| Towards sustainable concrete PJM Monteiro, SA Miller, A Horvath Nature materials 16 (7), 698-699, 2017 | 779 | 2017 |
| Environmental impacts and decarbonization strategies in the cement and concrete industries G Habert, SA Miller, VM John, JL Provis, A Favier, A Horvath, ... Nature Reviews Earth & Environment 1 (11), 559-573, 2020 | 526 | 2020 |
| Technologies and policies to decarbonize global industry: Review and assessment of mitigation drivers through 2070 J Rissman, C Bataille, E Masanet, N Aden, WR Morrow III, N Zhou, ... Applied Energy 266, 114848, 2020 | 521 | 2020 |
| Carbon dioxide reduction potential in the global cement industry by 2050 SA Miller, VM John, SA Pacca, A Horvath Cement and Concrete Research 114, 115-124, 2018 | 463 | 2018 |
| Readily implementable techniques can cut annual CO2 emissions from the production of concrete by over 20% SA Miller, A Horvath, PJM Monteiro Environmental Research Letters 11 (7), 074029, 2016 | 351 | 2016 |
| Impacts of booming concrete production on water resources worldwide SA Miller, A Horvath, PJM Monteiro Nature Sustainability 1 (1), 69-76, 2018 | 310 | 2018 |
| Supplementary cementitious materials to mitigate greenhouse gas emissions from concrete: can there be too much of a good thing? SA Miller Journal of Cleaner Production 178, 587-598, 2018 | 167 | 2018 |
| Climate and health damages from global concrete production SA Miller, FC Moore Nature Climate Change 10 (5), 439-443, 2020 | 125 | 2020 |
| Environmental impacts of alternative cement binders SA Miller, RJ Myers Environmental Science & Technology 54 (2), 677-686, 2019 | 108 | 2019 |
| Achieving net zero greenhouse gas emissions in the cement industry via value chain mitigation strategies SA Miller, G Habert, RJ Myers, JT Harvey One Earth 4 (10), 1398-1411, 2021 | 91 | 2021 |
| Concrete mixture proportioning for desired strength and reduced global warming potential SA Miller, PJM Monteiro, CP Ostertag, A Horvath Construction and Building Materials 128, 410-421, 2016 | 80 | 2016 |
| Rice-based ash in concrete: A review of past work and potential environmental sustainability SA Miller, PR Cunningham, JT Harvey Resources, Conservation and Recycling 146, 416-430, 2019 | 76 | 2019 |
| Greenhouse gas emissions from concrete can be reduced by using mix proportions, geometric aspects, and age as design factors SA Miller, A Horvath, PJM Monteiro, CP Ostertag Environmental Research Letters 10 (11), 114017, 2015 | 74 | 2015 |
| Comparison indices for design and proportioning of concrete mixtures taking environmental impacts into account SA Miller, PJM Monteiro, CP Ostertag, A Horvath Cement and Concrete Composites 68, 131-143, 2016 | 65 | 2016 |
| Integrating durability-based service-life predictions with environmental impact assessments of natural fiber–reinforced composite materials SA Miller, WV Srubar III, SL Billington, MD Lepech Resources, Conservation and Recycling 99, 72-83, 2015 | 56 | 2015 |
| Natural fiber textile reinforced bio-based composites: Mechanical properties, creep, and environmental impacts SA Miller Journal of Cleaner Production 198, 612-623, 2018 | 54 | 2018 |
| Reducing greenhouse gas emissions for prescribed concrete compressive strength C Fan, SA Miller Construction and Building Materials 167, 918-928, 2018 | 52 | 2018 |
| Literature review on policies to mitigate GHG emissions for cement and concrete P Busch, A Kendall, CW Murphy, SA Miller Resources, Conservation and Recycling 182, 106278, 2022 | 51 | 2022 |
| A review of bioplastics at end-of-life: Linking experimental biodegradation studies and life cycle impact assessments EC Van Roijen, SA Miller Resources, Conservation and Recycling 181, 106236, 2022 | 48 | 2022 |
| The role of cement service-life on the efficient use of resources SA Miller Environmental Research Letters 15 (2), 024004, 2020 | 43 | 2020 |
