姓名：劉日成
出生年月：1986.03
學(xué)位：博士
職稱(chēng)：研究員/博導/碩導
研究領(lǐng)域：深部復雜裂隙巖體非線(xiàn)性滲流機理，巖石力學(xué)，流體力學(xué)
個(gè)人簡(jiǎn)介
劉日成，男，1986年生，山東煙臺人，博士，研究員，博士生導師，中國礦業(yè)大學(xué)“優(yōu)秀青年學(xué)者”。主要從事深部裂隙巖體分形特征、剪切-非線(xiàn)性滲流機理與深部地下能源開(kāi)采等方面的研究工作。入選江蘇省333高層次人才、江蘇省優(yōu)青、日本學(xué)術(shù)振興會(huì )JSPS Fellow和中國科協(xié)青年人才托舉工程；獲山東省技術(shù)發(fā)明一等獎、中國發(fā)明協(xié)會(huì )發(fā)明創(chuàng )業(yè)成果獎一等獎（R1）、中國巖石力學(xué)與工程學(xué)會(huì )青年科技獎金獎（現改名為“錢(qián)七虎獎”）和科技進(jìn)步一等獎、日本巖石力學(xué)學(xué)會(huì )優(yōu)秀博士學(xué)位論文獎及優(yōu)秀期刊論文獎、COGE期刊Scott Sloan最佳論文獎；主持國家自然科學(xué)基金面上項目與青年基金、國家重點(diǎn)研發(fā)計劃子課題、博士后國際交流計劃派出等項目16項，參與中日櫻花計劃2項、中日韓亞洲校園計劃1項、中俄“一帶一路”創(chuàng )新合作國際交流項目1項、中美政府間國際科技創(chuàng )新合作重點(diǎn)專(zhuān)項1項；在IJRMMS、RMRE、TUST等國際權威期刊上，以第一/通訊作者發(fā)表SCI論文55篇，影響因子總和為256，其中8篇入選ESI高被引論文，以第一/通訊作者在《巖石力學(xué)與工程學(xué)報》、《巖土力學(xué)》等期刊發(fā)表EI論文10篇，研究成果已被引2772次，h指數為31，i10指數為57，單篇最高被引204次；以第一發(fā)明人授權發(fā)明專(zhuān)利12項（國際2項、國內10項）、軟件著(zhù)作權4件、出版英文專(zhuān)著(zhù)1部；擔任SCI期刊《巖石力學(xué)與工程學(xué)報（英文）》編委、《深地科學(xué)（英文）》和《應用力學(xué)學(xué)報》青年編委，兼任中國巖石力學(xué)與工程學(xué)會(huì )日本分會(huì )秘書(shū)長(cháng)；受邀在2014年歐洲巖石力學(xué)大會(huì )、2016年和2017年日本巖石力學(xué)學(xué)會(huì )年度大會(huì )、第8、9、10屆亞洲巖石力學(xué)大會(huì )、China Rock 2018、2019、2021等國內外學(xué)術(shù)會(huì )議作特邀或專(zhuān)題報告20余次，擔任分會(huì )場(chǎng)主席1次。
教育經(jīng)歷
2013/04-2016/03，長(cháng)崎大學(xué)，巖土工程系，博士
2011/04-2013/03，長(cháng)崎大學(xué)，巖土工程系，碩士
2006/09-2010/06，山東大學(xué)，城市地下空間工程系，學(xué)士
科研、學(xué)術(shù)與訪(fǎng)學(xué)工作經(jīng)歷
1. 2020/01-至今，中國礦業(yè)大學(xué)，深部巖土力學(xué)與地下工程國家重點(diǎn)實(shí)驗室，研究員
2. 2017/01-2019/12，中國礦業(yè)大學(xué)，深部巖土力學(xué)與地下工程國家重點(diǎn)實(shí)驗室，副研究員
3. 2017/11-2019/10，日本長(cháng)崎大學(xué)，工學(xué)研究科，訪(fǎng)問(wèn)學(xué)者
4. 2017/01-2017/06，日本長(cháng)崎大學(xué)，工學(xué)研究科，訪(fǎng)問(wèn)學(xué)者
5. 2016/08-2016/12，中國礦業(yè)大學(xué)，深部巖土力學(xué)與地下工程國家重點(diǎn)實(shí)驗室，助理研究員
主持或參加科研項目（課題）及人才計劃項目情況
1.國家自然科學(xué)基金面上項目，51979272，深部巖體三維裂隙網(wǎng)絡(luò )高溫-應力-滲流作用機理研究，2020.01-2023.12，60萬(wàn)元，在研，主持。
2.中華人民共和國科技部,國家重點(diǎn)研發(fā)計劃項目, 2020YFA0711800,頁(yè)巖儲層甲烷原位燃爆壓裂理論與技術(shù), 2020-12至2025-11, 2779萬(wàn)元,在研,子題主持。
3.中華人民共和國科技部，重點(diǎn)研發(fā)計劃（政府間國際科技創(chuàng )新合作），2022YFE0128300，干熱巖水力壓裂復合擾動(dòng)誘發(fā)地震機理及監測方法，2023-01至2025-12,199.76萬(wàn)元,在研,子題主持。
4.中國工程院，戰略研究與咨詢(xún)項目，2022-XZ-51，新時(shí)代城市地下空間發(fā)展戰略研究，2022.10-2023.9，150萬(wàn)，在研，子題主持
5.江蘇省科學(xué)技術(shù)廳,優(yōu)秀青年基金項目, BK20211584,增強型地熱系統水力剪切儲層增透機理及其對采收率的影響規律, 2021-07至2024-06, 50萬(wàn)元,在研,主持
6.江蘇省科學(xué)技術(shù)廳，江蘇省科技計劃“一帶一路”創(chuàng )新合作項目（中俄），廢棄礦井再利用圍巖穩定及防滲控制技術(shù)的聯(lián)合研發(fā)，2020.6-2022.8，90萬(wàn)，結題，子題主持
7.山東能源集團有限公司，9000B2022000200，山東省深層高溫地熱資源形成機制、分布規律研究及地熱資源調查評價(jià)，2022-07至2023-12，1644萬(wàn)元，在研，子題主持
8.國家自然科學(xué)基金委員會(huì ),青年科學(xué)基金項目, 51709260,基于分形理論的三維巖體裂隙網(wǎng)絡(luò )非線(xiàn)性滲流機理研究, 2018-01-01至2020-12-31, 25萬(wàn)元,結題,主持。
9.中國礦業(yè)大學(xué),重大項目培育專(zhuān)項, 2021ZDPYYQ002,增強型地熱系統水力剪切儲層增透機理及其 對采收率的影響機制, 2021-01至2023-12, 40萬(wàn)元,在研,主持。
10.西安理工大學(xué),國家重點(diǎn)實(shí)驗室開(kāi)放基金, 2020KFKT-13,基于CT掃描和3D打印的巖體三維裂隙網(wǎng)絡(luò )剪切機理及非線(xiàn)性水力特征, 2021-01至2022-12, 7萬(wàn)元,結題,主持。
11.中國礦業(yè)大學(xué)深部巖土力學(xué)與地下工程國家重點(diǎn)實(shí)驗室,自主課題學(xué)科前沿專(zhuān)項, Z18011,基于分形重構的深部裂隙巖體滲透特性及氣態(tài)能源開(kāi)采研究, 2018-10至2020-09, 20萬(wàn)元,結題,主持。
12.江蘇省自然科學(xué)基金青年項目，BK20170276，深部巖體裂隙網(wǎng)絡(luò )分形特性與滲流特性研究，2017.07-2020.06，20萬(wàn)元，結題，主持。
13.中國博士后科學(xué)基金會(huì ),博士后國際交流計劃派出項目, PC2018094,深部地下工程巖體的流-固-熱-化多場(chǎng)耦合作用機理研究, 2018-07至2020-06, 30萬(wàn)元,結題,主持。
14.中國礦業(yè)大學(xué),學(xué)科前沿研究專(zhuān)項, 2017XKQY048,裂隙巖體分形與非線(xiàn)性滲流特性研究, 2017-01至2019-12, 20萬(wàn)元,結題,主持。
15.中國博士后基金面上一等資助，2017M610360，三維巖體裂隙網(wǎng)絡(luò )滲透系數預測模型研究，2017.04-2020.03，8萬(wàn)元，結題，主持。
16.中央高?；究蒲袠I(yè)務(wù)專(zhuān)項學(xué)科前沿項目，2017XKQY048，裂隙巖體分形與非線(xiàn)性滲流特性研究，2017.01-2019.12，20萬(wàn)元，結題，主持。
17.日本學(xué)術(shù)振興會(huì )（JSPS）特別研究員研究獎勵費，17F17382，巖盤(pán)內水理物質(zhì)移行機構の解明に基づく放射性廃棄物地層貯留安全性の評価，2017.11.01-2019.10.31，220萬(wàn)日元，結題，負責人。（國際合作項目，國內方面負責人）
18.中央高?；究蒲袠I(yè)務(wù)專(zhuān)項學(xué)科前沿項目，2018XKQYMS07，爆破荷載作用下深部硐室圍巖損傷演化與動(dòng)態(tài)失穩機理，2018.01-2020.12，20萬(wàn)元，結題，子題主持。
19.浙江省山體地質(zhì)災害防治協(xié)同中心開(kāi)放基金項目，PCMGH-2016-Z-01，基于3D打印技術(shù)的三維巖體裂隙網(wǎng)絡(luò )非線(xiàn)性滲流機理研究，2016/11-2018/10,5萬(wàn)元，結題，主持。
20.中國礦業(yè)大學(xué)第九批青年教師啟航計劃項目,深部裂隙巖體滲流機理研究，2016/09-2018/08，3萬(wàn)元，結題，主持。
21.入選日本學(xué)術(shù)振興會(huì )“外國人特別研究員”（JSPS），2017年11月。
22.入選中國科協(xié)第三屆“青年人才托舉工程”，2018年1月。
23.入選中國博士后“國際交流計劃派出項目”，2018年5月。
24.入選中國礦業(yè)大學(xué)“優(yōu)秀青年學(xué)者”，2021年12月。
25.入選江蘇省“333高層次人才培養工程”（第三層次），2022年01月。
代表性研究成果和學(xué)術(shù)獎勵情況
一、代表性論文
2023年度
1.S. Liu, S. Li*,R. Liu*, L. Yu, Y. Wang. (2023): Experimental study on evolutions of normal stiffness of fractured granites after different temperature treatments.Journal of Central South University. (SCI檢索) (accept)
2.Z. Liu, S. Li,R. Liu*, C. Zheng. (2023): Nonlinear flow properties of Newtonian fluids through rough crossed fractures. Computer Modeling in Engineering and Sciences, 2023, 136(2): 1427-1440.(SCI檢索)
3.L. Liu, Z. Li, J. Wu, L. Yu,S. Li*,R. Liu*. (2023): Effect of chemical corrosion on propagation of complex fracture networks under different hydraulic pressures in enhanced geothermal systems. Geomechanics and Geophysics for Geo-Energy and Geo-Resources, 2023, 9, 16. (SCI檢索)
4.季浩奇，劉日成*，蔚立元，李樹(shù)忱，王曉琳.(2023):卸載速率對卸載誘發(fā)頁(yè)巖滑移行為影響的試驗研究。巖石力學(xué)與工程學(xué)報，已錄用。
5.劉尚，劉日成*，李樹(shù)忱，蔚立元，胡明慧.(2023):化學(xué)腐蝕下節理花崗巖法向剛度演變規律試驗研究。巖土力學(xué)，已錄用。
6.C.Wang,R. Liu, Y. Jiang, G. Wang, H. Luan. (2023): Effect of shear-induced contact area and aperture variations on nonlinear flow behavior in fractal rock fractures. Journal of Rock Mechanics and Geotechnical Engineering, 2023, 15(2): 309-322, (SCI檢索)
7.蔚立元,楊瀚清,王曉琳,劉日成,王鎣森.(2023):循環(huán)剪切作用下三維粗糙裂隙非線(xiàn)性滲流特性數值模擬研究。巖土力學(xué)，已錄用。
2022年度
1.R. Liu,Y. Wang, B. Li, H. Jing, S. Li, H. Yang. (2022): Linear and nonlinear fluid flow responses of connected fractures subject to shearing under constant normal load and constant normal stiffness boundary conditions. Computers and Geotechnics, 2022, 141, 104517.(SCI檢索)
2.M. He,R. Liu*, Y. Xue, X. Feng, F. Dang. (2022): Modeling of Navier-Stokes flow through sheared rough-walled granite fractures split after thermal treatment. Geomechanics and Geophysics for Geo-Energy and Geo-Resources, 8, 96.(SCI檢索)
3.Z. Li,R. Liu*, S. Li, H. Jing, X. Li, L. Yu. (2022): Estimates of strength and cracking behaviors of pre-flawed granite specimens treated by chemical corrosion under triaxial compression tests. Frontiers of Earth Science, 16(2): 411-434.(SCI檢索)
4.M. He, L. Yu,R. Liu*, Y. Jiang, Z. Li, X. Wang. (2022): Experimental investigation on mechanical behaviors of granites after high temperature exposure. Journal of Central South University, 29:1332-1344. (SCI檢索)
5.Y. Wang,R. Liu*, H. Ji, S. Li*, L. Yu, X. Feng. (2022): Correlating mechanical properties to fractal dimensions of shales under uniaxial compression tests. Environmental Earth Sciences, 82, 2.(SCI檢索)
6.L. Yu, J. Zhang,R. Liu, S. Li, D. Liu, X. Wang. (2022): Estimation of the representative elementary volume of three-dimensional fracture networks based on permeability and trace map analysis: A case study. Engineering Geology, 309, 106848. (SCI檢索)
7.J. Zhang,R. Liu, L. Yu, S. Li, X. Wang, D. Liu. (2022): An equivalent pipe network modeling approach for characterizing fluid flow through three-dimensional fracture networks: Verification and applications. Water, 14, 1582. (SCI檢索)
8.D. Wu, L. Yu, M. Ju, S. Li,R. Liu, H. Su, L. Zhou. (2022): Study on the mode Ⅰ fracture properties of granites after heating and water-cooling treatments under different impact loadings. Rock Mechanics and Rock Engineering, 55: 4271-4290. (SCI檢索)
9.Z. Liu, S. Li, X. Feng,R. Liu. (2022): Numerical study on shear-induced nonlinear hydraulic properties of fluid flow through fractures: The role of initial normal stress. Geotechnique Letters, 12: 209-216. (SCI檢索)
2021年度
1.R. Liu, H. Jing, X. Li, Q. Yin, Z. Xu, M. He. (2021): An experimental study on fractal pore size distribution and hydro-mechanical properties of granites after high temperature treatment. Fractals,29(4), 2150083. (SCI檢索)
2.劉日成，尹乾，楊瀚清，靖洪文，蔣宇靜，蔚立元.(2021):恒定法向剛度邊界條件下三維粗糙節理面循環(huán)剪切力學(xué)特性。巖石力學(xué)與工程學(xué)報40（6）：1092-1109。(EI檢索)
3.N. Huang,R. Liu*, Y. Jiang, Y. Cheng. (2021): Development and application of three-dimensional discrete fracture network modeling approach for fluid flow in fractured rock masses. Journal of Natural Gas Science and Engineering, 91, 103957. (SCI檢索)
4.B. Li, J. Wang,R. Liu*, Y. Jiang. (2021): Nonlinear fluid flow through three-dimensional rough fracture networks: Insights from 3D-printing, CT-scanning, and high-resolution numerical simulations. Journal of Rock Mechanics and Geotechnical Engineering, 13: 1020-1032. (SCI檢索)
5.B. Li, R. Bao, Y. Wang,R. Liu*, C. Zhao. (2020): Permeability evolution of two-dimensional fracture networks during shear under constant normal stiffness boundary conditions.Rock Mechanics and Rock Engineering,54(1): 409-428. (SCI檢索)
6.Q. Zhang, X. Wang, B. Jiang,R. Liu*, G. Li. (2021): A finite strain solution for strain-softening rock mass around circular roadways. Tunnelling and Underground Space Technology, 111: 103873. (SCI檢索)
7.X. Wang, T. Iura, Y. Jiang, Z. Wang,R. Liu. (2021): Deformation and mechanical characteristics of tunneling in squeezing ground: a case study of the west section of the Tawarazaka Tunnel in Japan. Tunnelling and Underground Space Technology,109: 103697. (SCI檢索)
8.N. Huang, G. Han,R. Liu, Y. Jiang. (2021): Mechanical behaviors of artificial samples containing multiple parallel joints during shearing under constant normal stiffness conditions. Geotechnique Letters, 11(2): 133-139. (SCI檢索)
9.H. Yang, X. Wu, H. Jing, L. Yu,R. Liu. (2021): Physical and mechanical behaviors of red sandstones and marbles after high-temperature treatment. Lithosphere,2021, 8062826.
10.李博，汪佳飛，劉日成*，伍法權.(2021):巖石裂隙壓剪變形破壞與非線(xiàn)性滲流特性。工程科學(xué)與技術(shù)，53（6）：103-112。
11.H. Yang, X. Wu, H. Jing, L. Yu,R. Liu. (2021): Physical and mechanical behaviors of red sandstones and marbles after high-temperature treatment. Lithosphere,2021, 8062826.
12.W. Xu,X. Li, Y. Zhang, X. Wang,R. Liu, Z. He, J. Fan. (2021): Aperture measurements and seepage properties of typical single natural fractures. Bulletin of Engineering Geology and the Environment, 80: 8043–8058. (SCI)
13.W. Xu, Y. Zhang, X. Li, X. Wang,R. Liu, P. Zhao, Y. Zhang, J. Dai. Comprehensive identification of statistical homogeneity of fractured rock masses for a candidate HLW repository site, China. Engineering Geology, 293, 106279. (SCI)
14.Z. Dou, S. Tang, X. Zhang,R. Liu, C. Zhuang, J. Wang, Z. Zhou.(2021): Influence of shear displacement on fluid flow and solute transport in a 3D rough fracture. Lithosphere, 2021, 1569736.
15.張悅，李曉昭，許文濤，章楊松，余興建，劉日成.(2021):改進(jìn)Miller法及其在裂隙巖體統計均質(zhì)區劃分的應用。巖石力學(xué)與工程學(xué)報，40（3）：533-544。
16.武東陽(yáng)，蔚立元，蘇海健，吳疆宇，劉日成，周健.(2021):單軸壓縮下加錨裂隙類(lèi)巖石試塊裂紋擴展試驗及PFC3D模擬。巖土力學(xué)，42（6）：1681-1692。
17.黃娜，蔣宇靜，程遠方，劉日成.(2021):基于3D打印技術(shù)的復雜三維粗糙裂隙網(wǎng)絡(luò )滲流特性試驗及數值模擬研究。巖土力學(xué)，42（6）：1659-1668。
2020年度
1.R. Liu, N. Huang, Y. Jiang, H. Jing, L. Yu. (2020): A numerical study of shear-induced evolutions of geometric and hydraulic properties of self-affine rough-walled rock fractures. International Journal of Rock Mechanics and Mining Sciences, 127: 104211. (SCI檢索)
2.R. Liu, C. Wang, B. Li, Y. Jiang, H. Jing. (2020): Modeling linear and nonlinear fluid flow through sheared rough-walled joints taking into account boundary stiffness. Computers and Geotechnics, 120: 103452. (SCI檢索)
3.R. Liu,N. Huang, Y. Jiang, G. Han, H. Jing. (2020): Effect of shear direction change on shear-flow-transport processes in single rough-walled rock fractures. Transport in Porous Media,133(3): 373-395. (SCI檢索)
4.R. Liu,M. He, N. Huang, Y. Jiang, L. Yu. (2020): Three-dimensional double-rough-walled modeling of fluid flow through self-affine shear fractures. Journal of Rock Mechanics and Geotechnical Engineering,12: 41-49. (SCI檢索)
5.R. Liu, S. Lou, X. Li, G. Han, Y. Jiang. (2020): Anisotropic surface roughness and shear behavior of rough-walled plaster joints under constant normal load and constant normal stiffness conditions. Journal of Rock Mechanics and Geotechnical Engineering, 12:338-352. (SCI檢索)
6.R. Liu, L. Yu, Y. Gao, M. He, Y. Jiang. (2020): Analytical solutions for permeability of a three-dimensional fractal-like tree network model with fractures having variable widths. Fractals, 28(1): 2050013. (SCI檢索)
7.R. Liu, G. Han, Y. Jiang, L. Yu, M. He. (2020): Shear behavior of multi-joint specimens: role of surface roughness and spacing of joints, Geotechnique Letters 10(2): 113-118. (SCI檢索)
8.N. Huang,R. Liu*, Y. Jiang. (2020): Evaluating the effect of aperture variation on the hydraulic properties of the three-dimensional fractal-like tree networks model. Fractals, 28(6): 2050112. (SCI檢索)
9.Q. Zhang, X. Quan, H. Wang, B. Jiang,R. Liu*. (2020): A numerical solution of a circular tunnel in a confining pressure-dependent strain-softening rock mass. Computers andGeotechnics, 121, 103473. (SCI檢索)
10.Q. Zhang, C. Shao, H. Wang, B. Jiang, Y. Jiang,R. Liu*. (2020): A fully coupled hydraulic-mechanical solution of a circular tunnel in strain-softening rock masses. Tunnelling and Underground Space Technology, 99, 103375. (SCI檢索)
11.J. Zhang,R. Liu, L. Yu, H. Jing,Q. Yin. (2020): Investigations on representative elementary volume and directional permeability of fractal-based fracture networks using polygon sub-models. Fractals,28(5): 2050085. (SCI檢索)
12.YuL, Zhang Z, Wu J,R. Liu, Qin H,FanP. (2020): Experimental study on the dynamic fracture mechanical properties of limestone after chemical corrosion. Theoretical and Applied Fracture Mechanics, 2020, 108: 102620. (SCI檢索)
13.Q. Yin, H. Jing,R. Liu, H. Su, L. Yu, G. Han. (2020): Pore characteristics and nonlinear flow behaviors of granite exposed to high temperature. Bulletin of Engineering Geology and the Environment, 79(3): 1239-1257. (SCI檢索)
14.G. Han, H. Jing, Y. Jiang,R. Liu, J Wu. (2020): Effect of cyclic loading on the shear behaviours of both unfilled and infilled rough rock joints under constant stiffness conditions. Rock Mechanics and Rock Engineering, 53: 31-57. (SCI檢索)
15.C. Wang, Y. Jiang,R. Liu, C. Wang, Z. Zhang, S. Sugimoto. (2020): Experimental study of the nonlinear flow characteristics of fluid in 3D rough-walled fractures during shear process. Rock Mechanics and Rock Engineering, 53(6): 2581-2604. (SCI檢索)
16.Q. Zhang, W. He, H. Wang,R. Liu, M. Lu, B. Jiang. (2020): Elasto-plastic solutions for expanding cavities in strain-hardening and/or softening soils. Tunnelling and Underground Space Technology, 107: 103660. (SCI檢索)
17.X. Wang, Y. Jiang,R. Liu, B. Li, Z. Wang. (2019): A numerical study of equivalent permeability of 2-D fractal rock fracture networks. Fractals, 28(1): 2050014. (SCI檢索)
18.Y. Gao,R. Liu, H. Jing, W. Chen, Q. Yin. (2019): Hydraulic properties of single fractures grouted by different types of carbon nanomaterial-based cement composites. Bulletin of Engineering Geology and the Environment, 79(5): 2411-2421. (SCI檢索)
19.Q. Yin, X. Li, L. Yu, M. He,R. Liu. (2020): Solute Removal Analysis of a Large-scale Fracture Plane Considering Different Flow Paths and Different Hydraulic Head Differences.CMES-Computer Modeling in Engineering & Sciences, 124(1), 345–373. (SCI檢索)
20.尹乾，靖洪文，孟波，劉日成，吳應杰.恒定法向剛度條件下三維粗糙裂隙面剪切力學(xué)特性，巖石力學(xué)與工程學(xué)報，2020，39(11)：2213-2225.(EI檢索)
2019年度
1.R. Liu, T. Zhu, Y. Jiang, B. Li, L. Yu, Y. Du, Y. Wang. (2019): A predictive model correlating permeability to two-dimensional fracture network parameters. Bulletin of Engineering Geology and the Environment, 78(3): 1589-1605. (SCI檢索)
2.R. Liu, S. Lou, Y. Jiang. (2019): Recent advances in fluid flow in fractured porous media. Processes, 7(5), 255. (SCI檢索)
3.N. Huang,R. Liu*, Y. Jiang, Y. Cheng, B. Li. (2019): Shear-flow coupling characteristics of a three-dimensional discrete fracture network-fault model considering stress-induced aperture variations. Journal of Hydrology, 571: 416-424. (SCI檢索)
4.B. Li, Y. Li, Z. Zhao,R. Liu*. (2019): A mechanical-hydraulic-solute transport model for rough-walled rock fractures subjected to shear under constant normal stiffness conditions. Journal of Hydrology, 579: 124153. (SCI檢索)
5.T. Meng,R. Liu*, X. Meng, D.Zhang, Y Hu. (2019): Evolution of the permeability and pore structure of transversely isotropic calcareous sediments subjected to triaxial pressure and high temperature. Engineering Geology, 253: 27-35. (SCI檢索)
6.B. Li,R. Liu*, Y. Jiang. (2019): An experimental method to visualize shear-induced channelization of fluid flow in a rough-walled fracture. Hydrogeology Journal, 27(8): 3097-3106. (SCI檢索)
7.Q. Yin, H. Jing, G. Ma, H. Su,R. Liu*. (2019): Laboratory investigation of hydraulic properties of deformable rock samples subjected to different loading paths. Hydrogeology Journal, 27(7): 2617-2635. (SCI檢索)
8.Q. Yin,R. Liu, H. Jing, H. Su, L. Yu, L.He. (2019): Experimental study of nonlinear flow behaviors through fractured rock samples after high temperature exposure. Rock Mechanics and Rock Engineering, 52(9): 2963-2983. (SCI檢索)
9.N. Huang, Y. Jiang,R. Liu, B. Li, S. Sugimoto. (2019): A novel three-dimensional discrete fracture network model for investigating the role of aperture heterogeneity on fluid flow through fractured rock masses. International Journal of Rock Mechanics and Mining sciences, 116: 25-37. (SCI檢索)
10.N. Huang, Y. Jiang,R. Liu, B. Li. (2019): Experimental and numerical studies of the hydraulic properties of three-dimensional fracture networks with spatially distributed apertures. Rock Mechanics and Rock Engineering, 52: 4731-4746. (SCI檢索)
11.Q. Zhang, C. Peng,R. Liu, B. Jiang, M. Lu. (2019): Analytical solutions for the mechanical behaviors of a hard roof subjected to any form of front abutment pressures. Tunnelling and Underground Space Technology, 85: 128-139. (SCI檢索)
12.G. Han, H. Jing,R. Liu, H. Su, J. Wu, J. Wei. (2019): Experimental investigation on the mechanical behavior of red sandstone under the coupled effects of temperature and acidic etching. Arabian Journal of Geosciences, 12(18): 586. (SCI檢索)
13.G. Han, H. Jing, H. Su,R. Liu, Q. Yin, J. Wu. (2019): Effects of thermal shock due to rapid cooling on the mechanical properties of sandstone. Environmental Earth Science, 78: 146. (SCI檢索)
14.B. Li, Y. Mo, L. Zou,R. Liu, V. Cvetkovic. (2019): Influence of surface roughness on fluid flow and solute transport through 3D crossed rock fractures. Journal of Hydrology, No.124284. (SCI檢索)
2018年度
1.R. Liu, B. Li, L. Yu, Y. Jiang, H. Jing. (2018): A discrete-fracture-network fault model revealing permeability and aperture evolutions of a fault after earthquakes. International Journal of Rock Mechanics and Mining Sciences, 107: 19-24. (SCI檢索)
2.R. Liu, B. Li, Y. Jiang, L. Yu. (2018): A numerical approach for assessing effects of shear on equivalent permeability and nonlinear flow characteristics of 2-D fracture networks. Advances in Water Resources, 111: 289-300. (SCI檢索)
3.R. Liu, B. Li, H. Jing, W. Wei. (2018): Analytical solutions for water-gas flow through 3D rock fracture networks subjected to triaxial stresses. Fractals, 26(3): 1850053. (SCI檢索)
4.R. Liu, B. Li, Y. Jiang, H. Jing, L. Yu. (2018): Relationship between equivalent permeability and fractal dimension of dual-porosity media subjected to fluid-rock reaction under triaxial stresses. Fractals, 26(5): 1850072. (SCI檢索)
5.R. Liu, N. Huang, Y. Jiang, H. Jing, B. Li, Y. Xia. (2018): Effect of shear displacement on the directivity of permeability in 3D self-affine fractal fractures. Geofluids, 1723019. (SCI檢索)
6.R. Liu, T. Zhu, Y. Jiang, B. Li, L. Yu, Y. Du, Y. Wang. (2019): A predictive model correlating permeability to two-dimensional fracture network parameters. Bulletin of Engineering Geology and the Environment, 78: 1589–1605. (SCI檢索)
7.R. Liu, Y. Jiang, H. Jing, L. Yu. (2018): Nonlinear flow characteristics of a system of two intersecting fractures with different apertures. Processes, 6(7): 94. (SCI檢索)
8.R. Liu, Y. Jiang. (2018): Special Issue: Fluid Flow in Fractured Porous Media. Processes, 6(10): 178. (SCI檢索)
9.N. Huang,R. Liu*, Y. Jiang, B. Li, L. Yu. (2018): Effects of fracture surface roughness and shear displacement on geometrical and hydraulic properties of three-dimensional crossed rock fracture models. Advances in Water Resources, 113: 30-41. (SCI檢索)
10.L. Yu, H. Su,R. Liu*, H. Jing, G. Li, M. Li. (2018): Effect of thermal treatment on the dynamic mechanical behaviors of limestone in quasi-vacuum and air-filled environments. Latin American Journal of Solids and Structures, 15(3): e25. (SCI檢索)
11.Q. Yin, H. Jing, G. Ma, H. Su,R. Liu*. (2018): Investigating the roles of included angle and loading condition on the critical hydraulic gradient of real rock fracture networks. Rock Mechanics and Rock Engineering, 51(10), 3167-3177. (SCI檢索)
12.N. Huang, Y. Jiang,R. Liu. (2018): Size effect on the permeability and shear induced flow anisotropy of fractal rock fractures. Fractals, 26(2): 1840001. (SCI檢索)
13.Q. Yin, H. Jing,R. Liu, G. Ma, L Yu, H Su. (2018): Experimental study on stress-dependent nonlinear flow behavior and normalized transmissivity of real rock fracture networks. Geofluids, 8217921. (SCI檢索)
14.C.Wang, Y. Jiang,R. Liu, C. Wang. (2018): Visualized experimental investigation on the gas-water distribution characteristics in intersecting fractures. Geofluids, 4273450. (SCI檢索)
15.J. Zhang, L. Yu, H. Jing,R. Liu. (2018): Estimating the effect of fractal dimension on representative elementary volume of randomly distributed rock fracture networks. Geofluids, 7206074. (SCI檢索)
16.Z. Wang, W. Li, L. Bi, L. Qiao,R. Liu, J. Liu. (2018): Estimation of the REV size and equivalent permeability coefficient of fractured rock masses with an emphasis on comparing the radial and unidirectional flow configurations. Rock Mechanics and Rock Engineering, 51(5): 1457-1471. (SCI檢索)
17.G. Han, H. Jing, Y. Jiang,R. Liu, H. Su, J. Wu. (2018): The effect of joint dip angle on the mechanical behavior of infilled jointed rock masses under uniaxial and biaxial compressions. Processes, 6: 49. (SCI檢索)
2017年度
1.R. Liu, L. Yu, Y. Jiang. (2017): Quantitative estimates of normalized transmissivity and the onset of nonlinear fluid flow through rough rock fractures. Rock Mechanics and Rock Engineering,50: 1063-1071.(SCI檢索)
2.R. Liu, L. Yu, Y. Jiang, Y. Wang, B. Li. (2017):Recent developments on relationships between the equivalent permeability and fractal dimension of two-dimensional rock fracture networks. Journal of Natural Gas Science and Engineering, 45:771-785. (SCI檢索)
3.R. Liu, H. Jing, L. He, T. Zhu, L. Yu, H. Su. (2017): An experimental study of the effect of fillings on hydraulic properties of single fractures. Environmental Earth Sciences, 76: 684.(SCI檢索)
4.N. Huang,R. Liu*, Y.Jiang. (2017): Numerical study of the geometrical and hydraulic characteristics of 3D self-affine rough fractures during shear. Journal of Natural Gas Science and Engineering, 45:127-142. (SCI檢索)
5.L.Yu,R. Liu*, Y. Jiang. (2017): A review of critical conditions for the onset of nonlinear fluid flow in rock fractures. Geofluids, 2176932. (SCI檢索)
6.L. Yu, H. Su,R. Liu*, H. Jing, Q. Meng, N. Luo. (2017): Experimental study of the influence of loading rate on tensile mechanical behavior of sandstone damaged by blasting. Arabian Journal of Geosciences, 10: 432. (SCI檢索)
7.Q. Yin, G. Ma, H. Jing, H Wang, H. Su, Y. Wang,R. Liu*. (2017): Hydraulic properties of 3D rough-walled fractures during shearing: an experimental study. Journal of Hydrology, 555: 169-184. (SCI檢索)
8.L. Yu, J. Zhang,R. Liu, H. Jing, K. Xie. (2017): Semi-empirical solutions for fractal-based hydraulic properties of 3D rock fracture networks. Geotechnique Letters, 7(3): 266-271. (SCI檢索)
9.N. Huang, Y. Jiang,R. Liu, B. Li. (2017): Estimation of permeability of 3-D discrete fracture networks: An alternative possibility based on trace map analysis. Engineering Geology, 226: 12-19. (SCI檢索)
10.N. Huang, Y. Jiang,R. Liu, B. Li. (2017): A predictive model of permeability for fractal-based rough rock fractures during shear. Fractals, 25(5): 1750051. (SCI檢索)
11.J. Cai, W. Wei, X. Hu,R. Liu, J. Wang. (2017): Fractal characterization of dynamic fracture network extension in porous media. Fractals, 25(2): 1750023. (SCI檢索)
12.L. Yu, T. Zhang, H. Su, H. Jing,R. Liu, Q. Zhang. (2017): Influence of heat treatment on dynamic and physical properties of anthracite coal. Geotechnique Letters, 7(3): 253-259. (SCI檢索)
13.杜巖，謝謨文，蔣宇靜，宋紅克，李博，劉日成.(2017):應用激光多普勒測振儀的巖塊體累計損傷評價(jià)試驗研究，工程科學(xué)學(xué)報，39(1): 141-146. (EI檢索)
2016年度
1.R. Liu, B. Li, Y. Jiang. Critical hydraulic gradient for nonlinear flow through rock fracture networks: The roles of aperture, surface roughness, and number of intersections. Advances in Water Resources,2016,88: 53-65. (SCI檢索)
2.R. Liu, Y. Jiang, B. Li, L. Yu. Estimating permeability of porous media based on modified Hagen–Poiseuille flow in tortuous capillaries with variable lengths. Microfluidics and Nanofluidics,2016,20(8): 120. (SCI檢索)
3.R. Liu, L. Yu, Y. Jiang. Fractal analysis of directional permeability of gas shale fracture networks: a numerical study. Journal of Natural Gas Science and Engineering,2016,33: 1330-1341. (SCI檢索)
4.R. Liu, B. Li, Y. Jiang, N. Huang. Review: Mathematical expressions for estimating equivalent permeability of rock fracture networks. Hydrogeology Journal,2016,24: 1623-1649. (SCI檢索)
5.R. Liu, B. Li, Y. Jiang.Afractal model based on a new governing equation of fluid flow in fractures for characterizing hydraulic properties of rock fracture networks. Computers and Geotechnics,2016,75: 57-68. (SCI檢索)
6.R. Liu, Y. Jiang, B.Li. (2016): Effects of intersection and dead-end of fractures on nonlinear flow and particle transport in rock fracture networks. Geosciences Journal, 20: 415-426. (SCI檢索)
7.B. Li,R. Liu*, Y. Jiang. (2016): Influences of hydraulic gradient, surface roughness, intersecting angle, and scale effect on nonlinear flow behavior at single fracture intersections. Journal of Hydrology,2016,538: 440-453. (SCI檢索)
8.B. Li,R. Liu*, Y. Jiang. A multiple fractal model for estimating permeability of dual-porosity media. Journal of Hydrology,2016, 540:659-669. (SCI檢索)
9.N.Huang, Y. Jiang, B. Li,R. Liu. A numerical method for simulating fluid flow through 3-D fracture networks. Journal of Natural Gas Science and Engineering,2016,33: 1271-1281. (SCI檢索)
10.Y. Wang, X. Yin, H. Jiang,R. Liu, H. Su. A novel cloud model for risk analysis of water inrush in karst tunnels. Environmental Earth Sciences,2016,75: 1450. (SCI檢索)
11.N. Huang, Y. Jiang,R. Liu, B. Li. A fast calculation method for estimating the representative elementary volume of three-dimensional fracture network. Special Topics and Reviews in Porous Media,2016,7(2): 99-106. (EI檢索)
12.劉日成，李博，蔣宇靜，蔚立元.三維交叉裂隙滲流特性的實(shí)驗和數值模擬研究.巖石力學(xué)與工程學(xué)報,2016,35(增2):3813-3821.(EI檢索)
13.劉日成,李博,蔣宇靜,蔚立元.等效水力隙寬和水力梯度對巖體裂隙網(wǎng)絡(luò )非線(xiàn)性滲流特性的影響.巖土力學(xué),2016,37(11):3165-3174.(EI檢索)
14.劉日成,蔣宇靜,李博，蔚立元，杜巖.巖體裂隙網(wǎng)絡(luò )非線(xiàn)性滲流特性研究.巖土力學(xué),2016,37(10): 2394-2400.(EI檢索)
15.劉日成,蔣宇靜,李博,王肖珊,徐幫樹(shù),蔚立元.基于逆Broyden秩1擬牛頓迭代法的巖體裂隙網(wǎng)絡(luò )滲流特性研究.巖土力學(xué),2016,37(1): 219-228.(EI檢索)
2015年度
1.R. Liu, Y. Jiang, B. Li, X. Wang. A fractal model for characterizing fluid flow in fractured rock masses based on randomly distributed rock fracture networks.Computers and Geotechnics, 2015,65: 45-55. (SCI檢索)
2.劉日成,蔣宇靜,李樹(shù)忱,李博,王肖珊.交叉裂隙水力學(xué)開(kāi)度的計算及非線(xiàn)性水力特性研究.巖土力學(xué),2015,36(6):1581-1590.(EI檢索)
2014年度
1.劉日成,蔣宇靜,李博,王肖珊,徐幫樹(shù).巖體裂隙網(wǎng)絡(luò )等效滲透系數方向性的數值計算.巖土力學(xué),2014,35(8):2394-2400.(EI檢索)
二、發(fā)明專(zhuān)利
1.劉日成，靖洪文，李樹(shù)忱，蔚立元，馮現大，劉楓，王鎣森.УСТРОЙСТВО И СПОСОБ ПРОВЕДЕНИЯИСПЫТАНИЯ ПРОСАЧИВАНИЯ ПРИ СДВИГЕ ДЛЯСЕТИ ТРЕЩИН，2777701，俄羅斯，2022.8.8. （授權）
2.劉日成，蔚立元，靖洪文，李樹(shù)忱，馮現大，李志聰，劉尚.Device and method for shear and two-phase flow test of fracture network，500448，盧森堡，2022.8.22. （授權）
3.劉日成，黨文剛，李樹(shù)忱，蔚立元，張強，李博，劉尚，胡明慧.恒定法向剛度條件下巖石結構面動(dòng)態(tài)雙向剪切實(shí)驗系統，CN202210136156.7，中國，2022. （授權）
4.劉日成，胡明慧，蔚立元，李樹(shù)忱，張強，李博，賈世平，于峰.巖石結構面多向自由剪切實(shí)驗系統與實(shí)驗方法，CN 202210310585.1，中國，2022. （授權）
5.劉日成，李樹(shù)忱，劉振國，蔚立元，劉尚，劉蘭富，劉楓，王鎣森.一種塑性混凝土地下連續墻錨注一體化結構與施工方法，ZL2021114708241，中國，2022.06.03. （授權）
6.劉日成，蔚立元，李樹(shù)忱，朱欣杰，程舍予，張晶，王曉琳，胡明慧.水力剪切刺激干熱巖儲層增透模擬實(shí)驗系統與實(shí)驗方法，ZL202111470121.9，中國，2022.06.10. （授權）
7.劉日成，朱欣杰，李樹(shù)忱，蔚立元，張強，吳學(xué)震，楊瀚清，韓剛.巖石結構面多向自由剪切-滲流可視化實(shí)驗系統與方法，CN202210310033.0，中國，2022.12.23. （授權）
8.劉日成，尹乾，靖洪文，蔚立元，韓觀(guān)勝，蔣宇靜.一種用于裂隙網(wǎng)絡(luò )剪切滲流試驗裝置及其試驗方法，ZL2020107041559，中國，2021. （授權）
9.劉日成，蔚立元，靖洪文，尹乾，韓觀(guān)勝.一種裂隙網(wǎng)絡(luò )剪切-兩相流試驗裝置及試驗方法，ZL2020107041898，中國，2021. （授權）
10.劉日成，蔚立元，張晶，張站群.一種用于三維裂隙巖樣水-力耦合加載裝置及加載方法，ZL2018104364005，中國，2020. （授權）
11.劉日成，靖洪文，張晶，蔚立元，蘇海健.巖體裂隙網(wǎng)絡(luò )滲流各向異性測試及可視化系統，ZL2017101479642，中國，2020. （授權）
12.劉日成，蔚立元，靖洪文，李光雷，謝凱.巖體裂隙網(wǎng)絡(luò )滲透系數方向性測試及可視化系統，ZL2017101479765，中國，2020. （授權）
13.蔚立元，劉日成，張濤，李衛，鞠明和，陳彥龍，李文杰，于峰.一種隧道支護桿輸送機器人，ZL202210548789.9，中國，2023.02.17. （授權）
14.劉振國，劉日成，刀劍文，李樹(shù)忱，彭宏，蔚立元，鄭長(cháng)洲，陳占江，王玉，李蓉.一種雙層HDER膜片鎖接頭連接裝置及使用方法，ZL202210491004.9，2023. （授權）
15.吳疆宇，尹乾，劉日成，馬丹，蔚立元，姬永生，王逸鳴.用于深地工程圍巖加固的木質(zhì)納米纖維素-納米水泥改性注漿材料及其制備方法，ZL202111491044.5，中國，2023.3.3. （授權）
16.李樹(shù)忱，劉日成，趙世森，童里，王曼靈，彭科峰，陳祎，王新宇.一種丙烯酸樹(shù)脂注漿材料及其制備工藝，ZL202210027057.5，中國，2022.11.11. （授權）
17.李樹(shù)忱，劉日成，萬(wàn)澤恩，陳祎，劉祥坤，王新宇，彭科峰，童里.一種發(fā)泡堵水用有機無(wú)機雜化注漿材料及制備工藝，CN202210027030.6，中國，2022.11.29. （授權）
18.李樹(shù)忱，劉日成，萬(wàn)澤恩，陳祎，劉祥坤，王新宇，彭科峰，童里.一種改性硅酸鹽注漿加固材料及其制備方法與應用，CN202210026813.2，中國，2022. （授權）
19.尹乾，劉日成，靖洪文，劉江峰，蔚立元，江鄭.一種應力作用下深部硐室裂隙圍巖滲透試驗裝置及方法，ZL202011372184.6，中國，2022. （授權）
20.蔚立元，劉日成，李樹(shù)憂(yōu)，蘇海健，張明偉，武東陽(yáng)，韓剛.一種電纜隧道智能巡檢機器人，ZL202210558760.9，中國，2022. （授權）
21.李樹(shù)忱，萬(wàn)澤恩，劉日成，彭科峰，周慧穎，童里，王新宇，陳祎.一種低溫加固用有機無(wú)機雜化注漿材料及其制備方法與應用，CN202210026812.8，中國，2022.11.29. （授權）
22.尹乾，張強，鄧天慈，吳疆宇，劉日成，靖洪文.一種三維粗糙裂隙面卸荷誘發(fā)剪切滑移試驗裝置及方法，ZL 202111084572.9，中國，2022.5.24. （授權）
23.李博，趙志宏，葉鑫娜，沙鵬，劉日成，吳學(xué)震.一種高溫和滲流作用下的測驗巖石用的真三軸試驗系統，ZL201810425000.4，中國，2020.9.4. （授權）
24.李博，夏才初，杜時(shí)貴，陳咭仟，劉日成，陳忠清，鐘振.考慮巖石節理剪切過(guò)程中THMC耦合作用的試驗系統，ZL201610732783.1，中國，2019.4.5. （授權）
25.蔚立元，顧金才，靖洪文，蘇海健，吳興杰，劉日成.一種深長(cháng)隧道突水突泥三維模型試驗裝置及方法，ZL201510874596.2，中國，2017.7.7. （授權）
三、榮譽(yù)獎勵
1.2023年01月，獲COGE Scott Sloan Best Paper Award 2021（排名1）
2.2022年12月，獲徐州市自然科學(xué)優(yōu)秀學(xué)術(shù)論文三等獎（1/6）
3.2022年12月，獲山東省技術(shù)發(fā)明一等獎（11/15）
4.2022年10月，獲中國發(fā)明協(xié)會(huì )發(fā)明創(chuàng )業(yè)成果獎一等獎（1/6）
5.2022年10月，獲中國礦業(yè)大學(xué)第一屆“優(yōu)秀青年教師獎教金”（排名1）
6.2022年01月，入選江蘇省333高層次人才（第三層次）
7.2021年01月，獲中國產(chǎn)學(xué)研合作促進(jìn)會(huì )合作創(chuàng )新成果一等獎（8/10）
8.2020年11月，獲江蘇省科學(xué)技術(shù)三等獎（基礎類(lèi)）（1/7）
9.2019年09月，獲中國巖石力學(xué)與工程學(xué)會(huì )科技進(jìn)步一等獎（13/15）
10.2018年09月，獲中國巖石力學(xué)與工程學(xué)會(huì )“青年科技獎”（金獎）（排名1）
11.2018年05月，入選中國博士后“國際交流計劃派出項目”
12.2018年01月，入選中國科協(xié)第三屆“青年人才托舉工程”人才項目
13.2017年11月，入選日本學(xué)術(shù)振興會(huì )“外國人特別研究員”（JSPS Fellow）
14.2017年06月，獲日本巖石力學(xué)學(xué)會(huì )優(yōu)秀博士學(xué)位論文獎（排名1）
15.2016年06月，獲日本巖石力學(xué)學(xué)會(huì )優(yōu)秀期刊論文獎（排名1）
16.2016年03月，獲日本長(cháng)崎大學(xué)校長(cháng)獎（排名1）
17.2015年07月，獲日本長(cháng)崎大學(xué)特別研究獎學(xué)金
18.2015年04月，獲日本地盤(pán)工學(xué)會(huì )九州支部?jì)?yōu)良學(xué)生獎
19.2014年10月，獲亞洲巖石力學(xué)大會(huì )青年學(xué)者優(yōu)秀論文獎學(xué)金
20.2013年06月，獲日本長(cháng)崎大學(xué)和韓國濟州大學(xué)工學(xué)科學(xué)術(shù)交流會(huì )優(yōu)秀論文主席獎
21.2013年04月，獲國家留學(xué)基金委（CSC）公派留學(xué)獎學(xué)金
22.2012年04月，獲基于日中韓大學(xué)間水環(huán)境技術(shù)者培育的外國留學(xué)生獎學(xué)金
23.2011年04月，獲日本JASSO學(xué)習獎勵費獎學(xué)金