| Sustainable biochar to mitigate global climate change D Woolf, JE Amonette, FA Street-Perrott, J Lehmann, S Joseph Nature communications 1 (1), 56, 2010 | 2829 | 2010 |
| Biochar in climate change mitigation J Lehmann, A Cowie, CA Masiello, C Kammann, D Woolf, JE Amonette, ... Nature Geoscience 14 (12), 883-892, 2021 | 340 | 2021 |
| Land‐based measures to mitigate climate change: Potential and feasibility by country S Roe, C Streck, R Beach, J Busch, M Chapman, V Daioglou, ... Global Change Biology 27 (23), 6025-6058, 2021 | 192 | 2021 |
| Techno-economic assessment of biomass slow pyrolysis into different biochar and methanol concepts S Shabangu, D Woolf, EM Fisher, LT Angenent, J Lehmann Fuel 117, 742-748, 2014 | 186 | 2014 |
| Modelling the long-term response to positive and negative priming of soil organic carbon by black carbon D Woolf, J Lehmann Biogeochemistry 111, 83-95, 2012 | 150 | 2012 |
| Optimal bioenergy power generation for climate change mitigation with or without carbon sequestration D Woolf, J Lehmann, DR Lee Nature Communications 7 (1), 13160, 2016 | 149 | 2016 |
| Biochar as a soil amendment: A review of the environmental implications D Woolf Swansea University, 2008 | 141 | 2008 |
| Greenhouse gas inventory model for biochar additions to soil D Woolf, J Lehmann, S Ogle, AW Kishimoto-Mo, B McConkey, J Baldock Environmental Science & Technology 55 (21), 14795-14805, 2021 | 104 | 2021 |
| Microbial models with minimal mineral protection can explain long-term soil organic carbon persistence D Woolf, J Lehmann Scientific reports 9 (1), 6522, 2019 | 78 | 2019 |
| Biofuels from pyrolysis in perspective: trade-offs between energy yields and soil-carbon additions D Woolf, J Lehmann, EM Fisher, LT Angenent Environmental science & technology 48 (11), 6492-6499, 2014 | 76 | 2014 |
| Land restoration in food security programmes: synergies with climate change mitigation D Woolf, D Solomon, J Lehmann Climate Policy 18 (10), 1260-1270, 2018 | 70 | 2018 |
| Priming mechanisms with additions of pyrogenic organic matter to soil S DeCiucies, T Whitman, D Woolf, A Enders, J Lehmann Geochimica et Cosmochimica Acta 238, 329-342, 2018 | 59 | 2018 |
| Agricultural productivity and soil carbon dynamics: a bioeconomic model J Berazneva, JM Conrad, DT Güereña, J Lehmann, D Woolf American Journal of Agricultural Economics 101 (4), 1021-1046, 2019 | 52 | 2019 |
| Biochar, carbon accounting and climate change A Cowie, D Woolf, J Gaunt, M Brandão, RA de la Rosa, A Cowie Biochar for Environmental Management, 763-794, 2015 | 48 | 2015 |
| The role of synthetic biology in atmospheric greenhouse gas reduction: prospects and challenges J RobertsRichard, D WullschlegerStan BioDesign Research, 2020 | 36 | 2020 |
| Organic carbon dynamics in soils with pyrogenic organic matter that received plant residue additions over seven years RS Dharmakeerthi, K Hanley, T Whitman, D Woolf, J Lehmann Soil Biology and Biochemistry 88, 268-274, 2015 | 36 | 2015 |
| Biochar addition leads to more soil organic carbon sequestration under a maize-rice cropping system than continuous flooded rice I Mehmood, L Qiao, H Chen, Q Tang, D Woolf, M Fan Agriculture, ecosystems & environment 298, 106965, 2020 | 32 | 2020 |
| Biochar for climate change mitigation D Woolf, J Lehmann, A Cowie, ML Cayuela, T Whitman, S Sohi Soil and climate, 219-248, 2018 | 32 | 2018 |
| Biological and thermochemical conversion of human solid waste to soil amendments L Krounbi, A Enders, H van Es, D Woolf, B von Herzen, J Lehmann Waste management 89, 366-378, 2019 | 30 | 2019 |
| An open‐source biomass pyrolysis reactor D Woolf, J Lehmann, S Joseph, C Campbell, FC Christo, LT Angenent Biofuels, Bioproducts and Biorefining 11 (6), 945-954, 2017 | 28 | 2017 |
