| Future cost and performance of water electrolysis: An expert elicitation study O Schmidt, A Gambhir, I Staffell, A Hawkes, J Nelson, S Few International journal of hydrogen energy 42 (52), 30470-30492, 2017 | 2030 | 2017 |
| Energy systems modeling for twenty-first century energy challenges S Pfenninger, A Hawkes, J Keirstead Renewable and Sustainable Energy Reviews 33, 74-86, 2014 | 1395 | 2014 |
| The future cost of electrical energy storage based on experience rates O Schmidt, A Hawkes, A Gambhir, I Staffell Nature Energy 2 (8), 1-8, 2017 | 1196 | 2017 |
| Hydrogen and fuel cell technologies for heating: A review PE Dodds, I Staffell, AD Hawkes, F Li, P Grünewald, W McDowall, P Ekins International journal of hydrogen energy 40 (5), 2065-2083, 2015 | 856 | 2015 |
| Projecting the future levelized cost of electricity storage technologies O Schmidt, S Melchior, A Hawkes, I Staffell Joule 3 (1), 81-100, 2019 | 848 | 2019 |
| How to decarbonise international shipping: Options for fuels, technologies and policies P Balcombe, J Brierley, C Lewis, L Skatvedt, J Speirs, A Hawkes, I Staffell Energy conversion and management 182, 72-88, 2019 | 634 | 2019 |
| Levelized cost of CO 2 mitigation from hydrogen production routes B Parkinson, P Balcombe, JF Speirs, AD Hawkes, K Hellgardt Energy & environmental science 12 (1), 19-40, 2019 | 526 | 2019 |
| An assessment of CCS costs, barriers and potential S Budinis, S Krevor, N Mac Dowell, N Brandon, A Hawkes Energy strategy reviews 22, 61-81, 2018 | 520 | 2018 |
| A review of domestic heat pumps I Staffell, D Brett, N Brandon, A Hawkes Energy & Environmental Science 5 (11), 9291-9306, 2012 | 466 | 2012 |
| An inter-model assessment of the role of direct air capture in deep mitigation pathways G Realmonte, L Drouet, A Gambhir, J Glynn, A Hawkes, AC Köberle, ... Nature communications 10 (1), 3277, 2019 | 458 | 2019 |
| Cost-effective operating strategy for residential micro-combined heat and power AD Hawkes, MA Leach Energy 32 (5), 711-723, 2007 | 393 | 2007 |
| Modelling high level system design and unit commitment for a microgrid AD Hawkes, MA Leach Applied energy 86 (7-8), 1253-1265, 2009 | 373 | 2009 |
| Estimating marginal CO2 emissions rates for national electricity systems AD Hawkes Energy Policy 38 (10), 5977-5987, 2010 | 324 | 2010 |
| Methane emissions: choosing the right climate metric and time horizon P Balcombe, JF Speirs, NP Brandon, AD Hawkes Environmental Science: Processes & Impacts 20 (10), 1323-1339, 2018 | 235 | 2018 |
| Fuel cells for micro-combined heat and power generation A Hawkes, I Staffell, D Brett, N Brandon Energy & Environmental Science 2 (7), 729-744, 2009 | 213 | 2009 |
| Impacts of temporal precision in optimisation modelling of micro-Combined Heat and Power A Hawkes, M Leach Energy 30 (10), 1759-1779, 2005 | 205 | 2005 |
| Temporally explicit and spatially resolved global offshore wind energy potentials J Bosch, I Staffell, AD Hawkes Energy 163, 766-781, 2018 | 181 | 2018 |
| Societal transformations in models for energy and climate policy: the ambitious next step E Trutnevyte, LF Hirt, N Bauer, A Cherp, A Hawkes, OY Edelenbosch, ... One Earth 1 (4), 423-433, 2019 | 178 | 2019 |
| Global levelised cost of electricity from offshore wind J Bosch, I Staffell, AD Hawkes Energy 189, 116357, 2019 | 170 | 2019 |
| Long-run marginal CO2 emissions factors in national electricity systems AD Hawkes Applied Energy 125, 197-205, 2014 | 164 | 2014 |
