Your search keyword '"Yan, Haojing"' showing total 4 results

1. JWST's PEARLS: Improved Flux Calibration for NIRCam.

Author

Ma, Zhiyuan, Yan, Haojing, Sun, Bangzheng, Cohen, Seth H., Jansen, Rolf A., Summers, Jake, Windhorst, Rogier A., D'Silva, Jordan C. J., Koekemoer, Anton M., Coe, Dan, Conselice, Christopher J., Driver, Simon P., Frye, Brenda, Grogin, Norman A., Marshall, Madeline A., Nonino, Mario, Ortiz III, Rafael, Pirzkal, Nor, Robotham, Aaron, and Ryan Jr., Russell E.

Subjects

*SPACE telescopes, *PHOTOMETRY, *CALIBRATION

Abstract

The Prime Extragalactic Areas for Reionization and Lensing Science, a James Webb Space Telescope (JWST) GTO program, obtained a set of unique NIRCam observations that have enabled us to significantly improve the default photometric calibration across both NIRCam modules. The observations consisted of three epochs of 4-band (F150W, F200W, F356W, and F444W) NIRCam imaging in the Spitzer IRAC Dark Field (IDF). The three epochs were six months apart and spanned the full duration of Cycle 1. As the IDF is in the JWST continuous viewing zone, we were able to design the observations such that the two modules of NIRCam, modules A and B, were flipped by 180° and completely overlapped each other's footprints in alternate epochs. We were therefore able to directly compare the photometry of the same objects observed with different modules and detectors, and we found significant photometric residuals up to ∼0.05 mag in some detectors and filters, for the default version of the calibration files that we used (jwst_1039.pmap). Moreover, there are multiplicative gradients present in the data obtained in the two long-wavelength bands. The problem is less severe in the data reduced using the latest pmap (jwst_1130.pmap as of 2023 September), but it is still present, and is non-negligible. We provide a recipe to correct for this systematic effect to bring the two modules onto a more consistent calibration, to a photometric precision better than ∼0.02 mag. [ABSTRACT FROM AUTHOR]

Published

2024

2. Magellanic System Stars Identified in SMACS J0723.3-7327 James Webb Space Telescope Early Release Observations Images.

Author

Summers, Jake, Windhorst, Rogier A., Cohen, Seth H., Jansen, Rolf A., Carleton, Timothy, Kamieneski, Patrick S., Holwerda, Benne W., Conselice, Christopher J., Adams, Nathan J., Frye, Brenda L., Diego, Jose M., Willmer, Christopher N. A., Ortiz III, Rafael, Cheng, Cheng, Pigarelli, Alex, Robotham, Aaron, D'Silva, Jordan C. J., Tompkins, Scott, Driver, Simon P., and Yan, Haojing

Subjects

SPACE telescopes, LARGE magellanic cloud, DENSITY of stars, SPECTRAL energy distribution, STELLAR parallax, MAGELLANIC clouds

Abstract

We identify 71 distant stars in James Webb Space Telescope/NIRCam early release observations (ERO) images of the field of galaxy cluster SMACS J0723.3-7327 (SMACS 0723). Given the relatively small (∼10°) angular separation between SMACS 0723 and the Large Magellanic Cloud (LMC), it is likely that these stars are associated with the LMC outskirts or the Leading Arm. This is further bolstered by a spectral energy distribution (SED) analysis, which suggests an excess of stars at a physical distance of 40–100 kpc, consistent with being associated with or located behind the Magellanic system. In particular, we find that the overall surface density of stars brighter than 27.0 mag in the field of SMACS 0723 is ∼2.3 times that of stars in a blank field with similar Galactic latitude (the North Ecliptic Pole Time Domain Field), and that the density of stars in the SMACS 0723 field with SED-derived distances consistent with the Magellanic system is ∼6.1 times larger than that of the blank field. The candidate stars at these distances are consistent with a stellar population at the same distance modulus with [Fe/H] = −1.0 and an age of ∼5.0 Gyr. On the assumption that all of the 71 stars are associated with the LMC, then the stellar density of the LMC at the location of the SMACS 0723 field is ∼740 stars kpc−3, which helps trace the density of stars in the LMC outskirts. [ABSTRACT FROM AUTHOR]

Published

2023

3. Are JWST/NIRCam Color Gradients in the Lensed z = 2.3 Dusty Star-forming Galaxy El Anzuelo Due to Central Dust Attenuation or Inside-out Galaxy Growth?

Author

Kamieneski, Patrick S., Frye, Brenda L., Pascale, Massimo, Cohen, Seth H., Windhorst, Rogier A., Jansen, Rolf A., Yun, Min S., Cheng, Cheng, Summers, Jake S., Carleton, Timothy, Harrington, Kevin C., Diego, Jose M., Yan, Haojing, Koekemoer, Anton M., Willmer, Christopher N. A., Petric, Andreea, Furtak, Lukas J., Foo, Nicholas, Conselice, Christopher J., and Coe, Dan

Subjects

STAR formation, GALACTIC redshift, SPECTRAL energy distribution, DUST, STELLAR populations, GALAXIES

Abstract

Gradients in the mass-to-light ratio of distant galaxies impede our ability to characterize their size and compactness. The long-wavelength filters of JWST's NIRCam offer a significant step forward. For galaxies at Cosmic Noon (z ∼ 2), this regime corresponds to the rest-frame near-infrared, which is less biased toward young stars and captures emission from the bulk of a galaxy's stellar population. We present an initial analysis of an extraordinary lensed dusty star-forming galaxy at z = 2.3 behind the El Gordo cluster (z = 0.87), named El Anzuelo ("The Fishhook") after its partial Einstein-ring morphology. The far-UV to near-IR spectral energy distribution suggests an intrinsic star formation rate of 81 − 2 + 7 M ⊙ yr − 1 and dust attenuation A V ≈ 1.6, in line with other DSFGs on the star-forming main sequence. We develop a parametric lens model to reconstruct the source-plane structure of dust imaged by the Atacama Large Millimeter/submillimeter Array, far-UV to optical light from Hubble, and near-IR imaging with 8 filters of JWST/NIRCam, as part of the Prime Extragalactic Areas for Reionization and Lensing Science program. The source-plane half-light radius is remarkably consistent from ∼1 to 4.5 μ m, despite a clear color gradient where the inferred galaxy center is redder than the outskirts. We interpret this to be the result of both a radially decreasing gradient in attenuation and substantial spatial offsets between UV- and IR-emitting components. A spatial decomposition of the SED reveals modestly suppressed star formation in the inner kiloparsec, which suggests that we are witnessing the early stages of inside-out quenching. [ABSTRACT FROM AUTHOR]

Published

2023

4. A Strong-lensing Model for the WMDF JWST/GTO Very Rich Cluster A1489.

Author

Zitrin, Adi, Acebron, Ana, Coe, Dan, Kelly, Patrick L., Koekemoer, Anton M., Nonino, Mario, Windhorst, Rogier A., Frye, Brenda, Pascale, Massimo, Broadhurst, Tom, Cohen, Seth H., Diego, Jose M., Finkelstein, Steven L., Jansen, Rolf A., Larson, Rebecca L., Yan, Haojing, Alpaslan, Mehmet, Bhatawdekar, Rachana, Conselice, Christopher J., and Griffiths, Alex

Subjects

SUNYAEV-Zel'dovich effect, GALAXY clusters, SPACE telescopes, GRAVITATIONAL lenses, SPECTROGRAPHS, DATA mapping, LENSES, REDSHIFT

Abstract

We present a first strong-lensing model for the galaxy cluster RM J121218.5+273255.1 (z = 0.35; hereafter RMJ1212; also known as A1489). This cluster is among the top 0.1% richest clusters in the redMaPPer catalog; it is significantly detected in X-ray and through the Sunyaev–Zel'dovich effect in ROSAT and Planck data, respectively, and its optical luminosity distribution implies a very large lens, following mass-to-light scaling relations. Based on these properties it was chosen for the Webb Medium Deep Fields (WMDF) James Webb Space Telescope/Guaranteed Time Observations program. In preparation for this program, RMJ1212 was recently imaged with Gemini Multi-Object Spectrograph (GMOS) on Gemini North and in seven optical and near-infrared bands with the Hubble Space Telescope (HST). We use these data to map the inner mass distribution of the cluster, uncovering various sets of multiple images. We also search for high-redshift candidates in the data, as well as for transient sources. We find over a dozen high-redshift (z ≳ 6) candidates based on both photometric redshift and the dropout technique. No prominent (≳5σ) transients were found in the data between the two HST visits. Our lensing analysis reveals a relatively large lens with an effective Einstein radius of θE ≃ 32 ± 3″ (zs = 2), in broad agreement with the scaling-relation expectations. RMJ1212 demonstrates that powerful lensing clusters can be selected in a robust and automated way following the light-traces-mass assumption. [ABSTRACT FROM AUTHOR]

Published

2020