教师名录
基本情况
5657威尼斯教授、博士生导师,中国力学学会成员、中国有色金属学会成员、中国人类工效学学会成员、江苏省欧美同学会成员,学术期刊Advanced Powder Materials青年编委(2022-今)、学术期刊International Journal of Computational Materials Science and Surface Engineering编委(2019-今)。2004年毕业于5657威尼斯机械工程系获工学学士学位,2010年毕业于5657威尼斯材料学院获工学博士学位,随后在上海交通大学、美国普渡大学从事博士后研究工作,2016年回5657威尼斯工作。研究兴趣集中在面向工程和科学的多尺度模拟与高通量计算领域,包括复杂系统科学、多尺度计算方法、介观方法及其应用、机器学习工程应用、凝固过程数值模拟等。
长期专注于凝固过程的建模模拟,针对凝固过程中的熔体流动、枝晶生长、热质输运及缺陷形成等问题开展研究,现已成功将相场方法、元胞自动机方法与格子玻尔兹曼方法结合并用于金属熔体对流传热与微观组织形成规律的研究。近年来,他将格子玻尔兹曼方法与元胞自动机、相场方法结合,应用于凝固组织模拟、复杂流体流动、对流传热相变的研究中,推进了格子玻尔兹曼方法在凝固模拟、合金设计与相变动力学等方面的应用。他的研究兴趣还包括以分子动理论为基础的数学模型、数值方法和软件技术的研究。这些内容既是工程科学的核心问题之一,也是机械、能动、材料、化工与生医等学科的新兴交叉点,并可为相关领域的学术发展和技术进步提供全新思路。
主持和参加了国家、国防、国际合作及部省级科研项目27项,在Acta Mater.、Appl. Phys. Lett.、Int. J. Heat Mass Transfer等期刊发表SCI论文89篇。他曾组织举办第1至10届格子玻尔兹曼方法及其应用会议(2013-2022)、第2届相场与集成计算材料工程会议(2018)、The 31st Discrete Simulation of Fluid Dynamics Conference(2022.08,Suzhou,China),The 8th International Conference on Physical and Numerical Simulation of Materials Processing(2016.10, Seattle, USA),担任上海交通大学材料基因组联合研究中心成员(2015-2016)、第15届全国渗流力学会学术会议青委会委员(2019)、The European Physical Journal E客座编辑(2019-2020),获2018年中国颗粒学会自然科学一等奖1项、2019年中国化工学会基础研究成果一等奖1项。
工作时间
办公时间(Office Time 2024.02-2024.07) | 上课时间(Course Time 2024.02-2024.07) |
周一 09:00-11:30 周二 09:00-11:30 周三 09:00-11:30/14:00-17:00 周四 14:00-17:00 周五 09:00-11:30/14:00-17:00 | 周一 14:00-15:35 (J1-309) 周二 09:50-11:25/14:00-15:35 (J1-203) 周三 - 周四 09:50-11:25 (J1-309) 周五 - |
英才招收
• 本科生:有意申请本课题组免试生(含直博生)的本科生可申请参加本课题组的课外研学计划(SRTP)或其他类型的科研项目,或提前开始毕业设计工作;参加本课题组科研项目者,每周投入工作时间不得少于10小时,且每次连续工作不少于2小时;有优秀成果及展现学术潜力者,可获得继续读研深造、学术会议、出国交流的推荐与资助。
• 研究生:机械、数学、物理、化学、材料或计算机等相关学科优秀本科生,思想端正、身心健康、热爱科学、勇于探索、乐观开朗,积极进取,具有较强的科研能力或发展潜力;有英语成绩(CET4/6、TOEFL、IELTS)者或英语阅读、写作或口语熟练者优先;优先招收推免生、直博生和硕博连读生。
• 博士后:机械、数学、力学、材料、物理或计算机等学科专业领域;已正式获得博士学位且获得时间不超过三年者,已通过博士学位论文答辩且半年内能获得博士学位者;对博士后提供必要的科研、会议与交流等活动资助;在站待遇高于学校标准,特别优秀者可面议待遇。
• 共同约定:不得侵害直接实施建模、模拟或实验之研究生和本科生的基本署名权;不得强夺研究生和本科生第一作者署名权,不违反署名的必要性原则;遵守科研活动规范,确保研究成果真实可信,坚守学术道德底线,确保论文发表真实可靠。
毕业去向
本科生 | 研究生 |
• 庄晨悦(2024届),5657威尼斯/直博 • 丁雪容(2023届),5657威尼斯/免研 • 吴鹏霄(2023届),5657威尼斯/免研 • 吴寒(2023届),5657威尼斯/直博 • 吴意豪(2023届),5657威尼斯/免研 • 孙萌(2022届),5657威尼斯/免研 • 何雨亭(2022届),浙江大学/读研 • 于芊楠(2022届),5657威尼斯/免研 • 秦楚晋(2022届),5657威尼斯/直博 • 曹宇婷(2021届),University of Michigan, Ann Arbor/读研(博) • 吴津仪(2021届),5657威尼斯/直接攻博 • 邵小轩(2021届),RWTH Aachen University/读研(博) • 刘依琳(2021届),5657威尼斯/免研 • 陈俊伟(2020届),上海大学/读研 • 毛士麟(2019届),5657威尼斯/硕博连读 • 王学舟(2018届),5657威尼斯/免研 | • 张文斌(硕,2024届),苏州某企/机械工程&研发设计 • 刘依琳(硕,2024届),北京某所/航天科工&设计开发 • 毛子彧(硕,2023届),深圳某企/软件工程&测试运维 • 耿博(硕,2023届),南京小米/软件工程&开发测试 • 赵虎(硕,2023届),苏州同创/软件工程&软件开发 • 陈道梁(硕,2022届),杭州Tp-Link/软件工程&软件开发 • 王学舟(硕,2021届),挪威科技大学/读博 CFD&CMS • 张兆栋(硕,2020届),潍柴动力/CAE 建模与模拟 • 林羲(博,2020届,联培),上海交通大学/博士后 • G.Thomas(硕,2019届,法国),美国/读博 CFD&NHT |
合作交流
与德国Max Planck Institute for Dynamics and Self-Organization的Yong Wang博士 (Senior Scientist, Group Leader),美国Purdue University West Lafayette的Guang Lin教授、Xiaoming Wang教授,美国The Pennsylvania State University的Long-Qing Chen教授 (欧洲科学院外籍院士),美国The University of Texas at Dallas的Guoping Xiong教授,英国University of Edinburgh的Timm Krüger教授,Indiana University-Purdue University Indianapolis的Huidan Yu教授,澳大利亚Monash Unversity的Kerry Hourigan教授,澳大利亚University of New South Wales Canberra的Fang-Bao Tian教授以及全球著名热动力学软件公司CompuTherm LLC的Vice President的Shuanglin Chen博士 (ASM International Fellow)、Weisheng Cao博士等著名学者、研究机构和科技公司建立了密切的学术合作关系。
更新于2024年03月16日
• 2016.12– 今,5657威尼斯,5657威尼斯,教授
• 2015.11–2016.12,美国普渡大学,5657威尼斯, 博士后
• 2014.10–2015.11,上海交通大学,材料科学与工程学院,博士后
本科生课程:
• 计算材料学(专业基础课,2022-今)
• 工程流体力学(大类学科基础课,2021-今)
• 材料数值模拟基础(专业基础课,2019-2021)
• 程序设计与算法语言(C++面向对象,大类学科基础课,2017-2019)
研究生课程:
• 高等流体力学(静力学、动力学、数值传热学与计算流体力学,硕士学位课,2023-今)
• 流体力学(静力学、动力学、数值传热学与计算流体力学,硕士学位课,2017-2023)
• Advances in Water Resources
• Advances in Applied Mathematics and Mechanics
• Applied Mathematics Letters
• Applied Mathematical Modelling
• Applied Thermal Engineering
• Chinese Physics B
• Communications in Computational Physics
• Computational Materials Science
• Computers & Fluids
• International Journal of Computational Materials Science and Surface Engineering
• International Journal of Heat and Mass Transfer
• International Journal of Manufacturing Technology and Management
• International Journal of Numerical Methods for Heat and Fluid Flow
• International Journal of Thermal Sciences
• Journal of Hydrodynamics
• Journal of Materials Science & Technology
• Journal of Porous Media
• Material Science and Engineering Technology
• Nanoscale
• Nanoscale Research Letters
• Physics of Fluids
• Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science
• The Canadian Journal of Chemical Engineering
• The European Physical Journal E
• 机械工程学报
• 东北大学学报
• 科学通报
• 传感技术学报
• 钢铁研究学报(英文版)
• 西南交通大学学报
• 浙江科技学院学报
• 中国材料研究学会凝固科学与技术分会, 理事
• 中国机械工程学会材料数值模拟专委会, 委员
• 中国力学学会, 会员
• 中国有色金属学会, 会员
• 格子玻尔兹曼方法及其应用论坛, 理事
• 相场与集成计算材料工程论坛, 理事
• 第15届全国渗流力学会学术会议青委会, 委员
• Secretariat, Session Chair: The 8th International Conference on Physical and Numerical Simulation of Materials Processing Oct. 14-17, 2016 in Seattle, U.S.A.
• Guest Editor of EUROPEAN PHYSICAL JOURNAL E (2019)
[1] Jinyi Wu, Dongke Sun*, Wei Chen, Zhenhua Chai. A unified lattice Boltzmann - phase fieldscheme for simulations of solutal dendrite growth in the presence of meltconvection. International Journal of Heat and Mass Transfer, 2024, 22 : 124958.SCI WOS:
[2] Yuhong Zhao*, Hui Xing, Lijun Zhang,Houbing Huang, DongkeSun, Xianglei Dong, Yongxing Shen, Jincheng Wang. Development of Phase‑Field Modeling in MaterialsScience in China: A Review. Acta Metallurgica Sinica (English Letters), 2023, 36:1749-1775. SCI WOS:
[3] Bo Geng, Shilin Mao, Wei Chen, Dongke Sun*. Numerical modelingo f faceted crystal growth using a lattice Boltzmann- phase field model with a new interfacial energy function. ComputationalMaterials Science, 2023, 227: 112273. SCI WOS:
[4] Chengjie Zhan, Zhenhua Chai*,Baochang Shi, PingJiang, Shaoning Geng and Dongke Sun**.A Diffuse-Interface Lattice Boltzmann Method for the Dendritic Growth with ThermosolutalConvection. Communications in Computational Physics, 2023,. 33(4): 1164-1188. SCIWOS:
[5] Zhishan Yuan*, Cheng Zhang,Chujin Qin, DongkeSun**, Mingting Qiu, Haiyu Wang, Chengyong Wang**.Pre-wetting of sand for high speed oil-water separation. Journal of WaterProcess Engineering, 2022, 50: 103270. SCI WOS:
[6] Yihao Wu, Hui Xing, QingyuZhang and DongkeSun*. Numerical Study on Dynamics of Blood CellMigration and Deformation in Atherosclerotic Vessels. Mathematics, 2022, 10:2022. SCI WOS:
[7] Daoliang Chen, Wei Chen, YanfeiLiu and DongkeSun*. A Two-Relaxation-Time Lattice BoltzmannModel for Electron Beam Selective Melting Additive Manufacturing. Frontiers inMaterials. 2022, 9: 885481. SCIWOS:
[8] Xuezhou Wang, Shilin Mao,Jincheng Wang, DongkeSun*. Numerical modelling of equiaxed dendriticgrowth with sedimentation in the melt of binary alloys by using an anisotropic latticeBoltzmann - phase field model. International Journal of Thermal Sciences, 2022,178: 107592. SCI WOS:
[9] Shilin Mao, Xuezhou Wang, Dongke Sun*, Jincheng Wang. Numerical modeling of dendrite growth in a steady magneticfield using the two relaxation times latticeBoltzmann - phase field model. Computational Materials Science, 2022, 204,111149. SCI WOS:
[10] Yongping Huang, Dongcheng Cao, Dongke Sun, Xiangdong Liu*. Experimental and numerical studies on the heattransfer improvement of a latent heat storage unit using gradient tree-shapedfins. International Journal of Heat and Mass Transfer, 2022, 182: 121920. SCI WOS:
[11] Yuting Cao, Dongke Sun*, Hui Xing and Jincheng Wang. Modeling of crystal growth with density changeinduced flows by the anisotropic lattice Boltzmann scheme. Applied MathematicsLetters, 2021, 120: 107318. SCIWOS:
[12] Hui Xing*, Xianglei Dong, Dongke Sun** and Yongsheng Han. Anisotropic lattice Boltzmann-phase-fieldmodeling of crystal growth with melt convection induced by solid-liquid densitychange. Journal of Materials Science & Technology, 2020, 57: 26–32. SCI WOS:000572537200003.
[13] Qingyu Zhang*, Dongke Sun, Shunhu Zhang, Hui Wang and Mingfang Zhu**. Modelingof microporosity formation and hydrogen concentration evolution duringsolidification of an Al–Si alloy. Chin. Phys. B, 2020, 29(7): 078104. SCI WOS:000547008100001.
[14] Xuezhou Wang, Dongke Sun*, HuiXing**, Yongsheng Han***,Yanfei Liu and Jincheng Wang. Numerical modeling of equiaxed crystal growth insolidification of binary alloys using a lattice Boltzmann-finite volume scheme.2020 November, 184: 109855. DOI: 10.1016/j.commatsci.2020.109855.SCI WOS: 000567372100006.
[15] Jinyi Wu, Dongke Sun*, Jincheng Wang and Mingfang Zhu**.Modeling of free dendritic growth in a gravity environment by lattice Boltzmannmethod. Eur. Phys. J. E, 2020, 43: 30. DOI: 10.1140/epje/i2020-11958-7. SCI WOS:000538061300001.
[16] Dongke Sun*. A discrete kinetic scheme to model anisotropic liquid-solid phasetransitions. Applied Mathematics Letters. 2020, 103: 106222. DOI:10.1016/j.aml.2020.106222. SCI WOS: 000517664700047.
[17] Chongchen Xiang, Qingyu Zhang*, Dongke Sun, Shunhu Zhang,Mingfang Zhu and Markus Rettenmayr. European PhysicalJournal E. 2020, 43(1): 5. DOI: 10.1140/epje/i2020-11930-7. SCI WOS:000511948100001.
[18] Zhaodong Zhang, Yuting Cao, Dongke Sun*, Hui Xin, JinchengWang and Zhonghua Ni. A numerical study on pattern selection in crystal growthby using anisotropic lattice Boltzmann-phase field method, Chin. Phys. B,2020(2): 028103. DOI: 10.1088/1674-1056/AB6718. SCI WOS: 000526965800001.
[19] Chengbin Zhang, Suchen Wu, Feng Yao andDongke Sun*.Numerical study on vapor–liquid phasechange in an enclosed narrow space. Numerical Heat Transfer, Part A:Applications, 2020, 77(2): 199–214. SCI WOS: 000494727500001.
[20] Rui Du, Jincheng Wang andDongke Sun*.Lattice-Boltzmann Simulations of the Convection-Diffusion Equation withDifferent Reactive Boundary Conditions. Mathematics. 2020, 8 (1): 13. DOI:10.3390/math8010013. SCI WOS: 000515730100077.
[21] Qingyu Zhang*, Dongke Sun, Shiyan Pan andMingfang Zhu*. Microporosity formation and dendrite growth duringsolidification of aluminum alloys: Modeling and experiment. InternationalJournal of Heat and Mass Transfer, 2020, 146: 118838. DOI: 10.1016/j.ijheatmasstransfer.2019.118838.SCI WOS: 000500371700032.
[22] Rui Du, Dongke Sun, Baochang Shi and Zhenhua Chai*. Lattice Boltzmannmodel for time sub-diffusion equation in Caputo sense. Applied Mathematics andComputation. 2019, 358: 80-90. DOI: 10.1016/J.AMC.2019.04.014. SCI WOS:000467907700007.
[23] Xi Lin, Dongke Sun, Shuanglin Chen, Qi Zhu, Haiyan Leng and QianLi*. Numerical analysis on pulverization and self-densification for hydrogenstorage performance of a metal hydride tank. Applied Thermal Engineering, 2019,161: 114129. DOI: 10.1016/J.APPLTHERMALENG.2019.114129. SCI WOS: 000488887200017.EI Accession number: 20193007224463.
[24] Xiao Li, Kaibing Ren, Man Zhang, Wen Sang, Dongke Sun, TaoHu* and Zhonghua Ni**. Cobalt functionalized MoS2/carbon nanotubes scaffold forenzyme-free glucose detection with extremely low detection limit. DOI:10.1016/J.SNB.2019.04.137. Sensors and Actuators B-Chemical, 2019: 293:122-128. SCI WOS:000469021800017.
[25] Qun Luo, Cong Zhai, Dongke Sun, Wei Chen and QianLi*. Interpolation and extrapolation with the CALPHAD method, Journal ofMaterials Science & Technology, 2019, 35, 2115–2120. SCI WOS: 000475870600029.
[26] Dong An, Shuanglin Chen, Dongke Sun, Shiyan Pan, Bruce W.Krakauer and Mingfang Zhu*. A cellular automaton model integrated with CALPHAD-basedthermodynamic calculations for ferrite-austenite phase transformations inmulticomponent alloys. Computational Materials Science, 2019, 166:210-220. SCI WOS:000471870200024.
[27] Tao Hu, Jian Xu, Yi Ye , Yu Han , Xiao Li, Zhen Wang, Dongke Sun*,Yunlong Zhou** and Zhonghua Ni***. Visual detection of mixed organophosphorouspesticide using QD-AChE aerogel based microfluidic arrays sensor. Biosensorsand Bioelectronics, 2019, 136: 112–117. SCI WOS: WOS:000471081400015.
[28] Tao Lu, Wenke Chai, Ye Pan*, Ting Dai andDongke Sun.CoCrFeNi Multi-principal Element Alloy Prepared via Self-propagatingHigh-Temperature Synthesis Plus Investment Casting Method. Metallurgical andMaterials Transactions B, 2019, 50B: 32-35. SCI WOS: 000456070300006.
[29] Jinming Wu, Yingxue Yao, Dongke Sun*, Zhonghua Ni** and MalinGoeteman. Numerical and Experimental Study of the Solo Duck Wave EnergyConverter. Energies 2019, 12, 1941; doi:10.3390/en12101941 SCI WOS:000471016700120.
[30] Mengdan Hu, Qingyu Zhang, Dongke Sun andMingfang Zhu*. Three-dimensional lattice Boltzmann modeling of dropletcondensation on superhydrophobic nanostructured surfaces. Acta Physica Sinic A 2019,68, 3: 030501 DOI: 10.7498/aps.68.20181665. SCI WOS:000458164600009.
[31] Dongke Sun*,Hui Xing, Xianglei Dong and Yongsheng Han. An anisotropiclattice Boltzmann - phase field scheme for numerical simulations of dendriticgrowth with melt convection. International Journal of Heat and Mass Transfer,2019, 133: 1240-1250. SCI WOS:000460710100108, EI Accession number: 20190306372113.
[32] Dongke Sun*, Zhenhua Chai, Qian Li and Guanglin Lin. A lattice Boltzmann–cellular automaton study on dendrite growthwith melt convection in solidification of ternary alloys. Chinese Physics B,2018, 27(8): 088105. SCI WOS:000442033100005, EI Accession number:20183405716754.
[33] Dongke Sun*, Yong Wang, Hongyao Yu and Qingyou Han. A lattice Boltzmannstudy on dendritic growth of a binary alloy in the presence of melt convection.International Journal of Heat and Mass Transfer, 2018, 123: 213–226. SCI WOS:000434887000018, EI Accessionnumber: 20181004860237.
[34] Zhenhua Chai*, Dongke Sun, Huili Wang and BaochangShi. A comparative study of local and nonlocal Allen-Cahn equations with massconservation. International Journal of Heat and Mass Transfer, 2018, 122: 631–42. SCI WOS: 000431933500055.
[35] Tao Hu, Mengdan Hu, Sisi Zhou andDongke Sun*. AnImmersed Boundary-Lattice Boltzmann Prediction for Particle HydrodynamicFocusing in Annular Microchannels. Chinese Physics Letters, 2018, 35(10):108101. SCI WOS:000448135200021.
[36] Tao Hu, Yi Ye, Ke Chen, Feifei Long, Wen Sang, Yunlong Zhou*, DongkeSun** and Zhonghua Ni**. Visual detection of glucose based on quantumdots aerogel in microfluidic chips, Anal. Methods, 2018, 10, 5749. SCI WOS: 000453243200001.
[37] Qingyu Zhang, Dongke Sun and Mingfang Zhu*. Amulticomponent multiphase lattice Boltzmann model with large liquid-gas densityratios for simulations of wetting phenomena. Chinese Physics B, 2017, 26(8):084701. SCI WOS: 000407239300001, EI 20173304051709.
[38] Dongke Sun*, Shiyan Pan, Qingyou Han and Baode Sun**. Numerical simulation ofdendritic growth in directional solidification of binary alloys using a latticeBoltzmann scheme. International Journal of Heat and Mass Transfer, 2016, 103:821–831. SCI WOS: 000368953400031.
[39] Dongke Sun*, Yong Wang, Anping Dong and Baode Sun. A three-dimensionalquantitative study on the hydrodynamic focusing of particles with the immersedboundary-lattice Boltzmann method. International Journal of Heat and MassTransfer, 2016, 94: 306-315. SCI WOS: 000368953400031. EI 20155201712141.
[40] Dongke Sun*, Mingfang Zhu, Jun Wang and Baode Sun. Lattice Boltzmann modeling ofbubble formation and dendritic growth in solidification of binary alloys.International Journal of Heat and Mass Transfer, 2016, 94: 474-487. SCI WOS: 000368953400047.EI 20155101679631.
[41] Qingyu Zhang, Dongke Sun, Youfa Zhang and Mingfang Zhu*.Numerical modeling of condensate droplet on superhydrophobic nanoarrays usingthe lattice Boltzmann method. Chinese Physics B, 2016, 25(6): 066401. SCI WOS: 000377876400043,EI 20162602538014.
[42] Yuepeng Pang, Dongke Sun, Qinfen Gu, Kuo-Chih Chou, XunliWang and Qian Li*. Comprehensive determination of kinetic parameters insolid-state phase transitions: An extended Jonhson−Mehl−Avrami−Kolomogorovmodel with analytical solutions. Crystal Growth & Design, 2016, 16 (4):2404-2415. SCI WOS: 000373747700076, EI 20161802341016.
[43] Shuang Qiu, Nai J. Ge, Dongke Sun, Sheng Zhao, JianfeiSun*, Zhao B. Guo, Ke Hu and Ning Gu. Synthesis and characterization ofmagnetic polyvinyl alcohol (PVA) hydrogel microspheres for the embolization ofblood vessel. IEEE Transactions on Biomedical Engineering, 2016, 63(4):.730-736. SCI WOS: 000372983800005, EI 20161602270843.
[44] Mingfang Zhu*, Qianyu Tang, Qingyu Zhang, Shiyan Pan and DongkeSun. Cellular AutomatonModeling of Micro-Structure Evolution During Alloy Solidification. ActaMetallurgica Sinica, 2016(10): 1297-1310. (in Chinese) DOI:10.11900/0412.1961.2016.00361, SCI WOS: 000390080900014.
[45] Dongke Sun*, Qingyu Zhang, Weisheng Cao and Mingfang Zhu. Simulation of dendriticgrowth with melt convection in solidification of ternary alloys. ChinesePhysics Letters, 2015, 32 (6): 068103. SCI WOS: 000358597200043.
[46] Dongke Sun, Zheng Bo*. Numerical simulation of hydrodynamic focusing of particlesin straight channel flows with the immersed boundary-lattice Boltzmann method.International Journal of Heat and Mass Transfer, 2015, 80: 139-149. SCI WOS: 000345202100014,EI 20144200103906.
[47] Wang Yong*, Dongke Sun, Yaling He and Wenquan Tao. LatticeBoltzmann study on thermoacoustic onset in a Rijke tube. The European PhysicalJournal Plus (2015) 130(1): 1-10. SCI WOS: 000348344300001.
[48] Ke Chen, Yunlin Quan, Chunfeng Song, Nan Xiang, Di Jiang, DongkeSun, Juekuan Yang, Hong Yi and Zhonghua Ni*. Accurate controlof individual metallic nanowires by light-induced dielectrophoresis: Size-basedseparation and array-spacing regulation. Sensors and Actuators A: Physical,2015, 225: 139-147. SCI WOS: 000352666100018, EI 20151100639143.
[49] Qingyu Zhang, Dongke Sun, Youfa Zhang and Mingfang Zhu*.Lattice Boltzmann modeling of droplet condensation on superhydrophobicnanoarrays. Langmuir, 2014, 30 (42), 12559-12569. SCI WOS: 000347744100013, EI 20144500154833.
[50] Mingfang Zhu*, Dongke Sun, Shiyan Pan, Qingyu Zhang and RaabeD. Modelling of dendritic growth during alloy solidification under naturalconvection. Modelling and Simulation in Materials Science and Engineering,2014, 22: 034006. SCI WOS: 000335952900008, EI 20141717618173.
[51] Nan Xiang, Ke Chen, Qing Dai, Di Jiang, Dongke Sun and ZhonghuaNi*. Inertia-induced focusing dynamics of microparticles throughout a curvedmicrofluidic channel. Microfluidics and Nanofluidics, 2014, 18: 29-39. SCI WOS:000348977700004, EI 20143600007197.
[52] Ke Chen, Nan Xiang, Yunlin Quan, Xiaolu Zhu, Dongke Sun,Hong Yi and Zhonghua Ni*. Directed transport and location-designated rotation ofnanowires using AC electric fields. Microfluidics and Nanofluidics, 2014, 16:237-246. SCI WOS: 000329406900024, EI 20141817652459.
[53] Dongke Sun*, Yong Wang, Di Jiang, Nan Xiang, Ke Chen and Zhonghua Ni. Dynamicself-assembly of particles in an expanding channel flow. Applied PhysicsLetters, 2013, 103: 071905. SCI WOS: 000323769000020, EI 20133516662071.
[54] Dongke Sun*, Nan Xiang, Di Jiang, Ke Chen, Hong Yi and Zhonghua Ni. Multirelaxation time lattice Boltzmann simulation of inertial secondary flow in acurved microchannel. Chinese Physics B, 2013, 22(11): 114704. SCI WOS: 000327485400047,EI 20134917055097.
[55] Dongke Sun*, Di Jiang, Nan Xiang, Ke Chen and Zhonghua Ni. An immersed boundary -lattice Boltzmann simulation of particle hydrodynamic focusing in a straightmicrochannel. Chinese Physics Letters, 2013, 30(7): 074702. SCI WOS: 000321763700032.
[56] Dongke Sun*, Nan Xiang, Ke Chen and Zhonghua Ni. Lattice Boltzmann modeling ofparticle inertial migration in a curved channel. Acta Physica Sinica, 2013,62(2): 024703. (in Chinese) SCI WOS: 000316815000050.
[57] Nan Xiang, Ke Chen, Dongke Sun, Shanfang Wang, Hong Yi andZhonghua Ni*. Quantitative characterization of the focusing process and dynamicbehavior of differently sized microparticles in a spiral microchannel.Microfluidics and Nanofluidics, 2013, 14: 89-99. SCI WOS: 000313798700008, EI 20132416407255.
[58] Nan Xiang, Hong Yi, Ke Chen, Dongke Sun, Di Jiang, QingDai and Zhonghua Ni*. High-throughput inertial particle focusing in a curvedmicrochannel: Insights into the flow-rate regulation mechanism and processmodel. Biomicrofluidics, 2013, 7: 044116. SCI WOS: 000323907600018, EI 20133716726952.
[59] Di Jiang, Dongke Sun, Nan Xiang, Ke Chen, Hong Yi andZhonghua Ni*. Lattice Boltzmann numerical simulation and experimental researchof dynamic flow in an expansion-contraction microchannel. Biomicrofluidics,2013, 7: 034113. SCI WOS: 000321145800014, EI 20132916517455.
[60] Hainan Chen, Dongke Sun, Ting Dai and Mingfang Zhu*.Modeling of the interaction between solidification interface and bubble usingthe lattice Boltzmann method with large density ratio. Acta Physica Sinica,2013, 62(12): 120502. (in Chinese) SCI WOS: 000321185600007.
[61] Jianfei Sun*, Jian Dong, Dongke Sun, Zhirui Guo and NingGu. Magnetically mediated vortexlike assembly of gold nanoshells. Langmuir,2012, 28(16): 6520-6526. SCI WOS: 000303091300002, EI 20121814977036.
[62] Wei Wu, Mingfang Zhu*, Dongke Sun, Ting Dai, Qingyou Han andDierk Raabe. Modelling of dendritic growth and bubble formation. IOP ConfSeries: Materials Science and Engineering, 2012, 33: 012103. SCI WOS: 000307779900103,EI 20132116361118.
[63] Wei Wu, Dongke Sun, Ting Dai and Mingfang Zhu*. Modellingof dendritic growth and bubble formation. Acta Physica Sinica, 2012, 61(15):3394-3401. (in Chinese) SCI WOS: 000309089100006.
[64] Mingfang Zhu*, Shiyan Pan, Dongke Sun, Zhonglin Gui andFengmao Zhou. Numerical modeling of microstructure evolution in alloysolidification. Advances in Heterogeneous Material Mechanics, 2011: 643-650.SCI WOS: 000297713100159, EI 20124015499973.
[65] Dongke Sun, Mingfang Zhu*, Shiyan Pan, Chaorong Yang and Dierk Raabe. LatticeBoltzmann modeling of dendritic growth in forced and natural convection.Computers and Mathematics with Applications, 2011, 61(12): 3585-3592. SCI WOS: 000292583300016,EI 20112514070927.
[66] Dongke Sun, Mingfang Zhu*, Ting Dai, Weisheng Cao, Shuanglin Chen, Dierk Raabe andChun-Pyo Hong. Modelling of dendritic growth in ternary alloy solidificationwith melt convection. International Journal of Cast Metals Research, 2011, 24(3/4): 177-183. SCI WOS: 000293333900009, EI 20113114195046.
[67] Fengmao Zhou, Dongke Sun and Mingfang Zhu*. LatticeBoltzmann modelling of liquid-liquid phase separation of monotectic alloys.Acta Physica Sinica 2010, 59(5): 3394-3401. (in Chinese) SCI WOS: 000277733700073.
[68] Mingfang Zhu*, Shiyan Pan, Dongke Sun and Honglei Zhao.Numerical simulation of microstructure evolution during alloy solidification byusing cellular automaton method. ISIJ International 2010, 50 (12): 1851-1858.SCI WOS: 000285666400018, EI 20110913712196.
[69] Chaorong Yang, Dongke Sun, Shiyan Pan, Ting Dai andMingfang Zhu*. CA–LBM model for the simulation ofdendritic growth under natural convection. Acta Metallurgica Sinica 2009,45(1): 43-50. (in Chinese) SCI WOS: 000263767800007, EI 20091111955815.
[70] Honglei Zhao, Dongke Sun, Shiyan Pan, Ting Dai and MingfangZhu*. CA-LBM modeling of solutal dendritic growth with forced convection.Journal of Southeast University (Natural Science Edition), 2009, 39(2):255-261. (in Chinese) EI 20091812064354.
[71] Dongke Sun, Mingfang Zhu*, Shiyan Pan and Dierk Raabe. Numerical modeling ofdendritic growth in alloy solidification with forced convection. InternationalJournal of Modern Physics B, 2009, 23(6/7): 1609-1614. SCI WOS: 000266134700137.
[72] Dongke Sun, Mingfang Zhu*, Chaorong Yang, Shiyan Pan and Ting Dai. Modelling ofdendritic growth in forced and natural convections. Acta Physica Sinica, 2009,58: s285-s291. (in Chinese) SCI WOS: 000270312900047.
[73] Dongke Sun, Mingfang Zhu*, Shiyan Pan and Dierk Raabe. Lattice Boltzmann modelingof dendritic growth in a forced melt convection. Acta Materialia, 2009, 57(6):1755-1767. SCI WOS: 000264677600006 , EI 20091011940525.
[74] Dongke SunandMingfang Zhu*. Cellular automaton-lattice Boltzmann model for modeling ofdendritic growth in flowing melt. The Chinese Journal of Nonferrous Metals,2007, 17(s1): 84-89. (in Chinese)
[75] Dongke Sun, Mingfang Zhu*, Dierk Raabe and Chun-Pyo Hong. Cellular automaton -lattice Boltzmann model for the simulation of dendritic growth with meltconvection. Proceedings of the 7th Pacific Rim International Conference onModeling of Casting and Solidification Processes, Dalian University ofTechnology, Dalian, China, August 19-22, 2007.
[76] Min Su, Dongke Sun and Mingfang Zhu*. Application oflattice Boltzmann method in modeling of dendritic growth. Materials forMechanical Engineering, 2007, 31(2): 75-78. (in Chinese)
[77] Jianchun Wu, Yinsheng Dong*, Pinghua Lin, Dongke Sun and FengGao. Effects of cooling ways on microstructure of Zn-Cu peritectic alloy.Special Casting & Nonferrous Alloys, 2005, 25(6): 326-328. (in Chinese) EI 2005289209455.
Updated on December 07, 2023.
项目名称 | 项目类别 | 项目时间 | 工作类别 | 项目金额 |
电子束选区熔化*********及*********模拟研究 | 中国航空制造技术研究院 | 2020/01-2020/08 | 项目主持人 | ***万元 |
连续降温过程中马氏体相变温度的热力学预测 | 上海大学国家重点实验室开放课题 | 2019/11-2021/10 | 项目主持人 | 10万元 |
面向海空装备超轻超高强结构件的钛铝合金设计与制备工艺研究 | 中央高校基本科研业务费专项资金(重点项目) | 2019/01-2020/20 | 项目主持人 | 50万元 |
钛铝合金在电子束增材制造过程中凝固组织的形成规律研究 | 凝固技术国家重点实验室开放课题(重点项目) | 2019/01-2021/12 | 项目主持人 | 20万元 |
面向合金成分设计与微观组织模拟的高性能算法研究 | 新金属材料国家重点实验室开放研究基金 | 2019/07-2021/06 | 项目主持人 | 5万元 |
电子束增材制造钛铝金属间化合物的微观组织形成机制研究 | 5657威尼斯优青培育项目 | 2018/01–2018/12 | 项目主持人 | 5万元 |
脉冲电磁振荡对钢熔体热质输运与等轴晶迁移的影响规律 | 上海大学国家重点实验室开放课题 | 2018/01–2018/12 | 项目主持人 | 5万元 |
电子束增材制造钛铝合金叶片的组织与性能调控技术研究 | 装备预研教育部联合基金(青年人才) | 2018/01-2019/12 | 项目主持人 | 80万元 |
面向稀有循环肿瘤细胞的非标记精准检测仪器研制 | 国家重大科研仪器研制项目 | 2018/01-2022/12 | 项目参与人 | 690万元 |
肿瘤细胞流动治疗机理的多尺度模拟与实验研究 | 国家自然科学基金 | 2018/01–2019/12 | 中方合作者 | 18万元 |
复杂受限空间中强制对流条件下镍基高温合金凝固组织演变机制 | 国家自然科学基金面上项目 | 2018/01-2021/12 | 项目合作者 | 62万元 |
新型镍基高温合金组合设计与全流程集成制备 | 国家重点研发计划 | 2017/01-2020/12 | 一般参与人 | 2000万元 |
纳流体环境下单个DNA分子的过孔动力学研究 | 国家自然科学基金青年项目 | 2014/01-2016/12 | 项目主持人 | 25万元 |
磁场诱导的金纳米壳颗粒在多尺度上的组装集体 | 国家自然科学基金面上项目 | 2013/01-2016/12 | 项目参与人 | 78万元 |
单链DNA在纳流动作用下动力学行为的数值模拟研究 | 中国博士后科学基金面上项目 | 2013/01-2013/12 | 项目主持人 | 5万元 |
对流枝晶生长和气泡形成的格子Boltzmann方法模拟研究 | 国家自然科学基金面上项目 | 2010/01–2012/12 | 项目参与人 | 35万元 |
对流作用下三元合金凝固时枝晶生长行为的模拟研究 | 国家自然科学基金面上项目 | 2007/01–2009/12 | 项目参与人 | 30万元 |
基于前沿跟踪-格子Boltzmann方法的对流枝晶生长规律研究 | 教育部博士点基金 | 2008/01–2010/12 | 项目参与人 | 6万元 |
更新于2020年12月31日
国家专利 | ||||
专利号 | 专利名称 | 完成时间 | 专利类型 | |
CN201610855857.0. | 一种水下设施激光增材修复的方法与装置 | 2016/12 | 发明专利授权 | |
CN201210175163.4 | 一种基于无掩模光刻的变高度微流道制作方法 | 2012/12 | 发明专利授权 | |
CN201110407831.7 | 一种微米级粒子高通量分选的微流控器件及其制作方法 | 2011/12 | 发明专利授权 | |
CN201120502783.5 | 一种具有高深宽比微流道的微流控芯片 | 2011/12 | 实用新型授权 | |
软件著作权 | ||||
软件名称 | 著作权排序 | 完成时间 | 登记号 | |
单相熔体流动数值模拟与分析软件V1.0 | 第一完成人 | 2018/03 | 2018SR323869 | |
格子玻尔兹曼单相流动模拟软件V1.0 | 第一完成人 | 2017/04 | 2017SR417791 | |
固液两相颗粒聚焦熵软件V1.0 | 第一完成人 | 2017/04 | 2017SR449758 |
更新于2020年12月31日
基本情况
5657威尼斯教授、博士生导师,中国力学学会成员、中国有色金属学会成员、中国人类工效学学会成员、江苏省欧美同学会成员,学术期刊Advanced Powder Materials青年编委(2022-今)、学术期刊International Journal of Computational Materials Science and Surface Engineering编委(2019-今)。2004年毕业于5657威尼斯机械工程系获工学学士学位,2010年毕业于5657威尼斯材料学院获工学博士学位,随后在上海交通大学、美国普渡大学从事博士后研究工作,2016年回5657威尼斯工作。研究兴趣集中在面向工程和科学的多尺度模拟与高通量计算领域,包括复杂系统科学、多尺度计算方法、介观方法及其应用、机器学习工程应用、凝固过程数值模拟等。
长期专注于凝固过程的建模模拟,针对凝固过程中的熔体流动、枝晶生长、热质输运及缺陷形成等问题开展研究,现已成功将相场方法、元胞自动机方法与格子玻尔兹曼方法结合并用于金属熔体对流传热与微观组织形成规律的研究。近年来,他将格子玻尔兹曼方法与元胞自动机、相场方法结合,应用于凝固组织模拟、复杂流体流动、对流传热相变的研究中,推进了格子玻尔兹曼方法在凝固模拟、合金设计与相变动力学等方面的应用。他的研究兴趣还包括以分子动理论为基础的数学模型、数值方法和软件技术的研究。这些内容既是工程科学的核心问题之一,也是机械、能动、材料、化工与生医等学科的新兴交叉点,并可为相关领域的学术发展和技术进步提供全新思路。
主持和参加了国家、国防、国际合作及部省级科研项目27项,在Acta Mater.、Appl. Phys. Lett.、Int. J. Heat Mass Transfer等期刊发表SCI论文89篇。他曾组织举办第1至10届格子玻尔兹曼方法及其应用会议(2013-2022)、第2届相场与集成计算材料工程会议(2018)、The 31st Discrete Simulation of Fluid Dynamics Conference(2022.08,Suzhou,China),The 8th International Conference on Physical and Numerical Simulation of Materials Processing(2016.10, Seattle, USA),担任上海交通大学材料基因组联合研究中心成员(2015-2016)、第15届全国渗流力学会学术会议青委会委员(2019)、The European Physical Journal E客座编辑(2019-2020),获2018年中国颗粒学会自然科学一等奖1项、2019年中国化工学会基础研究成果一等奖1项。
工作时间
办公时间(Office Time 2024.02-2024.07) | 上课时间(Course Time 2024.02-2024.07) |
周一 09:00-11:30 周二 09:00-11:30 周三 09:00-11:30/14:00-17:00 周四 14:00-17:00 周五 09:00-11:30/14:00-17:00 | 周一 14:00-15:35 (J1-309) 周二 09:50-11:25/14:00-15:35 (J1-203) 周三 - 周四 09:50-11:25 (J1-309) 周五 - |
英才招收
• 本科生:有意申请本课题组免试生(含直博生)的本科生可申请参加本课题组的课外研学计划(SRTP)或其他类型的科研项目,或提前开始毕业设计工作;参加本课题组科研项目者,每周投入工作时间不得少于10小时,且每次连续工作不少于2小时;有优秀成果及展现学术潜力者,可获得继续读研深造、学术会议、出国交流的推荐与资助。
• 研究生:机械、数学、物理、化学、材料或计算机等相关学科优秀本科生,思想端正、身心健康、热爱科学、勇于探索、乐观开朗,积极进取,具有较强的科研能力或发展潜力;有英语成绩(CET4/6、TOEFL、IELTS)者或英语阅读、写作或口语熟练者优先;优先招收推免生、直博生和硕博连读生。
• 博士后:机械、数学、力学、材料、物理或计算机等学科专业领域;已正式获得博士学位且获得时间不超过三年者,已通过博士学位论文答辩且半年内能获得博士学位者;对博士后提供必要的科研、会议与交流等活动资助;在站待遇高于学校标准,特别优秀者可面议待遇。
• 共同约定:不得侵害直接实施建模、模拟或实验之研究生和本科生的基本署名权;不得强夺研究生和本科生第一作者署名权,不违反署名的必要性原则;遵守科研活动规范,确保研究成果真实可信,坚守学术道德底线,确保论文发表真实可靠。
毕业去向
本科生 | 研究生 |
• 庄晨悦(2024届),5657威尼斯/直博 • 丁雪容(2023届),5657威尼斯/免研 • 吴鹏霄(2023届),5657威尼斯/免研 • 吴寒(2023届),5657威尼斯/直博 • 吴意豪(2023届),5657威尼斯/免研 • 孙萌(2022届),5657威尼斯/免研 • 何雨亭(2022届),浙江大学/读研 • 于芊楠(2022届),5657威尼斯/免研 • 秦楚晋(2022届),5657威尼斯/直博 • 曹宇婷(2021届),University of Michigan, Ann Arbor/读研(博) • 吴津仪(2021届),5657威尼斯/直接攻博 • 邵小轩(2021届),RWTH Aachen University/读研(博) • 刘依琳(2021届),5657威尼斯/免研 • 陈俊伟(2020届),上海大学/读研 • 毛士麟(2019届),5657威尼斯/硕博连读 • 王学舟(2018届),5657威尼斯/免研 | • 张文斌(硕,2024届),苏州某企/机械工程&研发设计 • 刘依琳(硕,2024届),北京某所/航天科工&设计开发 • 毛子彧(硕,2023届),深圳某企/软件工程&测试运维 • 耿博(硕,2023届),南京小米/软件工程&开发测试 • 赵虎(硕,2023届),苏州同创/软件工程&软件开发 • 陈道梁(硕,2022届),杭州Tp-Link/软件工程&软件开发 • 王学舟(硕,2021届),挪威科技大学/读博 CFD&CMS • 张兆栋(硕,2020届),潍柴动力/CAE 建模与模拟 • 林羲(博,2020届,联培),上海交通大学/博士后 • G.Thomas(硕,2019届,法国),美国/读博 CFD&NHT |
合作交流
与德国Max Planck Institute for Dynamics and Self-Organization的Yong Wang博士 (Senior Scientist, Group Leader),美国Purdue University West Lafayette的Guang Lin教授、Xiaoming Wang教授,美国The Pennsylvania State University的Long-Qing Chen教授 (欧洲科学院外籍院士),美国The University of Texas at Dallas的Guoping Xiong教授,英国University of Edinburgh的Timm Krüger教授,Indiana University-Purdue University Indianapolis的Huidan Yu教授,澳大利亚Monash Unversity的Kerry Hourigan教授,澳大利亚University of New South Wales Canberra的Fang-Bao Tian教授以及全球著名热动力学软件公司CompuTherm LLC的Vice President的Shuanglin Chen博士 (ASM International Fellow)、Weisheng Cao博士等著名学者、研究机构和科技公司建立了密切的学术合作关系。
更新于2024年03月16日
[1] Jinyi Wu, Dongke Sun*, Wei Chen, Zhenhua Chai. A unified lattice Boltzmann - phase fieldscheme for simulations of solutal dendrite growth in the presence of meltconvection. International Journal of Heat and Mass Transfer, 2024, 22 : 124958.SCI WOS:
[2] Yuhong Zhao*, Hui Xing, Lijun Zhang,Houbing Huang, DongkeSun, Xianglei Dong, Yongxing Shen, Jincheng Wang. Development of Phase‑Field Modeling in MaterialsScience in China: A Review. Acta Metallurgica Sinica (English Letters), 2023, 36:1749-1775. SCI WOS:
[3] Bo Geng, Shilin Mao, Wei Chen, Dongke Sun*. Numerical modelingo f faceted crystal growth using a lattice Boltzmann- phase field model with a new interfacial energy function. ComputationalMaterials Science, 2023, 227: 112273. SCI WOS:
[4] Chengjie Zhan, Zhenhua Chai*,Baochang Shi, PingJiang, Shaoning Geng and Dongke Sun**.A Diffuse-Interface Lattice Boltzmann Method for the Dendritic Growth with ThermosolutalConvection. Communications in Computational Physics, 2023,. 33(4): 1164-1188. SCIWOS:
[5] Zhishan Yuan*, Cheng Zhang,Chujin Qin, DongkeSun**, Mingting Qiu, Haiyu Wang, Chengyong Wang**.Pre-wetting of sand for high speed oil-water separation. Journal of WaterProcess Engineering, 2022, 50: 103270. SCI WOS:
[6] Yihao Wu, Hui Xing, QingyuZhang and DongkeSun*. Numerical Study on Dynamics of Blood CellMigration and Deformation in Atherosclerotic Vessels. Mathematics, 2022, 10:2022. SCI WOS:
[7] Daoliang Chen, Wei Chen, YanfeiLiu and DongkeSun*. A Two-Relaxation-Time Lattice BoltzmannModel for Electron Beam Selective Melting Additive Manufacturing. Frontiers inMaterials. 2022, 9: 885481. SCIWOS:
[8] Xuezhou Wang, Shilin Mao,Jincheng Wang, DongkeSun*. Numerical modelling of equiaxed dendriticgrowth with sedimentation in the melt of binary alloys by using an anisotropic latticeBoltzmann - phase field model. International Journal of Thermal Sciences, 2022,178: 107592. SCI WOS:
[9] Shilin Mao, Xuezhou Wang, Dongke Sun*, Jincheng Wang. Numerical modeling of dendrite growth in a steady magneticfield using the two relaxation times latticeBoltzmann - phase field model. Computational Materials Science, 2022, 204,111149. SCI WOS:
[10] Yongping Huang, Dongcheng Cao, Dongke Sun, Xiangdong Liu*. Experimental and numerical studies on the heattransfer improvement of a latent heat storage unit using gradient tree-shapedfins. International Journal of Heat and Mass Transfer, 2022, 182: 121920. SCI WOS:
[11] Yuting Cao, Dongke Sun*, Hui Xing and Jincheng Wang. Modeling of crystal growth with density changeinduced flows by the anisotropic lattice Boltzmann scheme. Applied MathematicsLetters, 2021, 120: 107318. SCIWOS:
[12] Hui Xing*, Xianglei Dong, Dongke Sun** and Yongsheng Han. Anisotropic lattice Boltzmann-phase-fieldmodeling of crystal growth with melt convection induced by solid-liquid densitychange. Journal of Materials Science & Technology, 2020, 57: 26–32. SCI WOS:000572537200003.
[13] Qingyu Zhang*, Dongke Sun, Shunhu Zhang, Hui Wang and Mingfang Zhu**. Modelingof microporosity formation and hydrogen concentration evolution duringsolidification of an Al–Si alloy. Chin. Phys. B, 2020, 29(7): 078104. SCI WOS:000547008100001.
[14] Xuezhou Wang, Dongke Sun*, HuiXing**, Yongsheng Han***,Yanfei Liu and Jincheng Wang. Numerical modeling of equiaxed crystal growth insolidification of binary alloys using a lattice Boltzmann-finite volume scheme.2020 November, 184: 109855. DOI: 10.1016/j.commatsci.2020.109855.SCI WOS: 000567372100006.
[15] Jinyi Wu, Dongke Sun*, Jincheng Wang and Mingfang Zhu**.Modeling of free dendritic growth in a gravity environment by lattice Boltzmannmethod. Eur. Phys. J. E, 2020, 43: 30. DOI: 10.1140/epje/i2020-11958-7. SCI WOS:000538061300001.
[16] Dongke Sun*. A discrete kinetic scheme to model anisotropic liquid-solid phasetransitions. Applied Mathematics Letters. 2020, 103: 106222. DOI:10.1016/j.aml.2020.106222. SCI WOS: 000517664700047.
[17] Chongchen Xiang, Qingyu Zhang*, Dongke Sun, Shunhu Zhang,Mingfang Zhu and Markus Rettenmayr. European PhysicalJournal E. 2020, 43(1): 5. DOI: 10.1140/epje/i2020-11930-7. SCI WOS:000511948100001.
[18] Zhaodong Zhang, Yuting Cao, Dongke Sun*, Hui Xin, JinchengWang and Zhonghua Ni. A numerical study on pattern selection in crystal growthby using anisotropic lattice Boltzmann-phase field method, Chin. Phys. B,2020(2): 028103. DOI: 10.1088/1674-1056/AB6718. SCI WOS: 000526965800001.
[19] Chengbin Zhang, Suchen Wu, Feng Yao andDongke Sun*.Numerical study on vapor–liquid phasechange in an enclosed narrow space. Numerical Heat Transfer, Part A:Applications, 2020, 77(2): 199–214. SCI WOS: 000494727500001.
[20] Rui Du, Jincheng Wang andDongke Sun*.Lattice-Boltzmann Simulations of the Convection-Diffusion Equation withDifferent Reactive Boundary Conditions. Mathematics. 2020, 8 (1): 13. DOI:10.3390/math8010013. SCI WOS: 000515730100077.
[21] Qingyu Zhang*, Dongke Sun, Shiyan Pan andMingfang Zhu*. Microporosity formation and dendrite growth duringsolidification of aluminum alloys: Modeling and experiment. InternationalJournal of Heat and Mass Transfer, 2020, 146: 118838. DOI: 10.1016/j.ijheatmasstransfer.2019.118838.SCI WOS: 000500371700032.
[22] Rui Du, Dongke Sun, Baochang Shi and Zhenhua Chai*. Lattice Boltzmannmodel for time sub-diffusion equation in Caputo sense. Applied Mathematics andComputation. 2019, 358: 80-90. DOI: 10.1016/J.AMC.2019.04.014. SCI WOS:000467907700007.
[23] Xi Lin, Dongke Sun, Shuanglin Chen, Qi Zhu, Haiyan Leng and QianLi*. Numerical analysis on pulverization and self-densification for hydrogenstorage performance of a metal hydride tank. Applied Thermal Engineering, 2019,161: 114129. DOI: 10.1016/J.APPLTHERMALENG.2019.114129. SCI WOS: 000488887200017.EI Accession number: 20193007224463.
[24] Xiao Li, Kaibing Ren, Man Zhang, Wen Sang, Dongke Sun, TaoHu* and Zhonghua Ni**. Cobalt functionalized MoS2/carbon nanotubes scaffold forenzyme-free glucose detection with extremely low detection limit. DOI:10.1016/J.SNB.2019.04.137. Sensors and Actuators B-Chemical, 2019: 293:122-128. SCI WOS:000469021800017.
[25] Qun Luo, Cong Zhai, Dongke Sun, Wei Chen and QianLi*. Interpolation and extrapolation with the CALPHAD method, Journal ofMaterials Science & Technology, 2019, 35, 2115–2120. SCI WOS: 000475870600029.
[26] Dong An, Shuanglin Chen, Dongke Sun, Shiyan Pan, Bruce W.Krakauer and Mingfang Zhu*. A cellular automaton model integrated with CALPHAD-basedthermodynamic calculations for ferrite-austenite phase transformations inmulticomponent alloys. Computational Materials Science, 2019, 166:210-220. SCI WOS:000471870200024.
[27] Tao Hu, Jian Xu, Yi Ye , Yu Han , Xiao Li, Zhen Wang, Dongke Sun*,Yunlong Zhou** and Zhonghua Ni***. Visual detection of mixed organophosphorouspesticide using QD-AChE aerogel based microfluidic arrays sensor. Biosensorsand Bioelectronics, 2019, 136: 112–117. SCI WOS: WOS:000471081400015.
[28] Tao Lu, Wenke Chai, Ye Pan*, Ting Dai andDongke Sun.CoCrFeNi Multi-principal Element Alloy Prepared via Self-propagatingHigh-Temperature Synthesis Plus Investment Casting Method. Metallurgical andMaterials Transactions B, 2019, 50B: 32-35. SCI WOS: 000456070300006.
[29] Jinming Wu, Yingxue Yao, Dongke Sun*, Zhonghua Ni** and MalinGoeteman. Numerical and Experimental Study of the Solo Duck Wave EnergyConverter. Energies 2019, 12, 1941; doi:10.3390/en12101941 SCI WOS:000471016700120.
[30] Mengdan Hu, Qingyu Zhang, Dongke Sun andMingfang Zhu*. Three-dimensional lattice Boltzmann modeling of dropletcondensation on superhydrophobic nanostructured surfaces. Acta Physica Sinic A 2019,68, 3: 030501 DOI: 10.7498/aps.68.20181665. SCI WOS:000458164600009.
[31] Dongke Sun*,Hui Xing, Xianglei Dong and Yongsheng Han. An anisotropiclattice Boltzmann - phase field scheme for numerical simulations of dendriticgrowth with melt convection. International Journal of Heat and Mass Transfer,2019, 133: 1240-1250. SCI WOS:000460710100108, EI Accession number: 20190306372113.
[32] Dongke Sun*, Zhenhua Chai, Qian Li and Guanglin Lin. A lattice Boltzmann–cellular automaton study on dendrite growthwith melt convection in solidification of ternary alloys. Chinese Physics B,2018, 27(8): 088105. SCI WOS:000442033100005, EI Accession number:20183405716754.
[33] Dongke Sun*, Yong Wang, Hongyao Yu and Qingyou Han. A lattice Boltzmannstudy on dendritic growth of a binary alloy in the presence of melt convection.International Journal of Heat and Mass Transfer, 2018, 123: 213–226. SCI WOS:000434887000018, EI Accessionnumber: 20181004860237.
[34] Zhenhua Chai*, Dongke Sun, Huili Wang and BaochangShi. A comparative study of local and nonlocal Allen-Cahn equations with massconservation. International Journal of Heat and Mass Transfer, 2018, 122: 631–42. SCI WOS: 000431933500055.
[35] Tao Hu, Mengdan Hu, Sisi Zhou andDongke Sun*. AnImmersed Boundary-Lattice Boltzmann Prediction for Particle HydrodynamicFocusing in Annular Microchannels. Chinese Physics Letters, 2018, 35(10):108101. SCI WOS:000448135200021.
[36] Tao Hu, Yi Ye, Ke Chen, Feifei Long, Wen Sang, Yunlong Zhou*, DongkeSun** and Zhonghua Ni**. Visual detection of glucose based on quantumdots aerogel in microfluidic chips, Anal. Methods, 2018, 10, 5749. SCI WOS: 000453243200001.
[37] Qingyu Zhang, Dongke Sun and Mingfang Zhu*. Amulticomponent multiphase lattice Boltzmann model with large liquid-gas densityratios for simulations of wetting phenomena. Chinese Physics B, 2017, 26(8):084701. SCI WOS: 000407239300001, EI 20173304051709.
[38] Dongke Sun*, Shiyan Pan, Qingyou Han and Baode Sun**. Numerical simulation ofdendritic growth in directional solidification of binary alloys using a latticeBoltzmann scheme. International Journal of Heat and Mass Transfer, 2016, 103:821–831. SCI WOS: 000368953400031.
[39] Dongke Sun*, Yong Wang, Anping Dong and Baode Sun. A three-dimensionalquantitative study on the hydrodynamic focusing of particles with the immersedboundary-lattice Boltzmann method. International Journal of Heat and MassTransfer, 2016, 94: 306-315. SCI WOS: 000368953400031. EI 20155201712141.
[40] Dongke Sun*, Mingfang Zhu, Jun Wang and Baode Sun. Lattice Boltzmann modeling ofbubble formation and dendritic growth in solidification of binary alloys.International Journal of Heat and Mass Transfer, 2016, 94: 474-487. SCI WOS: 000368953400047.EI 20155101679631.
[41] Qingyu Zhang, Dongke Sun, Youfa Zhang and Mingfang Zhu*.Numerical modeling of condensate droplet on superhydrophobic nanoarrays usingthe lattice Boltzmann method. Chinese Physics B, 2016, 25(6): 066401. SCI WOS: 000377876400043,EI 20162602538014.
[42] Yuepeng Pang, Dongke Sun, Qinfen Gu, Kuo-Chih Chou, XunliWang and Qian Li*. Comprehensive determination of kinetic parameters insolid-state phase transitions: An extended Jonhson−Mehl−Avrami−Kolomogorovmodel with analytical solutions. Crystal Growth & Design, 2016, 16 (4):2404-2415. SCI WOS: 000373747700076, EI 20161802341016.
[43] Shuang Qiu, Nai J. Ge, Dongke Sun, Sheng Zhao, JianfeiSun*, Zhao B. Guo, Ke Hu and Ning Gu. Synthesis and characterization ofmagnetic polyvinyl alcohol (PVA) hydrogel microspheres for the embolization ofblood vessel. IEEE Transactions on Biomedical Engineering, 2016, 63(4):.730-736. SCI WOS: 000372983800005, EI 20161602270843.
[44] Mingfang Zhu*, Qianyu Tang, Qingyu Zhang, Shiyan Pan and DongkeSun. Cellular AutomatonModeling of Micro-Structure Evolution During Alloy Solidification. ActaMetallurgica Sinica, 2016(10): 1297-1310. (in Chinese) DOI:10.11900/0412.1961.2016.00361, SCI WOS: 000390080900014.
[45] Dongke Sun*, Qingyu Zhang, Weisheng Cao and Mingfang Zhu. Simulation of dendriticgrowth with melt convection in solidification of ternary alloys. ChinesePhysics Letters, 2015, 32 (6): 068103. SCI WOS: 000358597200043.
[46] Dongke Sun, Zheng Bo*. Numerical simulation of hydrodynamic focusing of particlesin straight channel flows with the immersed boundary-lattice Boltzmann method.International Journal of Heat and Mass Transfer, 2015, 80: 139-149. SCI WOS: 000345202100014,EI 20144200103906.
[47] Wang Yong*, Dongke Sun, Yaling He and Wenquan Tao. LatticeBoltzmann study on thermoacoustic onset in a Rijke tube. The European PhysicalJournal Plus (2015) 130(1): 1-10. SCI WOS: 000348344300001.
[48] Ke Chen, Yunlin Quan, Chunfeng Song, Nan Xiang, Di Jiang, DongkeSun, Juekuan Yang, Hong Yi and Zhonghua Ni*. Accurate controlof individual metallic nanowires by light-induced dielectrophoresis: Size-basedseparation and array-spacing regulation. Sensors and Actuators A: Physical,2015, 225: 139-147. SCI WOS: 000352666100018, EI 20151100639143.
[49] Qingyu Zhang, Dongke Sun, Youfa Zhang and Mingfang Zhu*.Lattice Boltzmann modeling of droplet condensation on superhydrophobicnanoarrays. Langmuir, 2014, 30 (42), 12559-12569. SCI WOS: 000347744100013, EI 20144500154833.
[50] Mingfang Zhu*, Dongke Sun, Shiyan Pan, Qingyu Zhang and RaabeD. Modelling of dendritic growth during alloy solidification under naturalconvection. Modelling and Simulation in Materials Science and Engineering,2014, 22: 034006. SCI WOS: 000335952900008, EI 20141717618173.
[51] Nan Xiang, Ke Chen, Qing Dai, Di Jiang, Dongke Sun and ZhonghuaNi*. Inertia-induced focusing dynamics of microparticles throughout a curvedmicrofluidic channel. Microfluidics and Nanofluidics, 2014, 18: 29-39. SCI WOS:000348977700004, EI 20143600007197.
[52] Ke Chen, Nan Xiang, Yunlin Quan, Xiaolu Zhu, Dongke Sun,Hong Yi and Zhonghua Ni*. Directed transport and location-designated rotation ofnanowires using AC electric fields. Microfluidics and Nanofluidics, 2014, 16:237-246. SCI WOS: 000329406900024, EI 20141817652459.
[53] Dongke Sun*, Yong Wang, Di Jiang, Nan Xiang, Ke Chen and Zhonghua Ni. Dynamicself-assembly of particles in an expanding channel flow. Applied PhysicsLetters, 2013, 103: 071905. SCI WOS: 000323769000020, EI 20133516662071.
[54] Dongke Sun*, Nan Xiang, Di Jiang, Ke Chen, Hong Yi and Zhonghua Ni. Multirelaxation time lattice Boltzmann simulation of inertial secondary flow in acurved microchannel. Chinese Physics B, 2013, 22(11): 114704. SCI WOS: 000327485400047,EI 20134917055097.
[55] Dongke Sun*, Di Jiang, Nan Xiang, Ke Chen and Zhonghua Ni. An immersed boundary -lattice Boltzmann simulation of particle hydrodynamic focusing in a straightmicrochannel. Chinese Physics Letters, 2013, 30(7): 074702. SCI WOS: 000321763700032.
[56] Dongke Sun*, Nan Xiang, Ke Chen and Zhonghua Ni. Lattice Boltzmann modeling ofparticle inertial migration in a curved channel. Acta Physica Sinica, 2013,62(2): 024703. (in Chinese) SCI WOS: 000316815000050.
[57] Nan Xiang, Ke Chen, Dongke Sun, Shanfang Wang, Hong Yi andZhonghua Ni*. Quantitative characterization of the focusing process and dynamicbehavior of differently sized microparticles in a spiral microchannel.Microfluidics and Nanofluidics, 2013, 14: 89-99. SCI WOS: 000313798700008, EI 20132416407255.
[58] Nan Xiang, Hong Yi, Ke Chen, Dongke Sun, Di Jiang, QingDai and Zhonghua Ni*. High-throughput inertial particle focusing in a curvedmicrochannel: Insights into the flow-rate regulation mechanism and processmodel. Biomicrofluidics, 2013, 7: 044116. SCI WOS: 000323907600018, EI 20133716726952.
[59] Di Jiang, Dongke Sun, Nan Xiang, Ke Chen, Hong Yi andZhonghua Ni*. Lattice Boltzmann numerical simulation and experimental researchof dynamic flow in an expansion-contraction microchannel. Biomicrofluidics,2013, 7: 034113. SCI WOS: 000321145800014, EI 20132916517455.
[60] Hainan Chen, Dongke Sun, Ting Dai and Mingfang Zhu*.Modeling of the interaction between solidification interface and bubble usingthe lattice Boltzmann method with large density ratio. Acta Physica Sinica,2013, 62(12): 120502. (in Chinese) SCI WOS: 000321185600007.
[61] Jianfei Sun*, Jian Dong, Dongke Sun, Zhirui Guo and NingGu. Magnetically mediated vortexlike assembly of gold nanoshells. Langmuir,2012, 28(16): 6520-6526. SCI WOS: 000303091300002, EI 20121814977036.
[62] Wei Wu, Mingfang Zhu*, Dongke Sun, Ting Dai, Qingyou Han andDierk Raabe. Modelling of dendritic growth and bubble formation. IOP ConfSeries: Materials Science and Engineering, 2012, 33: 012103. SCI WOS: 000307779900103,EI 20132116361118.
[63] Wei Wu, Dongke Sun, Ting Dai and Mingfang Zhu*. Modellingof dendritic growth and bubble formation. Acta Physica Sinica, 2012, 61(15):3394-3401. (in Chinese) SCI WOS: 000309089100006.
[64] Mingfang Zhu*, Shiyan Pan, Dongke Sun, Zhonglin Gui andFengmao Zhou. Numerical modeling of microstructure evolution in alloysolidification. Advances in Heterogeneous Material Mechanics, 2011: 643-650.SCI WOS: 000297713100159, EI 20124015499973.
[65] Dongke Sun, Mingfang Zhu*, Shiyan Pan, Chaorong Yang and Dierk Raabe. LatticeBoltzmann modeling of dendritic growth in forced and natural convection.Computers and Mathematics with Applications, 2011, 61(12): 3585-3592. SCI WOS: 000292583300016,EI 20112514070927.
[66] Dongke Sun, Mingfang Zhu*, Ting Dai, Weisheng Cao, Shuanglin Chen, Dierk Raabe andChun-Pyo Hong. Modelling of dendritic growth in ternary alloy solidificationwith melt convection. International Journal of Cast Metals Research, 2011, 24(3/4): 177-183. SCI WOS: 000293333900009, EI 20113114195046.
[67] Fengmao Zhou, Dongke Sun and Mingfang Zhu*. LatticeBoltzmann modelling of liquid-liquid phase separation of monotectic alloys.Acta Physica Sinica 2010, 59(5): 3394-3401. (in Chinese) SCI WOS: 000277733700073.
[68] Mingfang Zhu*, Shiyan Pan, Dongke Sun and Honglei Zhao.Numerical simulation of microstructure evolution during alloy solidification byusing cellular automaton method. ISIJ International 2010, 50 (12): 1851-1858.SCI WOS: 000285666400018, EI 20110913712196.
[69] Chaorong Yang, Dongke Sun, Shiyan Pan, Ting Dai andMingfang Zhu*. CA–LBM model for the simulation ofdendritic growth under natural convection. Acta Metallurgica Sinica 2009,45(1): 43-50. (in Chinese) SCI WOS: 000263767800007, EI 20091111955815.
[70] Honglei Zhao, Dongke Sun, Shiyan Pan, Ting Dai and MingfangZhu*. CA-LBM modeling of solutal dendritic growth with forced convection.Journal of Southeast University (Natural Science Edition), 2009, 39(2):255-261. (in Chinese) EI 20091812064354.
[71] Dongke Sun, Mingfang Zhu*, Shiyan Pan and Dierk Raabe. Numerical modeling ofdendritic growth in alloy solidification with forced convection. InternationalJournal of Modern Physics B, 2009, 23(6/7): 1609-1614. SCI WOS: 000266134700137.
[72] Dongke Sun, Mingfang Zhu*, Chaorong Yang, Shiyan Pan and Ting Dai. Modelling ofdendritic growth in forced and natural convections. Acta Physica Sinica, 2009,58: s285-s291. (in Chinese) SCI WOS: 000270312900047.
[73] Dongke Sun, Mingfang Zhu*, Shiyan Pan and Dierk Raabe. Lattice Boltzmann modelingof dendritic growth in a forced melt convection. Acta Materialia, 2009, 57(6):1755-1767. SCI WOS: 000264677600006 , EI 20091011940525.
[74] Dongke SunandMingfang Zhu*. Cellular automaton-lattice Boltzmann model for modeling ofdendritic growth in flowing melt. The Chinese Journal of Nonferrous Metals,2007, 17(s1): 84-89. (in Chinese)
[75] Dongke Sun, Mingfang Zhu*, Dierk Raabe and Chun-Pyo Hong. Cellular automaton -lattice Boltzmann model for the simulation of dendritic growth with meltconvection. Proceedings of the 7th Pacific Rim International Conference onModeling of Casting and Solidification Processes, Dalian University ofTechnology, Dalian, China, August 19-22, 2007.
[76] Min Su, Dongke Sun and Mingfang Zhu*. Application oflattice Boltzmann method in modeling of dendritic growth. Materials forMechanical Engineering, 2007, 31(2): 75-78. (in Chinese)
[77] Jianchun Wu, Yinsheng Dong*, Pinghua Lin, Dongke Sun and FengGao. Effects of cooling ways on microstructure of Zn-Cu peritectic alloy.Special Casting & Nonferrous Alloys, 2005, 25(6): 326-328. (in Chinese) EI 2005289209455.
Updated on December 07, 2023.
• 中国材料研究学会凝固科学与技术分会, 理事
• 中国机械工程学会材料数值模拟专委会, 委员
• 中国力学学会, 会员
• 中国有色金属学会, 会员
• 格子玻尔兹曼方法及其应用论坛, 理事
• 相场与集成计算材料工程论坛, 理事
• 第15届全国渗流力学会学术会议青委会, 委员
• Secretariat, Session Chair: The 8th International Conference on Physical and Numerical Simulation of Materials Processing Oct. 14-17, 2016 in Seattle, U.S.A.
• Guest Editor of EUROPEAN PHYSICAL JOURNAL E (2019)
项目名称 | 项目类别 | 项目时间 | 工作类别 | 项目金额 |
电子束选区熔化*********及*********模拟研究 | 中国航空制造技术研究院 | 2020/01-2020/08 | 项目主持人 | ***万元 |
连续降温过程中马氏体相变温度的热力学预测 | 上海大学国家重点实验室开放课题 | 2019/11-2021/10 | 项目主持人 | 10万元 |
面向海空装备超轻超高强结构件的钛铝合金设计与制备工艺研究 | 中央高校基本科研业务费专项资金(重点项目) | 2019/01-2020/20 | 项目主持人 | 50万元 |
钛铝合金在电子束增材制造过程中凝固组织的形成规律研究 | 凝固技术国家重点实验室开放课题(重点项目) | 2019/01-2021/12 | 项目主持人 | 20万元 |
面向合金成分设计与微观组织模拟的高性能算法研究 | 新金属材料国家重点实验室开放研究基金 | 2019/07-2021/06 | 项目主持人 | 5万元 |
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新型镍基高温合金组合设计与全流程集成制备 | 国家重点研发计划 | 2017/01-2020/12 | 一般参与人 | 2000万元 |
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CN201610855857.0. | 一种水下设施激光增材修复的方法与装置 | 2016/12 | 发明专利授权 | |
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CN201120502783.5 | 一种具有高深宽比微流道的微流控芯片 | 2011/12 | 实用新型授权 | |
软件著作权 | ||||
软件名称 | 著作权排序 | 完成时间 | 登记号 | |
单相熔体流动数值模拟与分析软件V1.0 | 第一完成人 | 2018/03 | 2018SR323869 | |
格子玻尔兹曼单相流动模拟软件V1.0 | 第一完成人 | 2017/04 | 2017SR417791 | |
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更新于2020年12月31日