Professional Experiences

• Professor, Department of Atmospheric Sciences, National Central University, Aug. 2015~present

• Chair, Department of Atmospheric Sciences, National Central University, Aug. 2020~Jul. 2023 

• Coordinator of Atmospheric Science Discipline, Ministry of Science and Technology (科技部大氣學門召集人), Jan. 2017~Dec. 2019

• Chair, Department of Atmospheric Sciences, Chinese Culture University, Aug. 2004~Jul. 2009

• Professor, Department of Atmospheric Sciences, Chinese Culture University, Feb. 1999~Jul. 2015

• Associate Professor, Department of Atmospheric Sciences, Chinese Culture University, Aug. 1994~Jan. 1999

• Research Associate of Atmospheric Sciences Department, University of California, Los Angeles, Jul. 1993~Jul. 1994

Research Areas

My recent research interests focus on the dynamics and energetics of climate variability and oscillation involving interactions between cumulus convection, large-scale circulation and radiation. Specific works include (1) developing a physically-based, convective quasi-equilibrium (CQE) theory suitable for low-frequency climate variability and climate change studies; (2) exploring the dynamics and energetics of cloud-radiation-circulation interactions in tropical waves and oscillation (e.g., Kelvin wave, Rossby wave, Madden-Julian Oscillation and El Niño/Southern Oscillation) in both the present climate and the future warming climate; (3) projecting the potential impacts of anthropogenic global warming on tropical cyclone (TC) activity (including genesis frequency, intensity and track) over the Western North Pacific and South China Sea. 

Honors and Awards

• 2023 Excellent Thesis Contribution Award, National Central University  (中央大學優良論文貢獻獎 ) 

• 2019, 2020, 2021, 2022, 2023, 2024: Outstanding Research Awards, National Central University (中央大學研究傑出獎勵六次) 

• 2019: Dr. Huang Research Paper Award, Meteorological Society of ROC (中華民國氣象學會黃廈千博士論文獎) 

• 2017: Excellent Paper Award, Meteorological Society of ROC (中華民國氣象學會優良論文獎)

• 2013, 2014, 2015: Special Outstanding Faculty Awards, Ministry of Science and Technology (科技部大專院校特殊優秀人才獎勵三次)

• 2012, 2014: TAO Best Article Award, Chinese Geoscience Union (地球科學會TAO期刊最佳論文獎兩次)

• 2012, 2014: TAO Best Reviewer Award, Chinese Geoscience Union (地球科學會TAO期刊最佳審查人獎兩次)

• 2012: Outstanding Teaching Award, Chinese Culture University (中國文化大學教學傑出獎)

• 2009~2014: Research Paper Award, Chinese Culture University (中國文化大學研究著作獎勵五次)

• 1995, 1997, 1998: Excellent Research Award, National Science Council (國科會甲種研究獎勵三次)

Journal Article Publications (* corresponding author)

2024

1. Li, J.-L., K.-M. Xu, J. H. Jiang, W.-L. Lee, J.-Y. Yu, J. Chern, G. V. Cesana, L. Wu, and G. Stephens, 2024: Investigating the "Too Bright" issue pertaining to non-PBL clouds over the South Pacific trade-wind regions in CMIP6 global climate models. Geophysical Research Letters, 51, https://doi.org/10.1029/2024GL112006 (in production)

2. Dang, D.-F., and J.-Y. Yu*, 2024: Solutions for tropical vertical motion under convective quasi-equilibrium constraints. Journal of the Atmospheric Sciences, 81, 1371-1381. https://doi.org/10.1175/JAS-D-23-0218.1

3. Li, Y.-X., H. Masunaga, H. Takahashi, and J.-Y. Yu*, 2024: When, where and to what extent do temperature perturbations near tropical deep convection follow convective quasi-equilibrium? Geophysical Research Letters, 51, e2024GL108233. https://doi.org/10.1029/2024GL108233

4. Horng, Y.-B., and J.-Y. Yu*, 2024: On the energetics of convectively coupled Kelvin waves: contrast between Indian and Pacific Basins. Climate Dynamics, 62, 6875-6891. https://doi.org/10.1007/s00382-024-07254-7

5. Chang, C.-W., M.-H. Lo, W.-L. Tseng, Y.-C. Tsai, and J.-Y. Yu, 2024: Impact of deforestation in the Maritime Continent on the Madden-Julian Oscillation. Journal of Climate, 37, 2247-2261. https://doi.org/10.1175/JCLI-D-22-0746.1

2023

6. Shen, M.-H., and J.-Y. Yu*, 2023: Changes in El Niño characteristics and air-sea feedback mechanisms under progressive global warming. Terrestrial Atmospheric & Oceanic Sciences, 34:19. https://doi.org/10.1007/s44195-023-00051-5【2024中華民國地球科學會大道新人獎獲獎論文】

7. Li, J.-L., W.-L. Lee, K.-M. Xu, Y.-C. Tsai, J. H. Jiang, J.-Y. Yu, G. Stephens, E. J. Fetzer, and W.-T. Chen, 2023: Radiatively-active hydrometeor frequencies from CloudSat-CALIPSO data for evaluating cloud fraction in global climate models. Journal of Geophysical Research: Atmospheres, 128, e2023JD038511. https://doi.org/10.1029/2023JD038511

8. Li, J.-L., K.-M. Xu, Y.-C. Tsai, W.-L. Lee, J. Jiang, J.-Y. Yu, E. J. Fetzer, L. Wu, and G. Stephens, 2023: Evaluation of radiatively active frozen hydrometeors mass in CMIP6 global climate models using CloudSat-CALIPSO observations. Journal of Geophysical Research: Atmospheres, 128, e2023JD039200. https://doi.org/10.1029/2023JD039200

9. Li, J.-L., K.-M. Xu, W.-L. Lee, J. H. Jiang, Y.-C. Tsai, J.-Y. Yu, E. J. Fetzer, L. Wu, and G. Stephens, 2023: Warm clouds biases in CMIP6 models linked to indirect effects of falling ice-radiation interactions over the tropical and subtropical Pacific. Geophysical Research Letters, 50, e2023GL104990. https://doi.org/10.1029/2023GL104990

10. Tsai, Y.-C., J.-L. Li, K.-M. Xu, W.-L. Lee, J. H. Jiang, E. Fetzer, and J.-Y. Yu*, 2023: Possible linkage of sea surface height anomaly, surface wind stress and sea surface temperature with the falling ice radiative effects under a gradual warming scenario. Environmental Research Communications, 5, 085004. https://doi.org/10.1088/2515-7620/acee4c

11. Fu, Y.-D., M.-C. Yen, N.-H. Lin, H. Bui-Manh, C.C. Lin, J.-Y. Yu, C.-M. Peng, and D.-T. Dinh, 2023: Footprints of El Niño La Niña on the particulate matter evolution over subtropical island Taiwan. npj Climate and Atmospheric Science, 6, 42. https://doi.org/10.1038/s41612-023-00383-6

12. Bui, H. X., Y.-X. Li, E. D. Maloney, J.-E Kim, S.-S. Lee, and J.-Y. Yu, 2023: Emergence of Madden-Julian Oscillation precipitation and wind amplitude changes in a warming climate. npj Climate and Atmospheric Science, 6, 22. https://doi.org/10.1038/s41612-023-00344-z

13. Tsai, Y.-C., and J.-Y. Yu*, 2023: Contrasting the energy recharge-discharge cycle between propagating and eastward-decaying Madden-Julian Oscillation events. Climate Dynamics, 61, 2565-2579. https://doi.org/10.1007/s00382-023-06711-z

14. Wang, L.-C., T. L. Dao, Y.-F. Lin, and J.-Y. Yu, 2023: The dynamics of the equatorial Atlantic upwelling seasonal cycle under global warming and its potential impact on Pacific ENSO. Climate Dynamics, 59, 1757-1768. https://doi.org/10.1007/s00382-022-06654-x

2022

15. Li, J.-L., Y.-C. Tsai, K.-M. Xu, W.-L. Lee, J. H. Jiang, J.-Y. Yu, E. J. Fetzer, and G. Stephens, 2022: Inferring the linkage of sea surface height anomalies, surface wind stress and sea surface temperature with the falling ice radiative effects using satellite data and global climate models. Environmental Research Communications, 4, 125004. https://doi.org/10.1088/2515-7620/aca3fe

16. Wang, L.-C., L.-T. Dao, and J.-Y. Yu, 2022: Continued weakening of the equatorial Pacific upwelling annual cycle in CMIP5 future projections. Scientific Reports, 12, 15595. https://doi.org/10.1038/s41598-022-19874-2

17. Lin, Q.-J., and J.-Y. Yu*, 2022: The potential impact of model horizontal resolution on the simulation of atmospheric cloud-radiative effect in CMIP6 models. Terrestrial Atmospheric & Oceanic Sciences, 33, 21. https://doi.org/10.1007/s44195-022-00021-3【2023中華民國地球科學會大道新人獎獲獎論文】

18. Li, Y.-X., J. D. Neelin, Y.-H. Kuo, H.-H. Hsu, and J.-Y. Yu*, 2022: How close are leading tropical tropospheric temperature perturbations to those under convective quasi-equilibrium? Journal of the Atmospheric Sciences, 79, 2139-2153. https://doi.org/10.1175/JAS-D-21-0315.1

19. Li, J.-L., K.-M. Xu, W.-L. Lee, J. H. Jiang, Y.-C. Tsai, E. J. Fetzer, G. Stephens, Y.-H. Wang, and J.-Y. Yu, 2022: Comparing surface wind stress and sea surface temperature biases over the tropical and subtropical oceans in subsets of CMIP6 models categorized by frozen hydrometeors-radiation interactions. Environmental Research Communications, 4, 055009. https://doi.org/10.1088/2515-7620/ac70ac

20. Dao, L T., and J.-Y. Yu*, 2022: Changes of local tropical cyclone activity over the South China Sea under global warming in HiRAM projections. International Journal of Climatology, 42(5), 2965-2980. https://doi.org/10.1002/JOC.7401

21. Li, J.-L., K.-M. Xu, W.-L. Lee, J. Jiang, E. J. Fetzer, G. Stephens, Y.-H. Wang, and J.-Y. Yu, 2022: Exploring radiation biases over the tropical and subtropical oceans based on treatments of frozen hydrometeor radiative properties in CMIP6 models. Journal of Geophysical Research: Atmospheres, 127(7), e2021JD035976. https://doi.org/10.1029/2021JD035976

22. Mandal, G., J.-Y. Yu, and S.-Y. Lee, 2022: The roles of orbital and meltwater climate forcings on the Southern Ocean dynamics during the last deglaciation. Sustainability, 14, 2927. https://doi.org/10.3390/su14052927

23. Li, J.-L., W.-L. Lee, K.-M. Xu, J. H. Jiang, Y.-H. Wang, E. J. Fetzer, G. Stephens, J.-Y. Yu, and Y. Liu, 2022: Observational evaluation of global climate model simulations of arctic sea ice and adjacent land pertaining to the radiative effects of frozen hydrometeors. Environmental Research Communications, 4, 025008. https://doi.org/10.1088/2515-7620/ac556b

2021

24. Wang, L.-C., J.-L. Li, K.-M. Xu, L. T. Dao, W.-L. Lee, J. H. Jiang, E. Fetzer, Y.-H. Wang, J.-Y. Yu., C.-A. Chen, 2021: The Potential Influence of Falling Ice Radiative Effects on Central-Pacific El Niño Variability under Progressive Global Warming. Environmental Research Letters, 16, 124062. https://doi.org/10.1088/1748-9326/ac3d56

25. Dao, L T., L.-C. Wang, and J.-Y. Yu*, 2021: Impacts of Madden-Julian Oscillation on Tropical Cyclone Activity over the western North Pacific under global warming. Terrestrial, Atmospheric & Oceanic Sciences, 32(6), 1081-1096. https://doi.org/10.3319/TAO.2021.10.01.02【2022中華民國地球科學會大道新人獎獲獎論文】

26. Li, J.-L. F., K.-M. Xu, W.-L. Lee, J. H. Jiang, E. Fetzer, G. Stephens, J.-Y. Yu, and Y.-H. Wang, 2021: Changes of south-central Pacific large-scale environment associated with hydrometeors-radiation-circulation interactions in a coupled GCM. Journal of Geophysical Research: Atmospheres, 126, e2021JD034973. https://doi.org/10.1029/2021JD034973

27. Li, J.-L., W.-L. Lee, K.-M. Xu, J. H. Jiang, E. Fetzer, L.-C. Wang, J.-Y. Yu, Y.-H. Wang, and G. Stephens, 2021: Linking global land surface temperature projections to radiative effects of hydrometeors under a global warming scenario. Environmental Research Letters, 16, 084044. https://doi.org/10.1088/1748-9326/ac153c

28. Li, J.-L., K.-M. Xu, M. Richardson, J. H. Jiang, G. Stephens, W.-L. Lee, E. Fetzer, J.-Y. Yu, Y.-H. Wang, and F.-J. Wang, 2021: Improved ice content, radiation, precipitation and low-level circulation over the tropical Pacific from ECMWF ERA-Interim to ERA5. Environmental Research Communications, 3, 081006. https://doi.org/10.1088/2515-7620/ac1bfe

29. Chen, Y.-C., and J.-Y. Yu*, 2021: Modes of tropical convection and their roles in transporting moisture and moist static energy: Contrast between deep and shallow convection. Climate Dynamics, 57(7), 1789-1803. https://doi.org/10.1007/s00382-021-05777-x

30. Bui, H.-X., and J.-Y. Yu*, 2021: Impacts of model spatial resolution and the associated cloud radiative effect on the simulation of convective spectrum in the tropics. Journal of the Meteorological Society of Japan, 99(4), 789-802. https://doi.org/10.2151/jmsj.2021-039

31. Li, J.-L., K.-M. Xu, W.-L. Lee, J. Jiang, Y.-H. Wang, E. Fetzer, J.-Y. Yu, and L.-C. Wang, 2021: Comparisons of radiation-circulation coupling over the tropical and subtropical ocean between AMIP6 and CMIP6. Terrestrial, Atmospheric & Oceanic Sciences, 32(1), 89-112. https://doi.org/10.3319/TAO.2020.09.17.01

32. Li, J.-L., W.-L. Lee, K.-M. Xu, J. Jiang, E. Fetzer, C.-A. Chen, P.-C. Hsu, H.-H. Hsu, J.-Y. Yu, and Y.-H. Wang, 2021: Impacts of falling ice radiative effects on projections of Southern Ocean sea ice change under global warming. Terrestrial, Atmospheric & Oceanic Sciences, 32(1), 113-131. https://doi.org/10.3319/TAO.2020.10.15.01

33. Darmawan, Y., H.-H. Hsu, and J.-Y. Yu, 2021: Characteristics of large-scale circulation affecting the inter-annual precipitation variability in northern Sumatra island during boreal summer. Atmosphere, 12(2), 136. https://doi.org/10.3390/atmos12020136

34. Mandal, G., S.-Y. Lee, and J.-Y. Yu, 2021: The roles of wind and sea ice in driving the deglacial change.in the Southern Ocean upwelling: A modeling study. Sustainability, 13, 353. https://doi.org/10.3390/su13010353

35. Dao, L. T., and J.-Y. Yu*, 2021: Impacts of Madden-Julian Oscillation on tropical cyclone activity over the South China Sea: Observations versus HiRAM simulations. International Journal of Climatology, 41, 830-845. https://doi.org/10.1002/JOC.6673

2020

36. Li, J.-L., K.-M. Xu, M. Richardson, W.-L. Lee, J. Jiang, J.-Y. Yu, Y.-H. Wang, E. Fetzer, L.-C. Wang, G. Stephens, H.-C. Liang, 2020: Annual and seasonal mean tropical and subtropical precipitation bias in CMIP5 and CMIP6 models. Environmental Research Letters, 15, 124068. https://doi.org/10.1088/1748-9326/abc7dd

37. Feng, T., X.-Q. Yang, J.-Y. Yu, and R. Huang, 2020: Convective coupling in tropical-depression-type waves. Part I: Rainfall characteristics and moisture structure. Journal of the Atmospheric Sciences, 77, 3407-3422. https://doi.org/10.1175/JAS-D-19-0172.1

38. Feng, T., J.-Y. Yu, X.-Q. Yang, and R. Huang, 2020: Convective coupling in tropical-depression-type waves. Part II: Moisture and moist static energy budgets. Journal of the Atmospheric Sciences, 77, 3423-3440. https://doi.org/10.1175/JAS-D-19-0173.1

39. Li, J.-L., K.-M Xu, J. Jiang, W.-L. Lee, L.-C. Wang, J.-Y. Yu, G. Stephens, E. Fetzer, and Y.-H. Wang, 2020: An overview of CMIP5 and CMIP6 simulated cloud ice, radiation fields, surface wind stress, sea surface temperatures, and precipitation over tropical and subtropical oceans. Journal of Geophysical Research: Atmospheres, 125, e2020JD032848. https://doi.org/10.1029/2020JD032848

40. Li, J.-L., W.-L. Lee, K.-M. Xu, J. H. Jiang, E. Fetzer, C.-A. Chen, Y.-H. Wang, J.-Y. Yu, P.-C. Hsu, and H.-H. Hsu, 2020: The role of falling ice radiative effects on climate projections over Arctic under Global Warming. Terrestrial, Atmospheric & Oceanic Sciences, 31(6), 633-648. https://doi.org/10.3319/TAO.2020.04.29.01

41. Hsiao, L.-P., C.-H. Tsou, and J.-Y. Yu*, 2020: Investigating the abrupt change of tropical cyclone activity in the western North Pacific by using different TC genesis indices. Internal Journal of Climatology, 40, 5959-5972. https://doi.org/10.1002/JOC.6558

42. Chen, Y.-C., J.-L. Li, W.-L. Lee, D. Diner, M. Garay, J. Jiang, Y.-H. Wang, J.-Y. Yu, and O. Kalashnikova, 2020: Evaluation of sea salt aerosols in climate systems: Global climate modeling and observation-based analyses. Environmental Research Letters, 15, 034047. https://doi.org/10.1088/1748-9326/ab751c

43. Li, Y.-X., and J.-Y. Yu*, 2020: Why rare tropical cyclone formation after maturity of super El Nino Events in the western North Pacific? Terrestrial, Atmospheric & Oceanic Sciences, 31(1), 21-32. https://doi.org/10.3319/TAO.2019.06.23.01【中華民國氣象學會黃廈千學術論文獎獲獎論文】

2019

44. Lee, W.-L., J.-L. Li, K.-M. Xu, E. Suhas, J. H. Jiang, Y.-H. Wang, G. Stephens, E. Fetzer, and J.-Y. Yu, 2019: Relating precipitating ice radiative effects to surface energy balance and temperature biases over the Tibetan Plateau in winter. Journal of Geophysical Research: Atmospheres, 124, 12455-12467. https://doi.org/10.1029/2018JD030204

45. Lan, C.-W., M.-H. Lo, C.-A. Chen, and J.-Y. Yu, 2019: The mechanisms behind changes in the seasonality of global precipitation found in reanalysis products and CMIP5 simulations. Climate Dynamics, 53, 4173-4187. https://doi.org/10.1007/s00382-019-04781-6

46. Wang, L.-C., and J.-Y. Yu, 2019: Dynamics of upwelling annual cycle in the equatorial Pacific Ocean. Sustainability, 11(18), 5038. https://doi.org/10.3390/su11185038

47. Bui, H. X., J.-Y. Yu*, H.-W. Liu, C.-Y. Tu, P.-G. Chiu, and H.-H. Hsu, 2019: Convective structure changes over the equatorial Pacific with highly increased precipitation under global warming simulated in the HiRAM. SOLA, 15, 119-124. https://doi.org/10.2151/sola.2019-022

48. Li, J.-L. F., M. Richardson, W.-L. Lee, E. Fetzer, G. Stephens, J. Jiang, Y. Hong, Y.-H. Wang, J.-Y. Yu, and Y. Liu, 2019: Potential faster Arctic sea ice retreat triggered by snowflakes’ greenhouse effect. Cryosphere, 13, 969-980. https://doi.org/10.5194/tc-13-969-2019

49. Bui, H. X., J.-Y. Yu*, and C. Chou, 2019: Impacts of model spatial resolution on the vertical structure of convection in the tropics. Climate Dynamics, 52, 15-27. https://doi.org/10.1007/s00382-018-4125-3

2018

50. Chen, C.-A., J.-L. F. Li, M. Richardson, W.-L. Lee, E. Fetzer, G. Stephens, H.-H. Hsu, Y.-H. Wang, J.-Y. Yu, 2018: Falling snow radiative effects enhance the global warming response of the tropical Pacific atmosphere. Journal of Geophysical Research: Atmospheres, 123, 10109-10124. https://doi.org/10.1029/2018JD028655 【Nature Climate Change Editors’ Highlight】

51. Liu, H.-W., J.-Y. Yu*, and C.-A. Chen, 2018: Changes of tropical precipitation and convective structure under global warming projected by CMIP5 model simulations. Terrestrial, Atmospheric & Oceanic Sciences, 29(4), 429-440. https://doi.org/10.3319/TAO.2017.11.29.01【中華民國氣象學會黃廈千學術論文獎獲獎論文】

52. Yu*, J.-Y., L.-P. Hsiao, and P.-G. Chiu, 2018: Evaluating the Emanuel-Nolan genesis potential index: Contrast between North Atlantic and western North Pacific. Terrestrial, Atmospheric & Oceanic Sciences, 29(2), 201-214. https://doi.org/10.3319/TAO.2017.09.27.01【中華民國氣象學會黃廈千學術論文獎獲獎論文】

53. Li, J.-L. F., E. Suhas, M. Richardson, W.-L. Lee, Y.-H. Wang, J.-Y. Yu, T. Lee, and E. Fetzer, G. Stephens, and M.-H. Shen, 2018: The impacts of bias in cloud-radiation-dynamics interactions on central-Pacific seasonal and El Nino simulations in contemporary GCMs. Earth and Space Science, 5, 50-60. https://doi.org/10.1002/2017EA000304

2017

54. 蕭立朋、余嘉裕*，2017: 適合西北太平洋海域之颱風生成潛在指數，大氣科學，45(3), 221-240. https://doi.org/10.3966/025400022017094503002

55. Li, J.-L. F., M. Richardson, Y. Hong, W.-L. Lee, Y.-H. Wang, J.-Y. Yu, E. Fetzer, G. Stephens, and Y. Liu, 2017: Improved simulation of Antarctic sea ice due to the radiative effects of falling snow. Environmental Research Letters, 12, 084010. https://doi.org/10.1088/1748-9326/aa7a17【ERL Editors’ Highlight】

2016

56. Li, J.-L. F., W.-L. Lee, Y.-H. Wang, E. Suhas, J.-Y. Yu, M. Richardson, E. J. Fetzer, M.-H. Lo, Q. Yue, 2016: Assessing the radiative impacts of precipitating clouds on winter surface air temperatures and land surface properties in general circulation models using observations. Journal of Geophysical Research: Atmospheres, 121, 11536-11555. https://doi.org/10.1002/2016JD025175【JGR Editors’ Highlight】

57. Bui, H. X., J.-Y. Yu*, and C. Chou, 2016: Impacts of vertical structure of large-scale vertical motion in tropical climate: Moist static energy framework. Journal of the Atmospheric Sciences, 73, 4427-4437. https://doi.org/10.1175/JAS-D-16-0031.1

58. Li, J.-L, F., Y.-H. Wang, T. Lee, D. Waliser, W.-L. Lee, J.-Y. Yu, Y.-C. Chen, E. Fetzer, and A. Hasson, 2016: The impacts of precipitating cloud radiative effects on ocean surface evaporation, precipitation, and ocean salinity in coupled GCM simulations. Journal of Geophysical Research: Atmospheres, 121, 9474-9491. https://doi.org/10.1002/2016JD024911

59. 劉曉薇、余嘉裕、張瓊文，2016: 全球暖化下黑潮變化及對區域氣候之影響，大氣科學，44(3)，197-213。

60. 劉曉薇、余嘉裕，2016: 熱帶地區氣柱水汽量與降水強度關係之分析，大氣科學，44(2)，135-147。【中華民國氣象學會優良論文獎獲獎論文】

61. Chen, C.-A., J.-Y. Yu, and C. Chou, 2016: Impacts of vertical structure of convection in global warming: The role of shallow convection. Journal of Climate, 29, 4665-4684. https://doi.org/10.1175/JCLI-D-15-0563.1

62. Li, J.-L. F., W.-L. Lee, D. Waliser, Y.-H. Wang, J.-Y. Yu, X. Jiang, T. L'Ecuyer, Y.-C. Chen, T. Kubar, E. Fetzer, and M. Mahakur, 2016: Considering the radiative effects of snow on tropical Pacific Ocean radiative heating profiles in contemporary GCMs using A-Train observations. Journal of Geophysical Research: Atmospheres, 121, 1621-1636. https://doi.org/10.1002/2015JD023587

63. Li, J.-L. F., W.-L. Lee, J.-Y. Yu, G. Hulley, E. Fetzer, Y.-C. Chen, and Y.-H. Wang, 2016: The Impacts of precipitating hydrometeors radiative effects on land surface temperature in contemporary GCMs using satellite observations. Journal of Geophysical Research: Atmospheres, 121, 67-79. https://doi.org/10.1002/2015JD023776

2015 and before

64. Wu, L., J.-L. F. Li, C.-J. Pi, J.-Y. Yu, and J.-P. Chen, 2015: An observationally based evaluation of WRF seasonal simulations over the Central and Eastern Pacific. Journal of Geophysical Research: Atmospheres, 120, 10664-10680. https://doi.org/10.1002/2015JD023561【JGR Featured Article】

65. Li, J.-L., W.-L. Lee, T. Lee, E. Fetzer, J.-Y. Yu, T. L. Kubar, and C. Boening, 2015: The impacts of cloud snow radiative effects on Pacific Ocean surface heat fluxes, surface wind stress, and ocean temperatures in coupled GCM simulations. Journal of Geophysical Research: Atmospheres, 120, 2242-2260. https://doi.org/10.1002/2014JD022538

66. 劉曉薇，余嘉裕*，2014：四種常用氣象再分析資料在熱帶地區氣柱水氣量之比較。大氣科學，42, 49-60。

67. Yu*, J.-Y., and C.-W. Chang, 2014: Anatomizing the ocean’s role in maintaining the Pacific decadal variability. Advances in Atmospheric Sciences, 31, 611-623. https://doi.org/10.1007/s00376-013-3032-0

68. Yu*, J.-Y., and P.-G. Chiu, 2012: Contrasting various metrics for measuring tropical cyclone activity. Terrestrial, Atmospheric & Oceanic Sciences, 23, 303-316. https://doi.org/10.3319/TAO.2011.11.23.01(A)【2011~2012 TAO Best Article Award】

69. Yu*, J.-Y., C.-W. Chang, and J.-Y. Tu, 2011: Evaluation and improvement of a SVD-based empirical atmospheric model. Advances in Atmospheric Sciences, 28, 636-652. https://doi.org/10.1007/s00376-010-0029-9

70. Yu*, J.-Y., I.-W. Wang, and C.-W. Chang, 2010: Asian dust storm activity and its association with atmospheric circulation from 1995 to 2006. Terrestrial, Atmospheric & Oceanic Sciences, 21, 375-391. https://doi.org/10.3319/TAO.2009.05.25.01(A)【2009~2010 TAO Best Article Award】

71. Yu*, J.-Y., C. Chou, and P.-G. Chiu, 2009: A revised accumulated cyclone energy index. Geophysical Research Letters, 36, L14710. https://doi.org/10.1029/2009GL039254

72. 余嘉裕*、林能暉、謝和修、林宗嵩，2008：東南亞地區春季前推軌跡群集分析及氣候影響，大氣科學，36，287-302。

73. 張振瑋、余嘉裕*，2008：奇異值分解法之介紹與應用，氣象預報與分析，196, 1-10。

74. Nee, J.-B., C.-W. Chiang, H. Hu, S. Hu, and J.-Y. Yu, 2007: Lidar measurements of Asian dust storms and dust cloud interactions. Journal of Geophysical Research: Atmospheres, 112, D15202. https://doi.org/10.1029/2007JD008476

75. 邱品竣，余嘉裕*，2006：西北太平洋地區颱風活躍度分析：活躍年和不活躍年比較，大氣科學，34，201-216。

76. 張振瑋，余嘉裕*，2005：大氣與海洋年代震盪特徵分析，大氣科學，33，321-340。

77. 林宗嵩，余嘉裕*，2005：1995年3月12日台灣北部黃雨個案分析，大氣科學，33, 143-160。

78. 余嘉裕*，2004：亞洲沙塵暴簡介，科學月刊，412，272~274。

79. 邱品竣, 余嘉裕*，2004：西北太平洋地區颱風活躍度分析，華岡理科學報，21, 85-102。

80. 張振瑋, 余嘉裕*，2003：大氣海洋系統年際變異度之初步分析，華岡理科學報, 20, 209-228。

81. Chou, C., J.-Y. Tu, and J.-Y. Yu, 2003: Interannual variability of the Western North Pacific summer monsoon: Differences between ENSO and Non-ENSO years. Journal of Climate, 16, 2275-2287. https://doi.org/10.1175/2761.1

82. 余嘉裕*，涂建翊，許惠雯，2003：熱帶30~60天週期振盪：海面蒸發之角色，大氣科學, 31, 95-114。

83. 李萬彪、吳龍濤、張呈祥、余嘉裕，2003：氣象衛星遙感探測海面大氣溫度垂直廓線，北京大學學報(自然科學版)，39 (5)，656-665。

84. 余嘉裕*，卓盈旻，涂建翊，2002：東亞沙塵暴的時空特徵分析，中華民國環境保護期刊, 25, 178-198。

85. 許晃雄，柯文雄，隋中興，曾仁佑，盧孟明，余嘉裕，陳正達，周佳，2002: 本地變遷趨勢、衝擊評估、長期基礎資料調查與因應策略整合模式之氣候研究構想，全球變遷通訊雜誌，34，50-58。

86. 涂建翊、蔡梨敏、余嘉裕*，2001：初夏亞洲季風環流、熱源與東太平洋海溫年際變化關係，大氣科學, 29, 343-360。

87. 卓盈旻，余嘉裕*，涂建翊，1999：西北太平洋颱風年際變化研究，氣象預報與分析, 160, 15-28。

88. 涂建翊，余嘉裕*，1998：二十世紀後期聖嬰現象與台灣地區短期氣候變化，華岡理科學報, 15，139-158。

89. 余嘉裕*，花雲挺，涂建翊，1998：熱帶太平洋地區大氣與海洋年際變異度研究：海溫、低層大氣與颱風，大氣科學, 26, 63-76。

90. Yu, J.-Y., C. Chou, and J. D. Neelin, 1998: Estimating the gross most stability of the tropical atmosphere. Journal of the Atmospheric Sciences, 55, 1354-1372. https://doi.org/10.1175/1520-0469(1998)055<1354:ETGMSO>2.0.CO;2

91. 涂建翊，余嘉裕*，1997：台灣地區降水之時空氣候特徵。氣象預報與分析, 152, 23-33。

92. Yu, J.-Y., and J. D. Neelin, 1997: Analytic approximations for moist convectively adjusted regions. Journal of the Atmospheric Sciences, 54, 1054-1063.https://doi.org/10.1175/1520-0469(1997)054<1054:AAFMCA>2.0.CO;2

93. 余嘉裕*，1996：熱力強迫作用下產生之熱帶大氣環流特徵，氣象預報與分析, 146, 25-41。

94. Yu, J.-Y., and J. D. Neelin, 1994: Modes of tropical variability under convective adjustment and the Madden-Julian Oscillation. Part II: Numerical results. Journal of the Atmospheric Sciences, 51, 1895-1914. https://doi.org/10.1175/1520-0469(1994)051<1895:MOTVUC>2.0.CO;2 

95. Neelin, J. D., and J.-Y. Yu, 1994: Modes of tropical variability under convective adjustment and the Madden-Julian Oscillation. Part I: Analytical theory. Journal of the Atmospheric Sciences, 51, 1876-1894. https://doi.org/10.1175/1520-0469(1994)051<1876:MOTVUC>2.0.CO;2

96. Yu, J.-Y., and C.-Y. Lee, 1987: The baroclinic ocean Kelvin wave induced by a moving storm. ACTA Oceanographica Taiwanica, 18, 82-91.

Graduate Students Supervised

MS Degree (Name, Year, University)

1. On the Energetics of Convectively-coupled Kelvin Waves (洪翊彬, 2023, NCU)

2. MSE Budget Analysis of Strong and Weak MJO Events Using ERA5 and COSMIC RO Data: A Case-to-Case Comparison Study (林淑軒, 2022, NCU)

3. The Role of Shallow Convection in Tropical Circulation: a Simple Analytic Approach (Dong Pha Dang 鄧東坡, 2022, NCU)

4. Distinct Propagating Behaviors of Madden-Julian Oscillation over Indian Ocean and Maritime Continent (蔡雨虔, 2021, NCU)【110年度中華民國氣象學會周佳博士學位論文獎】

5. Potential Changes of Surface Latent Heat Flux over Oceans under Global Warming (李亭萱, 2021, NCU)

6. Impacts of Global Warming on a Super Madden-Julian Oscillation Event in the WRF Simulation (楊斯惟, 2020, NCU)

7. Changes of Tropical Tropopause in Response to Global Warming (蘇瑋, 2020, NCU)

8. Changes of Hadley Cell during the Last Four Decades (李澤邑, 2020, NCU)

9. Impacts of Madden-Julian Oscillation on Tropical Cyclone Activity over the South China Sea (Thi Lan Dao 陶氏蘭, 2020, NCU)

10. Changes of Tropical Precipitation and Convection under Global Warming Projected from HiRAM Simulations (楊淳安, 2019, NCU)【108年度中華民國氣象學會周佳博士氣候學位論文獎】

11. A Moist Static Energy Budget Analysis of Super Madden-Julian Oscillation Events (黃齡慧, 2018, NCU)

12. Moisture and Energy Transports by Tropical Convection: Contrast between Deep and Shallow Modes (陳怡蒨, 2018, NCU)【107年度中華民國氣象學會周佳博士氣候學位論文獎】

13. 全球暖化下季風亞洲降水的變化 (葉芳利, 2018, NCU)

14. 利用再分析資料重新估計粗濕穩定度 (張偉軍, 2016, CCU)

15. 全球暖化下海洋經向環流之變化:大西洋與太平洋之比較 (沈敏樺, 2015, CCU)

16. 熱帶海溫和對流活動關係分析 (許思婷, 2015, CCU)

17. 亞洲季風區旱澇變異特徵 (陳苡甄, 2015, CCU)

18. 全球暖化對颱風活動影響:西北太平洋與北大西洋之比較 (蕭立朋, 2013, CCU)

19. 全球暖化對聖嬰現象影響之數值模擬 (張智鈞, 2010, CCU)

20. 從粗濕分層度探討熱帶擴張現象 (陳俞綸, 2010, CCU)

21. 黑潮對氣候變遷反應之數值模擬 (劉曉薇, 2009, CCU)

22. 東亞沙塵暴季節氣流軌跡與氣候條件分析 (王怡文, 2007, CCU)

23. 東南亞生質燃燒氣流軌跡之分析 (謝和修, 2006, CCU)

24. 亞洲地區懸浮微粒時空變化之研究 (林瑋翔, 2005, CCU)

25. 東亞春季沙塵暴氣候特徵分析 (陳盈蓁, 2004, CCU)

26. 聖嬰年東亞夏季水汽南北輸送和颱風之關係 (李巨祥, 2003, CCU)

27. 海溫年際變異與西北太平洋颱風活動之關係 (林介崙, 2002, CCU)

28. 熱帶季內震盪與海溫關係研究 (許惠雯, 2001, CCU)

29. 東亞短期氣候變遷研究--水文循環 (葉時良, 2000, CCU)

30. 1997/1998年東亞及鄰近熱帶太平洋地區大氣環流分析 (高鈺盛, 2000, CCU)

31. 熱帶大氣與海洋交互作用之數值模擬 (陳御群, 2000, CCU)

32. 東亞季風熱源與環流之年際變異分析 (蔡梨敏, 1999, CCU)

33. 熱帶太平洋地區海氣通量交換研究 (王澤輝, 1998, CCU)

34. 春季東亞長輸型沙塵暴現象大氣環流特徵分析 (洪夢白, 1998, CCU)

35. 熱帶太平洋地區大氣與海洋低頻變異特性之分析 (花雲挺, 1996, CCU)

PhD Degree (Name, Year, University)

1. Changes in El Niño characteristics and air-sea feedback mechanisms under progressive global warming (沈敏樺, 2024, NCU)

2. Atmospheric Cloud-Radiaitve Effect Changes in the Madden-Julian Oscillation under Global Warming (林巧均, 2023, NCU)

3. How Close Are Leading Tropical Tropospheric Temperature Perturbations to Those under Convective Quasi-Equilibrium? (李羿賢, 2022, NCU)

4. 發展一個適合西北太平洋海域之熱帶氣旋潛在生成指數 (蕭立朋, 2018, CCU)

5. Observed and Simulated Vertical Structure of Convection in Tropical Pacific Climate  (Hien Xuan Bui 朴春星, 2016, NCU)

6. 全球暖化下熱帶深對流區變化及未來趨勢探討 (劉曉薇, 2015, CCU)

7. 西北太平洋地區颱風活動與氣候變遷之關係 (邱品竣, 2012, CCU)

8. 太平洋大氣與海洋系統中年際至年代震盪研究 (張振瑋, 2008, CCU)

9. 亞洲夏季季風年際變化研究 (卓盈旻, 2006, CCU)

10. 熱帶大氣與海洋低頻交互作用研究 (涂建翊, 2002, CCU)