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Publications

학술 논문 (114편)

2026(6)

  1. Machine learning based prediction of tropical cyclone rapid intensification in the Western North Pacific: Importance of data augmentation and loss function, Journal of Geophysical Research: Machine Learning and Computation 3 (2 …, 2026, (Citations: 1)
  2. A spectral test of the butterfly effect and physical consistency in the diffusion-based GenCast’s ensembles, npj Climate and Atmospheric Science, 2026
  3. Emerging trans-Eurasian heatwave-drought train in a warming climate, EGU26, 2026
  4. Data-driven forecasts of extreme weather in East Asia: feasibility of operational use, Weather and Climate Extremes, 100875, 2026
  5. Doubling frequency of summer cold surges in recent decades and their impact on East Asian extreme precipitation, Atmospheric Research, 108836, 2026
  6. New Indices for the Classification of Cold Surges Over South Korea, Asia-Pacific Journal of Atmospheric Sciences 62 (1), 3, 2026

2025(10)

  1. Emerging trans-Eurasian heatwave-drought train in a warming climate, Science Advances 11 (18), eadr7320, 2025, (Citations: 14)
  2. Tree growth responses to summer temperature on the Korean Peninsula detected by tree-ring blue intensity, Dendrochronologia 92, 126345, 2025, (Citations: 2)
  3. Time of emergence (TOE) of potential aridification in the western United States, Journal of Hydrology 656, 133029, 2025, (Citations: 2)
  4. Long-term evolution and synoptic meteorological modulation of PM2. 5 and PM10 in Seoul, Atmospheric Pollution Research, 102649, 2025, (Citations: 1)
  5. Amplification of Northern Hemisphere winter stationary waves in a warming world, npj Climate and Atmospheric Science 8 (1), 20, 2025, (Citations: 1)
  6. A new phase of land–atmosphere interactions in the East Asian Jet variability during summer, Environmental Research: Climate 4 (4), 045010, 2025
  7. East Asian dust source region restructuring linked to recent extreme drying, Science of the Total Environment 1006, 180889, 2025
  8. Divergent trends of Tmax-based and Tw-based heat extremes across Asia's climatic divide, Climatic Change 178 (10), 1-11, 2025
  9. Concurrent increases in winter precipitation and summer wildfire risk in a warming Alaska, Environmental Research Letters 20 (10), 104059, 2025
  10. Aerosol-induced surface cooling elevates relative humidity on the Indo-Gangetic Plain, Communications Earth & Environment 6 (1), 541, 2025

2024(9)

  1. From peak to plummet: impending decline of the warm Arctic-cold continents phenomenon, npj Climate and Atmospheric Science 7 (1), 66, 2024, (Citations: 8)
  2. Evolving winter atmospheric teleconnection patterns and their potential triggers across western North America, npj Climate and Atmospheric Science 7 (1), 63, 2024, (Citations: 7)
  3. Improving the seasonal forecast by utilizing the observed relationship between the Arctic Oscillation and Northern Hemisphere surface air temperature, Environmental Research Letters 19 (7), 074039, 2024, (Citations: 6)
  4. Precipitation-induced abrupt decrease of Siberian wildfire in summer 2022 under continued warming, Environmental Research Letters 19 (7), 074037, 2024, (Citations: 5)
  5. Statistical seasonal prediction of Arctic sea ice concentration based on spatiotemporal anomaly persistent method, Environmental Research Letters 19 (11), 114060, 2024, (Citations: 3)
  6. Sub-seasonal prediction skill: is the mean state a good model evaluation metric?, Climate Dynamics 62 (8), 7927-7942, 2024, (Citations: 3)
  7. Siberian vegetation growth intensifies monsoon precipitation in southern East Asia in late spring and early summer, npj Climate and Atmospheric Science 7 (1), 98, 2024, (Citations: 3)
  8. Dynamical-statistical method for seasonal forecasting of wintertime PM10 concentration in South Korea using multi-model ensemble climate forecasts, Environmental Research Letters 19 (6), 064073, 2024, (Citations: 2)
  9. Divergent Trends of Temperature and Humid-Heat Extremes Across Asia's Climatic Divide, Available at SSRN 4846093, 2024

2023(4)

  1. Anthropogenic warming induced intensification of summer monsoon frontal precipitation over East Asia, Science Advances 9 (47), eadh4195, 2023, (Citations: 37)
  2. Arctic-associated increased fluctuations of midlatitude winter temperature in the 1.5° and 2.0° warmer world, npj Climate and Atmospheric Science 6 (1), 26, 2023, (Citations: 18)
  3. Review of the weather hazard research: Focused on typhoon, heavy rain, drought, heat wave, cold surge, heavy snow, and strong gust, 대기 33 (2), 223-246, 2023, (Citations: 18)
  4. The global/regional integrated model system (GRIMs): an update and seasonal evaluation, Asia-Pacific Journal of Atmospheric Sciences 59 (2), 113-132, 2023, (Citations: 10)

2022(7)

  1. Arctic cloud properties and associated radiative effects in the three newer reanalysis datasets (ERA5, MERRA-2, JRA-55): Discrepancies and possible causes, Atmospheric Research 270, 106080, 2022, (Citations: 39)
  2. Arctic warming-induced cold damage to East Asian terrestrial ecosystems, Communications Earth & Environment 3 (1), 16, 2022, (Citations: 19)
  3. A novel statistical-dynamical method for a seasonal forecast of particular matter in South Korea, Science of The Total Environment 848, 157699, 2022, (Citations: 17)
  4. Relationship between synoptic weather pattern and surface particulate matter (PM) concentration during winter and spring seasons over South Korea, Journal of Geophysical Research: Atmospheres 127 (24), e2022JD037517, 2022, (Citations: 16)
  5. Deep learning provides substantial improvements to county‐level fire weather forecasting over the western united states, Journal of Advances in Modeling Earth Systems 14 (10), e2022MS002995, 2022, (Citations: 15)
  6. Large-scale sea surface temperature forcing contributed to the 2013–17 record-breaking meteorological drought in the Korean Peninsula, Journal of Climate 35 (12), 3767-3783, 2022, (Citations: 8)
  7. Characteristics of high-latitude climate and cloud simulation in Community Atmospheric Model Version 6 (CAM6), Atmosphere 13 (6), 936, 2022, (Citations: 8)

2021(3)

  1. Changes in fire weather climatology under 1.5 C and 2.0 C warming, Environmental Research Letters 16 (3), 034058, 2021, (Citations: 37)
  2. Recurrent pattern of extreme fire weather in California, Environmental Research Letters 16 (9), 094031, 2021, (Citations: 25)
  3. Classification of large-scale circulation patterns and their spatio-temporal variability during High-PM10 events over the Korean Peninsula, Atmospheric Environment 262, 118632, 2021, (Citations: 20)

2020(6)

  1. Abrupt shift to hotter and drier climate over inner East Asia beyond the tipping point, Science 370 (6520), 1095-1099, 2020, (Citations: 326)
  2. Intensification of the East Asian summer monsoon lifecycle based on observation and CMIP6, Environmental Research Letters 15 (9), 0940b9, 2020, (Citations: 44)
  3. Impacts of the Arctic-midlatitude teleconnection on wintertime seasonal climate forecasts, Environmental Research Letters 15 (9), 094045, 2020, (Citations: 18)
  4. Impact of poleward heat and moisture transports on Arctic clouds and climate simulation, Atmospheric Chemistry and Physics 20 (5), 2953-2966, 2020, (Citations: 11)
  5. Modulation of ENSO teleconnection on the relationship between arctic oscillation and wintertime temperature variation in South Korea, Atmosphere 11 (9), 950, 2020, (Citations: 7)
  6. The potential of using tree-ring chronology from the southern coast of Korea to reconstruct the climate of subtropical Western North Pacific: A pilot study, Atmosphere 11 (10), 1082, 2020, (Citations: 1)

2019(2)

  1. Impact of soil moisture initialization on boreal summer subseasonal forecasts: mid-latitude surface air temperature and heat wave events, Climate dynamics 52 (3), 1695-1709, 2019, (Citations: 111)
  2. The potential of using tree-ring data from Jeju Island to reconstruct climate in subtropical Korea and the western North Pacific, Asia-Pacific Journal of Atmospheric Sciences 55 (3), 293-301, 2019, (Citations: 8)

2018(7)

  1. Changes in cold surge occurrence over East Asia in the future: role of thermal structure, Atmosphere 9 (6), 222, 2018, (Citations: 32)
  2. The observed relationship of cloud to surface longwave radiation and air temperature at Ny-Ålesund, Svalbard, Tellus B: Chemical and Physical Meteorology 70 (1), 1-10, 2018, (Citations: 29)
  3. Season‐dependent warming characteristics observed at 12 stations in South Korea over the recent 100 years, International Journal of Climatology 38 (11), 4092-4101, 2018, (Citations: 27)
  4. Spring forest-fire variability over Korea associated with large-scale climate factors, Atmosphere 28 (4), 457-467, 2018, (Citations: 9)
  5. Evaluation of tree growth relevant atmospheric circulation patterns for geopotential height field reconstructions for Asia, Journal of Climate 31 (11), 4391-4401, 2018, (Citations: 8)
  6. Projection of circum-Arctic features under climate change, Atmosphere 28 (4), 393-402, 2018, (Citations: 1)
  7. Advancing forecasting, EOS: Transactions, American Geophysical Union 99 (2), 16-21, 2018

2017(5)

  1. How does the SST variability over the western North Atlantic Ocean control Arctic warming over the Barents–Kara Seas?, Environmental Research Letters 12 (3), 034021, 2017, (Citations: 68)
  2. The status and prospect of seasonal climate prediction of climate over Korea and East Asia: a review, Asia-Pacific Journal of Atmospheric Sciences 53 (1), 149-173, 2017, (Citations: 29)
  3. Characteristics of East Asian cold surges in the CMIP5 climate models, Atmosphere 27 (2), 199-211, 2017, (Citations: 12)
  4. Advancing climate forecasting, American Geophysical Union, 2017, (Citations: 7)
  5. A numerical simulation study of strong wind events at Jangbogo station, Antarctica, (Citations: 2)

2016(4)

  1. Recent changes in winter Arctic clouds and their relationships with sea ice and atmospheric conditions, Tellus A: Dynamic Meteorology and Oceanography 68 (1), 29130, 2016, (Citations: 41)
  2. Sensitivity of Arctic warming to sea ice concentration, Journal of Geophysical Research: Atmospheres 121 (12), 6927-6942, 2016, (Citations: 25)
  3. Assessment of climate variability over East Asia-Korea for 2015/16 winter, Atmosphere 26 (2), 337-345, 2016, (Citations: 22)
  4. Improvement of soil moisture initialization for a global seasonal forecast system, Atmosphere 26 (1), 35-45, 2016, (Citations: 13)

2015(9)

  1. Two distinct influences of Arctic warming on cold winters over North America and East Asia, Nature Geoscience 8 (10), 759-762, 2015, (Citations: 660)
  2. Changes in weather and climate extremes over Korea and possible causes: a review, Asia-Pacific Journal of Atmospheric Sciences 51 (2), 103-121, 2015, (Citations: 129)
  3. Two distinct influences of Arctic warming on cold winters over North America and East Asia. Nat. Geosci., 8, 759–762, (Citations: 107)
  4. A new dynamical index for classification of cold surge types over East Asia, Climate dynamics 45 (9), 2469-2484, 2015, (Citations: 61)
  5. Changes in winter cold surges over southeast China: 1961 to 2012, Asia-Pacific Journal of Atmospheric Sciences 51 (1), 29-37, 2015, (Citations: 32)
  6. Synoptic characteristics of cold days over South Korea and their relationship with large-scale climate variability, Atmosphere 25 (3), 435-447, 2015, (Citations: 19)
  7. Quantitative decomposition of radiative and non-radiative contributions to temperature anomalies related to siberian high variability, Climate dynamics 45 (5), 1207-1217, 2015, (Citations: 10)
  8. Development and assessment of dynamical seasonal forecast system using the cryospheric variables, Atmosphere 25 (1), 155-167, 2015, (Citations: 5)
  9. Arctic Cloud Microphysical Characteristics from 8-year Space-based lidar CALIOP Measurements, American Meteorological Society Meeting Abstracts 95, 4.3, 2015

2014(6)

  1. Weakening of the stratospheric polar vortex by Arctic sea-ice loss, Nature communications 5 (1), 4646, 2014, (Citations: 874)
  2. Weakening of the stratospheric polar vortex by Arctic sea-ice loss. Nat. Commun., 5, 4646, (Citations: 127)
  3. Intensified Arctic warming under greenhouse warming by vegetation–atmosphere–sea ice interaction, Environmental Research Letters 9 (9), 094007, 2014, (Citations: 47)
  4. A dissection of the surface temperature biases in the Community Earth System Model, Climate dynamics 43 (7), 2043-2059, 2014, (Citations: 34)
  5. Sensitivity of Arctic warming to sea surface temperature distribution over melted sea-ice region in atmospheric general circulation model experiments, Climate dynamics 42 (3), 941-955, 2014, (Citations: 7)
  6. Estimation of Energy Use in Residential and Commercial Sectors Attributable to Future Climate Change, Atmosphere 24 (4), 515-522, 2014, (Citations: 4)

2013(5)

  1. Impacts of snow initialization on subseasonal forecasts of surface air temperature for the cold season, Journal of Climate 26 (6), 1956-1972, 2013, (Citations: 107)
  2. Evaluation of global climate models in simulating extreme precipitation in China, Tellus A: Dynamic Meteorology and Oceanography 65 (1), 19799, 2013, (Citations: 106)
  3. Evaluation of the warm season diurnal cycle of precipitation over Sweden simulated by the Rossby Centre regional climate model RCA3, Atmospheric Research 119, 131-139, 2013, (Citations: 56)
  4. Exploring teleconnections between the summer NAO (SNAO) and climate in East Asia over the last four centuries–A tree-ring perspective, Dendrochronologia 31 (4), 297-310, 2013, (Citations: 42)
  5. Development of dynamical seasonal prediction system for northern winter using the cryospheric condition of late autumn, (Citations: 6)

2012(5)

  1. Decadal changes in surface air temperature variability and cold surge characteristics over northeast Asia and their relation with the Arctic Oscillation for the past three …, Journal of Geophysical Research: Atmospheres 117 (D18), 2012, (Citations: 106)
  2. Greening in the circumpolar high-latitude may amplify warming in the growing season, Climate dynamics 38 (7), 1421-1431, 2012, (Citations: 56)
  3. Improvement in simulation of Eurasian winter climate variability with a realistic Arctic sea ice condition in an atmospheric GCM, Environmental Research Letters 7 (4), 044041, 2012, (Citations: 11)
  4. Nonlinear impact of the Arctic Oscillation on extratropical surface air temperature, Journal of Geophysical Research: Atmospheres 117 (D19), 2012, (Citations: 11)
  5. Impact of snow depth initialization on seasonal prediction of surface air temperature over east Asia for winter season, (Citations: 2)

2011(7)

  1. The second phase of the global land–atmosphere coupling experiment: soil moisture contributions to subseasonal forecast skill, Journal of Hydrometeorology 12 (5), 805-822, 2011, (Citations: 435)
  2. Recent recovery of the Siberian High intensity, Journal of Geophysical Research: Atmospheres 116 (D23), 2011, (Citations: 187)
  3. Interannual teleconnections between the summer North Atlantic Oscillation and the East Asian summer monsoon, Journal of Geophysical Research: Atmospheres 116 (D13), 2011, (Citations: 159)
  4. Diurnal variations of summer precipitation in the Beijing area and the possible effect of topography and urbanization, Advances in Atmospheric Sciences 28 (4), 725-734, 2011, (Citations: 83)
  5. Diurnal cycle of precipitation amount and frequency in Sweden: observation versus model simulation, Tellus A: Dynamic Meteorology and Oceanography 63 (4), 664-674, 2011, (Citations: 62)
  6. Impact of urban warming on earlier spring flowering in Korea, International Journal of Climatology 31 (10), 1488, 2011, (Citations: 41)
  7. Impacts of aerosols on regional meteorology due to Siberian forest fires in May 2003, Atmospheric Environment 45 (7), 1407-1412, 2011, (Citations: 20)

2010(4)

  1. Contribution of land surface initialization to subseasonal forecast skill: First results from a multi‐model experiment, Geophysical Research Letters 37 (2), 2010, (Citations: 517)
  2. Influences of Arctic Oscillation and Madden‐Julian Oscillation on cold surges and heavy snowfalls over Korea: A case study for the winter of 2009–2010, Journal of Geophysical Research: Atmospheres 115 (D23), 2010, (Citations: 121)
  3. Dendroclimatology in Fennoscandia–from past accomplishments to future potential, Climate of the Past 6 (1), 93-114, 2010, (Citations: 116)
  4. Potential impact of vegetation feedback on European heat waves in a 2xCO2 climate: Vegetation impact on European heat waves, Climatic change 99 (3), 625-635, 2010, (Citations: 14)

2009(6)

  1. Influence of stratospheric quasi‐biennial oscillation on tropical cyclone tracks in the western North Pacific, Geophysical Research Letters 36 (6), 2009, (Citations: 147)
  2. Increase in vegetation greenness and decrease in springtime warming over east Asia, Geophysical Research Letters 36 (2), 2009, (Citations: 116)
  3. Reduction of spring warming over East Asia associated with vegetation feedback, Geophysical Research Letters 36 (18), 2009, (Citations: 78)
  4. Investigation of stratospheric precursor for the East Asian cold surge using the potential vorticity inversion technique, (Citations: 20)
  5. Adaptive change in intra-winter distribution of relatively cold events to East Asian warming, TAO: Terrestrial, Atmospheric and Oceanic Sciences 20 (6), 8, 2009, (Citations: 13)
  6. Dendroclimatology in Fennoscandia-from past accomplishments to future potentials., Climate of the Past Discussions 5 (3), 2009, (Citations: 3)

2008(3)

  1. Systematic variation in wintertime precipitation in East Asia by MJO-induced extratropical vertical motion, Journal of Climate 21 (4), 788-801, 2008, (Citations: 208)
  2. Characteristics of atmospheric circulation associated with cold surge occurrences in East Asia: A case study during 2005/06 winter, Advances in Atmospheric Sciences 25 (5), 791-804, 2008, (Citations: 69)
  3. Land surface initialization using an offline CLM3 simulation with the GSWP-2 forcing dataset and its impact on CAM3 simulations of the boreal summer climate, Journal of Hydrometeorology 9 (6), 1231-1248, 2008, (Citations: 10)

2006(3)

  1. Variation of tropical cyclone activity in the South Indian Ocean: El Niño–southern oscillation and Madden‐Julian oscillation effects, Journal of Geophysical Research: Atmospheres 111 (D22), 2006, (Citations: 174)
  2. Large increase in heavy rainfall associated with tropical cyclone landfalls in Korea after the late 1970s, Geophysical Research Letters 33 (18), 2006, (Citations: 162)
  3. Stratospheric origin of cold surge occurrence in East Asia, Geophysical Research Letters 33 (14), 2006, (Citations: 106)

2005(2)

  1. Changes in occurrence of cold surges over East Asia in association with Arctic Oscillation, Geophysical Research Letters 32 (14), 2005, (Citations: 354)
  2. Influence of the Madden‐Julian Oscillation on wintertime surface air temperature and cold surges in East Asia, Journal of Geophysical Research: Atmospheres 110 (D11), 2005, (Citations: 198)

2002(1)

  1. Influence of Arctic Oscillation on the East Asian summer monsoon, Available from the American Meteorological Society (AMS) Web site: http …, 2002, (Citations: 1)