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2. Wang, H., C. Wang, & L. Zhang, 2024: Differentiated impacts of central and eastern Atlantic Niño on hurricane activity in the tropical North Atlantic.  Geophys. Res. Lett., 51, e2024GL112178.

3. Richter, I., N. Keenlyside, T. Tozuka, Y. Okumura, C. Wang, P. Chang, S. Kido, & H. Tokinaga, 2024: Comment on “Resolving the tropical Pacific/Atlantic interaction conundrum” by Feng Jiang et al. (2023).  Geophys. Res. Lett., 51, e2024GL111563.

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5. Hou, Y., S.-P. Xie, N. Jonhson, C. Wang, C. Yoo, K. Deng, W. Sun, & Xichen Li, 2024: Unveiling the Indian Ocean forcing on winter eastern warming–western cooling pattern over North America.  Nature Communications, 15, 9654.

6. Yao, Y., & C. Wang, 2024: Subsurface marine heatwaves in the South China Sea.  J. Geophys. Res., 129, e2024JC021356.

7. Hu, Y., X. H. Wang, H. Beggs, & C. Wang, 2024: Intrinsic short Marine Heatwaves from the perspective of sea surface temperature and height.  Weather and Climate Extremes, 46, 100725.

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9. Fan, H., C. Wang, S. Yang, & G. Zhang, 2024: Coupling is key for the tropical Indian and Atlantic Oceans to boost super El Niño.  Science Advances, 10, eadp2281. 

10. Lu, Z., L. Dong, F. Song, B. Wu, S. Wu, & C. Wang, 2024: Quantifying relative contributions of three tropical oceans to the western North Pacific anomalous anticyclone.  Environ. Res. Lett., 19, 104016.

11. Ji, X., J. Feng, J. Li, X. Chen, & C. Wang, 2024: A quantitative explanation for the large impacts of El Niño during its decaying stage.  Environ. Res. Lett., 19, 084034.

12. Liu, T., C. Wang, J. Yang, X. Song, J. Zheng, & Y. Wen, 2024: Investigating the seasonal SST predictability in the northern tropical Atlantic Ocean in an ensemble prediction system.  Clim. Dyn., 62, 7889–7904.

13. Wang, Y., W. Zhou, & C. Wang, 2024: Physical mechanism of the rapid increase in intense and long-lived extreme heatwaves in the Northern Hemisphere since 1980.  Sci. China Earth Sci., 67, 2103–2121.

14. Song, Q., C. Wang, Y. Yao, & H. Fan, 2024: Unraveling the Indian monsoon’s role in fueling the unprecedented 2022 marine heatwave in the western North Pacific.  npj Clim. Atmos. Sci., 7: 90.

15. Xie, M., B. Wu,J.-Z. Wang, C. Wang, & X. Sun, 2024: Formation mechanisms of the decadal Indian Ocean dipole driven by remote forcing from the tropical Pacific.  J. Climate, 37, 3493–3507.

16. Ji, X., J. Feng, J. Li, & C. Wang, 2024: Do CMIP6 models capture the observed anomalous asymmetric Hadley circulation during historical El Niño decaying stage?  Clim. Dyn., 62, 2475–2487.

17. Chen, B., L. Zhang, & C. Wang, 2024: Distinct impacts of the central and eastern Atlantic Niño on the European climate.  Geophys. Res. Lett., 51, e2023GL107012.

18. Wei, S., X. Wang, C. Wang, & Q. Xie, 2024: El Niño phase transition by deforestation in the Maritime Continent.  npj Clim. Atmos. Sci., 7: 3.

19. Xing, W., C. Wang, L. Zhang, & J. Zheng, 2024: Prediction of summer surface air temperature over Northern Hemisphere continents by a physically based empirical model.  Clim. Dyn., 62: 3289–3303.

20. Zhu, Q., & C. Wang, 2024: Contributions of Indo-Pacific forcings to interannual variability of the Indonesian Throughflow in the upper and lower layers.  J. Geophys. Res., 129, e2023JC020306.

21. Zhang, L., C. Wang, W. Han, M. J. McPhaden, A. Hu, & W. Xing, 2023: Emergence of the central Atlantic Niño.  Science Advances, 9, eadi5507.

22. Song, Q., Y. Yao, & C. Wang, 2023: Response of future summer marine heatwaves in the South China Sea to enhanced western Pacific subtropical high.  Geophys. Res. Lett., 50, e2023GL103667.

23. Fan, H., C. Wang, & S. Yang, 2023: Asymmetry between positive and negative phases of the pacific meridional mode: a contributor to ENSO transition complexity.  Geophys. Res. Lett., 50, e2023GL104000.

24. Wang, F., X Li, X. Tang, X. Sun, J. Zhang, D. Yang, L. Xu, H. Zhang, H. Yuan, Y. Wang, Y. Yao, C. Wang, Y. Guo, Q. Ren, Y. Li, R. Zhang, X. Wang, B. Zhang, and Z. Sha, 2023: The seas around China in a warming climate.  Nature Reviews Earth & Environment, 4, 535–551.

25. Wang, H., and C. Wang, 2023: Large-scale anomalous cyclone in the western North Pacific.  J. Climate, 36, 5895-5906.

26. Fan, H., S. Yang, C. Wang, and S. Lin, 2023: Revisiting impacts of tropical Pacific SST anomalies on Pacific meridional mode during the decay of strong eastern Pacific El Niño events.  J. Climate, 36, 4987-5002.

27. Yao, Y., C. Wang, and C. Wang, 2023: Record-breaking 2020 summer marine heatwaves in the western North Pacific.  Deep-Sea Research II, 208, 105288.

28. Zhang, R., W. Guo, X. Wang, and C. Wang, 2023: Ambiguous variations in tropical latent heat flux since the years around 1998.  J. Clim., 36, 3403–3415.

29. Wei, L., and C. Wang, 2023: Characteristics of ocean mesoscale eddies in the Agulhas and Tasman leakage regions from two eddy datasets.  Deep-Sea Research II, 208, 105264. 

30. Zhang, J., and C. Wang, 2023: Zonal current structure of the Indian Ocean in CMIP6 models.  Deep-Sea Research II, 208, 105260. 

31. Wang, Y., and C. Wang, 2023: Classification of extreme heatwave events in the Northern Hemisphere through a new method.  Clim. Dyn., 61, 1947-1969.

32. Lin, W., and C. Wang, 2023: Detection and attribution of the summer length changes in the Northern Hemisphere.  Clim. Dyn., 60 (11-12), 3801-3812.

33. Wang, C, J. Zheng, W. Lin, and Y. Wang, 2023: Unprecedented heatwave in western North America during late June of 2021: Roles of atmospheric circulation and global warming.  Adv. Atmos. Sci., 40, 14-28.

34. Gao, C., L. Zhou, C. Wang, I.-I. Lin, and R. Murtugudde, 2022: Unexpected limitation of tropical cyclone genesis by subsurface tropical central-north Pacific during El Niño.  Nature Communications, 13 (1): 7746.

35. Lu, H., Z. Chen, K. Xu, Z. Liu, C. Wang, J. Xu, Y. Gong, and S. Cai, 2022: Interannual variability of near-inertial energy in the South China Sea and western North Pacific.  Geophys. Res. Lett., 49 (24).

36. Liu, T., Y. Tang, C. Wang, and X. Song, 2022: Probabilistic prediction of ENSO over the past 137 years using the CESM model.  J. Geophys. Res., 127 (12).

37. Yao, Y., and C. Wang, 2022: Marine heatwaves and cold-spells in global coral reef zones.  Progress in Oceanography, 209, 102920.

38. Yao, Y., C. Wang, and Y. Fu, 2022: Global marine heatwaves and cold-spells in present climate to future projections.  Earth's Future, 10, e2022EF002787.

39. Jiang, S., H. Fan, and C. Wang, 2022: Improvement of typhoon intensity forecasting by using a novel spatio-temporal deep learning model.  Remote Sens., 14, 5205.

40. Ding, R., Y.-H. Tseng, E. D. Lorenzo, L. Shi, J. Li, J.-Y. Yu, C. Wang, C. Sun, J.-J. Luo, K.-J. Ha, Z.-Z. Hu, and F. Li, 2022: Multi-year El Niño events tied to the North Pacific Oscillation.  Nature Communications, 13 (1), 1-11.

41. Sun, C., Y. Liu, T. Wei, F. Kucharski, J. Li, and C. Wang, 2022: Cross-hemispheric SST propagation enhances the predictability of tropical western Pacific climate.  npj Clim. Atmos. Sci., 5, 38.

42. Fan, H., S. Yang, C. Wang, Y. Wu, and G. Zhang, 2022: Strengthening amplitude and impact of the Pacific meridional mode on ENSO in the warming climate depicted by CMIP6 models.  J. Climate, 35, 5195-5213.

43. Wang, H., and C. Wang, 2022: What caused the increase of tropical cyclones in the western North Pacific during the period of 2011-2020?  Clim. Dyn., 60, 165-177.

44. Zheng, M., and C. Wang, 2022: Interdecadal changes of tropical cyclone intensity in the South China Sea.  Clim. Dyn., 60, 409-425.

45. Li, W., X. Li, X. Zhao, C. Sun, T. Nie, Y. Hu, and C. Wang, 2022: Impacts of climate change and human perturbations on organic carbon burial in the Pearl River Estuary over the last century.  Front. Mar. Sci., 9, 848757.

46. Fu, Y., P. Brandt, F. P. Tuchen, J. F. Lübbecke, and C. Wang, 2022: Representation of the mean Atlantic subtropical cells in CMIP6 models.  J. Geophy. Res., 127, e2021JC018191.

47. Zhao, H., K. Zhao, P. J. Klotzbach, L. Wu, and C. Wang, 2022: Interannual and interdecadal drivers of meridional migration of western North Pacific tropical cyclone lifetime maximum intensity location.  J. Climate, 35, 2709-2722.

48. Lin, W., and C. Wang, 2022: Longer summers in the Northern Hemisphere under global warming.  Clim. Dyn., 58, 2293–2307.

49. Xie, M., C. Wang, and S. Chen, 2022: The role of the Maritime Continent SST anomalies in maintaining the Pacific-Japan pattern on decadal time scales.  J. Climate, 35, 1079-1095.

50. He, C., Z. Cui, and C. Wang, 2022: Response of western North Pacific anomalous anticyclone in the summer of decaying El Niño to global warming: Diverse projections based on CMIP6 and CMIP5 models.  J. Climate, 35, 359-372.