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Research Interests

I am a professor in Sun Yat-sen University. My primary interests are theoretical and observational cosmology, specifically the cosmic microwave background (CMB), early-universe physics, dark energy, and modified gravity. I have been a core team member of the Planck collaboration and have contributed to a few legacy papers in the 2015 and 2018 releases. Currently, I am working in AliCPT collaboration and aim to measure the primordial gravitational waves from CMB data.

Career in three lines

Publications/eprints (see also arXiv list)

[all] [published] [1st/co-1st/corresponding author]
  1. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Key drivers of the preference for dynamic dark energy (Zhiqi Huang, Jianqi Liu, Jianfeng Mo, Yan Su, Junchao Wang, Yanhong Yao, Guangyao Yu, Zhengxin Zhu, Zhuoyang Li, Zhenjie Liu, Haitao Miao, Hui Tong, PRD 110, 123512, 2024)
  2. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Pair Counting without Binning -- A New Approach to Correlation Functions in Clustering Statistics (Shiyu Yue, Longlong Feng, Wenjie Ju, Jun Pan, Zhiqi Huang, Feng Fang, Zhuoyang Li, Yan-Chuan Cai, Weishan Zhu, MNRAS 535(4), 3500, 2024)
  3. [arxiv] [ADS] Analysis of Polarized Dust Emission from the First Flight of the SPIDER Balloon-Borne Telescope (P. A. R. Ade, M. Amiri, S. J. Benton, et al., ApJ)
  4. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]A PAge-like Unified Dark Fluid Model (Junchao Wang, Zhiqi Huang, Yanhong Yao, Jianqi Liu, Lu Huang, Yan Su, JCAP 2024(09), 053, 2024)
  5. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Forecast of foreground cleaning strategies for AliCPT-1 (Junzhou Zhang et al., ApJS 274(2), 26, 2024)
  6. [arxiv] [ADS] A new unified dark sector model and its implications on the σ8 and S8 tensions (Yan-Hong Yao, Jian-Qi Liu, Zhi-Qi Huang, Jun-Chao Wang, Yan Su)
  7. [arxiv] [ADS] MEET-U project II: Curvature perturbations from kinetic preheating after α-attractor inflation (Zhiqi Huang, Xichang Ouyang, Yu Cui, Jianqi Liu, Yanhong Yao, Zehong Qiu, Guangyao Yu, Lu Huang, Zhuoyang Li, Chi-Fong Wong)
  8. [arxiv] [ADS] In-Flight Performance of Spider's 280 GHz Receivers (Elle C. Shaw, P. A. R. Ade, S. Akers et al.., Journal of Astronomical Telescopes, Instruments, and Systems)
  9. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Forecasting the BAO Measurements of the CSST galaxy and AGN Spectroscopic Surveys (Haitao Miao, Yan Gong, Xuelei Chen, Zhiqi Huang, Xiao-Dong Li, Hu Zhan, MNRAS 531(4), 3991, 2024)
  10. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Quantifying the tension between cosmological models and JWST red candidate massive galaxies (Jun-Chao Wang, Zhi-Qi Huang, Lu Huang, Jianqi Liu, RAA 24, 045001, 2024)
  11. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Cosmological constraints on neutrino masses in light of JWST red and massive candidate galaxies (Jian-Qi Liu, Zhi-Qi Huang, Yan Su, RAA 24, 045002, 2024)
  12. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Revisiting progenitor-age dependence of type Ia supernova luminosity standardization process (Junchao Wang, Zhiqi Huang, Lu Huang, SCPMA 66(12), 129511, 2023)
  13. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Toward a stellar population catalog in the Kilo Degree Survey: the impact of stellar recipes on stellar masses and star formation rates (Linghua Xie, Nicola R. Napolitano, Xiaotong Guo, Crescenzo Tortora, Haicheng Feng, Antonios Katsianis, Rui Li, Sirui Wu, Mario Radovich, Leslie K. Hunt, Yang Wang, Lin Tang, Baitian Tang, Zhiqi Huang, SCPMA 66(12), 129513, 2023)
  14. [arxiv] [ADS] Sum of digamma asymptotic error terms of an arithmetic series (Zhiqi Huang)
  15. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Tomographic Alcock-Paczynski Method with Redshift Errors (Liang Xiao, Zhiqi Huang, Yi Zheng, Xin Wang, Xiaodong Li, MNRAS 518(4), 6253, 2022)
  16. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Cosmological forecasts of the CSST photometric and spectroscopic multi-probe surveys (Haitao Miao, Yan Gong, Xuelei Chen, Zhiqi Huang, Xiao-Dong Li, Hu Zhan, MNRAS 519(1), 1132, 2022)
  17. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Constraints on compact dark matter from lensing of gravitational waves for the third-generation gravitational wave detector (Huan Zhou, Zhengxiang Li, Kai Liao, Zhiqi Huang, MNRAS 518, 149, 2022)
  18. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Performance forecasts for the primordial gravitational wave detection pipelines for AliCPT-1 (Shamik Ghosh, Yang Liu, Le Zhang, et al., JCAP 2022(10), 063, 2022)
  19. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Forecasts on CMB lensing observations with AliCPT-1 (Jinyi Liu, Zeyang Sun, Jiakang Han et al., SCPMA 65(10), 109511, 2022)
  20. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Thawing k-essence dark energy in the PAge space (Zhiqi Huang, Communications in Theoretical Physics 74(9), 095404, 2022)
  21. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]The Galactic interstellar medium has a preferred handedness of magnetic misalignment (Zhiqi Huang, Universe 8(8), 423, 2022)
  22. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Superclustering with the Atacama Cosmology Telescope and Dark Energy Survey: I. Evidence for thermal energy anisotropy using oriented stacking (M. Lokken, R. Hlozek, A. van Engelen et al., ApJ 933(2), 134, 2022)
  23. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]In-Flight Gain Monitoring of SPIDER's Transition-Edge Sensor Arrays (J. P. Filippini, A. E. Gambrel, A. S. Rahlin et al.., JOURNAL OF LOW TEMPERATURE PHYSICS 209(3-4), 649, 2022)
  24. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Revisiting the quasi-molecular mechanism of recombination (Zhiqi Huang, MNRAS 513(3), 3368, 2022)
  25. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Constraints on the abundance of supermassive primordial black holes from lensing of compact radio sources (Huan Zhou, Zhengxiang Li, Shuo Cao, Zhiqi Huang, MNRAS 513(3), 3627, 2022)
  26. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Search for lensing signatures from the latest fast radio burst observations and constraints on the abundance of primordial black holes (Huan Zhou, Zhengxiang Li, Kai Liao, Chenhui Niu, He Gao, Zhiqi Huang, Lu Huang, Bing Zhang, ApJ 928(2), 124, 2022)
  27. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]A Simulation-based Method for Correcting Mode Coupling in CMB Angular Power Spectra (Leung, JSY; Hartley, J ; Nagy, JM et al.., ApJ 928(2), 109, 2022)
  28. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Cosmological constraints from the density gradient weighted correlation function (Xiaoyuan, Xiao et al., MNRAS 513(1), 595, 2022)
  29. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]A Constraint on Primordial B-Modes from the First Flight of the SPIDER Balloon-Borne Telescope (P. A. R. Ade, M. Amiri, S. J. Benton, et al.., ApJ 927(2), 174, 2022)
  30. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Constraints on the abundance of primordial black holes with different mass distributions from lensing of fast radio bursts (Huan Zhou, Zhengxiang Li, Zhiqi Huang, He Gao, Lu Huang, MNRAS 511(1), 1141, 2022)
  31. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]The S8 tension in light of updated redshift-space distortion data and PAge approximation (Lu Huang, Zhiqi Huang, Huan Zhou, Zhuoyang Li, SCPMA 65(3), 239512, 2022)
  32. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]High-quality Strong Lens Candidates in the Final Kilo-Degree Survey Footprint (R. Li, N. R. Napolitano, C. Spiniello et al., ApJ 923(1), 16, 2021)
  33. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]The XFaster Power Spectrum and Likelihood Estimator for the Analysis of Cosmic Microwave Background Maps (Gambrel, AE ; Rahlin, AS; Song, X, ApJ 922(2), 132, 2021)
  34. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]A More Accurate Parameterization based on cosmic Age (MAPAge) (Lu Huang, Zhiqi Huang, Zhuoyang Li, Huan Zhou, RAA 21(11), 277, 2021)
  35. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Statistics of thawing k-essence dark energy models (Zhiqi Huang, PRD 104(10), 103533, 2021)
  36. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Reconciling low and high redshift GRB luminosity correlations (Lu Huang, Zhiqi Huang, Xiaolin Luo, Yuhong Fang, PRD 103(12), 123521, 2021)
  37. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck intermediate results. LVI. Detection of the CMB dipole through modulation of the thermal Sunyaev-Zeldovich effect: Eppur si muove II (Y. Akrami, M. Ashdown, C. Baccigalupi et al., A&A 644, A100, 2020)
  38. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Reaffirming the Cosmic Acceleration without Supernovae and the Cosmic Microwave Background (Xiaolin Luo, Zhiqi Huang, Qiyue Qian, Lu Huang, ApJ 905(1), 53, 2020)
  39. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Design and pre-flight performance of SPIDER 280 GHz receivers (E. C. Shaw, P. A. R. Ade, S. Akers, et al., Proc. SPIE 11453, Millimeter, Submillimeter, and Far-Infrared Detectors and Instrumentation for Astronomy X 11453(2F), 1, 2020)
  40. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck intermediate results. LV. Reliability and thermal properties of high-frequency sources in the Second Planck Catalogue of Compact Sources (Y. Akrami, M. Ashdown, J. Aumont et al., A&A 644, A99, 2020)
  41. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck intermediate results. LVII. Joint Planck LFI and HFI data processing (Y. Akrami, K. J. Andersen, M. Ashdown et al., A&A 643, A42, 2020)
  42. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2018 results. IX. Constraints on primordial non-Gaussianity (Y. Akrami, F. Arroja, M. Ashdown et al., A&A 641, A9, 2020)
  43. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2018 results. VIII. Gravitational lensing (N. Aghanim, Y. Akrami, M. Ashdown et al., A&A 641, A8, 2020)
  44. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2018 results. VII. Isotropy and Statistics of the CMB (Y. Akrami, M. Ashdown, J. Aumont et al., A&A 641, A7, 2020)
  45. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2018 results. VI. Cosmological parameters (N. Aghanim, Y. Akrami, M. Ashdown et al., A&A 641, A6, 2020)
  46. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2018 results. V. CMB power spectra and likelihoods (N. Aghanim, Y. Akrami, M. Ashdown et al., A&A 641, A5, 2020)
  47. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2018 results. IV. Diffuse component separation (Y. Akrami, M. Ashdown, J. Aumont et al., A&A 641, A4, 2020)
  48. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2018 results. III. High Frequency Instrument data processing and frequency maps (N. Aghanim, Y. Akrami, M. Ashdown et al., A&A 641, A3, 2020)
  49. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2018 results. II. Low Frequency Instrument data processing (Y. Akrami, F. Argueso, M. Ashdown et al., A&A 641, A2, 2020)
  50. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2018 results. XII. Galactic astrophysics using polarized dust emission (N. Aghanim, Y. Akrami, M. I. R. Alves et al., A&A 641, A12, 2020)
  51. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2018 results. XI. Polarized dust foregrounds (Y. Akrami, M. Ashdown, J. Aumont et al., A&A 641, A11, 2020)
  52. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2018 results. X. Constraints on inflation (Y. Akrami, F. Arroja, M. Ashdown et al., A&A 641, A10, 2020)
  53. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2018 results. I. Overview and the cosmological legacy of Planck (Y. Akrami, F. Arroja, M. Ashdown et al., A&A 641, A1, 2020)
  54. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]New high-quality strong lens candidates with deep learning in the Kilo Degree Survey (R. Li, N. R. Napolitano, C. Tortora, C. Spiniello, L. V. E. Koopmans, Z. Huang, G. Vernardos, S. Chatterjee, B. Giblin, F. Getman, G. Covone, K. Kuijken, ApJ 893(1), 30, 2020)
  55. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Band-limited Features in Primordial Power Spectrum Do Not Resolve the Hubble Tension (MiaoXin Liu, Zhiqi Huang, ApJ 897(2), 166, 2020)
  56. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Can Non-standard Recombination Resolve the Hubble Tension? (Miaoxin Liu, Zhiqi Huang, Xiaolin Luo, Haitao Miao, Naveen K. Singh, Lu Huang, SCPMA 63(9), 290405, 2020)
  57. [arxiv] [ADS] Design of a novel monolithic parabolic-mirror ion-trap to precisely align the RF null point with the optical focus (Zhao Wang, Ben-Ran Wang, Qing-Lin Ma, Jia-Yu Guo, Ming-Shen Li, Yu Wang, Xin-Xin Rao, Zhi-Qi Huang, Le Luo)
  58. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Supernova Magnitude Evolution and PAge Approximation (Zhiqi Huang, ApJL 892(2), L28, 2020)
  59. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Forecasting Cosmological Bias due to Local Gravitational Redshift (Haoting Xu, Zhiqi Huang, Na Zhang, Yundong Jiang, IJMPD 28(12), 1950150, 2019)
  60. [arxiv] [ADS] The Simons Observatory: Astro2020 Decadal Project Whitepaper (Maximilian H. Abitbol, Shunsuke Adachi, Peter Ade et al., BAAS 51(7), 147, 2019)
  61. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Revisiting Ryskin's Model of Cosmic Acceleration (Zhiqi Huang, Han Gao, Haoting Xu, Astroparticle Physics 114, 77, 2019)
  62. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Flatness without CMB - the Entanglement of Spatial Curvature and Dark Energy Equation of State (Haoting Xu, Zhiqi Huang, Zhenjie Liu, Haitao Miao, ApJ 877(2), 107, 2019)
  63. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]High-redshift Mini-haloes from Modulated Preheating (Zhiqi Huang, PRD 99(10), 103537, 2019)
  64. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]The Simons Observatory: science goals and forecasts (Peter Ade, James Aguirre, Zeeshan Ahmed et al., JCAP 2019(02), 056, 2019)
  65. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Anti-Evaporation of n-dimensional Reissner-Nordström Black Hole (YuHong Fang, Zhiqi Huang, HaiTao Miao, Naveen K Singh, PRD 99(4), 044011, 2019)
  66. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]The H0 Tension in Non-flat QCDM Cosmology (Haitao Miao, Zhiqi Huang, ApJ 868(1), 20, 2018)
  67. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck intermediate results. LIV. The Planck Multi-frequency Catalogue of Non-thermal Sources (Y. Akrami, F. Argüeso, M. Ashdown et al., A&A 619, A94, 2018)
  68. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck intermediate results. LIII. Detection of velocity dispersion from the kinetic Sunyaev-Zeldovich effect (N. Aghanim, Y. Akrami, M. Ashdown et al., A&A 617, A48, 2018)
  69. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]280 GHz Focal Plane Unit Design and Characterization for the Spider-2 Suborbital Polarimeter (A.S. Bergman, P.A.R. Ade, S. Akers et al., Journal of Low Temperature Physics 193, 1075, 2018)
  70. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Cosmology and fundamental physics with the Euclid satellite (Luca Amendola, Stephen Appleby, Anastasios Avgoustidis et al., Living Review in Relativity 21, 2, 2018)
  71. [arxiv] [ADS] Equipartition Dark Energy (Weipeng Lin, Zhiqi Huang, Yiming Hu, Shuang Wang, Yi-Jung Yang)
  72. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Comparison of Einstein-Boltzmann solvers for testing general relativity (E. Bellini, A. Barreira, N. Frusciante et al., PRD 97(2), 023520, 2018)
  73. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck intermediate results. LI. Features in the cosmic microwave background temperature power spectrum and shifts in cosmological parameters (N. Aghanim, Y. Akrami, M. Ashdown et al., A&A 607, A95, 2017)
  74. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]A New Limit on CMB Circular Polarization from SPIDER (J. M. Nagy, P. A. R. Ade, M. Amiri et al., ApJ 844(2), 151, 2017)
  75. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]The Atacama Cosmology Telescope: Two-Season ACTPol Spectra and Parameters (Thibaut Louis, Emily Grace, Matthew Hasselfield et al., JCAP 2017(06), 031, 2017)
  76. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck intermediate results. L. Evidence for spatial variation of the polarized thermal dust spectral energy distribution and implications for CMB B-mode analysis (N. Aghanim, M. Ashdown, J. Aumont et al., A&A 599, A51, 2017)
  77. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Weakening Gravity on Redshift-Survey Scales with Kinetic Matter Mixing (Guido D'Amico, Zhiqi Huang, Michele Mancarella, Filippo Vernizzi, JCAP 2017(02), 014, 2017)
  78. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Marginalized Fisher Forecast for Horndeski Dark Energy Models (Jason S.-Y. Leung, Zhiqi Huang, IJMPD 26(7), 1750070, 2017)
  79. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck intermediate results. XLIX. Parity-violation constraints from polarization data (N. Aghanim, M. Ashdown, J. Aumont et al., A&A 596, A110, 2016)
  80. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck intermediate results. XLVIII. Disentangling Galactic dust emission and cosmic infrared background anisotropies (N. Aghanim, M. Ashdown, J. Aumont et al., A&A 596, A109, 2016)
  81. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck intermediate results. XLVII. Planck constraints on reionization history (R. Adam, N. Aghanim, M. Ashdown et al., A&A 596, A108, 2016)
  82. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck intermediate results. XLVI. Reduction of large-scale systematic effects in HFI polarization maps and estimation of the reionization optical depth (N. Aghanim, M. Ashdown, J. Aumont et al., A&A 596, A107, 2016)
  83. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck intermediate results. XLIV. The structure of the Galactic magnetic field from dust polarization maps of the southern Galactic cap (N. Aghanim, M. I. R. Alves, D. Arzoumanian et al., A&A 596, A105, 2016)
  84. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]The Future of Primordial Features with Large-Scale Structure Surveys (Xingang Chen, Cora Dvorkin, Zhiqi Huang, Mohammad Hossein Namjoo, Licia Verde, JCAP 2016(11), 014, 2016)
  85. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2015 results. XX. Constraints on inflation (P. A. R. Ade, N. Aghanim, M. Arnaud et al., A&A 594, A20, 2016)
  86. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2015 results. XVII. Constraints on primordial non-Gaussianity (P. A. R. Ade, N. Aghanim, M. Arnaud et al., A&A 594, A17, 2016)
  87. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2015 results. XVI. Isotropy and statistics of the CMB (P. A. R. Ade, N. Aghanim, Y. Akrami et al., A&A 594, A16, 2016)
  88. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2015 results. XIV. Dark energy and modified gravity (P. A. R. Ade, N. Aghanim, M. Arnaud et al., A&A 594, A14, 2016)
  89. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2015 results. XIII. Cosmological parameters (P. A. R. Ade, N. Aghanim, M. Arnaud et al., A&A 594, A13, 2016)
  90. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck 2015 results. I. Overview of products and scientific results (R. Adam, P. A. R. Ade, N. Aghanim et al., A&A 594, A1, 2016)
  91. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Observational effects of a running Planck mass (Zhiqi Huang, PRD 93(4), 043538, 2016)
  92. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Planck intermediate results. XXXVIII. E- and B-modes of dust polarization from the magnetized filamentary structure of the interstellar medium (P. A. R. Ade, N. Aghanim, M. Arnaud et al., A&A 586, A141, 2016)
  93. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Revisiting the cosmological bias due to local gravitational redshifts (Zhiqi Huang, PRD 91(12), 121301(R), 2015)
  94. [arxiv] [ADS] Testing Inflation with Large Scale Structure: Connecting Hopes with Reality (Marcelo Alvarez, Tobias Baldauf, J. Richard Bond et al.)
  95. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Chameleons in the early Universe: Kicks, rebounds, and particle production (Adrienne L. Erickcek, Neil Barnaby, Clare Burrage, Zhiqi Huang, PRD 89(8), 084074, 2014)
  96. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Full cosmic microwave background temperature bispectrum from single-field inflation (Zhiqi Huang, Filippo Vernizzi, PRD 89(2), 021302, 2014)
  97. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Catastrophic Consequences of Kicking the Chameleon (Adrienne L. Erickcek, Neil Barnaby, Clare Burrage, Zhiqi Huang, PRL 110(17), 171101, 2013)
  98. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Cosmic Microwave Background Bispectrum from Recombination (Zhiqi Huang, Filippo Vernizzi, PRL 110(10), 101303, 2013)
  99. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]A cosmology forecast toolkit - CosmoLib (Zhiqi Huang, JCAP 2012(06), 012, 2012)
  100. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Constraining inflation with future galaxy redshift surveys (Zhiqi Huang, Licia Verde, Filippo Vernizzi, JCAP 2012(04), 005, 2012)
  101. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Art of lattice and gravity waves from preheating (Zhiqi Huang, PRD 83(12), 123509, 2011)
  102. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Parameterizing and Measuring Dark Energy Trajectories from Late-Inflatons (Zhiqi Huang, J. Richard Bond, Lev Kofman, ApJ 726(2), 64, 2011)
  103. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Particle production during inflation: Observational constraints and signatures (Neil Barnaby, Zhiqi Huang, PRD 80(12), 126018, 2009)
  104. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Preheating after modular inflation (Neil Barnaby, J. Richard Bond, Zhiqi Huang, Lev Kofman, JCAP 2009(12), 021, 2009)
  105. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Non-Gaussian Curvature Spikes from Chaotic Billiards in Inflation Preheating (J. Richard Bond, Andrei V. Frolov, Zhiqi Huang, Lev Kofman, PRL 103(7), 071301, 2009)
  106. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Cosmological fluctuations from infrared cascading during inflation (Neil Barnaby, Zhiqi Huang, Lev Kofman, Dmitry Pogosyan, PRD 80(4), 043501, 2009)
  107. [arxiv] [ADS] [doi] [bibtex] [wos] [CH]Cosmological Constraints on Decaying Dark Matter (Santiago De Lope Amigo, William Man-Yin Cheung, Zhiqi Huang, Siew-Phang Ng, JCAP 2009(06), 005, 2009)

Teaching

I have taught methods of mathematical physics, general relativity, quantum field theory, thermodynamics etc. Below are some notes (in Chinese) for undergraduate students.

Contributions to the Community:

Grants, Honors and Prizes

Invited Talks

Contact

Email: huangzhq25@mail.sysu.edu.cn
Tel:0756-3668932 (international: +86-756-3668932)
Address: School of Astronomy and Physics,
Sun Yat-sen University (Zhuhai campus),
2 Daxue Rd, Tangjia,
Zhuhai, 519082, CHINA
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