Publications of Chuanbing Wang

A list of publications authored or co-authored by Chuanbing Wang, derived from the SAO/NASA Astrophysics Data System (ADS). The number in brackets after each title indicates the number of citations that the paper has received.

Orcid ID: 0000-0001-6252-5580

List of publications ordered by citations
Number of papers: 40 (refereed: 40)
No. of citations: 838
First author papers: 7 (refereed: 7)

2026

  1. A Jovian Decametric Emission Event Observed Locally by Juno and Remotely by Wind and STEREO-A at 1 au [0]
    Zheng, Ruobing, Wang, Yuming & Wang, Chuanbing, ApJ, 996, 56

2025

  1. A Monte Carlo Simulation on the Scattering Coefficients of Solar Radio Wave Propagation [0]
    Gan, Jiazhen & Wang, Chuanbing, ApJ, 991, 153

2022

  1. FastQSL: A Fast Computation Method for Quasi-separatrix Layers [28]
    Zhang, PeiJin, Chen, Jun, Liu, Rui & Wang, ChuanBing, ApJ, 937, 26
  2. Imaging of the Quiet Sun in the Frequency Range of 20-80 MHz [26]
    Zhang, PeiJin, Zucca, Pietro, Kozarev, Kamen, Carley, Eoin, Wang, ChuanBing, Franzen, Thomas, Dabrowski, Bartosz, Krankowski, Andrzej, Magdalenic, Jasmina & Vocks, Christian, ApJ, 932, 17

2021

  1. Three-dimensional Reconstruction of Coronal Mass Ejections by the Correlation-aided Reconstruction Technique through Different Stereoscopic Angles of the Solar Terrestrial Relations Observatory Twin Spacecraft [8]
    Lyu, Shaoyu, Wang, Yuming, Li, Xiaolei, Guo, Jingnan, Wang, Chuanbing & Zhang, Quanhao, ApJ, 909, 182
  2. Parametric Simulation Studies on the Wave Propagation of Solar Radio Emission: The Source Size, Duration, and Position [17]
    Zhang, PeiJin, Wang, ChuanBing & Kontar, Eduard P., ApJ, 909, 195

2020

  1. A New Way for Walén Test of Alfvénic Fluctuations in Solar Wind Streams via EEMD [3]
    Liu, Jin, Wang, ChuanBing, Wang, PengYu, Du, Dan, Li, Xiang & Liu, GuoQi, ApJ, 891, 162
  2. The Frequency Drift and Fine Structures of Solar S-bursts in the High Frequency Band of LOFAR [4]
    Zhang, PeiJin, Zucca, Pietro, Wang, ChuanBing, Bisi, Mario M., Dabrowski, Bartosz, Fallows, Richard A., Krankowski, Andrzej, Magdalenic, Jasmina, Mann, Gottfried, Morosan, Diana E. & Vocks, Christian, ApJ, 891, 89

2019

  1. On the Source Position and Duration of a Solar Type III Radio Burst Observed by LOFAR [15]
    Zhang, PeiJin, Yu, SiJie, Kontar, Eduard P. & Wang, ChuanBing, ApJ, 885, 140
  2. Forward Modeling of the Type III Radio Burst Exciter [5]
    Zhang, Peijin, Wang, Chuanbing, Ye, Lin & Wang, Yuming, Solar Physics, 294, 62

2018

  1. A type III radio burst automatic analysis system and statistic results for a half solar cycle with Nançay Decameter Array data [36]
    Zhang, P. J., Wang, C. B. & Ye, L., A&A, 618, A165

2017

  1. A parametric investigation on the cyclotron maser instability driven by ring-beam electrons with intrinsic Alfvén waves [4]
    Tong, Zi-Jin, Wang, Chuan-Bing, Zhang, Pei-Jin & Liu, Jin, Physics of Plasmas, 24, 052902

2016

  1. The response of local power grid at low-latitude to geomagnetic storm: An application of the Hilbert Huang transform [3]
    Liu, Jin, Wang, Chuan-Bing, Liu, Lu & Sun, Wei-Huai, Space Weather, 14, 300

2015

  1. A Scenario for the Fine Structures of Solar Type IIIb Radio Bursts Based on Electron Cyclotron Maser Emission [16]
    Wang, C. B., ApJ, 806, 34
  2. A theory of heating of quiet solar corona [4]
    Wu, C. S., Yoon, P. H. & Wang, C. B., Physics of Plasmas, 22, 032901

2014

  1. Anomalous dynamics of the extremely compressed magnetosphere during 21 January 2005 magnetic storm [31]
    Dmitriev, A. V., Suvorova, A. V., Chao, J.-K., Wang, C. B., Rastaetter, L., Panasyuk, M. I., Lazutin, L. L., Kovtyukh, A. S., Veselovsky, I. S. & Myagkova, I. N., Journal of Geophysical Research (Space Physics), 119, 877
  2. Intense duskside lower band chorus waves observed by Van Allen Probes: Generation and potential acceleration effect on radiation belt electrons [51]
    Su, Zhenpeng, Zhu, Hui, Xiao, Fuliang, Zheng, Huinan, Wang, Yuming, He, Zhaoguo, Shen, Chao, Shen, Chenglong, Wang, C. B., Liu, Rui, Zhang, Min, Wang, Shui, Kletzing, C. A., Kurth, W. S., Hospodarsky, G. B., Spence, H. E., Reeves, G. D., Funsten, H. O., Blake, J. B., Baker, D. N. & Wygant, J. R., Journal of Geophysical Research (Space Physics), 119, 4266
  3. Compound Effect of Alfvén Waves and Ion-Cyclotron Waves on Heating/Acceleration of Minor Ions via the Pickup Process [6]
    Wang, C. B., Wang, Bin & Lee, L. C., Solar Physics, 289, 3895
  4. Ion temperature in plasmas with intrinsic Alfven waves [3]
    Wu, C. S., Yoon, P. H. & Wang, C. B., Physics of Plasmas, 21, 104507
  5. A study of line widths and kinetic parameters of ions in the solar corona [4]
    Zhao, G. Q., Wu, D. J. & Wang, C. B., Astrophysics and Space Science, 353, 373

2013

  1. Physical Process for the Pick-Up of Minor Ions by Low-Frequency Alfvén Waves [5]
    Wang, Chuan-Bing, Wei, Jing-Dong, Wang, Bin & Wang, Shui, Chinese Physics Letters, 30, 055201
  2. Effects of ion-neutral collisions on Alfvén waves: The presence of forbidden zone and heavy damping zone [1]
    Weng, C. J., Lee, L. C., Kuo, C. L. & Wang, C. B., Physics of Plasmas, 20, 032902

2012

  1. Resonant wave-particle interactions modified by intrinsic Alfvénic turbulence [27]
    Wu, C. S., Wang, C. B., Wu, D. J. & Lee, K. H., Physics of Plasmas, 19, 082902

2011

  1. Correlation Analyses Between the Characteristic Times of Gradual Solar Energetic Particle Events and the Properties of Associated Coronal Mass Ejections [9]
    Pan, Z. H., Wang, C. B., Wang, Yuming & Xue, X. H., Solar Physics, 270, 593
  2. Stochastic heating and acceleration of minor ions by Alfvén waves [20]
    Wang, Bin, Wang, C. B., Yoon, P. H. & Wu, C. S., Geophysical Research Letters, 38, L10103
  3. Imaging interplanetary CMEs at radio frequency from solar polar orbit [10]
    Wu, Ji, Sun, Weiying, Zheng, Jianhua, Zhang, Cheng, Liu, Hao, Yan, Jingye, Wang, Chi, Wang, Chuanbing & Wang, Shui, Advances in Space Research, 48, 943

2009

  1. Heating rate of ions via nonresonant interaction with turbulent Alfvén waves with ionization and recombination [15]
    Wang, Bin & Wang, C. B., Physics of Plasmas, 16, 082902
  2. Pseudoheating of protons in the presence of Alfvénic turbulence [31]
    Wang, C. B. & Wu, C. S., Physics of Plasmas, 16, 020703
  3. On nonresonant proton heating via intrinsic Alfvénic turbulence [12]
    Wu, C. S., Yoon, P. H. & Wang, C. B., Physics of Plasmas, 16, 054503
  4. Pitch-angle diffusion of ions via nonresonant interaction with Alfvénic turbulence [26]
    Yoon, P. H., Wang, C. B. & Wu, C. S., Physics of Plasmas, 16, 102102

2007

  1. Ring-beam driven maser instability for quasiperpendicular shocks [16]
    Yoon, Peter H., Wang, C. B. & Wu, C. S., Physics of Plasmas, 14, 022901

2006

  1. Heating of Ions by Alfvén Waves via Nonresonant Interactions [73]
    Wang, C. B., Wu, C. S. & Yoon, P. H., Physical Review Letters, 96, 125001
  2. Density Depletion in a Coronal Flux Tube Associated With Solar Radio Emission [12]
    Wu, C. S., Wang, C. B. & Lu, Q. M., Solar Physics, 235, 317

2005

  1. Altitude-dependent Emission of Type III Solar Radio Bursts [24]
    Wu, C. S., Wang, C. B., Zhou, G. C., Wang, S. & Yoon, P. H., ApJ, 621, 1129
  2. An ice-cream cone model for coronal mass ejections [88]
    Xue, X. H., Wang, C. B. & Dou, X. K., Journal of Geophysical Research (Space Physics), 110, A08103

2003

  1. Comment on ``Effects of fast and slow solar wind on the correlation between interplanetary medium and geomagnetic activity'' by P. Ballatore [1]
    Wang, C. B. & Chao, J. K., Journal of Geophysical Research (Space Physics), 108, 1386
  2. Influence of the solar wind dynamic pressure on the decay and injection of the ring current [101]
    Wang, C. B., Chao, J. K. & Lin, C.-H., Journal of Geophysical Research (Space Physics), 108, 1341

2002

  1. Generation of Type III Solar Radio Bursts in the Low Corona by Direct Amplification [65]
    Wu, C. S., Wang, C. B., Yoon, Peter H., Zheng, H. N. & Wang, S., ApJ, 575, 1094
  2. Generation of Type III Solar Radio Bursts in the Low Corona by Direct Amplification. II. Further Numerical Study [33]
    Yoon, Peter H., Wu, C. S. & Wang, C. B., ApJ, 576, 552

1995

  1. Influence of poloidal rotation on the toroidally coupled tearing mode [5]
    Li, Ding & Wang, Chuanbing, Physics of Plasmas, 2, 1026

Created on Wed Apr 22 04:28:04 2026.