Outside the Lyman-break box: detecting Lyman continuum emitters at 3.5 &amp;lt; <i>z</i> &amp;lt; 5.1 with CLAUDS

Meštrić, U.; Ryan-Weber, E. V.; Cooke, Jeff; Bassett, Robert; Sawicki, Marcin; Faisst, Andreas L.; Kakiichi, Koki; Inoue, Akio; Rafelski, Marc; Prichard, Laura; Arnouts, S.; Moutard, T.; Coupon, J.; Golob, Anneya; Gwyn, Stephen

doi:10.1093/mnras/staa920

Cited by 23 publications

(29 citation statements)

References 113 publications

(186 reference statements)

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“…In recent years, direct 𝑓 esc studies have largely concentrated on two redshift windows set by available UV instrumentation -one at 𝑧 ≈ 0.3 where Lyman continuum (LyC) is accessible to HST/COS (e.g., Izotov et al 2016aIzotov et al , 2018bIzotov et al , 2021aWang et al 2019Wang et al , 2021, and another at 𝑧 ≈ 2 − 4 accessible to ground-based facilities and HST/WFC3 UVIS (e.g., Jones et al 2018;Smith et al 2020;Ji et al 2020;Meštrić et al 2020;Marques-Chaves et al 2021;Davis et al 2021;Prichard et al 2021). The 𝑧 ≈ 0.3 COS efforts were first undertaken at a time when only a handful of robust LyC leakers had been identified, and it was unclear whether LyC leakage even occurred among the 0.5𝐿 * galaxies for which 𝑓 esc measurements were feasible (e.g., Izotov et al 2016a,b).…”

Section: Introductionmentioning

confidence: 99%

The synchrony of production and escape: half the bright Lyα emitters at z ≈ 2 have Lyman continuum escape fractions ≈50

Naidu

Matthee

Oesch

et al. 2021

Monthly Notices of the Royal Astronomical Society

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The ionizing photon escape fraction (LyC fesc) of star-forming galaxies is the single greatest unknown in the reionization budget. Stochastic sightline effects prohibit the direct separation of LyC leakers from non-leakers at significant redshifts. Here we circumvent this uncertainty by inferring fesc using resolved (R > 4000) Lyα profiles from the X-SHOOTER Lyα survey at z = 2 (XLS-z2). With empirically motivated criteria, we use Lyα profiles to select leakers (fesc$>20\%$) and non-leakers (fesc$<5\%$) from a representative sample of >0.2L* Lyman-α emitters (LAEs). We use median stacked spectra of these subsets over λrest ≈ 1000 − 8000Å to investigate the conditions for LyC fesc. Our stacks show similar mass, metallicity, MUV, and βUV. We find the following differences between leakers vs. non-leakers: (i) strong nebular CIV and HeII emission vs. non-detections, (ii) [O iii]/[O ii]≈8.5 vs. ≈3, (iii) Hα/Hβ indicating no dust vs. E(B − V) ≈ 0.3, (iv) MgII emission close to the systemic velocity vs. redshifted, optically thick MgII, (v) Lyα fesc of $\approx 50\%$ vs. $\approx 10\%$. The extreme EWs in leakers ([O iii]+Hβ ≈ 1100 Å rest-frame) constrain the characteristic timescale of LyC escape to ≈3 − 10 Myr bursts when short-lived stars with the hardest ionizing spectra shine. The defining traits of leakers – extremely ionizing stellar populations, low column densities, a dust-free, high ionization state ISM – occur simultaneously in the fesc$>20\%$ stack, suggesting they are causally connected, and motivating why indicators like [O iii]/[O ii] may suffice to constrain fesc at z > 6 with JWST. The leakers comprise half our sample, have a median LyC fesc$\approx 50\%$ (conservative range: $20-55\%$), and an ionising production efficiency $\log ({\xi _{\rm {ion}}/\rm {Hz\ erg^{-1}}})\approx 25.9$ (conservative range: 25.7 − 25.9). These results show LAEs – the type of galaxies rare at z ≈ 2, but that become the norm at higher redshift – are highly efficient ionizers, with extreme ξion and prolific fesc occurring in sync.

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Section: Introductionmentioning

confidence: 99%

The synchrony of production and escape: half the bright Lyα emitters at z ≈ 2 have Lyman continuum escape fractions ≈50

Naidu

Matthee

Oesch

et al. 2021

Monthly Notices of the Royal Astronomical Society

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“…As in previous works (e.g. Bassett et al 2019;Meštrić et al 2020) 𝑢-band data comes from the CFHT Large Area Uband Deep Survey (CLAUDS, Sawicki et al 2019), which reaches a maximum depth of ∼27.2-27.3 mag in the 𝑢-band. We note that the 𝑢-band used here for LyC detections is distinct from the 𝑢 * -band of the ZFOURGE survey.…”

Section: Sample Selection and Observationsmentioning

confidence: 96%

“…The difficulty in definitively answering the question of which sources are primarily responsible for reionization can be attributed to the faintness of these sources (e.g. Bian & Fan 2020;Meštrić et al 2020) and the high opacity of the IGM during the EoR. Based on known samples of Lyman Break Galaxies (Steidel et al 2018, LBGs) and Lyman 𝛼 emitters (LAEs Fletcher et al 2019), Bassett et al (2021) predict that LyC emission from the bulk of star-forming galaxies at 𝑧 ≥ 3.0 should be fainter than 28 mag AB.…”

Section: Introductionmentioning

confidence: 99%

A Cautionary Tale of LyC Escape Fraction Estimates from High Redshift Galaxies

Bassett,

Ryan-Weber,

Cooke

et al. 2022

Preprint

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Measuring the escape fraction, 𝑓 esc , of ionizing, Lyman Continuum (LyC) radiation is key to our understanding of the process of cosmic reionization. In this paper we provide a methodology for recovering the posterior probability distribution of the LyC escape fraction, 𝑓 PDF esc , considering both the observational uncertainties and ensembles of simulated transmission functions through the intergalactic medium (IGM). We present an example of this method applied to a VUDS galaxy at 𝑧 = 3.64 and find 𝑓 PDF esc = 0.51 +0.33 −0.34 and compare this to the values computed assuming averaged IGM transmission with and without consideration of detection bias along average sightlines yielding 𝑓 𝑇 esc = 1.40 +0.80 −0.42 , and 𝑓 bias esc = 0.82 +0.33 −0.16 . Our results highlight the limitations of methods assuming average, smooth transmission functions. We also present MOSFIRE data for a sample of seven LyC candidates selected based on photometric redshifts at 𝑧 > 3.4, but find that all seven have overestimated photometric redshifts by Δ𝑧 ∼ 0.2 making them unsuitable for LyC measurements. This results likely due to a bias induced by our selection criteria.

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“…Nevertheless, both of these systems show a similar specific−SFR (sSFR) lying in the range of 10 −7 − 10 −9 yr −1 . In the literature, several of these GPs and Bluebrries have now been confirmed as Lyman Continuum (LyC) and Lyα leakers showing an escape fraction of ionizing photons in the range of 2 − 72% (Borthakur et al 2014;Jaskot et al 2019;Leitherer et al 2016;Izotov et al 2016aIzotov et al ,b, 2018a, like the high-redshift leaky star-forming galaxies (e.g., Shapley et al 2016;Bian et al 2017;Vanzella et al 2018;Fletcher et al 2019;Meštrić et al 2020;Marques-Chaves et al 2021).…”

Section: Introductionmentioning

confidence: 96%

SDSS-IV MaNGA: an observational evidence of density bounded region in a Lyman-$α$ emitter

Paswan,

Saha,

Leitherer

et al. 2021

Preprint

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Using Integral Field Unit (IFU) spectroscopy, we present here the spatially resolved morphologies of [SII]λ6717,6731/Hα and [SII]λ6717,6731/[OIII]λ5007 emission line ratios for the first time in a Blueberry Lyman-α emitter (BBLAE) at z ∼ 0.047. Our derived morphologies show that the extreme starburst region of the BBLAE, populated by young ( 10 Myr), massive Wolf-Rayet stars, is [SII]-deficient, while the rest of the galaxy is [SII]-enhanced. We infer that the extreme starburst region is density-bounded (i.e., optically thin to ionizing photons), and the rest of the galaxy is ionization-bounded − indicating a Blister-type morphology. We find that the previously reported small escape fraction (10%) of Lyα photons is from our identified densitybounded HII region of the BBLAE. This escape fraction is likely constrained by a porous dust distribution.We further report a moderate correlation between [SII]-deficiency and inferred Lyman Continuum (LyC) escape fraction using a sample of confirmed LyC leakers studied in the literature, including the BBLAE studied here. The observed correlation also reveals its dependency on the stellar mass and gas-phase metallicity of the leaky galaxies. Finally, the future scope and implications of our work are discussed in detail.

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Outside the Lyman-break box: detecting Lyman continuum emitters at 3.5 < z < 5.1 with CLAUDS

Cited by 23 publications

References 113 publications

The synchrony of production and escape: half the bright Lyα emitters at z ≈ 2 have Lyman continuum escape fractions ≈50

The synchrony of production and escape: half the bright Lyα emitters at z ≈ 2 have Lyman continuum escape fractions ≈50

A Cautionary Tale of LyC Escape Fraction Estimates from High Redshift Galaxies

SDSS-IV MaNGA: an observational evidence of density bounded region in a Lyman-$α$ emitter

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Outside the Lyman-break box: detecting Lyman continuum emitters at 3.5 &lt; z &lt; 5.1 with CLAUDS

Cited by 23 publications

References 113 publications

The synchrony of production and escape: half the bright Lyα emitters at z ≈ 2 have Lyman continuum escape fractions ≈50

The synchrony of production and escape: half the bright Lyα emitters at z ≈ 2 have Lyman continuum escape fractions ≈50

A Cautionary Tale of LyC Escape Fraction Estimates from High Redshift Galaxies

SDSS-IV MaNGA: an observational evidence of density bounded region in a Lyman-$α$ emitter

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Outside the Lyman-break box: detecting Lyman continuum emitters at 3.5 < z < 5.1 with CLAUDS