| Towards sustainable production of biofuels from microalgae V Patil, KQ Tran, HR Giselrød International journal of molecular sciences 9 (7), 1188-1195, 2008 | 701 | 2008 |
| Wet torrefaction of biomass for high quality solid fuel production: A review C He, C Tang, C Li, J Yuan, KQ Tran, QV Bach, R Qiu, Y Yang Renewable and Sustainable Energy Reviews 91, 259-271, 2018 | 204 | 2018 |
| A kinetic study of gaseous alkali capture by kaolin in the fixed bed reactor equipped with an alkali detector KQ Tran, K Iisa, BM Steenari, O Lindqvist Fuel 84 (2-3), 169-175, 2005 | 203 | 2005 |
| Comparative assessment of wet torrefaction QV Bach, KQ Tran, RA Khalil, Ø Skreiberg, G Seisenbaeva Energy & Fuels 27 (11), 6743-6753, 2013 | 192 | 2013 |
| Fast hydrothermal liquefaction of a Norwegian macro-alga: screening tests QV Bach, MV Sillero, KQ Tran, J Skjermo Algal Research 6, 271-276, 2014 | 146 | 2014 |
| Pyrolysis of microalgae residues–a kinetic study HH Bui, KQ Tran, WH Chen Bioresource Technology 199, 362-366, 2016 | 138 | 2016 |
| Stump torrefaction for bioenergy application KQ Tran, X Luo, G Seisenbaeva, R Jirjis Applied energy 112, 539-546, 2013 | 130 | 2013 |
| Effects of wet torrefaction on pyrolysis of woody biomass fuels QV Bach, KQ Tran, Ø Skreiberg, TT Trinh Energy 88, 443-456, 2015 | 126 | 2015 |
| Variation of lignocellulosic biomass structure from torrefaction: A critical review HC Ong, KL Yu, WH Chen, MK Pillejera, X Bi, KQ Tran, A Pétrissans, ... Renewable and Sustainable Energy Reviews 152, 111698, 2021 | 113 | 2021 |
| Pyrolysis characteristics and kinetics of biomass torrefied in various atmospheres QV Bach, TN Trinh, KQ Tran, NBD Thi Energy conversion and management 141, 72-78, 2017 | 113 | 2017 |
| Torrefaction of Norwegian birch and spruce: an experimental study using macro-TGA D Tapasvi, R Khalil, Ø Skreiberg, KQ Tran, M Grønli Energy & Fuels 26 (8), 5232-5240, 2012 | 113 | 2012 |
| A review on disposal and utilization of phytoremediation plants containing heavy metals Z Liu, KQ Tran Ecotoxicology and environmental safety 226, 112821, 2021 | 106 | 2021 |
| Effects of wet torrefaction on reactivity and kinetics of wood under air combustion conditions QV Bach, KQ Tran, Ø Skreiberg, RA Khalil, AN Phan Fuel 137, 375-383, 2014 | 104 | 2014 |
| Fast hydrothermal liquefaction for production of chemicals and biofuels from wet biomass–The need to develop a plug-flow reactor KQ Tran Bioresource technology 213, 327-332, 2016 | 92 | 2016 |
| A simulation study on the torrefied biomass gasification D Tapasvi, RS Kempegowda, KQ Tran, Ø Skreiberg, M Grønli Energy Conversion and Management 90, 446-457, 2015 | 90 | 2015 |
| Non-isothermal pyrolysis of torrefied stump–A comparative kinetic evaluation KQ Tran, QV Bach, TT Trinh, G Seisenbaeva Applied energy 136, 759-766, 2014 | 80 | 2014 |
| Capture of potassium and cadmium by kaolin in oxidizing and reducing atmospheres QK Tran, BM Steenari, K Iisa, O Lindqvist Energy & fuels 18 (6), 1870-1876, 2004 | 77 | 2004 |
| Comparative study on the thermal degradation of dry-and wet-torrefied woods QV Bach, KQ Tran, Ø Skreiberg Applied Energy 185, 1051-1058, 2017 | 70 | 2017 |
| Combustion kinetics of wet-torrefied forest residues using the distributed activation energy model (DAEM) QV Bach, KQ Tran, Ø Skreiberg Applied Energy 185, 1059-1066, 2017 | 66 | 2017 |
| On the application of surface ionization detector for the study of alkali capture by kaolin in a fixed bed reactor KQ Tran, K Iisa, M Hagström, BM Steenari, O Lindqvist, JBC Pettersson Fuel 83 (7-8), 807-812, 2004 | 66 | 2004 |
