[15] Oh, S.-Y., Yeh, S.-W., Park, I.-H., Yoo, C. & Moon, B.-K. Role of the warm Arctic cold Eurasian-like pattern on the near future warming rate of East Asian surface temperature. Environmental Research Letters, 2024.
[14] Park, I.-H., Yeh, S.-W., Min, S.-K., An, S.-I., Xie, S.-P., & Shin, J. Irreversible changes in the sea surface temperature threshold for tropical convection to CO2 forcing. Communications Earth & Environment, 2024, 5(1), 659.
[13] Park I-H, Yeh S-W, Dewitte B, Wang G, Kirtman BP and An S-I. North Atlantic warming hole modulates interhemispheric asymmetry of future temperature and precipitation. Earth's Future, 2024,12(6), e2023EF004146.
[12] Park, I.-H. & Yeh, S.-W. Projections of the North Atlantic warming hole can be constrained using ocean surface density as an emergent constraint. Communications Earth & Environment, 2024, 5(1), 98.
[11] Park I-H, Yeh S-W, Cai W, Wang G, Min S-K, Lee S-K. Present-day North Atlantic salinity constrains future warming of the Northern Hemisphere. Nature Climate Change 2023, 13(8): 816-822.
[10] Yeh S-W, Ma S-J, Park I-H, Park H-J, Kug J-S. Low frequency changes in CO2 concentration in East Asia related to Pacific decadal oscillation and Atlantic multi-decadal oscillation for mid-summer and early fall. Science of The Total Environment 2023, 876: 162377.
[10] Yeh S-W, Ma S-J, Park I-H, Park H-J, Kug J-S. Low frequency changes in CO2 concentration in East Asia related to Pacific decadal oscillation and Atlantic multi-decadal oscillation for mid-summer and early fall. Science of The Total Environment 2023, 876: 162377.
[9] Park I-H, Yeh S-W, Min S-K, Ham Y-G, Kirtman BP. Present-day warm pool constrains future tropical precipitation. Communications Earth & Environment 2022, 3(1): 310.
[8] Lee D, Min SK, Park I-H, Ahn JB, Cha DH, Chang EC, et al. Enhanced role of convection in future hourly rainfall extremes over South Korea. Geophysical Research Letters 2022, 49(22): e2022GL099727.
[7] Park I-H, Yeh SW, Min SK, Son SW. Emergent constraints on future expansion of the Indo‐Pacific warm pool. Geophysical Research Letters 2022, 49(1): e2021GL097343
[6] Yeh S-W, Lee E-H, Min S-K, Lee Y-H, Park I-H, Hong J-S. Contrasting factors on the trends in hot days and warm nights over Northern Hemisphere land during summer. Weather Climate Extremes 2021, 34: 100389.
[5] Yeh SW, Hyun SH, Park I-H, Zheng XT. Surface temperature variability in climate models with large and small internal climate variability. Quarterly Journal of the Royal Meteorological Society 2021, 147(738): 3004-3016
[4] Min S-K, Kim Y-H, Park I-H, Lee D, Sparrow S, Wallom D, et al. Anthropogenic contribution to the 2017 earliest summer onset in South Korea. Bulletin of the American Meteorological Society 2019, 100(1).
[3] Park I-H, Min S-K. Role of convective precipitation in the relationship between subdaily extreme precipitation and temperature. Journal of Climate 2017, 30(23): 9527-9537.
[2] Lee J-Y, Kwon M, Yun K-S, Min S-K, Park I-H, Ham Y-G, et al. The long-term variability of Changma in the East Asian summer monsoon system: A review and revisit. Asia-Pacific Journal of Atmospheric Sciences 2017, 53(2): 257-272.
[1] Park I-H, Min S-K, Yeh S-W, Weller E, Kim ST. Attribution of the 2015 record high sea surface temperatures over the central equatorial Pacific and tropical Indian Ocean. Environmental Research Letters 2017, 12(4): 044024.