| Assessment of hydrogen direct reduction for fossil-free steelmaking V Vogl, M Åhman, LJ Nilsson Journal of cleaner production 203, 736-745, 2018 | 505 | 2018 |
| A review of technology and policy deep decarbonization pathway options for making energy-intensive industry production consistent with the Paris Agreement C Bataille, M Åhman, K Neuhoff, LJ Nilsson, M Fischedick, ... Journal of Cleaner Production 187, 960-973, 2018 | 426 | 2018 |
| Government policy and the development of electric vehicles in Japan M Åhman Energy Policy 34 (4), 433-443, 2006 | 339 | 2006 |
| Decarbonising the energy intensive basic materials industry through electrification–Implications for future EU electricity demand S Lechtenböhmer, LJ Nilsson, M Åhman, C Schneider Energy 115, 1623-1631, 2016 | 295 | 2016 |
| The transition of energy intensive processing industries towards deep decarbonization: Characteristics and implications for future research JH Wesseling, S Lechtenböhmer, M Åhman, LJ Nilsson, E Worrell, ... Renewable and Sustainable Energy Reviews 79, 1303-1313, 2017 | 251 | 2017 |
| Primary energy efficiency of alternative powertrains in vehicle M Åhman Energy 26 (11), 973-989, 2001 | 224 | 2001 |
| Global climate policy and deep decarbonization of energy-intensive industries M Åhman, LJ Nilsson, B Johansson Climate Policy 17 (5), 634-649, 2017 | 217 | 2017 |
| Data centres in future European energy systems—energy efficiency, integration and policy C Koronen, M Åhman, LJ Nilsson Energy Efficiency 13 (1), 129-144, 2020 | 116 | 2020 |
| Adopting hydrogen direct reduction for the Swedish steel industry: A technological innovation system (TIS) study D Kushnir, T Hansen, V Vogl, M Åhman Journal of Cleaner Production 242, 118185, 2020 | 114 | 2020 |
| Path dependency and the future of advanced vehicles and biofuels M Åhman, LJ Nilsson Utilities Policy 16 (2), 80-89, 2008 | 98 | 2008 |
| Biomethane in the transport sector—An appraisal of the forgotten option M Åhman Energy Policy 38 (1), 208-217, 2010 | 97 | 2010 |
| The making of green steel in the EU: a policy evaluation for the early commercialization phase V Vogl, M Åhman, LJ Nilsson Climate Policy 21 (1), 78-92, 2021 | 89 | 2021 |
| Electricity-based plastics and their potential demand for electricity and carbon dioxide E Palm, LJ Nilsson, M Åhman Journal of Cleaner Production 129, 548-555, 2016 | 80 | 2016 |
| Which countries are prepared to green their coal-based steel industry with electricity?-Reviewing climate and energy policy as well as the implementation of renewable electricity M Arens, M Åhman, V Vogl Renewable and Sustainable Energy Reviews 143, 110938, 2021 | 69 | 2021 |
| An industrial policy framework for transforming energy and emissions intensive industries towards zero emissions LJ Nilsson, F Bauer, M Åhman, FNG Andersson, C Bataille, ... Climate Policy 21 (8), 1053-1065, 2021 | 67 | 2021 |
| A comparison of technologies for carbon-neutral passenger transport B Johansson, M Åhman Transportation Research Part D: Transport and Environment 7 (3), 175-196, 2002 | 63 | 2002 |
| Hydrogen steelmaking for a low-carbon economy M Åhman, O Olsson, V Vogl, B Nyqvist, A Maltais, LJ Nilsson, K Hallding, ... Stockholm Environment Institute., 2018 | 60 | 2018 |
| Decarbonizing industry in the EU: Climate, trade and industrial policy strategies M Åhman, LJ Nilsson Decarbonization in the European Union: Internal Policies and External …, 2015 | 55 | 2015 |
| Decarbonising industry in Sweden M Åhman, A Nikoleris, LJ Nilsson IMES/EES Report, 2012 | 50 | 2012 |
| Demonstrating climate mitigation technologies: An early assessment of the NER 300 programme M Åhman, JB Skjærseth, PO Eikeland Energy Policy 117, 100-107, 2018 | 49 | 2018 |
