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学術論文(2017年以前は工事中)

● 2023年

  • Liu, H.-Y., Satoh, M., Gu, J.-F., Lei, L., Tang, J., Tan, Z.-M., et al. (2023). Predictability of the most long-lived tropical cyclone Freddy (2023) during its westward journey through the southern tropical Indian Ocean. Geophysical Research Letters, 50, e2023GL105729, doi: 10.1029/2023GL105729.
  • Wang, M., Nakajima, T. Y., Roh, W., Satoh, M., Suzuki, K., Kubota, T., and Yoshida, M. (2023) Evaluation of the spectral misalignment on the Earth Clouds, Aerosols and Radiation Explorer/multispectral imager cloud product. Atmospheric Measurement Techniques, 16, 603–623, doi: 10.5194/amt-16-603-2023.
  • 佐藤正樹, 松岸修平 (2023) 全球ラージエディシミュレーションへの挑戦, 月刊海洋, 55(4), 172–179, doi: 10.15083/0002007328.

● 2022年

  • Chen Y.-W., Satoh M., Kodama C., Noda A. T., Yamada T. (2022) Projection of high clouds and its link to ice hydrometeors: An approach by using long-term global cloud-system resolving simulations. Journal of Climate, 35, 3495-3514, doi: 10.1175/JCLI-D-21-0150.1.
  • Goto Y., Satoh M. (2022) Statistical analysis of“Senjo-Kousuitai”in East Asia and characteristics of associated large-scale circulations in the Baiu season. SOLA, 18A, 15-20, doi: 10.2151/sola.18A-003.
  • Hagihara Y., Ohno Y., Horie H., Roh W., Satoh M., Kubota T., and Oki R. (2022) Assessments of Doppler velocity errors of EarthCARE Cloud Profiling Radar using global cloud system resolving simulations: Effects of Doppler broadening and folding. IEEE Transactions on Geoscience and Remote Sensing, 60, doi: 10.1109/tgrs.2021.3060828.
  • Ikuta Y., Sawada M., Satoh M. (2022) Determining the impact of boundary layer schemes on the secondary circulation of Typhoon FAXAI using radar observations in the gray zone. Journal of the Atmospheric Sciences, 80, 961-981, doi: 10.1175/ JAS-D-22-0169.1.
  • Ishiyama, T., Satoh, M., Yamada, Y. (2022) Possible roles of the sea surface temperature warming of the Pacific Meridional Mode and the Indian Ocean warming on tropical cyclone genesis over the North Pacific for the super El Nino in 2015. Journal of the Meteorological Society of Japan Ser. II, 100, 767-782, doi: 10.2151/jmsj.2022-040.
  • Islam M.R., M. Satoh, H. Takagi (2022) Tropical Cyclones Affecting Japan Central Coast and Changing Storm Surge Hazard since 1980. Journal of the Meteorological Society of Japan Ser. II, 100, 493-507, doi: 10.2151/jmsj.2022-024.
  • Kodama, S., Satoh, M. (2022) Statistical analysis of remote precipitation in Japan caused by typhoons in September. Journal of the Meteorological Society of Japan Ser. II, 100, 893-911, doi: 10.2151/jmsj.2022-046.
  • Lin J., Qian T., Bluestein H.B., Ditlevsen P., Lin H., Seiki T., Tochimoto E., Barnes H., Bechtold P., Carr P.H., Freitas S.R., Goodman S.J., Grell G., Han J., Klotzbach P., Roh W., Satoh M., Schubert S., Zhang G., Zhu P. (2022) Current challenges in climate and weather research and future directions. Atmosphere-Ocean, 60, 506-517, doi: 10.1080/07055900.2022.2079473.
  • Matsugishi S., Satoh M. (2022) Sensitivity of horizontal scale of convective self-aggregation to sea surface temperature: Radiative convective equilibrium experiments with a global nonhydrostatic model. Journal of Advances in Modeling Earth Systems, 14, doi: 10.1029/2021MS002636.
  • Nakanishi M., Niino H. and Anzai T. (2022) Stability functions in the stable surface layer derived from the MYNN scheme. Journal of the Meteorological Society of Japan Ser. II, 100, 245-256, doi: 10.2151/jmsj.2022-013.
  • Saito, K., T. Matsunobu, T. Oizumi (2022) Effect of upper-air moistening by northward ageostrophic winds associated with a tropical cyclone on the PRE enhancement. SOLA, 18, 81-87, doi:10.2151/sola.2022-014.
  • Satoh M., Matsugishi S., Roh W., Ikuta Y., Kuba N., Seiki T., Hashino T., Okamoto H. (2022) Evaluation of cloud and precipitation processes in regional and global models with ULTIMATE (ULTra-sIte for Measuring Atmosphere of Tokyo metropolitan Environment): A case study using the dual-polarization Doppler weather radars. Progress in Earth and Planetary Science, 9, doi: 10.1186/s40645-022-00511-5.
  • Seiki T., W. Roh, M. Satoh (2022) Cloud microphysics in global cloud resolving models. Atmosphere-Ocean, 477-505, doi: 10.1080/07055900.2022.2075310.
  • Tochimoto E., and Niino H. (2022) Tornadogenesis in a quasi-linear convective system over Kanto Plain in Japan: A numerical case study. Monthly Weather Review, 150, 259-282, doi:10.1175/MWR-D-20-0402.1.
  • Tochimoto E., and Niino H. (2022) Comparing frontal structures of extratropical cyclones in the Northwetern Pacific and Northwestern Atlantic storm tracks. Monthly Weather Review, 150, 369-392, doi: 10.1175/MWR-D-21-0181.1.
  • Tochimoto E., Yokota S., Niino H. and Yanase W. (2022) Ensemble experiments for a maritime meso-β-scale vortex that spawned tornado-like vortices causing shipwrecks. Journal of the Meteorological Society of Japan Ser. II, 100, 141-165, doi: 10.2151/jmsj.2022-007.
  • Watanabe S., Niino H. and Spengler T. (2022) Formation of maritime convergence zones within cold air outbreaks due to the shape of the coastline or sea ice edge. Quarterly Journal of the Royal Meteorological Society, 148, 2546-2562, doi: 10.1002/qj.4324.
  • Yamamoto M., Hirose T., Ikeda K., Takahashic M., Satoh M. (2022) Short-period planetary-scale waves in a Venus general circulation model: Rotational and divergent component structures and energy conversions. Icarus, 392, doi: 10.1016/ j.icarus.2022.115392.
  • 佐藤正樹 (2022)「対流」をめぐる気候モデルの発展 - 真鍋淑郎志のモデルから次世代モデルへ . 岩波「科学」, 92, 444-446.
  • 佐藤正樹 (2022) 極端気象現象の気候変化 . IPCC 第 6 次報告 ( 自然科学的根拠 ) をめぐって ─その現代的意義─ , 学術の動向 , 27, 81-84.
  • 佐 藤 正 樹 ・ 佐 藤 芳 昭 ・ 八 代 尚 ・ 伊 藤 耕 介 ・ 筆 保 弘 徳 ・ 三 好 建 正 ・ 川 畑 拓 矢 ・ 坪 木 和 久・ 堀 之 内 武 ・ 岡 本 幸 三 ・ 山 口 宗 彦 ・ 中 野 満 寿 男 ・ 和田章義・金田幸恵・辻野智紀 (2022) 今後の台風予測研究に関する展望 . 天気 , 69, 285-294.
  • 新野 宏・益子 渉 (2022) 我が国における竜巻研究 ─気象学の立場から─ . 月刊海洋号外 , 63, 8-22.

● 2021年

  • Ikehata K., Satoh M. (2021) Climatology of tropical cyclone seed frequency and survival rate in tropical cyclones. Geophysical Research Letters, 48, doi: 10.1029/2021GL093626.
  • Ikuta Y., Satoh M., Sawada M., Kusabiraki H., Kubota T. (2021) Improvement of the cloud microphysics scheme of the mesoscale model at the Japan Meteorological Agency using space-borne radar and microwave imager of the Global Precipitation Measurement as reference. Monthly Weather Review (MWR), 149, 3803-3819.
  • Inoue T., Rajendran K., Satoh M., Miura H. (2021) On the semidiurnal variation in surface rainfall rate over the tropics in a global cloud-resolving model simulation and satellite observations. Journal of Meteorological Society of Japan, 99, 1371-1388.
  • Ito J., Tsuguchi H., Hayashi S., Niino H. (2021) Idealized high-resolution simulations of a back-building convective system that causes torrential rain. Journal of the Atmospheric Sciences, 78, 117-131.
  • Judt F., Klocke D., Rios-Berrios R., Vanniere B., Ziemen F., Auger L., Biercamp J., Bretherton C., Chen X., Düben P., Hohenegger C., Kharaidnutov M., Kodama C., Kornblueh L., Lin S.-J., Nakano M., Neumann P., Putman W., Röber N., Roberts M., Satoh M., Shibuya R., Stevens B., Vidale P.L., Wedi N., Zhou L. (2021) Tropical cyclones in global storm-resolving models. Journal of the Meteorological Society of Japan, Ser. II, 99, 579-602.
  • Kato S., Loeb N.G., Fasullo J.T., Trenberth K.E, Laurizen P.H., Rose F.G., Rutan D.A., Satoh M. (2021) Regional energy and water budget of a precipitating atmosphere over ocean. Journal of Climate, 34, 4189-4205.
  • Kodama C., Ohno T., Seiki T., Yashiro H., Noda A.T., Nakano M., Yamada Y., Roh W., Satoh M., Nitta T., Goto D., Miura H., Nasuno T., Miyakawa T., Chen Y.-W., Sugi M. (2021) The Nonhydrostatic ICosahedral Atmospheric Model for CMIP6 HighResMIP simulations (NICAM16-S): Experimental design, model description, and impacts of model updates. Geoscientific Model Development, 14, 795-820.
  • Miyoshi T., Terasaki K., Kotsuki S., Otsuka S., Chen Y., Kanemaru K., Okamoto K., Kondo K., Lien G., Yashiro H., Tomita H., Satoh M., Kalnay E. (2021) Enhancing data assimilation of GPM observations. In Precipitation Science, edited by Michaelides S., Elsevier, 787-804.
  • Noda A.T., Seiki T., Roh W., Satoh M., Ohno T. (2021) Improved representation of low-level mixed-phase clouds in a global cloudsystem-resolving simulation. Journal of Geophysical Research: Atmospheres, 126, doi: 10.1029/2021JD035223.
  • Ohno T., Noda A.T., Seiki T., Satoh M. (2021) Importance of pressure changes in high-cloud feedback due to global warming. Geophysical Research Letters, 48, doi: 10.1029/2021GL093646.
  • Roh W., Satoh M., Hohenegger C. (2021) Intercomparison of cloud properties in DYAMOND simulations over the Atlantic Ocean. Journal of the Meteorological Society of Japan, Ser. II, 99, 1439-1451.
  • Seneviratne S., Zhang X., Adnan M., Badi W., Dereczynski C., Luca A.D., Ghosh S., Iskandar I., Kossin J., Lewis S., Otto F., Pinto I., Satoh M., Vicente-Serrano S.M., Wehner M., Zhou B. (2021) Weather and climate extreme events in a changing climate. In IPCC AR6 Climate Change 2021, 1513-1765.
  • Shibuya R., Nakano M., Kodama C., Nasuno T., Kikuchi K., Satoh M., Miura H., Miyakawa T. (2021) Prediction skill of the boreal Summer intra-seasonal oscillation in global non-hydrostatic atmospheric model simulations with explicit cloud microphysics. Journal of the Meteorological Society of Japan, Ser. II, 99, 973-992.
  • Takasuka D., Satoh M. (2021) Diversity of the Madden–Julian oscillation: Initiation region modulated by the interaction between the intraseasonal and interannual variabilities. The Journal of Climate (JCLI), 34, 2297-2318.
  • Tochimoto E., Miglietta M.M., Bagaglini L., Ingrosso R., Niino H. (2021) Characteristics of extratropical cyclones that cause tornadoes in Italy: A preliminary study. Atmosphere, 12, doi: 10.3390/atmos12020180.
  • Yamada Y., Kodama C., Satoh M., Sugi M., Roberts M.J., Mizuta R., Noda A.T., Nasuno T., Nakano M., Vidale P.L. (2021) Evaluation of the contribution of tropical cyclone seeds to changes in tropical cyclone frequency due to global warming in high-resolution multi-model ensemble simulations. Progress in Earth and Planetary Science,, 8, doi: 10.1186/s40645- 020-00397-1.
  • Yamashita Y., Takigawa M., Goto D., Yashiro H., Satoh M., Kanaya Y., Taketani F., Miyakawa T. (2021) Effect of model resolution on black carbon transport from Siberia to the Arctic associated with the well-developed low-pressure systems in September. Journal of the Meteorological Society of Japan, Ser. II, 99, 287-308.
  • 佐藤正樹 (2021) ULTIMATE:関東圏ウルトラサイト観測の包括的利用による高解像度数値モデルの連携研究推進 . 日本リモートセンシン グ学会誌 , 41, 133-139.
  • 佐藤正樹・川畑拓矢・宮川知己・八代 尚・三好建正 (2021) 「富岳」による新時代の大アンサンブル気象・大気環境予測 . 繊維学会誌 , 77, 54-58.
  • 新野 宏・小林文明・栃本英伍・末木健太・足立 透・梅原章仁・田村幸雄・野田 稔・佐々浩司・加藤輝之・加茂直幸・中里真久・益子 渉・ 伊藤純至・横田 祥・田村哲郎・楠 研一・石津尚喜 (2021) 「竜巻シンポジウム : 藤田哲也博士生誕 100 年を記念して」の報告 . 天気 , 68, 511-520.
  • 山本晃立・伊賀啓太 (2021) 偏西風帯で持続する渦における高・低気圧非対称性 . ながれ , 40, 414-417.

● 2020年

  • Arakawa T., Inoue T., Yashiro H., and Satoh M. (2020) Coupling library Jcup3: its philosophy and application. Progress in Earth and Planetary Science, 7, doi:10.1186/s40645-019-0320-z.
  • Ito J., Niino H., and Yoshino K. (2020) Large eddy simulation on horizontal convection rolls that caused an aircraft accident during its landing at Narita Airport. Geophysical Research Letters, 47, doi:10.1029/2020GL086999.
  • Kuba N., Seiki T., Suzuki K., Roh W., and Satoh M. (2020) Evaluation of rain microphysics using a radar simulator and numerical models: Comparison of two-moment bulk and bin cloud microphysics schemes. Journal of Advances in Modeling Earth Systems, 12, doi:10.1029/2019MS001891.
  • Kubota T., Seto S., Satoh M., Nasuno T., Iguchi T., Masaki T., Kwiatkowski J.M., and Oki R. (2020) Cloud assumption of Precipitation Retrieval Algorithms for the Dual-frequency Precipitation Radar. Journal of Atmospheric and Oceanic Technology, 37, 2015-2031.
  • Matsugishi S., Miura H., Nasuno T., and Satoh M. (2020) Impact of latent heat flux modifications on the reproduction of a Madden-Julian oscillation event during the 2015 Pre-YMC campaign using a global cloud-system-resolving model. SOLA, 16A, 12-18.
  • Miglietta M.M., Arai K., Kusunoki K., Inoue H., Adachi T., and Niino H. (2020) Observational analysis of two waterspouts in northwestern Italy using an OPERA Doppler radar. Atmospheric Research, 234, doi:10.1016/j.atmosres.2019.104692.
  • Miyoshi T., Kotsuki S., Terasaki K., Otsuka S., Lien G.-Y., Yashiro H., Tomita H., Satoh M., and Kalnay E. (2020) Precipitation ensemble data assimilation in NWP models. In: Levizzani V., Kidd C., Kirschbaum D., Kummerow C., Nakamura K., Turk F. (eds) Satellite Precipitation Measurement. Advances in Global Change Research, vol. 69, Springer, 983-991.
  • Nakamura Y., Miyakawa T., and Satoh M. (2020) The role of Typhoon Kilo (T1517) in the Kanto-Tohoku heavy rainfall event in Japan in September 2015. Journal of the Meteorological Society of Japan, 98, 915-926.
  • Ohno T., Noda A.T., and Satoh M. (2020) Impacts of sub-grid ice cloud physics in a turbulence scheme on high clouds and their response to global warming. Journal of the Meteorological Society of Japan, 98, 1069-1081.
  • Roh W., Satoh M., Hashino T., Okamoto H., and Seiki T. (2020) Evaluations of the thermodynamic phases of clouds in a cloud system-resolving model using CALIPSO and a satellite simulator over the Southern Ocean. Journal of the Atmospheric Sciences, 77, 3781-3801.
  • Sugi M., Yamada Y., Kodama C., Yoshida K., Mizuta R., and Satoh M. (2020) Future changes in the global frequency of tropical cyclone seeds. SOLA, 16, 70-74.
  • Takahashi H.G., Kamizawa N., Nasuno T., Yamada Y., Kodama C., Sugimoto S., and Satoh M. (2020) Response of the Asian summer monsoon precipitation to global warming in a high-resolution global nonhydrostatic model. Journal of Climate, 33, 8147-8164.
  • Takasuka D. and Satoh M. (2020) Dynamical roles of mixed Rossby-gravity waves in driving convective initiation and propagation of the Madden-Julian oscillation: General views. Journal of the Atmospheric Sciences, 77, 4211-4231.
  • Wing A.A., Stauffer C.L., Becker T., Reed K.A., Ahn M.-S., Arnold, N.P., Bony S., Branson M., Bryan G.H., Chaboureau J.- P., De Roode S.R., Gayatri K., Hohenegger C., Hu I.-K., Jansson F., Jones T.R., Khairoutdinov M., Kim D., Martin Z.K., Matsugishi S., Medeiros B., Miura H., Moon Y., Müller S.K., Ohn T., Popp M., Prabhakaran T., Randall D., RiosBerrios R., Rochetin N., Roehrig R., Romps D.M., Ruppert Jr. J.H., Satoh M., Silvers L.G., Singh M.S., Stevens B., Tomassini L., van Heerwaarden C.C., Wang S., and Zhao M. (2020) Clouds and convective self‐aggregation in a multimodel ensemble of radiative‐convective equilibrium simulations. Journal of Advances in Modeling Earth Systems, 12, doi:10.1029/2020MS002138.
  • Yashiro H., Terasaki K., Kawai Y., Kudo S., Miyoshi T., Imamura T., Minami K., Inoue H., Nishiki T., Saji T., Satoh M., and Tomita H. (2020) A 1024-member ensemble data assimilation with 3.5-km mesh global weather simulations. IEEE Xplore, 2020, doi:10.1109/SC41405.2020.00005.
  • 佐藤正樹 (2020) 近年における降雨状況の実態 : 極端豪雨は増えているか ( 特集 「雨」とつきあう). 水環境学会誌 , 43, 142-147.

● 2019年

  • Brooks H.E., Doswell C.A. III, Zhang X., Chernokulsky A.M.A., Tochimoto E., Hanstrum B., Nascimento E.L., Sills D.M.L., Antonescu B., Barrett B. (2019) A century of progress in severe convective storm research and forecasting. Meteorological Monograph, 59, 18.1-18.41.
  • Ito J., Nagoshi T., Niino H. (2019) A numerical study of "Hijikawa-Arashi": a thermally-driven gap wind visualized by nocturnal fog. Journal of Applied Meteorology and Climatology, 58, 1293-1307.
  • Knutson T., Camargo S.J., Chan J.C.L., Emanuel K., Ho C.-H., Kossin J., Mohapatra M., Satoh M., Sugi M., Walsh K., Wu L. (2019) Tropical cyclones and climate change assessment. Bulletin of the American Meteorological Society, 100, 1987-2007.
  • Kodama C., Stevens B., Mauritsen T., Seiki T., Satoh M. (2019) A new perspective for future precipitation change from intense extratropical cyclones. Geophysical Research Letters, 46, 12435-12444.
  • Kotsuki S., Terasaki K., Kanemaru K., Satoh M., Kubota T., Miyoshi T. (2019) Predictability of record-breaking rainfall in Japan in july 2018: Ensemble forecast experiments with the near-real-time global atmospheric data assimilation system NEXRA. Scientific Online Letters on the Atmosphere, 15A, 1-7.
  • Ohtake H., Uno F., Oozeki T., Hayashi S., Ito J., Hashimoto A., Yoshimura H., Yamada Y. (2019) Solar irradiance forecasts by mesoscale numerical weather prediction models with different horizontal resolutions. Energies, 12, doi: 10.3390/ en12071374.
  • Satoh M., Stevens B., Judt F., Khairoutdinov M., Lin S.-J., Putman W.M., Düben P. (2019) Global cloud-resolving models. Current Climate Change Reports, 5, 172-184.
  • Seiki T., Kodama C., Satoh M., Hagihara Y., Okamoto H. (2019) Characteristics of ice clouds over mountain regions detected by CALIPSO and CloudSat satellite observations. Journal of Geophysical Research Atmospheres, 124, 10858-10877.
  • Stevens B., Satoh M., Auger L., Biercamp J., Bretherton C.S., Chen X., Düben P., Judt F., Khairoutdinov M., Klocke D., Kodama C., Kornblueh L., Lin S.-J., Neumann P., Putman W.M., Röber N., Shibuya R., Vanniere B., Vidale P.L., Wedi N., Zhou L. (2019) DYAMOND: the DYnamics of the Atmospheric general circulation Modeled On Non-hydrostatic Domains. Progress in Earth and Planetary Science, 6, doi: 10.1186/s40645-019-0304-z.
  • Tochimoto E., Sueki K., Niino H. (2019) Entraining CAPE for better assessment of tornado outbreak potential in the warm sector of extratropical cyclones. Monthly Weather Review, 147, 913-930.
  • Tochimoto E., Yokota S., Niino H., Yanase W. (2019) A hierarchy of violent vortices in an extratropical cyclone: A potential risk to maritime traffic. Monthly Weather Review, 147, 1989-2007.
  • Yamada Y., Kodama C., Satoh M., Nakano M., Nasuno T., Sugi M. (2019) High‐resolution ensemble simulations of intense tropical cyclones and their internal variability during the El Niños of 1997 and 2015. Geophysical Research Letters, 46, 7592-7601.
  • Yanase W., Niino H. (2019) Parameter sweep experiments on a spectrum of cyclones with diabatic and baroclinic processes. Journal of the Atmospheric Science, 76, 1917-1935.
  • 伊賀啓太 (2019) 円筒水槽内の底面の回転円盤によって作られる渦 . 月刊海洋号外 , 62, 12-17.
  • 伊藤純至 (2019) ラージ・エディ・シミュレーションを活用した微細気象の研究 . 月刊海洋号外 , 62, 147-151.
  • 佐藤正樹 , 山田洋平 , 杉 正人 , 小玉知央 , 野田暁 (2019) 全球非静力学モデル NICAM による台風研究 . 月刊海洋号外 , 62, 62-67.
  • 新野 宏 (2019) 大気・海洋の渦・対流・シア流とその相互作用の研究:回顧と展望 . 月刊海洋号外 , 62, 169-190.
  • 野田 暁 , 中村晃三 , 岩崎俊樹 , 佐藤正樹 (2019) 下層大気の変動によって起こる下層雲の応答 . 月刊海洋号外 , 62, 152-156.
  • 吉﨑正憲 , 髙咲良規 , 伊賀晋一 , 佐藤正樹 , 高野かれん , 小宮山祐矢 , 酒井絵梨 , 宮田 学 , 森田将矢 , 森泉慎一 (2019) 理想化された aqua-planet における NICAM の結果と JRA-55 のデータにより解析した対流圏における気温の鉛直分布と気温減率の特徴 . 地 球環境研究 , 21, 1-12.

● 2018年

  • Chen Y.-W., Seiki T., Kodama C., Satoh M. and Noda A.T. (2018) Impact of precipitating ice hydrometeors on longwave radiative effect estimated by a global cloud-system resolving model. Journal of Advances in Modeling Earth Systems, 10, 284-296.
  • Ishijima K., Takigawa M., Yamashita Y., Yashiro H., Kodama C., Satoh M., Tsuboi K., Matsueda H., Niwa Y. and Hirao S. (2018) Analysis of high radon-222 concentration events using multi-horizontal-resolution NICAM simulations. SOLA, 14, 111-115.
  • Kotsuki S., Terasaki K., Yashiro H., Tomita H., Satoh M. and Miyoshi T. (2018) Online model parameter estimation with ensemble data assimilation in the real global atmosphere: A case with the Nonhydrostatic Icosahedral Atmospheric Model (NICAM) and the Global Satellite Mapping of Precipitation data. Journal of Geophysical Research, 123, 7375-7392.
  • Ohno T. and Satoh M. (2018) Roles of cloud microphysics on cloud responses to sea surface temperatures in radiative-convective equilibrium experiments using a high-resolution global nonhydrostatic model. Journal of Advances in Modeling Earth Systems, 10, 1970-1989.
  • Oizumi T., Saito K., Ito J., Kuroda T. and Duc L. (2018) Ultra-high-resolution numerical weather prediction with a large domain using the K Computer: A case study of the Izu Oshima heavy rainfall event on October 15-16, 2013. Journal of Meteorological Society of Japan, 96, 25-54.
  • Roberts M.J., Vidale P.L., Senior C., Hewitt H., Bates C., Berthou S., Chang P., Christensen H.M., Danilov S., Demory M., Griffies S.M., Haarsma R., Jung T., Martin G., Minobe S., Ringler T., Satoh M., Schiemann R., Scoccimarro E., Stephens G. and Wehner M.F. (2018) The benefits of global high-resolution for climate simulation: process-understanding and the enabling of stakeholder decisions at the regional scale. The Bulletin of the American Meteorological Society, 99, 2341-2359.
  • Roh W. and Satoh M. (2018) Extension of a multisensor satellite radiance-based evaluation for cloud system resolving models. Journal of the Meteorological Society of Japan, 96, 55-63.
  • Satoh M., Noda A.T., Seiki T., Chen Y., Kodama C., Yamada Y., Kuba N. and Sato Y. (2018) Toward reduction of the uncertainties in climate sensitivity due to cloud processes using a global non-hydrostatic atmospheric model. Progress in Earth and Planetary Science, 5, doi:10.1186/s40645-018-0226-1.
  • Takasuka D., Satoh M., Miyakawa T. and Miura H. (2018) Initiation processes of the tropical intraseasonal variability simulated in an aqua-planet experiment: What is the intrinsic mechanism for MJO onset? Journal of Advances in Modeling Earth Systems, 10, 1047-1073.
  • Tochimoto E. and Niino H. (2018) Structure and environment of tornado-spawning extratropical cyclones around Japan. Journal of the Meteorological Society of Japan, 96, 355-380.
  • Watanabe S.I., Niino H. and Yanase W. (2018) Composite analysis of polar mesocyclones over the western part of the Sea of Japan. Monthly Weather Review, 146, 985-1004.
  • Wing A.A., Reed K.A., Satoh M., Stevens B., Bony S. and Ohno T. (2018) Radiative-Convective Equilibrium Model Intercomparison Project. Geoscientific Model Development, 11, 793-813.
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