| A contribution to understanding the hardening process of cemented pastefill M Benzaazoua, M Fall, T Belem Minerals engineering 17 (2), 141-152, 2004 | 489 | 2004 |
| A contribution to understanding the effects of curing temperature on the mechanical properties of mine cemented tailings backfill M Fall, JC Célestin, M Pokharel, M Touré Engineering Geology 114 (3-4), 397-413, 2010 | 457 | 2010 |
| Experimental characterization of the influence of tailings fineness and density on the quality of cemented paste backfill M Fall, M Benzaazoua, S Ouellet Minerals engineering 18 (1), 41-44, 2005 | 421 | 2005 |
| Mix proportioning of underground cemented tailings backfill M Fall, M Benzaazoua, EG Saa Tunnelling and Underground space technology 23 (1), 80-90, 2008 | 351 | 2008 |
| Coupled effects of sulphate and temperature on the strength development of cemented tailings backfills: Portland cement-paste backfill M Fall, M Pokharel Cement and concrete composites 32 (10), 819-828, 2010 | 340 | 2010 |
| Modeling the effect of sulphate on strength development of paste backfill and binder mixture optimization M Fall, M Benzaazoua Cement and Concrete Research 35 (2), 301-314, 2005 | 274 | 2005 |
| Experimental characterization of the stress–strain behaviour of cemented paste backfill in compression M Fall, T Belem, S Samb, M Benzaazoua Journal of materials science 42, 3914-3922, 2007 | 210 | 2007 |
| Saturated hydraulic conductivity of cemented paste backfill M Fall, D Adrien, JC Célestin, M Pokharel, M Touré Minerals engineering 22 (15), 1307-1317, 2009 | 206 | 2009 |
| Coupled thermo-hydro-mechanical–chemical behaviour of cemented paste backfill in column experiments: Part II: Mechanical, chemical and microstructural processes and characteristics A Ghirian, M Fall Engineering Geology 170, 11-23, 2014 | 201 | 2014 |
| A multi-method approach to study the stability of natural slopes and landslide susceptibility mapping M Fall, R Azzam, C Noubactep Engineering geology 82 (4), 241-263, 2006 | 200 | 2006 |
| Coupled thermo-hydro-mechanical–chemical behaviour of cemented paste backfill in column experiments. Part I: Physical, hydraulic and thermal processes and characteristics A Ghirian, M Fall Engineering Geology 164, 195-207, 2013 | 189 | 2013 |
| Sulphate effect on the early age strength and self-desiccation of cemented paste backfill W Li, M Fall Construction and building materials 106, 296-304, 2016 | 183 | 2016 |
| Coupling temperature, cement hydration and rheological behaviour of fresh cemented paste backfill D Wu, M Fall, SJ Cai Minerals Engineering 42, 76-87, 2013 | 181 | 2013 |
| Yield stress of cemented paste backfill in sub-zero environments: experimental results J Haiqiang, M Fall, L Cui Minerals Engineering 92, 141-150, 2016 | 177 | 2016 |
| Coupling binder hydration, temperature and compressive strength development of underground cemented paste backfill at early ages O Nasir, M Fall Tunnelling and Underground Space Technology 25 (1), 9-20, 2010 | 173 | 2010 |
| Combined influence of sulphate and temperature on the saturated hydraulic conductivity of hardened cemented paste backfill M Pokharel, M Fall Cement and Concrete Composites 38, 21-28, 2013 | 171 | 2013 |
| Shear behaviour of cemented pastefill-rock interfaces O Nasir, M Fall Engineering Geology 101 (3-4), 146-153, 2008 | 163 | 2008 |
| Effect of high temperature on strength and microstructural properties of cemented paste backfill M Fall, SS Samb Fire Safety Journal 44 (4), 642-651, 2009 | 153 | 2009 |
| Initial temperature-dependence of strength development and self-desiccation in cemented paste backfill that contains sodium silicate Y Wang, M Fall, A Wu Cement and Concrete Composites 67, 101-110, 2016 | 148 | 2016 |
| Effect of mineral admixtures on flow properties of fresh cemented paste backfill: Assessment of time dependency and thixotropy H Jiang, M Fall, E Yilmaz, Y Li, L Yang Powder Technology 372, 258-266, 2020 | 140 | 2020 |
