近3年
[1] Wang L F, Jin S J, Zhang J F, and Zhang X. Forecast for cosmological parameter estimation with gravitational-wave standard sirens from the LISA-Taiji network[J]. Science China Physics, Mechanics and Astronomy, 2022, 65(1):13. (中科院一区)
[2] Wang L F, Zhao Z W, Zhang J F, and Zhang X. A preliminary forecast for cosmological parameter estimation with gravitational-wave standard sirens from TianQin[J]. Journal of Cosmology and Astroparticle Physics, 2020, 2020(11):012-012. (中科院二区)
[3] Wang L F, Zhang J H, Zhang J F, and Zhang X. Constraints on interacting dark energy models from time-delay cosmography with seven lensed quasars[J]. Monthly Notices of the Royal Astronomical Society, 2022, 514(1): 1433–1440. (中科院二区)
[4] Song J Y, Wang L F, Li Y C, Zhao Z W, Zhang J F, Zhao W, and Zhang X. Synergy between CSST galaxy survey and gravitational-wave observation: Inferring the Hubble constant from dark standard sirens[J]. Science China Physics, Mechanics and Astronomy, 67 (2024) 3, 230411.(中科院一区)
[5] Jin S J, Wang L F, Wu P J, Zhang J F, and Zhang X. How can gravitational-wave standard sirens and 21 cm intensity mapping jointly provide a precise late-universe cosmological probe?[J]. Physical Review D, 104 (2021) 10, 1035072021. (中科院二区)
[6]Zhao Z W, Wang L F, Zhang J G, Zhang J F, and Zhang X. Probing the interaction between dark energy and dark matter with future fast radio burst observations[J]. Journal of Cosmology and Astroparticle Physics, 04 (2023) 022. (中科院二区)
[7] Qiu X W, Zhao Z W, Wang L F, Zhang J F, and Zhang X. A forecast of using fast radio burst observations to constrain holographic dark energy[J]. 2021. Journal of Cosmology and Astroparticle Physics, 02 (2022) 02, 006. (中科院二区)
[8] Jin S J, Zhu R Q, Wang L F, Li H L, Zhang J F, and Zhang X. Impacts of gravitational-wave standard siren observations from Einstein Telescope and Cosmic Explorer on weighing neutrinos in interacting dark energy models[J]. Communications in Theoretical Physics, 2022, 74(10): 105404. (中科院三区)