金毅

1998/9~2002/7，焦作工學院，本科 ^[1] 

2002/9~2005/7，中國礦業大學（北京），理學碩士

2007/9~2011/7，北京大學，理學博士

現為河南理工大學資源環境學院副院長，教授，博士生導師 ^[10] 

2016、2017年獲得河南省優秀碩士論文指導老師稱號

2015年“河南省第三屆自然科學學術獎”壹等獎:“Lattice Boltzmann simulation of fluid flow through coal reservoir’s fractal pore structure”

2015年“河南省第三屆自然科學學術獎”壹等獎: “Derivation of permeability-pore relationship for fractal porous reservoirs using series-parallel flow resistance model and lattice Boltzmann method”

2014年獲河南理工大學“校級示範教師稱號” ^[1] 

2013年河南省教育廳科技成果一等獎，排名第4。

2011年“河南省第三屆自然科學學術獎”三等獎: “地質變量變異函數統一套盒方法的原理及驗證”

2011年“河南省第三屆自然科學學術獎”三等獎: “一種穩健變差函數計算方法” ^[4] 

主持國家自然科學青年基金項目：煤巖多孔介質中多相流體動態滲流機理與數值模擬

主持山西省煤層氣聯合基金項目：煤多尺度孔隙結構中煤層氣運移響應機制及生物繁衍模式

主持國家自然科學基金面上項目：煤裂-孔性雙重介質中煤層氣吸附/解吸運移機理的分形研究

主持山西省煤層氣聯合基金項目：西山礦區煤變質作用對儲層物性的影響及煤層氣開採潛能評估

主持河南省高校科技創新人才項目：煤儲層物性精細描述及煤層氣運移控制機理研究 ^[1] 

主持國家自然科學基金面上項目：煤儲層複雜類型組構模式及其煤層氣運移行為控制機理 ^[11] 

主持山西省科技重大專項課題：深部煤層氣勘查開發關鍵技術研究 ^[9] 

主持河南省高校科技創新團隊項目：煤系氣儲層物性定量表徵與評價 ^[2] 

金毅*、潘懋、姚凌青、馬翀：一種穩健變差函數計算方法. 北京大學學報（自然科學版），45（6）：1033 – 1038，2009

金毅*、潘懋、 馬翀：地質變量變異函數統一套合方法的原理及驗證. 中國礦業大學學報，39（3）：420 – 425，2010

金毅*、平瑞、潘懋、喬金海：區域土體膨脹率空間變異特徵分析與三維模擬. 岩石力學與工程學報，30（S2）：3811 – 3819，2011

金毅*、鄭德順、潘懋、張璐：各向異性礦化特徵的分析與模擬及其在儲量估算中的應用. 地質學報，85（9）：1519 – 1527，2011

金毅*、宋慧波、潘結南、鄭軍領、祝一搏：煤微觀結構三維表徵及其孔-滲時空演化模式數值分析. 岩石力學與工程，32(S1)：2632 – 2641，2013

金毅*、宋慧波、胡斌等：煤儲層分形孔隙結構中流體運移格子玻爾茲曼模擬.中國科學：地球科學，43(12): 1984-1995,2013

金毅*、祝一搏、吳影、鄭軍領、董佳斌、李翔：煤儲層粗糙割理中煤層氣運移機理數值分析. 煤炭學報，39（9）：1826-1834，2014

金毅*、鄭軍領、董佳斌、黃存捍等：自仿射粗糙割理中流體滲流的分形定律. 科學通報，60（21）：2036 – 2047

金毅, 權偉哲, 秦建輝*, 劉仙鶴, 鄭軍領, 宋慧波: 孔隙-孔喉分形多孔介質複雜類型組構模式表徵. 煤炭學報, 2020, 45(05): 1845-1854 ^[12] 

宋慧波, 安紅亮, 劉順喜, 于振鋒, 金毅*, 王保玉: 沁水盆地武鄉南煤層氣賦存主控地質因素及富集區預測. 煤炭學報, 2021, doi: 10.13225/j.cnki.jccs.2020.1911 ^[24] 

金毅, 王俏俏, 董佳斌*, 等. 顆粒填充型分形孔隙結構複雜組構表徵. 岩石力學及工程學報, doi: 10.13722/j.cnki.jrme.2021.1050, 2022 ^[27] 

劉順喜, 樊坤雨, 金毅*, 等. 深部煤儲層應力敏感性特徵及其對產能的影響. 煤田地質與勘探, doi: 10.12363/issn.1001-1986.21.09.0534, 2022 ^[27] 

Jin Yi*、Song Huibo、Hu Bin、Zhu Yibo、Zheng Junling: Lattice Boltzmann simulation of fluid flow through coal reservoir's fractal pore structure. Science China Earth Sciences, 56 (9)：1519-1530, 2013 ^[13] 

Yi Jin*、Jiabin Dong、Xiang Li, et.al. Kinematical measurement of hydraulic tortuosity of fluid flow in porous media. International Journal of Modern Physics C, 26 (2): 1550017, 2015 ^[14] 

Baoyu Wang、Yi Jin*、QING CHEN、et. al. Derivation of permeability-pore relationship for fractal porous reservoirs using series-parallel flow resistance model and lattice Boltzmann method. Fractals，22(3): 1440005, 2014 ^[15] 

Yi Jin*, Yibo Zhu, Xiang Li, Junling Zheng and Jiabin Dong: Scaling Invariant Effects on the Permeability of Fractal Porous Media. Transport in porous media, 109(2) : 433–453, 2015 ^[16] 

Yi Jin*, Jiabin Dong, Xiangyu Zhang, Xiang Li and Ying Wu: Scale and size effects on fluid flow through self-affine rough fractures. International Journal of Heat and Mass Transfer, 105: 443-451, 2017 ^[7] 

Yi Jin*, Jiabin Dong, Xiangyu Zhang, Xiang Li and Ying Wu: A mathematical model of fluid flow in tight porous media based on fractal assumptions.International Journal of Heat and Mass Transfer, 108, Part A: 1078-1088, 2017 ^[8] 

Yi Jin*，Ying Wu，Hui Li，Xianhe Liu and Mengyu Zhao. Definition of fractal topography to essential understanding of scale-invariance. Scientific Reports (Nature), doi: 10.1038/ srep46672, 2017 ^[5] 

Yi Jin*, Xianhe Liu, Huibo Song, Junling Zheng, Jienan Pan. General Fractal Topography: an open mathematical framework to characterize and model mono-scale-invariances. Nonlinear Dynamics, 96: 2413-2436, 2017,https://doi.org/10.1007/s11071-019-04931-9 ^[6] 

Yi Jin*, Junling Zheng, Xianhe Liu, Jienan Pan, Shunxi Liu. Control mechanisms of self-affine, rough cleat networks on flow dynamics in coal reservoir. Energy, 189: 116146, 2019,https://doi.org/10.1016/j.energy.2019.116146 ^[17] 

Yi Jin*, Cheng Wang, Shunxi Liu, Weizhe Quan, Xiaokun Liu: Systematic definition of complexity assembly in fractal porous media. Fractals, 2020 ^[18] 

Junling Zheng, Yi Jin*, Xianhe Liu, Cheng Wang, Xiaokun Liu. Validity of triple-effect model for fluid flow in mismatched, self-affine fractures. Advances in Water Resources, 2020 ^[19] 

Mengyu Zhao, Yi Jin*, Xianhe Liu, Junling Zheng, Shunxi Liu. Characterizing the complexity assembly of pore structure in a coal matrix: principle, methodology, and modeling application. JGR Solid Earth, 2020 ^[20] 

Junling Zheng、Xiaokun Liu、Yi Jin*、Jiabin Dong、Qiaoqiao Wang. Effects of surface geometry on advection-diffusion process in rough fractures. Chemical Engineering Journal, 2021 ^[23] 

Huibo Song, Shasha Nie, Yi Jin*, Xiangyu Zhang, Hongliang An. Characterization of behavioral complexity in marine trace fossils and its paleoenvironmental significance: A case study of Zoophycos. Fractals, 2021 ^[25] 

Yi Jin*, Junling Zheng, Jiabin Dong, Qiaoqiao Wang, Yonghe Liu, Baoyu Wang, Huibo Song. Fractal topography and complexity assembly in multifractals. Fractals, 30: 2250052, 2022 (IF: 3.665) ^[27] 

Junling Zheng, Yi Jin*, Jiabin Dong, et al. Reexamination of the permeability-aperture relationship for rough fractures with mismatched self-affine surfaces. J. Hydrol., 609: 127727, 2022 (IF: 5.722) ^[27] 

Shi, X., J. Pan, Q. Hou, Y. Jin, Z. Wang, Q. Niu, M. Li , Micrometer-scale fractures in coal related to coal rank based on micro-CT scanning and fractal theory, Fuel, 212: 162-172, 2018,https://doi.org/10.1016/j.fuel.2017.09.115 ^[21] 

Niu, Q., J. Pan, Y. Jin, H. Wang, M. Li, Z. Ji, K. Wang, Z. Wang, Fractal study of adsorption-pores in pulverized coals with various metamorphism degrees using N2 adsorption, X-ray scattering and image analysis methods, Journal of Petroleum Science and Engineering, 176, 584-593, 2019,https://doi.org/10.1016/j.petrol.2019.01.107 ^[22] 

Pan, J., Y. Zhao, Q. Hou and Y. Jin: Nanoscale Pores in Coal Related to Coal Rank and Deformation Structures. Transport in porous media, 107(2) : 543 – 554, 2015 ^[1]