2020年度
SCIE対象雑誌
1) Akita, H., 2020: Quantitative progress in the evaluation of the wear of wooden check dam elements: case study of Aomori cypress wood 64 years after construction. European journal of wood and wood products 2021 v.79 no.2, pp.465-476.
Akita, H, 2020: Influence of different structural installation conditions on the progress of wear of wooden check dam elements, Wood Science and Technology volume 54, 737–753.
2) Iizuka, S., R. Kawamura, H. Nakamura T. Miyama, 2021: Influence of Warm SST in the Oyashio Region on Rainfall Distribution of Typhoon Hagibis (2019). SOLA, 17A(Special_Edition), 21-28.
3) Ohigashi, T., T. Maesaka, S. Suzuki, Y. Shusse, N. Sakurai, K. Iwanami, 2021: Clear-Air Echoes Observed by Ka-band Polarimetric Cloud Radar: A Case Study on Insect Echoes in the Tokyo Metropolitan Area, Japan. JOURNAL OF THE METEOROLOGICAL SOCIETY OF JAPAN, 99(1), 101-112.
4) Kikuchi, H., T. Suezawa, T. Ushio, N. Takahashi, H. Hanado, K. Nakagawa, M. Osada, T. Maesaka, K. Iwanami, K. Yoshimi, F. Mizutani, M. Wada, Y. Hobara, 2020: Initial Observations for Precipitation Cores With X-Band Dual Polarized Phased Array Weather Radar. IEEE TRANSACTIONS ON GEOSCIENCE AND REMOTE SENSING, 58(5), 3657-3666.
5) Tsujino, S. K. Tsuboki, H. Yamada, T. Ohigashi, K. Ito, N. Nagahama, 2021: Intensification and maintenance of a double warm-core structure in Typhoon Lan (2017) simulated by a cloud-resolving model. Journal of the Atmospheric Sciences, 78(2), 595-617.
Ohigashi, T., K. Tsuboki, Y. Suzuki, H. Yamada, K. Nakagawa, 2020: Characteristics of upper-tropospheric outflow-layer clouds of Typhoon Francisco (2013) observed by hydrometeor videosonde. Atmospheric Research, 235, 104736.
6) Shakti P. C., H. Kamimera, R. Misumi, 2020: Inundation analysis of the Oda River basin in Japan during the flood event of 6–7 July 2018 utilizing local and global hydrographic data. Water, 12(4), 1005; https://doi.org/10.3390/w12041005
7) Nimura, M., S. Nishida, K. Kawasaki, T. Murakami, S. Shimokawa, 2020: Storm Surge Inundation Analysis with Consideration of Building Shape and Layout at Ise Bay by Maximum Potential Typhoon. Journal of Marine Science and Engineering, 8(12), 1024-1024.
8) Tochimoto, E., M. M. Miglietta, L. Bagaglini, R. Ingrosso, H. Niino, 2021: Characteristics of Extratropical Cyclones That Cause Tornadoes in Italy: A Preliminary Study. Atmosphere, 12(2), 180.
9) Notarangelo, N. M., K. Hirano, R. Albano, A. Sole, 2021: Transfer Learning with Convolutional Neural Networks for Rainfall Detection in Single Images. WATER, 13(5), 588-588.
10) Misumi, R., Y. Uji, T. Maesaka, 2021: Modification of raindrop size distribution due to seeder-feeder interactions between stratiform precipitation and shallow convection observed by X-band polarimetric radar and optical disdrometer. Atmospheric Science Letters, 22, e1034.
11) Yoshida, S., R. Misumi, T. Maesaka, 2021: Early detection of convective echoes and their development using a ka-band radar network. Weather and Forecasting, 36(1), 253-264.
12) Tobo, Y., J. Uetake, H. Matsui, N. Moteki, Y. Uji, Y. Iwamoto, K. Miura, R. Misumi, 2020: Seasonal Trends of Atmospheric Ice Nucleating Particles Over Tokyo. JOURNAL OF GEOPHYSICAL RESEARCH-ATMOSPHERES, 125(23), e2020JD033658.
13) Shima, S., Y. Sato, A. Hashimoto, R. Misumi, 2020: Predicting the morphology of ice particles in deep convection using the super-droplet method: Development and evaluation of SCALE-SDM 0.2.5-2.2.0, -2.2.1, and -2.2.2. Geoscientific Model Development, 13(9), 4107-4157.
その他査読誌
1) Shakti P. C., K. Hirano, S. Iizuka, 2020: Flood Inundation Mapping of the Hitachi Region in the Kuji River Basin, Japan, During the October 11–13, 2019 Extreme Rain Event. Journal of Disaster Research, 15, 712-725.
2) Iizuka, S. and N. Sakai, 2020: What Factors Contributed to the Torrential Rainfall of Hurricane Harvey over Texas? Journal of Disaster Research, 15(6), 726-734.
3) 二村 昌樹, 川崎 浩司, 村上 智一, 下川 信也, 飯塚 聡, 西田 修三, 2020: 津波シミュレータT-STOCの静水圧・非静水圧モデルの高潮浸水解析に対する適用性. 土木学会論文集B2(海岸工学) 76(2) I_115-I_120.
4) 二村 昌樹, 川崎 浩司, 村上 智一, 下川 信也, 飯塚 聡, 西田 修三, 2020: 建物形状・配置を考慮した名古屋港周辺における可能最大級高潮の3次元浸水解析. 海洋開発シンポジウム講演集 45(2) 6p-I_227.
5) Danjo, T. and T. Ishizawa, 2020: Quantitative Evaluation of the Relationship Between Slope Gradient and Infiltration Capacity Based on a Rainfall Experiment Using Pit Sand. Journal of Disaster Research 15(6) 745-753.
6) 石澤 友浩, 國生 剛治, ハザリカ・ へマンタ, 2020: 2016年熊本地震の地震観測記録(KiK-net)における波動エネルギーの距離減衰.地盤工学ジャーナル, 15(1), 81-89.
宮本 崇, Zheng Shitao, 阿部 雅人, 岩波 越, 2020: クープマン作用素論に基づく非線形動的現象のデータ駆動型解析と降水短期予測への適用. 土木学会論文集A2(応用力学), 76(1), 22-37.
7) 長谷川 歩, 松田 曜子, 諸橋 和行, 樋口 勲, 上米良 秀行, 佐野 可寸志, 鳩山 紀一郎, 2020:河川防災情報表示に対するユーザー要求の明確化と改善策の提示.土木学会論文集D3, ,76(5),I_609-I_619.
8) 六川修一, 田口仁, 酒井直樹,2020:衛星データ等即時共有システムと被災状況解析・予測技術の開発.日本リモートセンシング学会誌,40(3),147-152.
9) 田口仁, 酒井直樹, 臼田裕一郎,2020:衛星リモートセンシングデータ等の災害情報共有・流通のためのプラットフォーム開発.写真測量とリモートセンシング,59(1),10-13.
10) 石川綾乃, 小笠原敏記, 村上智一, 河野裕美, 水谷晃, 下川信也, 2020:西表島網取湾における長期定点観測による台風時の海水流動特性.土木学会論文集B2(海岸工学)、76(2),I_127-I_132.
11) 村上智一, 河野裕美, 中村雅子, 則武幸輝, 木下日波乃, 水谷晃, 下川信也,2020:西表島網取湾におけるサンゴ大規模白化前後の幼生分散・滞留の数値解析.土木学会論文集B3(海洋開発),76(2),I_840-I_845.
12) Shakti, P.C., P. Ishwar, T. Rocky, K. Darshan, 2021: The Role of Glaciers in Hydropower Production in Nepal. Journal of Asian Energy Studies, 5, 1-13.
13) Shakti P. C., M. Miyamoto, R. Misumi, Y. Nakamura, A. Sriariyawat, S. Visessri, D. Kakinuma, 2020: Assessing Flood Risk of the Chao Phraya River Basin Based on Statistical Rainfall Analysis. Journal of Disaster Research, 15(7), 1025-1039.
14) 檀上 徹, 酒匂 一成, 藤本 将光, 石澤 友浩, 伊藤 真一, 深川 良一, 2021:テンシオメータの計測結果を加味した雨量指標による計測斜面での斜面崩壊予測精度向上に関する検討.土木学会論文集C(地圏工学)(Web), 77(1), 87-102.
15) 中澤博志, 石澤友浩, 檀上徹, 原忠, 末次大輔, 西剛整, 2020:地震と降雨の作用を受ける蛇籠擁壁の安定性に関する模型実験.第14回地盤改良シンポジウム論文集, 12(7), 515-522.
16) 檀上徹, 藤本将光, 石澤友浩, 深川良一, 里深好文, 2020:重要文化財後背斜面での現地計測結果に基づく降雨量と斜面の変位量との関係.歴史都市防災論文集,14,99-106.
17) Nakazawa, H., T. Ishizawa, T. Danjo, Y. Sawada, Y. Onoue, 2020: Model tests on the deformation and collapse processes of small earth dams due to earthquakes and rainfall. 17th World Conference on Earthquake Engineering, 4c-0026, 1-12.
18) Sano, H., Y. Usuda, I. Iwai, H. Taguchi, R. Misumi, H. Hayashi, 2020: Generation of Risk Information Based on Comprehensive Real-Time Analysis of Flooding and Landslide Disaster Occurrence Hazard and Social Vulnerability. Journal of Disaster Research, 15(6), 676-687.
2019年度
SCIE対象雑誌
1) S. Shimizu, K. Iwanami, R.Kato, N. Sakurai, T. Maesaka, K. Kieda, Y. Shusse, and S. Suzuki, 2019, Assimilation impact of high-temporal-resolution volume scans on quantitative precipitation forecasts in a severe storm; Evidence from nudging data assimilation experiments with a thermodynamical retrieval method., Quarterly Journal of the Royal Meteorological Society, 145, 2139-2160.
2) Shusse, Y., T. Maesaka, K. Kieda, and K. Iwanami, 2019, Polarimetric radar observation of the melting layer in a winter precipitation system associated with a south-coast cyclone in Japan., Journal of the Meteorological Society of Japan, 97, 375-385.
3) Misumi, R., Y. Shoji, K. Saito, H. Seko, N. Seino, S. Suzuki, Y. Shusse, K. Hirano, S. Belair, V. Chandrasekar, D. Lee, A. Pereira Filho, T. Nakatani, and M. Maki, 2019, Results of the Tokyo Metropolitan Area Convection Study for Extreme Weather Resilient Cities (TOMACS)., Bulletin of the American Meteorological Society, 100, 2027-2041.
4) Suzuki, K., R. Kamamoto, K. Nakagawa, M. Nonaka, T. Shinoda, T. Ohigashi, Y. Minami, M. Kubo, and Y. Kaneko, 2019, Ground validation of GPM DPR precipitation type classification algorithm by precipitation particle measurements in winter, SOLA, 15, 94-98.
5) Uetake, J., Y. Tobo, Y., Uji, Y., Hill, T. C. J., DeMott, P. J., Kreidenweis, S. M., Misumi, R., 2019, Seasonal changes of airborne bacterial communities over Tokyo and influence of local meteorology, Frontiers in Microbiology, 10, https://doi.org/10.3389/fmicb.2019.01572.
6) Hashimoto, A., H. Motoyoshi, N. Orikasa, and R. Misumi, 2020, Process-Tracking Scheme Based on Bulk Microphysics to Diagnose the Features of Snow Particles, SOLA, 16, 51-56.
その他査読誌
1) P.C. Shakti, T. Nakatani and R. Misumi, 2019, The role of the spatial distribution of radar rainfall on hydrological modeling for an urbanized river basin in Japan, Water, 11, 1-25.
2) P.C. Shakti and H. Kamimera, 2019, Flooding in Oda river basin during torrential rainfall event in July 2018, Engineering Journal, 23, 477-485.
3) 石澤友浩・檀上徹・酒井直樹,小林政美,2019,大型降雨実験施設を活用した防災技術の向上,地盤工学会誌,Vol.67, No.8,32-33.
4) Tomohiro Ishizawa and Toru Danjo, 2019, Rainfall Indices at Estimated Occurrence Times of Sediment Disasters Triggered by the July 2018 Heavy Rainfall , JOURNAL OF DISASTER RESEARCH, Vol.14, No.9, 1227-1235.
5) 石澤友浩・國生剛治・ハザリカ・へマンタ,2020,2016年熊本地震の地震観測記録(KiK-net)における波動エネルギーの距離減衰,地盤工学ジャーナル,15(1),81-89.
6) 村上智一・河野裕美・中村雅子・黒澤華織・國島綾乃・竹下遥平・水谷晃・下川信也,2019,2016年大規模白化後の西表島網取湾におけるミドリイシ科サンゴ群集の回復状況,土木学会論文集B3(海洋開発),75,498-503.
7) 真木 雅之, 鈴木 郁子, 井口 正人, Shakti P.C., 2019:気象レーダによる降灰量推定—2013年8月18日桜島噴火のZ-RA 関係式—.火山,64 巻 4 号 p. 219-241.
8) S. Ito, T. Danjo, T. Ishizawa, S. Baba, and K. Sako, 2019, Data assimilation of parallel tanks model based on measurement data of groundwater level on full-scale test, Proceedings of the Technical Forum on Mitigation of Geo-disasters in Asia, 148-151.
9) 伊藤真一・小田和広・小泉圭吾,西村美紀,檀上徹,酒匂一成,2020,融合粒子フィルタを用いた境界条件を含む浸透解析モデルの推定手法の提案,土木学会論文集C(地圏工学),Vol. 76, No. 1,52-66.
10) K. Kawasaki, M. Nimura and T. Murakami, S.Shimokawa, 2019, Application of tsunami simulator in oceans and coastal areas “T-STOC”to storm surge simulation, Proc. The 29th International Ocean and Polar Engineering Conference, 29, 3211-3217.
11) 川崎浩司・二村昌樹・村上智一・下川信也・尼子順子,2019,非構造格子海洋流動モデルFVCOMによる伊勢湾湾奥部の高潮浸水計算,土木学会論文集B1(海岸工学),75,223-281.
12) 二村昌樹・川崎浩司・村上智一・下川信也・飯塚聡,2019,津波シミュレータT-STOCを用いた可能最大級高潮による名古屋港周辺の高潮浸水解析,土木学会論文集B1(海岸工学),75,229-234.
13) 西山賢一・鳥井真之・横田修一郎・若月 強・井上 弦・中尾賢一・星出和裕・奥野 充,2019,阿蘇カルデラ壁斜面における斜面崩壊の発生頻度,第四紀研究,58-2,.
14) M. Hasan IMAM, C.T.Oguchi and T.Wakatsuki, M.Ueda, 2019, Assessment of climate-induced degree of chemical weathering in some granite and granodiorite slopes of Japan, Modeling Earth Systems and Environment, 5, 1751-1767.
15) 篠原 徹・酒井将也・若月 強, 中谷 剛, 三隅良平,2019,テキストマイニングを用いた消防職員が大規模土砂災害現場で必要とする消防防災技術と情報共有に関する分析〜平成26年(2014年) 8月広島豪雨の経験者を対象とした調査~,自然災害科学,38-1,55-72.
2018年度
SCIE対象雑誌
1) Suzuki, S, T. Maesaka, K. Iwanami, S. Shimizu, and K. Kieda, 2018, X-band dual-polarization radar observations of the supercell storm that generated an F3 tornado on 6 May 2012 in Ibaraki Prefecture, Japan, J. Meteor. Soc. Japan, 96A, 25-33.
2) Iizuka, S. and H. Nakamura, 2019, Sensitivity of Midlatitude Heavy Precipitation to SST: A Case Study in the Sea of Japan Area on 9 August 2013, Journal of Geophysical Research-Atmospheres, doi:10.1029/2018JD029503, .
3) Hirano, K. and Masayuki MAKI, 2018, Imminent nowcasting for severe rainfall using vertically integrated liquid water content derived from X-band polarimetric radar, J. Meteor. Soc. Japan, 96A, 201-220.
4) Misumi, R, N. Sakurai, T. Maesaka, S.-I. Suzuki, S. Shimizu, and K. Iwanami, 2018, Transition process from non-precipitating cumuli to precipitating convective clouds over mountains: Observation by Ka-band Doppler radar and stereo photogrammetry., Journal of the Meteorological Society of Japan, 96A, 51-66.
5) Misumi, R., Y. Uji, Y. Tobo, K. Miura, J. Uetake, Y. Iwamoto, T. Maesaka, and K. Iwanami, 2018, Characteristics of droplet size distributions in low-level stratiform clouds observed from Tokyo Skytree, Journal of the Meteorological Society of Japan, 96, 405-413.
6) SETO Yoshihito, YOKOYAMA Hitoshi and NAKATANI Tsuyoshi,ANDO Haruo,TSUNEMATSU Nobumitsu,SHOJI Yoshinori,KUSUNOKI Kenichi,NAKAYAMA Masaya,SAITOH Yuto,TAKAHASHI Hideo, 2018, Relationships among Rainfall Distribution, Surface Wind, and Precipitable Water Vapor during Heavy Rainfall in Central Tokyo in Summer, J. Meteor. Soc. Japan , 96A, 35-49.
その他査読誌
1) Kato, R., Ken-ichi Shimose and Shingo Shimizu, 2018, Predictability of Precipitation Caused by Linear Precipitation Systems During the July 2017 Northern Kyushu Heavy Rainfall Event Using a Cloud-Resolving Numerical Weather Prediction Model, Journal of Disaster Research, 13, 846-859.
2) P.C., S., Nakatani T. and Misumi R., 2018, Analysis of flood inundation in ungauged mountainous river basins: a case study of an extreme rain event on 5–6 July 2017 in northern Kyushu, Japan. Journal of Disaster Research 13: 860-872.
3) Danjo, T., Ishizawa, T. and Kimura, T., 2018, Spatial Analysis of the Landslide Characteristics Caused by Heavy Rainfall in the Northern Kyushu District in July, 2017 Using Topography, Geology, and Rainfall Levels, Journal of Disaster Research, 13, 832-845.
4) Kamimera, H., 2019, Assessment of Satellite-based Rainfall Estimates over Japan, Online proceedings of THA 2019, TD439-1.
5) Iwanami, K., K. Hirano and S. Shimizu, 2019, Statistical validation of the predicted amount and start time of heavy rainfall in 2015 based on the VIL nowcast method, J. Disaster Research, 14, 248-259.
6) Kenji Ishihara and Tomohiro Ishizawa, 2018, Steady-State Residual Strength of Partly Saturated Soils to Evaluate Runout Distance of Landslides during Earthquakes, ASCE Special Publication in honor of Professor Jeans Louis Briaud to be published, 1-22.
7) M. Hasan IMAM, C.T.Oguchi and T.Wakatsuki, 2018, Climatic influences on weathering degree of soil layer in the soil-slip scar on granitic slopes in Japan, Transactions, Japanese Geomorphological Union, 39, 325-348.
8) Miki, Toru, M. Saito, T. Shindo, M. Ishii, and N. Sakurai, 2018, Lightning-initiated upward lightning flashes observed at Tokyo skytree in April 2017, 2018 34th international conference on lightning protection(ICLP) IEEE, DOI:10.1109/ICLP.2018.8503275.
9) Shimokawa, S. and T. Matsuura, 2018, Chaos excitation and stochastic synchronization in an oceanic double gyre, Theor. Appl. Mech. Jpn., 64, 15-22.
10) P.C., S. and H.Kamimera, 2019, Flooding in Oda River Basin during Torrential Rainfall Event in July 2018, Online proceedings of THA 2019, TD438-1.
11) Ishizawa, T. and T. Kokusho, 2018, Evaluation of seismically induced slope displacement by energy approach and applicability to a Case Study related to the 2016 Kumamoto Earthquake, Journal of the International Association of Lowland Technology, 19(4), 229-236.
12) Takahashi, N., T. Ushio, K. Nakagawa, F. Mizutani, K. Iwanami, A. Yamaji, T. Kawagoe, M. Osada, T. Ohta, and M. Kawasaki, 2019, Development of multi-parameter phased array weather radar (MP-PAWR) and early detection of torrential rainfall and tornado risk, J. Disaster Research, 14, 235-247.
13) 横山 仁,2016,東京都におけるゲリラ豪雨の実態とその適応策について (地域の気候変動適応策の推進 : 持続可能な社会を目指して),地球環境 ,21(2),167-172.
14) 河村 圭・中村 優志・若月 強・佐村 俊和,2019,深層学習を用いた空中写真からの土砂移動範囲自動検出に関する研究,土木学会論文集F3(土木情報学),74-2,144-152.
15) 吉野純・村上智一・鵜飼亮行・河野裕美・下川信也・中瀬浩太・水谷晃,2018,西表島白浜湾と船浮湾を繋ぐ接続水路の形状が海水交換過程に及ぼす影響,土木学会論文集B3(海洋開発),74,976-981.
16) 山粼 雄大・常松 展充・横山 仁・梅木 清・本條 毅 ,2016,温熱快適感マップの作成と夏季マラソンコースの温熱環境予測,環境情報科学学術研究論文集 ,30,43-48.
17) 酒匂 一成・横田 裕介・里見 知昭・檀上徹・深川 良一,2018,無線センサネットワークを利用した斜面内の負の間隙水圧の長期多点計測システム,土木学会論文集,Vol.74, No.2,144-163.
18) 村上智一・河野裕美・中村雅子・水谷晃・岡辺拓巳・下川信也,2018,西表島網取湾における礁斜面40 mまでの造礁サンゴの水平・鉛直分布,土木学会論文集B3(海洋開発),74,456-461.
19) 檀上徹・石澤友浩,2018,平成29年7月九州北部豪雨に伴う朝倉市内における文化財被害および斜面崩壊に起因する地質・地形・降雨量の空間分析,歴史都市防災論文集,Vol.12,43-50.
20) 中島 虹・高橋 日出男・横山 仁・常松 展充,2018,晴天弱風の夜間における東京都心の温位鉛直分布 : 東京タワーの気温観測値を用いた統計的解析,地理学評論, 91(1),24-42.
21) 長谷美波・松浦知徳・村上智一・下川信也・川崎浩司,2018,寄り回り波の海底地形変化に伴う波浪変形特性,土木学会論文集B3(海洋開発),74,563-568.
22) 田中義朗・酒井直樹・木村誇・九鬼和広,2018,熊本地震後の土砂災害監視システム構築とWEB-GISでの情報共有,地盤工学会誌,66,12-15.
23) 土井航・村上智一・吉岡雅人・水谷晃・下川信也・河野裕美,2018,西表島網取湾におけるオカガニ類浮遊幼生の移動と加入に関する数値解析,土木学会論文集B3(海洋開発),74,462-467.
24) 南秀樹・深沢徹・捫垣 勝哉・渡邊 裕・野坂裕一 ・崎原 健・村上智一,2018,西表島網取湾および崎山湾 におけるケイ素・ アルミニウムの水平分布,東海大学紀要,7,21-27.
25) 二村昌樹・川崎浩司・下川信也・村上智一・佐々木敦,2018,津波シミュレータT-STOCの高潮解析への適用と精度検証,土木学会論文集B2(海岸工学),74,559-564.
26) 波多野頼子・飯塚聡・中谷剛・三隅良平・鈴木真一,2018,2017年7月九州北部豪雨における福祉施設の避難行動と今後の情報活用に対する考察,地域安全学会論文集,No.33,1-8.
27) 板宮朋基・村上智一・小笠原敏記・川崎浩司・下川信也,2018,スマートフォン用ヘッドマウントディスプレイを用いた高潮想定没入体験システムの開発,土木学会論文集B3(海洋開発),74,773-778.
28) 木村誇・山田隆二・苅谷愛彦,2019,9世紀後半の赤石山地ドンドコ沢岩石なだれが形成した堰き止め湖沼堆積物中の材化石群,第四紀研究,58,65-72.
2017年度
SCIE対象雑誌
1) Yamada, R., Kariya, Y. and Kimura, T., Sano, M., Li, Z., Nakatsuka, T., 2018, Age determination on a catastrophic rock avalanche using tree-ring oxygen isotope ratios - the scar of a historical gigantic earthquake in the Southern Alps, central Japan, Quaternary Geochronology, 44, 47-54.
2) Chen, CW., Iida, T. and Yamada, R., 2017, Effects of active fault types on earthquake-induced deep-seated landslides: A study of historical cases in Japan, Geomorphology, 295, 680-689.
3) Chen, CW, Chen, H. and Yamada, R., 2017, Evaluating the susceptibility of landslide landforms in Japan using slope stability analysis: a case study of the 2016 Kumamoto earthquake, Landslides, 14, 1793-1801.
4) Janet Barlow, Martin Best, Sylvia I. Bohnenstengel, Peter Clark, Sue Grimmond, Humphrey Lean, Andreas Christen, Stefan Emeis, Martial Haeffelin, Ian N. Harman, Aude Lemonsu, Alberto Martilli, Eric PardyJak, Mathias W RotaCh, Susan Ballard, Ian Boutle, Andy Brown, XiaoMing Cai, Matteo Carpentieri, Omduth Coceal, Ben Crawford, Silvana Di Sabatino, JunXia dou, Daniel R. Drew, John M. Edwards, Joachim Fallmann, Krzysztof Fortuniak, Jemma Gornall, Tobias Gronemeier, Christos H. Halios, Denise Hertwig, Kohin Hirano, Albert A. M. Holtslag, ZhiWen Luo, Gerald Mills, Makoto Nakayoshi, Kathy Pain, K. Heinke Schlu?nzen, Stefan Smith, Lionel Soulhac, Gert-Jan Steeneveld, Ting Sun, Natalie E Theeuwes, David Thomson, James A. Voogt, Helen C. Ward, Zheng-Tong Xie, and Jian Zhong, 2017, Developing a Research Strategy to Better Understand, Observe, and Simulate Urban Atmospheric Processes at Kilometer to Subkilometer Scales, Bulletin of the American Meteorological Society, 98, ES261-ES264.
5) H. Shimizu, R. Kawamura, T. Kawano, and S. Iizuka, 2017, Dynamical Modulation of Wintertime Synoptic-scale Cyclone Activity over the Japan Sea due to Changbai Mountain in the Korean Peninsula, Advances in Meteorology, vol. 2017, Article ID 6216032, 14 pages, 2017. doi:10.1155/2017/6216032.
その他査読誌
6) S. Shimizu, S. Shimada and K. Tsuboki, 2017, Assimilation impact of different GPS analysis methods on precipitation forecast: A heavy rainfall case study of Kani city, Gifu prefecture on July 15, 2010, Journal of Disaster Research, 12, 944-955.
7) K. Shimose, S. Shimizu and R. Kato, K. Iwanami, 2017, Analysis of the 6 September 2015 Tornadic Storm Around the Tokyo Metropolitan Area Using Coupled 3DVAR and Incremental Analysis Updates, Journal of Disaster Research, 12, 956-966.
8) R. Kato, S. Shimizu and K. Shimose, K. Iwanami, 2017, Very Short Time Range Forecasting Using CReSS-3DVAR for a Meso-γ-Scale, Localized, Extremely Heavy Rainfall Event: Comparison with an Extrapolation-Based Nowcast, Journal of Disaster Research, 12, 967-979.
9) P.C.Shakti and M.Maki, 2017, Challenges in estimating Quantitative Precipitation Estimation (QPE) using weather radar observation over the mountainous country of Nepal, HYDRO Nepal: Journal of Water Energy and Environment, 21, 50-59.
10) P.C.Shakti, Nakatani T and Misumi R, 2018, Hydrological simulation of small river basins in northern Kyushu, Japan during the extreme rainfall event of 5-6 July 2017, Journal of Disaster Research, Vol. 13 , 396-406
11) T. Ishizawa, T. Danjo and N. Sakai, 2017, Real-Time Prediction Method for Slope Failure Caused by Rainfall Using Slope Monitoring Records, Journal of Disaster Research, Vol.12, No.5, 980-992.
12) T. Danjo, T. Ishizawa, M. Fujimoto, N. Sakai, and R. Fukagawa, 2017, Characteristics of Groundwater Response to Precipitation for Landslide Prevention at Kiyomizu-Dera, Journal of Disaster Research, Vol.12, No.5, 43-47.
13) S. Shimokawa, Murakami, T., H. Kohno and A. Mizutani, 2017, Transport properties of soil particles in Sakiyamawan?Amitoriwan nature conservation area, Iriomote Island, Japan, Geoscience Letters, 4, DOI 10.1186/s40562-017-0084-5.
14) 若月 強・佐藤昌人・菊池輝海・石川美樹・山岸千鶴・山下久美子,2017,土砂移動分布図を利用した土石流到達流域の推定−降雨を考慮した地形的閾値について―,地すべり学会誌,54-3,13-24.
15) 村上智一・河野裕美・中村雅子・玉村直也・水谷晃・下川信也,2017,西表島網取湾のサンゴ鉛直分布における白化現象とその物理環境,土木学会論文集B3(海洋開発),73,881-886.
16) 木村誇・山田隆二・苅谷愛彦・井上公夫,2018,赤石山地ドンドコ沢岩石なだれの発生に起因する地形変化の再検討,日本地すべり学会誌,55,42-52.
17) 飯田智之・山田隆二,2018,誘因と素因を考慮した斜面崩壊確率モデルと降雨に対する慣れの検討,地形,39,29-46.
18) H. Hazarika, S. Yamamoto, T. Ishizawa, T. Danjo, Y. Kochi, T. Fujishiro, K. Okamoto, D. Matsumoto and S. Ishibashi, 2017, The 2017 July Northern Kyushu Torrential Rainfall Disaster ~ Geotechnical and Geological Perspectives ~, 3rd Indo-Japan Workshop on Geotechnics for Natural Disaster Mitigation and Management, 1-15.
19) 中村雅子・村上智一・ 河野裕美・ 野田航・ 松下裕亮・ 水谷晃,2017,西表島網取湾における付着基盤および数値計算を用いたサンゴ幼生加入の狭域解析,土木学会論文集B2(海岸工学),73,1279-1284.
20) 横川京香・小田和広・伊藤真一,檀上徹,石澤友浩,2017,データ同化に基づく降雨履歴ごとの土壌水分特性の変化に関する研究,Kansai Geo-Simposium 2017−地下水地盤環境・防災・計測技術に関するシンポジウム―,200-205.
21) 佐藤剛・後藤聡・木村誇・林信太郎・ISTIYANTI Mega Lia・小森次郎,2017,阿蘇カルデラ内で発見されたテフラ被覆斜面堆積物の重力変形,日本地すべり学会誌,54,199-204.
22) 岡辺拓巳・村上智一・河野裕美・水谷晃・下川信也,2017,蛍光X線分析と画像解析による崎山湾・網取湾自然環境保全地域での底質分布の把握,土木学会論文集B3(海洋開発),73,1036-1041.
23) 中島 虹・高橋 日出男・横山 仁・常松 展充,2018,晴天弱風の夜間における東京都心の温位鉛直分布 : 東京タワーの気温観測値を用いた統計的解析,地理学評論, 91(1),24-42.
2016年度
SCI対象雑誌
(3) Shimose, K., Shingo Shimizu, Takeshi Maesaka, Ryohei Kato, Kaori Kieda and Koyuru Iwanami, 2016, Impact of Observation Operators on Low-Level Wind Speed Retrieved by Variational Multiple-Doppler Analysis, SOLA, 12, 215-219.
(2) Kato, R., S. Shimizu, K. Shimose, T. Maesaka, K. Iwanami and H. Nakagaki, 2017, Predictability of meso-γ-scale, localized, extreme, heavy rainfall during the warm season in Japan using high-resolution precipitation nowcasts, Quartery Journal of the Royal Meteorological Society, DOI: 10.1002/qj.3013.
(1) Fathrio, I., S. Iizuka, A. Manda, Y.-M. Kodama, S. Ishida, Q. Moteki, H. Yamada, and Y. Tachibana, 2017, Assessment of western Indian Ocean SST bias of CMIP5 odels, Journal of Geophysical Research-Oceans, DOI: 10.1002/2016JC012443.
その他査読誌
(22) P.C., Shakti, 2017, Quantitative precipitation estimation and hydrological modeling in Japan, 水文・水資源学会誌,Vol.30, 6-17.
(21) P.C.,Shakti, R.Misumi, T. Nakatani, K. Iwanami, M. Maki, T. Maesaka, and K. Hirano, 2016, Acuracy of quantitative precipitation estimation using operational weather radars: A case study of heavy rainfall on 9-10 September 2015 in the East Kanto region, Japan, Journal of Disaster Research, 11, 1003-1016.
(20) 下川信也・河野裕美・村上智一・宮内星七・鈴木舞弓・水谷晃,2016,西表島崎山湾における造礁サンゴの分布とその物理環境との関係,土木学会論文集B2(海岸工学),72,1435-1440.
(19) 村上智一・河野裕美・下川信也・水谷晃,2016,西表島網取湾における最大瞬間風速50 m/sを超える台風時の流速・波浪観測,土木学会論文集B2(海岸工学),72,469-474.
(18) 村上智一・小花和宏之・河野裕美・下川信也・田林雄・水谷晃,2016,サンゴ礁海域を対象としたSfMによる水中3次元計測の可能性,土木学会論文集B3(海洋開発),72,766-771.
(17) 村上智一・谷野賢二・南秀樹・三浦博・崎原健・水谷晃・下川信也・河野裕美,2016,西表島浦内川河岸域におけるオヒルギの植生分布とその物理環境,土 木学会論文集B3(海洋開発),72,1029-1034.
(16) 檀上徹・藤本将光・石澤友浩・有光悠紀・深川良一,2016,清水寺観測斜面における地上雨量とレーダ雨量との差異に関する一考察,歴史都市防災論文集,Vol.10,47-54.
(15) 横山 仁,2016,東京都におけるゲリラ豪雨の実態とその適応策について(地域の気候変動適応策の推進 : 持続可能な社会を目指して),地球環境,21(2),167-172.
(14) Kusunoki, K., Ken-ichiro Arai and Ryohei Kato, 2017, Observations of the Intensity and Structure Changes within a Winter Tornadic Storm during Landfall over the Japan Sea Area, IEEJ Transactions on Fundamentals and Materials, 137, 141-146.
(13) Kusunoki, K., Ken-ichiro Arai and Ryohei Kato, Eiichi Sato, Chusei Fujiwara, 2016, A Linear Array of Wind and Pressure Sensors for High Resolution in situ Measurements in Winter Tornadoes, IEEJ Transactions on Fundamentals and Materials, 136, 286-290.
(12) Arimitsu, Y., Masamitsu Fujimoto, Nobutaka Hiaraoka, Toru Danjo, Yuko Ishida and Ryoichi Fukagawa, 2016, CHARACTERISTICSOF RAIN INFILTRATION IN SOIL LAYERS ON THE HILLSLOPE BEHIND IMPORTANT CULTUAL ASSET, Intenational Journal of GEOMATE, vol.10, 2109-2115.
(11) 井上太之・村上智一・南條楠土・水谷 晃・河野裕美,2016,西表島網取湾ウダラ川汽水域の潮汐に伴う塩分動態および優占する魚類の分布,土木学会論文 集B3(海洋開発),72,1087-1092.
(10) 岡辺拓巳・青木勇介・加藤茂・村上智一・下川信也・河野裕美,2016,円筒型捕砂器の特性評価と浅海域における漂砂観測への適用,土木学会論文集B3(海洋開発),72,922-927.
(9) 吉野純・村上智一・鵜飼亮行・河野裕美・北恵伍・下川信也・崎原健・水谷晃,2016,西表島白浜湾および船浮湾における海水交換過程に関する研究,土木学会論文集B2(海岸工学),72,1207-1212.
(8) 赤星明紀・下瀬健一・岸田岳士・植松康・義江龍一郎,2016,風環境評価のための三杯型風速計と超音波型風速計による平均風速の差の検討,風工学シンポジウム論文集,24,79-84.
(7) 川崎浩司・下川信也・村上智一,2016,超巨大台風による伊勢湾湾奥部における高潮浸水予測,土木学会論文集B2(海岸工学),72,211-216.
(6) 川崎浩司・金明奎・下川信也・村上智一,2016,巨大地震・台風の複合災害による大阪港沿岸部の高潮浸水予測,土木学会論文集B3(海洋開発),72,13-18.
(5) 川崎浩司・二村昌樹・下川信也・飯塚聡・栢原孝浩,2016,海洋流動モデルFVCOMとメソ数値予報モデルを用いた日本周辺海域の高潮推算,土木学会論文集B2(海岸工学),72,119-204.
(4) 太田俊紀・松浦知徳・村上智一・下川信也,2016,地形効果による寄り回り波の波浪特性,土木学会論文集B3(海洋開発),72,289-294.
(3) 中瀬浩太・村上智一・河野裕美・鵜飼亮行・水谷晃・下川信也,2016,月別外力再現計算を用いた西表島北西部海域のウミショウブ分布条件の評価,土木学会論文集B2(海岸工学),72,429-434.
(2) 秋山一弥・池田慎二・木村誇・松下拓樹,2016,014年2月の大雪によって山梨県早川周辺で発生した雪崩の到達距離と地形の関係,雪 氷,78,439-457.
(1) 山粼 雄大・常松 展充・ 横山 仁・梅木 清・本條 毅 ,2016,温熱快適感マップの作成と夏季マラソンコースの温熱環境予測,環境情報科学学術研究論文集 ,30,43-48.