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paper
12. "The Seoul National University AGN Monitoring Project. VI. Dynamical Modeling of 10 High-Luminosity AGNs", Wang et al., 2024, in prep.
11. "The Seoul National University AGN Monitoring Project. V. Velocity-Resolved Hβ Lags and Evidence of Kinematics Evolution", Wang et al., 2025, submitted
10. "Dormancy and Reawakening Over Years: Eight New Recurrent Changing-Look AGNs", Wang et al., 2025, ApJ, accepted
9. "Revisiting the Hβ Size--Luminosity Relation Using a Uniform Reverberation-Mapping Analysis ", Wang and Woo et al., 2024, ApJS, in press
8. "Identifying Changing-look AGNs using Variability Characteristics", Wang et al., 2024, ApJ, 966, 128
7. "The Seoul National University AGN Monitoring Project. III. Hβ Lag Measurements of 32 Luminous Active Galactic Nuclei and the High-luminosity End of the Size–Luminosity Relation", Woo, Wang et al., 2024, ApJ, 962, 67
6. "Estimating AGN Black Hole Masses via Continuum Reverberation Mapping in the Era of LSST", Wang et al., 2023, ApJL, 948, L23
5. "Metallicity in Quasar Broad-line Regions at Redshift ~ 6", Wang et al., 2022, ApJ, 925, 121
4. "Active Galactic Nuclei Continuum Reverberation Mapping Based on Zwicky Transient Facility Light Curves", Guo, Barth, & Wang, 2022, ApJ, 940, 20
3. "A possible bright ultraviolet flash from a galaxy at redshift z ≈ 11", Jiang, Wang et al., 2021, Nature Astronomy, 5, 262
2. "The Sloan Digital Sky Survey Reverberation Mapping Project: How Broad Emission Line Widths Change When Luminosity Changes", Wang et al., 2020, ApJ, 903, 51
1. "The Sloan Digital Sky Survey Reverberation Mapping Project: Low-ionization Broad-line Widths and Implications for Virial Black Hole Mass Estimation", Wang et al., 2019, ApJ, 882, 4
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