教授(正高职)

张洁

职  称:青年教授
职  务:
专  业:工程力学,环境流体力学,实验力学
所在系所:工程力学研究所
通讯地址:甘肃省兰州市天水南路222号betway88中文官网,730000
电子信箱: zhang-j@lzu.edu.cn
联系电话:
传  真:
主要学历
2010/01–2013/10,科隆大学(德国),数学与自然科学系气象与地球物理研究所,自然科学博士(气象学),导师:Prof. Yaping Shao
2005/09–2008/06,兰州大学,betway88中文官网 工程力学,硕士,导师:黄宁 教授
2001/09–2005/06,兰州大学,物理科学与技术学院 理论与应用力学,大学本科
主要学术经历
2022/12-至今,兰州大学,betway88中文官网,教授
2017/07-2022/11,兰州大学,betway88中文官网,青年教授
2011/10–2017/06,兰州大学,betway88中文官网,工程师
2008/07–2011/10,兰州大学,betway88中文官网,助理工程师。
主要研究方向
1. 工程力学
2. 环境流体力学
3. 实验力学
主要讲授课程
1. 弹性力学与有限元 (本科生)
2. 风沙环境力学(研究生)
3. 现代实验力学及方法
招生专业
0801 力学 080104工程力学
欢迎力学、大气专业学生报考
主要学术成就、奖励及荣誉
主要科研项目及角色

1.中国国家铁路集团有限公司科技研究项目、和若铁路防沙综合技术研究,N2022G068、2022/11-2023/12、75万,在研、主持。
2.中铁工程设计咨询集团有限公司郑州设计院技术服务项目、鄂上铁路风沙地区基于防护带宽度优化的多层次平面防护体系研究、LZUKYHT1219202112281806、2021/12-2023/12、47.16万、在研、主持。
3.甘肃省科技计划项目重大项目、八步沙及河西走廊典型风沙区防风固沙体系稳定性评价与修复模式构建、21ZD4FA010、2021/10-2024/09、40万、在研、主持。
4.新疆和若铁路有限责任公司科技研究开发计划项目、植物防沙体系配置防护效益评价与模式优化实验研究、2020620005001908、2020/04-2022/08, 135万、在研、主持。
5.科技部科考专项、第二次青藏高原综合科学考察研究务二第六专题第十一子专题:青藏高原复杂地形上积雪时空分布产品精细化方案、2019QZKK020611、2019-11至2022-10、128万、在研、主持。
6.国家自然科学基金青年基金、复杂条件下地表颗粒物运动的力学机制研究、11602100、2017/01-2019/12、28万元、结题、主持。
7.国家重点研发计划、北方半干旱荒漠区沙化土地形成的物理-生物机制、2016YFC0500901、2016/07-2020/12、270万、结题、参加。
8.国家自然科学基金重大研究计划、面向黑河上游水文模型集成的基于风吹雪动力学过程的积雪分布研究、D010105、2014/01-2017/12、300万、结题、参加。
9.国家自然科学基金面上项目、41371034、基于风沙两相流的机械固沙措施防护机理及优化研究、2014/01-2017/12、90万、结题、参加。
10.国家自然科学基金面上项目、11172118、不同下垫面沙尘起扬的风洞实验与野外观测研究、2011/01-2015/12、80万、结题、参加。
11.国家自然科学基金面上项目、40971009、风吹雪两相流及其防治研究、56万元、2010/01-2012/12、结题、参加。
12.德国研究基金(DFG)、沙尘沉降机制的风洞试验与沙尘沉降参数化方案的开发、2009/01-2011/12、13.2万欧元、结题、参加。

代表性论著

学术论文(*为通讯作者,#为共同1作)
1.Zhang, J., Li, G., Shi, L., Huang, N., and Shao, Y.: Impact of turbulence on aeolian particle entrainment: results from wind-tunnel experiments, Atmos. Chem. Phys., 22, 9525–9535, https://doi.org/10.5194/acp-22-9525-2022, 2022.
2.P. He, J. Zhang#, H.J. Herrmann, N. Huang*, Large-eddy simulation of wind-blown sand under unstable atmospheric boundary layer, Science Bulletin (2022), doi: https://doi.org/10.1016/j.scib. 2022.05.011.
3.Yin X, Jiang C, Shao Y, Huang N, Zhang J*, LES study on turbulent dust deposition and its dependence on atmospheric boundary-layer stability. Atmos. Chem. Phys., 22, 4509–4522, 2022. https://doi.org/10.5194/acp-22-4509-2022. 
4.Huo X, Huang N, Zhang J*,A Numerical Research on the Relationship between Aeolian Sand Ripples and the Sand Flux. Processes. 2022 Feb 12;10(2):354. 
5.Liu Y, Li G, Zhang J*, Wind tunnel studies on the prevention of particle accumulation onto the bogie of high-speed train. Frontiers In Earth Science. 2022 Jan 25;10(ARTICLE):829309. 
6.Li G, He W, Yang B, Yu H, Huang N, Herrmann HJ, Zhang J*, Application of superstatistical analysis on fluctuant surface shear in particle-laden turbulence boundary layer. The European Physical Journal E. 2022 Jan;45(1):1-0. 
7.Dun H, Yue P, Huang N, Zhang J*, Discrete Element Simulation on Sand-Bed Collision Considering Surface Moisture Content. Processes. 2021 Dec 28;10(1):52. 
8.Wang P, Zhang J, Huang N*, An Idealized 3D Model of Interfacial Instability of Aeolian Bedform. Applied Sciences. 2021 Jan;11(19):8956.
9.李广, 于鸿翔, 张洁, 黄宁*, 风吹雪多相流运动及其在寒区雪水文中的应用. 空气动力学学报, 2021, 39(3): 170−181. 
10.Fattahi SM, Soroush A*, Huang N, Zhang J, Jodari Abbasi S, Yu Y, A framework for predicting abrasion rupture of crusts in wind erosion. Earth Surface Processes and Landforms. 2021 Oct;46(13):2565-81. 
11.Dun H, Xin G, Huang N, Shi G, Zhang J*. Wind-Tunnel Studies on Sand Sedimentation Around Wind-Break Walls of Lanxin High-Speed Railway II and Its Prevention. Applied Sciences. 2021 Jan;11(13):5989. 
12.Huo X, Dun H*, Huang N, Zhang J*, 3d direct numerical simulation on the emergence and development of aeolian sand ripples. Frontiers in Physics. 2021 Jun 28;9:358. 
13.Fattahi SM, Soroush A*, Huang N, Zhang J, Abbasi SJ, Yu Y. Durability of biotechnologically induced crusts on sand against wind erosion. Journal of Arid Environments. 2021 Jun 1;189:104508. 
14.Dun H, Huang N*, Zhang J*. Optimization designs of artificial facilities in deserts based on computational simulation. Journal of Arid Land. 2021 Mar;13(3):290-302. 
15.He W, Huang N, Zhang J*, Aerodynamic wall shear fluctuation in sand-laden flow in a turbulent boundary layer. The European Physical Journal E. 2021 Mar;44(3):1-5. 
16.Xin G, Huang N*, Zhang J, Dun H. Investigations into the design of sand control fence for Gobi buildings. Aeolian Research. 2021 Feb 1;49:100662. 
17.Yin X, Huang N, Jiang C, Parteli EJ, Zhang J*, Splash function for the collision of sand-sized particles onto an inclined granular bed, based on discrete-element-simulations. Powder Technology. 2021 Jan 22;378:348-58. 
18.Shao Y, Zhang J*, Ishizuka M, Mikami M, Leys J, Huang N*, Dependency of particle size distribution at dust emission on friction velocity and atmospheric boundary-layer stability. Atmospheric Chemistry and Physics. 2020 Nov 5;20(21):12939-53. 
19.Wang P, Zhang J#, Dun H, Herrmann HJ, Huang N, Aeolian creep transport: Theory and experiment. Geophysical Research Letters. 2020 Aug 16;47(15):e2020GL088644. 
20.Fattahi SM, Soroush A*, Huang N, Zhang J, Abbasi SJ, Yu Y, Soil properties affecting erosion induced by saltating particles. Environmental Geotechnics. 2020 May;40(XXXX):1-4. 
21.Fattahi SM, Soroush A*, Huang N, Zhang J, Abbasi SJ, Yu Y, Laboratory study on biophysicochemical improvement of desert sand. Catena. 2020 Jul 1;190:104531. 
22.Li G, Zhang J*, Herrmann HJ, Shao Y, Huang N*, Study of aerodynamic grain entrainment in aeolian transport. Geophysical Research Letters. 2020 Jun 16;47(11):e2019GL086574. 
23.Huang N, He P, Zhang J*, Large-eddy simulation of sand transport under unsteady wind. Geomorphology. 2020 Jun 1; 358:107105. 
24.辛国伟, 黄宁, 张洁*. 大风区铁路沿线挡风墙积沙机理及优化措施的风洞实验研究. 力学学报, v.52(03):36-45, 2020.
25.Zhu W, Huo X, Zhang J, Wang P, Pähtz T, Huang N, He Z. Large effects of particle size heterogeneity on dynamic saltation threshold. Journal of Geophysical Research: Earth Surface. 2019 Aug;124(8):2311-21. 
26.Chen Y, Zhang J*, Huang N*, Xu B, An experimental study on splash functions of natural sand‐bed collision. Journal of Geophysical Research: Atmospheres. 2019 Jul 16;124(13):7226-35. 
27.Zhang XX*, Sharratt B, Lei JQ, Wu CL, Zhang J, Zhao C, Wang ZF, Wu SX, Li SY, Liu LY, Huang SY. Parameterization schemes on dust deposition in northwest China: Model validation and implications for the global dust cycle. Atmospheric environment. 2019 Jul 15;209:1-3. 
28.Wang P, Zhang J*, Huang N*, A theoretical model for aeolian polydisperse-sand ripples. Geomorphology. 2019 Jun 15;335:28-36. 
29.Dun H, Huang N*, Zhang J, He W. Effects of shape and rotation of sand particles in saltation. Journal of Geophysical Research: Atmospheres. 2018 Dec 16;123(23):13-462. 
30.Xu B, Zhang J, Huang N*, Gong K, Liu Y. Characteristics of turbulent aeolian sand movement over straw checkerboard barriers and formation mechanisms of their internal erosion form. Journal of geophysical research: Atmospheres. 2018 Jul 16;123(13):6907-19. 
31.Fan YW, Huang N*, Zhang J, Zhao T. Simulation of soil wetting pattern of vertical moistube-irrigation. Water. 2018 May;10(5):601. 
32.Chen S*, Yuan T, Zhang X, Zhang G, Feng T, Zhao D, Zang Z, Liao S, Ma X, Jiang N, Zhang J. Dust modeling over East Asia during the summer of 2010 using the WRF-Chem model. Journal of Quantitative Spectroscopy and Radiative Transfer. 2018 Jul 1;213:1-2. 
33.Fan Y, Huang N*, Gong J, Shao X, Zhang J, Zhao T. A simplified infiltration model for predicting cumulative infiltration during vertical line source irrigation. Water. 2018 Jan;10(1):89. 
34.Zhang J, Teng Z, Huang N*, Guo L, Shao Y. Surface renewal as a significant mechanism for dust emission. Atmospheric Chemistry and Physics. 2016 Dec 15;16(24):15517-28. 
35.Huang N*, Dai X, Zhang J. The impacts of moisture transport on drifting snow sublimation in the saltation layer. Atmospheric Chemistry and Physics. 2016 Jun 20;16(12):7523-9. 
36.Huang N*, Zhang J. Wind-tunnel experiment on dust atmosphere-surface exchange: Emission and dry deposition. Procedia IUTAM. 2015 Jan 1;17:129-35. 
37.Zhang J*, Shao Y. A new parameterization of particle dry deposition over rough surfaces. Atmospheric Chemistry and Physics. 2014 Nov 27;14(22):12429-40. 
38.Zhang J*, Shao Y, Huang N, Measurements of dust deposition velocity in a wind-tunnel experiment. Atmospheric Chemistry and Physics. 2014 Sep 1;14(17):8869-82.
39.Zhang J, Shao Y*, Huang N. Wind-tunnel experiment on dust dry deposition. In AIP Conference Proceedings 2013 Oct 17 (Vol. 1558, No. 1, pp. 1063-1066). American Institute of Physics.
40.李卓群, 张洁, 黄宁, 邵亚平, 郑晓静*. 粉尘干沉降研究. 中国沙漠. 2011 May 20; 31(3): 639.

发明专利
1.张洁,宋彦宏,黄宁,蒋红.一种型面夹紧装置.ZL202120116824.0, 2021-10-29.
2.黄宁,辛国伟,张洁,顿洪超. 一种基于挡风墙的二次防积沙设施[P]. ZL202020389589.X,2021-03-09.
3.张洁,宋彦宏,黄宁,陈冠言. 一种分离的野外塔装式温湿度探头快速夹紧装置[P]. ZL202023005922.1,2021-06-15.
4.张洁,宋彦宏,黄宁,葛正虎,岳鹏,杨博. 一种高空布置传感器的自动升降和固定系统[P]. ZL202022988116.4,2021-08-20.
5.张洁, 薛晓敏, 杨博, 田树宝,覃俊铭,一种表面自平式颗粒托盘组,中国,ZL202020065774.3.
6.张洁, 杨博, 薛晓敏, 黄宁, 一种新型集沙集雪仪, 中国,ZL202020214494.4.
7.张洁, 宋彦宏, 黄宁, 葛正虎, 岳鹏, 杨博,一种高空布置传感器的自动升降和固定系统, 中国,ZL202022988116.4.
8.张洁, 赵煜, 李星, 石利, 葛正虎, & 武建军等. 一种新型的独立式实验用高空粉尘扩散机. 中国, ZL202022475175.1.
9.张洁, 宋彦宏, 黄宁, 蒋红, 一种型面夹紧装置,中国, ZL202120116824.0.
10.张洁, 宋彦宏, 黄宁, 陈冠言, 一种分离的野外塔装式温湿度探头快速夹紧装置, 中国, ZL202023005922.1.
11.黄宁,辛国伟,张洁,顿洪超,一种基于挡风墙的二次防积沙设施,中国, ZL202020389589.X.
12.Huang, Ning; Xin, Guowei; Zhang, Jie and Dun, Hongchao , Facility for Preventing Sand from Depositing on Railway Track Based on Windbreak Wall, Australian Patents, 2020102367.
13.张洁, 刘耘溥, 陈头, 孙海涛, 肖雁泽,李亦斐,黄宁,车载移动式城市空气净化装置,中国,ZL201922067547.4.
14.张洁, 朱升贺, 马磊, 刘玉胜, 滕震礁, 徐彬, 黄宁,一种便携式地表沙尘释放观测仪,2018.02.09,中国,ZL201610299858.1.
15.马磊;张洁;黄宁;朱升贺;滕震礁,一种用于风洞实验的蠕移集沙仪,2017.09.22,中国,ZL201720214845.X.
16.张洁, 徐彬,黄宁,邵亚平,一种长期分时段干、湿降尘采集分析仪,2018.06.15,中国,ZL201610197759.2.
17.陈有兴, 黄宁, 张洁, 何畏,徐彬,一种可控速度角度的自然沙粒发射装置,中国,ZL201620343647.9.
18.张洁,马磊,朱升贺,刘玉胜,滕震礁,徐彬,黄宁,可移动多功能动模型列车试验平台,2019.06.11,中国,ZL201610305462.3.
19.张洁, 黄宁,孙文海,风洞粉尘供应装置, 2012.10.25,中国,ZL 2012 2 0550834.6.