Hassan, AbubakarHaseeb, MohammadBekun, Festus VictorYazdi, Asieh HaieriUllah, EhsanHossain, Md. Emran2024-03-132024-03-1320240149-19701878-4224https://hdl.handle.net/11363/7200https://doi.org/Growing concern over climate change mitigation has heightened the search for low-carbon, affordable, and nonintermittent energy alternatives. In this perspective, hydropower, thermal, solar, photovoltaic, and nuclear energy sources fit all these qualities as they are well-known as cleaner and ecosystem-friendly energy sources. However, despite the attractiveness of the clean energy transition, the extant literature has less documentation on the pertinent role of nuclear energy in the “climate change mitigation (SDG-13)” agenda, hence making it difficult to predict nuclear energy-CO2 emissions (CO2e) nexus. Hence, the present study, using IPAT and the “environmental Kuznets curve (EKC)” framework, explores the consequences of nuclear energy generation, population dynamics, and economic progress on CO2e in the “United States of America (USA)” by applying a “dynamic autoregressive distributed lag (DARDL)” model from 1973 to 2021. The study provides evidence the existence of the EKC phenomena, suggesting that economic expansion hurts the environment up to a specific threshold level of per capita income, which is identified as US$ 29,581.16. Further empirical findings also show the detrimental effect of population-induced-emission. Remarkably, a 1% rise in nuclear energy generation dwindles CO2e by around 0.819%. The outcomes of this research demonstrate that economic growth level, population, and CO2 emission are entangled. However, there is a need for a collective role from both stakeholders and policymakers in achieving “SDG-13” as well as “clean and affordable energy (SDG-7)” with a paradigm shift of the USA energy portfolio away from fossil fuels to renewables.eninfo:eu-repo/semantics/openAccessNuclear energyEconomic growthPopulationCO2 emissionsDynamic ARDL modelArticle16911110.1016/j.pnucene.2024.1050592-s2.0-85183178471Q2WOS:001170665200001N/A