Journal Publications

• [1]D Zhang, Q Zhang, Q Chen*, Z Su.Recycling Lead–Zinc Tailings for Cemented Paste Backfill and Stabilisation of Excessive Metal.Minerals, 2019, 9 (11) : 710.
• [2]C Xin, A Fourie, Q Zhang, Q Chen.Utilization of phosphogypsum and phosphate tailings for cemented paste backfill.Journal of environmental management, 2017, 201: 19-27.
• [3]C Qi, X Chen, A Fourie, Q Zhang, Q Chen.Experimental investigation on the strength characteristics of cement paste backfill in a similar stope model and its mechanism.Construction and Building Materials, 2018, 154: 34-43.
• [4]C Xiao, A Fourie, C Qi, Q Zhang, Q Chen.Recycling phosphogypsum and construction demolition waste for cemented paste backfill and its environmental impact.Journal of Cleaner Production, 2018, 186: 418-429.
• [5]C Xiao, Q Zhang, C Qi, Q Chen*, Y He.Lithium slag and fly ash-based binder for cemented fine tailings backfill.Journal of environmental management, 248: 1092.
• [6]Z Huang, Z Su, C Qi, Q Chen*, Q Zhang, Y Liu.Utilisation of water-washing pre-treated phosphogypsum for cemented paste backfill.Minerals, 9 (3) : 175.
• [7]C Qi, C Samuelsson, F Engstr？m, Q Chen*, Q Yang, J Kero, Y Feng.Mechanical activation of granulated copper slag and its influence on hydration heat and compressive.Materials, 2019, 12 (5) : 772.
• [8]C, Fredrik Engstr？m, Hesham Ahmed, Anton Andersson, Jakob Kero, Qiusong Chen*, Qixing Yang, Yan Feng.Characterization and evaluation of the pozzolanic activity of granulated copper slag modified with C.Journal of Cleaner Production, 2019, 232 (1112-1120)
• [9]X Wang, Q Chen*, Q Zhang.Cemented backfilling technology of paste-like based on aeolian sand and tailings.Minerals, 2016, 6 (4) : 132.
• [10]X Wang, Q Chen*, S Li.Superiority of filtered tailings storage facility to conventional tailings impoundment in southern rainy Regions of China.Sustainability, 2016, 8 (11) : 1130.
• [11]Y Gou, X Shi*, Q Chen*, J Zhou, X Chen.CFD simulation of pipeline transport properties of mine tailings three-phase foam slurry backfill.Minerals, 2017, 7 (8) : 149.
• [12]Q Chen*, A Fourie, C Qi.Neural network and particle swarm optimization for predicting the unconfined compressive strength of cemented paste backfill.Construction and Building Materials, 2018, 159: 473-478.
• [13]Q Zhang, Q Chen*, A Fourie, C Qi.A strength prediction model using artificial intelligence for recycling waste tailings as cemented paste backfill.Journal of cleaner production, 2016, 183 (566-578)
• [14]Q Zhang, A Fourie, Q Chen*, C Qi.An intelligent modelling framework for mechanical properties of cemented paste backfill.Minerals Engineering, 2018, 123: 16-27.
• [15]P Liu, Q Chen, A Fourie, C Qi.Application of first-principles theory in ferrite phases of cemented paste backfill.Minerals Engineering, 2019, 133: 47-51.
• [16]Q Chen*, C Qi.Evolutionary Random Forest Algorithms for Predicting the Maximum Failure Depth of Open Stope Hangingwalls.IEEE Access, 6: 72808-72813.
• [17]Y Feng, X Dong, Q Zhang, X Tang, A Fourie, Q Chen, C Qi.Constitutive modelling of cemented paste backfill: A data-mining approach.Construction and Building Materials, 197: 262-270.
• [18]ZM Yaseen, Q Zhang, X Dong, Q Chen*, C Qi.Pressure drops of fresh cemented paste backfills through coupled test loop experiments and machine learning techniques[J].Powder Technology, 2019