihood distributions for metallicity and age. We stack the posteriors for subgroups of galaxies in different redshift ranges that include different combinations of stellar absorption features. Our results give editone{light-weighted ages of $t_{z sim 1.1}= 3.2pm 0.7$~Gyr, $t_{z sim 1.2}= 2.2pm 0.6$~Gyr, $t_{zsim1.3}= 3.1pm 0.6$~Gyr, and $t_{zsim1.6}= 2.0 pm 0.6$~Gyr, editone{for galaxies at $zsim 1.1$, 1.2, 1.3, and 1.6. This} implies that most of the massive quiescent galaxies at $1<z<1.8$ had formed $>68$% of their stellar mass by a redshift of $z>2$}. The posteriors give metallicities of editone{$Z_{zsim1.1}=1.16 pm 0.29$~$Z_odot$, $Z_{zsim1.2}=1.05 pm 0.34$~$Z_odot$, $Z_{zsim1.3}=1.00 pm 0.31$~$Z_odot$, and $Z_{zsim1.6}=0.95 pm 0.39$~$Z_odot$}. This is evidence that massive galaxies had enriched rapidly to approximately Solar metallicities as early as $zsim3$.