课题1
1.Bing Tan, Lei Wang, Peng Lu, Zhijun Li, Enmin Feng, 2018. A novel strategy to analyse the form drag on pressure ridges and the air–ice drag coefficient in the northwestern Weddell Sea. Applied Mathematical Modelling, 58: 158-165.
2.Du L , Chen W , Xie T, 2017 . Design of underwater ultrasonic distance measurement using in arctic sea ice melting monitoring with high precision[C]// Seventh International Conference on Information Science & Technology. IEEE.
3.Fang H , Xie T , Perrie W , et al, 2017. Ocean Wind and Current Retrievals Based on Satellite SAR Measurements in Conjunction with Buoy and HF Radar Data[J]. Remote Sensing, 9(12):1321.
4.Fang H, Xie T, Perrie W, et al, 2018. Comparison of C-Band Quad-Polarization Synthetic Aperture Radar Wind Retrieval Models. Remote Sensing, 10(9): 1448.
5.Hao Guanghua, Su Jie, 2015. A Study on the Dynamic Tie Points ASI Algorithm in the Arctic Ocean,Acta Oceanologica Sinica., 34(11): 126–135, doi: 10.1007/s13131-015-0659-y (
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6.Li Lele, Chen Haihua, Guan Lei, 2017. Retrieval of snow depth on sea ice in the Arctic from FY3B/M WRI. IEEE Transactions on Geoscience and Remote Sensing Symposium(IGARSS), 1: 4976-4979.
7.Li Zhao,Tao Xie, Lei Meng, 2018. Polarization ratio characteristics of electromagnetic scattering from sea ice in polar areas. Chin. Phys. B, 27(12): 124102.
8.Li Zhijun, 2015, Experimental relationships of arctic sea ice uniaxial compressive strength with porosity. Proceedings of the 23rd International Conference on Port and Ocean Engineering under Arctic Conditions: 1-10.
9.Li Zhijun, 2015, Statistical navigation conditions along XUELONG Arctic Cruise Path in the summer of 2012. Proceedings of the 23rd International Conference on Port and Ocean Engineering under Arctic Conditions
10.Li Zhijun, Wang Jiankang, LiGe, Guo Kecai, 2017. Preliminary analysis on the drift ice floe areas and concentration near the structures along Bohai coastal based on satellite images. Proceedings of the 24th International Conference on Port and Ocean Engineering under Arctic Conditions, POAC17-032:
11.Li Zhijun, Xu Zijun, Wang Qingkai, Li Guoyu, 2018. Experimental Study on Uniaxial Compressive Strength Features of Wuliangsu Lake Ice. Proceedings of the 24th IAHR International Symposium on Ice, 1: 258-165.
12.Liu Mingshen,Guan Lei, Zhao Wei,Chen Ge, 2017. Evaluation of Sea Surface Temperature From the HY-2 Scanning Microwave Radiometer. IEEE Transactions on Geoscience and Remote Sensing, 55(3): 1372-1380.
13.Liu,M., Merchant CJ, Guan L, Mittaz JPD, 2018. Inter-Calibration of HY-1B/CO CTS Thermal Infrared Channels with MetOp-A/IASI. Remote Sensing, 10(8).
14.Lu P , Cheng B , Lepparanta M , et al, 2018. Partitioning of solar radiation in Arctic sea ice during melt season[J]. Oceanologia:S0078323418300563.
15.Lu P., Cao X., Wang Q., et al, 2018. Impact of a surface ice lid on the optical properties of melt ponds. Journal of Geophysical Research: Oceans, 123(11): 8313-8328.
16.Lu Peng, Matti Lepparanta, Bin Cheng, Zhijun Li, 2016. Influence of melt-pond depth and ice thickness on Arctic sea-ice albedo and light transmittance[J]. Cold Regions Science and Technology, 124:1-10.
17.Lu, P., Lepparanta, M., Cheng, B., et al, 2018. The color of melt ponds on Arctic sea ice. The Cryosphere, 12(4): 1331-1345.
18.Peng Lu, Zhijun Li, Bin Cheng, Matti Lepparanta, 2018. Optics of Melt Ponds on Arctic Sea Ice. Proceedings of the 24th IAHR International Symposium on Ice, 1: 402-409.
19.Q. Shi, J. Su, 2018. Retrieval and validation of sea ice concentration from AMSR-E/AMSR2 in polar regions. IGARSS 2018, IEEE International Geoscience and Remote Sensing Symposium, 7097-7100
20.Qingkai W , Zhijun L , Peng L , et al, 2018. In Situ Experimental Study of the Friction of Sea Ice and Steel on Sea Ice[J]. Applied Sciences, 8(5):675
21.Qingkai Wang, Zhijun Li, Xiaowei Cao, et al, 2017. Test on friction of sea ice on different materials. Proceedings of the 24th International Conference on Port and Ocean Engineering under Arctic Conditions, POAC17-032: 1-13.
22.Tao Xie , William Perrie , YiJun He , 2015. Ocean surface wave measurements from fully polarimetric SAR imagery[J]. Science China Earth Sciences, 58(10):1849-1861.
23.Wang Hongyan, Guan Lei, 2016. Evaluation of sea surface temperature from FY-3C VIRR data in the Arctic. IEEE Geoscience and Remote Sensing Letters, 13(2): 292-296.
24.Wang Mingfeng, Su Jie, Li Tao, Wang Xiaoyu, Ji Qing, Cao Yong, Lin Long, Liu Yilin, Wang Mingfeng et. al., 2018.Determination of Arctic melt pond fraction and sea ice roughness from Unmanned Aerial Vehicle (UAV) imagery[J]. Advances in Polar Science, 29 (3), in publish.
25.Wang Q , Li Z , Lei R , et al. , 2018,Estimation of the uniaxial compressive strength of Arctic sea ice during melt season[J]. Cold Regions Science and Technology, 151:9-18.
26.Wu Fan, Peter Cornillon, Brahim Boussid, Guan Lei, 2017. Determining the Pixel-to-Pixel uncertainty in Satellite-Derives SST fields. Remote Sensing, 9.
27.Wu Fan, Peter Cornillon, Li Lele, Guan Lei, 2017. Evaluation of the Precision in Level-2 AVHRR sea surface temperature fields. IEEE Transactions on Geoscience and Remote Sensing Symposium(IGARSS), 1: 2954-2957.
28.Xiaowei Cao, Peng Lu, Baosen Zhang, Guoyu Li, Zhijun LI, 2018. Observations of Ice Bottom Morphology and Flow Velocities under Ice. Proceedings of the 24th IAHR International Symposium on Ice, 1: 281-288.
29.Xiaowei CAO, Zhijun LI, Qingkai Wang, et al, 2017. Estimation of lake ice thickness using measured temperature profile in ice and water. Proceedings of the 24th International Conference on Port and Ocean Engineering under Arctic Conditions, POAC17-032:
30.Xie T , Fang H , Perrie W , et al, 2015. Propagation characteristics of damped traveling wave in a one-dimensional marginal sea ice[J]. Wuhan University Journal of Natural Sciences, 20(1):79-86.
31.Xie T , Perrie W , Zhao S Z , et al, 2016. Electromagnetic backscattering from one-dimensional drifting fractal sea surface II: Electromagnetic backscattering model[J]. Chinese Physics B, 25(7):074102.
32.Xie T , Zhao S Z , Perrie W , et al, 2016. Electromagnetic backscattering from one-dimensional drifting fractal sea surface I: Wave–current coupled model[J]. Chinese Physics B, 25(6).
33.Xie T, Zhao L, Perrie W and Fang, H, 2017. The sea-ice detection capability of synthetic aperture radar. Satellite Oceanography and Meteorology, 2(2): 261.
34.Xie Tao, William Perrie, Fang He, et al, 2017. Spatial and temporal variability of sea ice deformation rates in the Arctic Ocean observed by RADARSAT-1[J]. Science China(Earth Sciences), 5:54-61.
35.Xie Tao, William Perrie, Fang He, et al,2017. Effective dielectric constant model of electromagnetic backscattering from stratified air–sea surface film–sea water medium[J]. Chinese Physics B (05):124-129.
36.Yang M, Guan L, Qu L, Zhang K, 2018. Comparison of Suomi NPP VII RS SST Product with Shipboard Skin SST Measurements in the Northwest Pacific. IGARSS 2018, IEEE, 7: 5621-5624.
37.Yuanyuan Yang, Wei Chen, Tao Xie, William Perrie, 2018. Detection of meso-micro scale surface features based on microc anonical multifractal formalism. Chin. Phys. B, 27(1): 10502.
38.Zhang K.; Guan L.; Yang, M;Qu L.Autonomous Infrared Radiometer for Sea Surface Skin Temperature Measurements.
39.曹晓卫, 李春江, 颜小飞, et al, 2016. 利用探地雷达探测黄河弯道及桥墩周围冰层厚度[J]. 南水北调与水利科技, 14(6):91-95.
40.方贺, 谢涛, 杜路遥, et al, 2018. 一种用于观测北极海冰侧边界融化的水下超声波测距系统[J]. 仪表技术与传感器 (9): 112-117.
41.方贺,谢涛,周育锋,杨劲松,赵立,何宜军,William.Perrie,2018.基于C-2PO模型和CMOD5.N地球物理模式函数的SAR风速反演性能评估[J].海洋学报,40(09):103-112.(download1)
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43.李珵, 苏洁, 魏立新, 梁红杰, 黄菲, 赵进平, 2018. 北极中央区海冰低密集度现象研究, 海洋学报, 40(11), 33-45.
44.王传印,苏洁,2015. CICE海冰模式中融池参数化方案的比较研究,海洋学报,37(11):41-56.
45.王庆凯, 方贺, 李志军, et al, 2018. 湖冰侧、底部融化现场观测与热力学分析[J]. 水利学报, 49(10):1207-1215.
46.王庆凯, 李志军, 曹晓卫, et al, 2016,. 实测冰-水侧向界面热力学融化速率[J]. 南水北调与水利科技14(6).
47.王庆凯,雷瑞波,李志军,2018.基于现场试验的北极海冰单轴压缩强度评估. 哈尔滨工程大学学报, 39(10): 1589-1598.
48.王晓雨, 管磊, 李乐乐, 2018. FY-3B/MWRI和Aqua/AMSR-E海冰密集度比较及印证[J]. 遥感学报, 22(5): 723–736
49.谢涛, 方贺, 赵尚卓, et al, 2015. 基于合成孔径雷达遥感的北极海冰总形变率分析[J]. 海洋学报, 37(11):118-126.
50.杨新飞,管磊,2016。全球海气界面潜热通量产品对比研究。中国海洋大学学报,46(1):123-130.
51.张宝森, 张防修, 刘滋洋, et al, 2017. 黄河河道冰层雷达波特征图谱的现场实验研究 [J]. 南水北调与水利科技, 2017(1):121-125
课题2
1.Cao Yong, Zhao Jinping, Shao Qiuli, 2017. Progress in Chinese research on water masses and circulation in the Arctic and subarctic ocean. Advances in Polar Science, 28(2):91-99. (download)
2.Cao, Y., Bian, L.G. and Zhao, J.P, 2019.. Impacts of Changes in Sea Ice and Heat Flux on Arctic Warming. Atmospheric and Climate Sciences, 9: 84-99.
3.Chang L , Guo L , Feng G , et al, 2018. Comparison of the Arctic upper-air temperatures from radiosonde and radio occultation observations[J]. Acta Oceanologica Sinica, 37(1):30-39.
4.Chang L , Song S , Feng G , et al, 2017. Assessment of the Uncertainties in Arctic Low-Level Temperature Inversion Characteristics in Radio Occultation Observations[J]. IEEE Transactions on Geoscience and Remote Sensing, 55(3):1793-1803.
5.Cheng J , Liu Z , Zhang S , et al, 2016. Reduced interdecadal variability of Atlantic Meridional Overturning Circulation under global warming[J]. Proceedings of the National Academy of Sciences:201519827.
6.Guo Guijun and Shi Jiuxin, Temporal variability of vertical heat flux in the Makarov Basin during the ice camp observation in summer 2010, Acta Oceanologica Sinica, 34(11):118-125.(download)
7.Liang Chang, Guiping Feng, Yang Zhang, et al, 2018. Effect of Cloud Fraction on Arctic Low-Level Temperature Inve rsions in AIRS Observations Over Both Land and Ocean. IEEE Transactions on Geoscience and Remote Sensing, 56(4): 2025-2032.
8.Ma Y , Halsall C J , Koetke D , et al, 2017. Polycyclic aromatic hydrocarbons in ocean sediments from the North Pacific to the Arctic Ocean[J]. Environmental Pollution, 227:498-504.
9.Ma Y , Xie Z , Lohmann R , et al, 2017. Organophosphate Ester Flame Retardants and Plasticizers in Ocean Sediments from the North Pacific to the Arctic Ocean[J]. Environmental Science & Technology, 51(7):3809-3815.)
10.Sun Ruili, Gao Guoping, 2018. Impact of polar lows on synoptic scale variability of Atlantic inflow in the Fram Strait[J]. Acta Oceanologica Sinica, 37: 37-42.
11.Wang Zeliang, James Hamilton, Jie Su, 2017. Variations in freshwater pathways from the Arctic Ocean into the North Atlantic Ocean, Progress in Oceanography, 155:54-73. (download)
12.Yu T , Guo P , Cheng J , et al, 2018. Reduced connection between the East Asian Summer Monsoon and Southern Hemisphere Circulation on interannual timescales under intense global warming[J]. Climate Dynamics, 51: 3943-3955.
13.Yu Tianlei, Cheng Jun, Lin Pengfei, et al, 2018. Responses and mechanisms of East Asian winter and summer monsoons to weakened Atlantic meridional overturning circulation using the FGOALS‐g2 model[J]. International Journal of Climatology, 38(5): 2618-2626.
14.Zhang Y , Chen C , Beardsley R C , et al, 2016. Seasonal and interannual variability of the Arctic sea ice: A comparison between AO-FVCOM and observations[J]. Journal of Geophysical Research: Oceans, 121(11).
15.Zhong W, Guo G, Zhao J, Li Tao, Wang Xiaoyu, Mu Longjiang, 2018. Turbulent mixing above the Atlantic Water around the Chukchi Borderland in 2014[J]. Acta Oceanologica Sinica, 37(3):31-41.
16.Zhong W, Steele M, Zhang J, Zhao J, 2018. Greater role of geostrophic currents in Ekman dynamics in the western Arctic Ocean as a mechanism for Beaufort Gyre Stabilization[J]. Journal of Geophysical Research: Oceans, 123, 149–165. https://doi.org/10.1002/2017JC013282.
17.Zhong Wenli, Zhao Jinping, Shi Jiuxin and Cao Yong. 2015. The Beaufort Gyre Variation and its Impacts on the Canada Basin in 2003-2012. Acta Oceanol. Sin., 34(7): 1–10, doi: 10.1007/s13131-015-0657-0.(download)
18.曹勇,赵进平,2015。2011-2014年中国北极物理海洋学的研究进展. 海洋学报, 37(11):1-10. (download)
19.程军, 张瑾, 2017. 北大西洋高纬度海区湍流热通量对全球增暖的响应[J]. 大气科学学报.
20.王佳彬, 高郭平, 程灵巧, et al, 2016. 基于锚系观测的北冰洋加拿大海盆中层水多年变化研究[J]. 极地研究, 28(3):336-345.
21.吴静, 高郭平, 徐飞翔, et al, 2018. 向极跨越70°N气旋的主要特征分析[J]. 极地研究 (4): 391-405.
22.徐道欢, 杜凌, 马靖凯, 2018. 北极海冰减退期间加拿大海盆潮流变化特征[J]。海洋科学前沿, 5(2), 38-47.
23.张春玲, 夏燕军, 高郭平, 2016. 北欧海中尺度涡旋特征分析[J]. 海洋科学进展, 34(2):207-215.)
24.左正道, 高郭平, 程灵巧, et al, 2016. 1979-2012年北极海冰运动学特征初步分析[J]. 海洋学报, 38(5):57-69.
课题3
1.Basu S., Zhang X., Wang Z, 2018. Eurasian Winter Storm Activity at the End of the Century: A CMIP5 Multi-model Ensemble Projection[J]. Earth’s Future, 6(1): 61-70.
2.Chen Ping, Zhao Jinping, 2017. Variation of sea ice extent in different regions of the Arctic Ocean, Acta Oceanologica Sinica, 36(8): 9-19. (download)
3.Chen Xianyao, Zhang X. B., Church J. A., Watson C. S., King M. A., Monselesan D., Legresy B., Harig C,2017. The increasing rate of global mean sea-level rise during 1993-2014, Nature Climate Change, doi:10.1038/nclimate3325. (download)
4.Chen, X. Y.,Tung K-K, 2018. Global surface warming enhanced by weak Atlantic overturning circulation[J], Nature, doi:10.1038/s41586-018-0320.
5.Luo D , Xiao Y , Diao Y , et al. Impact of Ural Blocking on Winter Warm Arctic–Cold Eurasian Anomalies, 2016. Part II: The Link to the North Atlantic Oscillation[J]. Journal of Climate, 29(11):3949-3971.
6.Mu Longjiang, Zhao Jinping, Zhong Wenli, 2017. Regime shift of the dominant factor for halocline depth in the Canada Basin during 1990-2008, Acta Oceanologica Sinica, 36(1): 35-43. (download)
7.Wang J, Chen X, 2018. Intercomparison of the Extended Reconstructed Sea Surface Temperature v4 and v3b Datasets[J], J. Ocean Univ. China, 17(2), 209-218.
8.Wei J , Zhang X , Wang Z , 2018. Impacts of extratropical storm tracks on Arctic sea ice export through Fram Strait[J]. Climate Dynamics (2):1-12.
9.wnqi, Zhao Jinping, Lian Xihu, Wang Xiaoyu, Chen Weibin, 2017. Slowdown of sea surface height rises in the Nordic seas and related mechanisms, Acta Oceanologica Sinica, 36(8): 20-34. (download)
10.Zhang Shugang, Bian Lingen, Zhao Jinping, Li Min, Chen Shizhe, Jiao Yutian, Chen Ping, 2017. Thermodynamic model of melt pond and its application during summer of 2010 in the central Arctic Ocean, Acta Oceanologica Sinica, 36(8): 85-94. (download)
11.Zhang Shugang, Zhao Jinping, Li Min, Liu Shixuan, Zhang Shuwei, 2018. An improved dual-polarized ratio algorithm for sea ice concentration retrieval from passive microwave satellite data and inter-comparison with ASI, ABA and NT2[J]. Journal of Oceanology and Limnology, 36(5): 1494-1508.
12.Zhao J, Barber D, Zhang S, Yang Q, Wang X, Xie H, 2018. Record low sea-ice concentration in the central Arctic during summer 2010[J]. Adv. Atmos. Sci., 35(1), 106–115, https://doi.org/10.1007/s00376-017-7066-6.
13.Zhao J, Cao Y, Wang X, 2018. The physical significance of the synthetic running correlation coefficient and its applications in oceanic and atmospheric studies [J]. Journal of Ocean University of China. 17(3), 451-460.
14.Zhao Jinping, Li Tao, J. Ehn, D. Barber, 2015, An analytical validation for the attenuation of lateral propagating light in sea ice, Acta Oceanologica Sinica, 34(3):1-8. (download)
15.Zhao Jinping, Weibo Wang, Sung-Ho Kang, Eun-Jin Yang, and Tae-Wan Kim, 2015, Optical properties around Mendeleev Ridge related to the physical features of water masses, Deep Sea Research II, 120, 43-51. (download)
16.陈萍, 赵进平, 2017. 北极海面风场对海冰区域性和整体性变化的影响研究. 中国海洋大学学报(自然科学版), 47(8): 1-12. (download)
17.纪旭鹏,赵进平,2015. 北极中央区海冰密集度与云量相关性分析,海洋学报,37(11):92-104. (download)
18.林龙, 赵进平, 2018.雪热传导系数与穿过海冰的热通量研究[J].海洋学报, 40(11): 23-32, doi:10.3969/j.issn.0253-4193.201811.003(download)
19.刘喻道, 高郭平, 赵进平, 矫玉田, 王晓宇, 2018. 基于海气耦合浮标分析北欧海夏季海气热通量及其对ERA- Interim/OAFlux 的评估[J]. 上海海洋大学学报, 27(1): 149-160. (download)
20.牟龙江,赵进平,2015. 高低分辨率大气再分析资料强迫下的北冰洋冰海耦合模式,海洋学报,37(11):79-91.
21.牟龙江,赵进平.北极冰海耦合模式对两种不同大气再分析资料响应的分析[J].海洋学报,2015,37(11):79-91.
22.任丽媛,刁一娜,2018。冬季北太平洋的温带气旋活动及其与前期秋季北极海冰的关系。中国海洋大学学报(自然科学版), 48(3):20-29.
23.史文奇, 赵进平,2017,北欧海溢流的水温特征和变化机理综述,地球科学进展,32(3): 245-26. (download)
24.王晓宇,赵进平,李涛,钟文理,矫玉田,2015. 2012年夏季格陵兰海与挪威海水文特征分析。地球科学进展,30 (3): 346-356. (download)
25.肖贻青,黄斌,刁一娜,罗德海,2015. 北半球夏季中高纬度大气阻塞对北极海冰变化的影响[J]. 极地研究, 27(4): 364-378.
26.赵进平、史久新、王召民、李志军、黄菲,2015. 北极海冰减退引起的北极放大机理与全球气候效应,地球科学进展,30(9):985-995.
课题4
1.Basu S., Zhang X., Wang Z, 2018. Eurasian Winter Storm Activity at the End of the Century: A CMIP5 Multi-model Ensemble Projection[J]. Earth’s Future, 6(1): 61-70.
2.Bo Y , Yong C, 2018 . Dynamics of high-order solitons in the nonlocal nonlinear Schr?dinger equations[J]. Nonlinear Dynamics.
3.Bo Y , Yong C, 2018 . Several reverse-time integrable nonlocal nonlinear equations: Rogue-wave solutions[J]. Chaos: An Interdisciplinary Journal of Nonlinear Science, 28(5):053104-.
4.Chen J , Chen Y , Feng B F , et al, 2015. General Mixed Multi-Soliton Solutions to One-Dimensional Multicomponent Yajima–Oikawa System[J]. Journal of the Physical Society of Japan, 84(7):074001.
5.Chen J , Chen Y , Feng B F , et al, 2015. Multi-dark soliton solutions of the two-dimensional multi-component Yajima-Oikawa systems[J]. Journal of the Physical Society of Japan. 84(3): 034002
6.Chen J , Chen Y , Feng B F , et al., 2017. General high-order rogue waves of the (1+1)-dimensional Yajima-Oikawa system[J].
7.Chen J , Feng B F , Chen Y, 2017 . Bilinear Bäcklund transformation, Lax pair and multi-soliton solution for a vector Ramani equation[J]. Modern Physics Letters B, 31(12):1.
8.Chen J, Chen Y, Feng, Bao-Feng, et al. 2015. Rational solutions to multicomponent Yajima-Oikawa systems [J]. Phys. Lett. A,379(24):1510-1519.
9.Chen Junchao, Feng Baofeng, Chen Yong andMa Zhengyi,2017. General bright–dark soliton solution to (2+1)-dimensional multi-component long-wave–short-wave resonance interaction system[J]. Nonlinear Dyn.,88:1273-1288
10.Han Z , Chen Y , 2017. Bright-Dark Mixed N-Soliton Solution of Two-Dimensional Multicomponent Maccari System[J]. Zeitschrift für Naturforschung A.
11.Han Z , Chen Y , 2017. Symmetry Analysis and Exact Solutions of the 2D Unsteady Incompressible Boundary-Layer Equations[J]. Communications in Theoretical Physics, 67(1):1.(download)
12.Han Z , Chen Y , 2017.. Bright-Dark Mixed N-Soliton Solution of Two-Dimensional Multicomponent Maccari System[J]. Zeitschrift für Naturforschung A
13.Han Z , Chen Y , Chen J, 2017 . General $N$-Dark Soliton Solutions of the Multi-Component Mel'nikov System[J]. Journal of the Physical Society of Japan, 86(7).
14.Han Zhong, Chen Yong and Chen Junchao, 2017. Bright-Dark Mixed N-Soliton Solutions of the Multi-Component Melnikov System[J]. J. Phys. Soc. Jpn. 2017, 86: 104008
27.Huang Fei, Zhou Xiao, Wang Hong,2017. Arctic sea ice in CMIP5 climate model projections and their seasonal variability, Acta Oceanologica Sinica, 36(8): 1-8.
15.Huang L , Chen Y , 2016. Nonlocal symmetry and similarity reductions for the Drinfeld–Sokolov–Satsuma–Hirota system[J]. Applied Mathematics Letters, 64:177-184.
16.Huang L L , Qiao Z J , Chen Y , 2018. Soliton–cnoidal interactional wave solutions for the reduced Maxwell–Bloch equations[J]. Chinese Physics B, 27(2):020201.
17.Huang L L , Qiao Z J , Chen Y , 2018. Soliton–cnoidal interactional wave solutions for the reduced Maxwell–Bloch equations[J]. Chinese Physics B, 27(2):020201.
18.Huang Lili, ChenYong, 2018. Nonlocal symmetry and similarity reductions for a (2 + 1)-dimensional Korteweg–de Vries equation[J]. Nonliear Dyn. 2018, 92-2: 221-234
19.Jin R , Wu Z , Zhang P , 2017. Tibetan Plateau capacitor effect during the summer preceding ENSO: from the Yellow River climate perspective[J]. Climate Dynamics.
20.Li Z L , Wen P, 2017 . Comparison between the response of the Northwest Pacific Ocean and the South China Sea to Typhoon Megi (2010)[J]. Advances in Atmospheric Sciences, 34(1):79-87.
21.Lili H , Yunfei Y , Yong C, 2018 . Localized waves and interaction solutions to a (3+1)-dimensional generalized KP equation[J]. Computers & Mathematics with Applications:S0898122118302918.
22.Lou, S. Y , 2015. Consistent Riccati Expansion for Integrable Systems[J]. Studies in Applied Mathematics, 134(3):372-402.
23.Lu, Chuhan, 2017. A modified algorithm for identifying and tracking extratropical cyclones[J]. Advances in Atmospheric Sciences, 34(7):909-924.
24.Nie Y , Zhang Y , Chen G , et al, 2016. Delineating the Barotropic and Baroclinic Mechanisms in the Midlatitude Eddy-Driven Jet Response to Lower-Tropospheric Thermal Forcing[J]. Journal of the Atmospheric Sciences, 73(1):429-448
25.Qin Y , Lu C , Li L, 2017 . Multi-scale cyclone activity in the Changjiang River–Huaihe River valleys during spring and its relationship with rainfall anomalies[J]. Advances in Atmospheric Sciences, 34(2):246-257.(NSFC:No. 41575081;
26.Ren Y , Song L , Xiao Y , et al, 2018. Underestimated interannual variability of East Asian summer rainfall under climate change[J]. Theoretical and Applied Climatology.
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