Publications by authors named "Cheryl S Harrison"
Article Synopsis
- Marine animal biomass is projected to decline in the 21st century due to climate change, impacting apex predators more significantly through a process called trophic amplification.
- Using simulations from nine marine ecosystem models, researchers found that consumer biomass could decrease by 16.7% more than net primary production by the end of the century, with major variations across different regions.
- The study highlights complex responses within marine food webs, emphasizing the need for improved models to understand and predict the ecological consequences of climate change on marine ecosystems.
Article Synopsis
- Researchers in life sciences contribute evidence for the IPCC to help policymakers plan for climate change.
- There's a risk that non-experts may misinterpret complex climate model data, leading to incorrect conclusions.
- The text aims to offer an easy-to-understand guide on climate model outputs to help life scientists effectively tackle related questions.
Atmospheric soot loadings from nuclear weapon detonation would cause disruptions to the Earth's climate, limiting terrestrial and aquatic food production. Here, we use climate, crop and fishery models to estimate the impacts arising from six scenarios of stratospheric soot injection, predicting the total food calories available in each nation post-war after stored food is consumed. In quantifying impacts away from target areas, we demonstrate that soot injections larger than 5 Tg would lead to mass food shortages, and livestock and aquatic food production would be unable to compensate for reduced crop output, in almost all countries.
View Article and Find Full Text PDFProjections of climate change impacts on marine ecosystems have revealed long-term declines in global marine animal biomass and unevenly distributed impacts on fisheries. Here we apply an enhanced suite of global marine ecosystem models from the Fisheries and Marine Ecosystem Model Intercomparison Project (Fish-MIP), forced by new-generation Earth system model outputs from Phase 6 of the Coupled Model Intercomparison Project (CMIP6), to provide insights into how projected climate change will affect future ocean ecosystems. Compared with the previous generation CMIP5-forced Fish-MIP ensemble, the new ensemble ecosystem simulations show a greater decline in mean global ocean animal biomass under both strong-mitigation and high-emissions scenarios due to elevated warming, despite greater uncertainty in net primary production in the high-emissions scenario.
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- Deliberate climate interventions like solar radiation modification (SRM) aim to counteract human-induced climate change by reflecting solar radiation to increase Earth's albedo.
- The study focuses on stratospheric aerosol intervention (SAI), a feasible SRM method, emphasizing the need for research on its ecological impacts, which have been largely overlooked in current climate science.
- Collaboration between ecologists and climate scientists is crucial to address knowledge gaps and effectively communicate potential risks of SAI on biodiversity and ecosystem services.
Loggerhead sea turtles () nest globally on sandy beaches, with hatchlings dispersing into the open ocean. Where these juveniles go and what habitat they rely on remains a critical research question for informing conservation priorities. Here a high-resolution Earth system model is used to determine the biophysical geography of favourable ocean habitat for loggerhead sea turtles globally during their first year of life on the basis of ocean current transport, thermal constraints and food availability (defined here as the summed lower trophic level carbon biomass).
View Article and Find Full Text PDFNuclear war, beyond its devastating direct impacts, is expected to cause global climatic perturbations through injections of soot into the upper atmosphere. Reduced temperature and sunlight could drive unprecedented reductions in agricultural production, endangering global food security. However, the effects of nuclear war on marine wild-capture fisheries, which significantly contribute to the global animal protein and micronutrient supply, remain unexplored.
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- Pakistan and India are projected to have between 400 to 500 nuclear weapons by 2025, with explosive yields varying from 12 to several hundred kilotons.
- A hypothetical conflict using 100 strategic weapons by India and 150 by Pakistan could lead to 50 to 125 million fatalities and massive environmental impact, including significant black carbon emissions.
- Resulting climate effects could cause a 20 to 35% decrease in surface sunlight, a global temperature drop of 2° to 5°C, reduced precipitation, and long-term agricultural decline, potentially leading to mass starvation.