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Awareness of the threats to mental health posed by climate change leads to questions about the potential impacts on climate scientists because they are immersed in depressing information and may face apathy, denial and even hostility from others. But they also have sources of resilience.
Research on climate change mitigation tends to focus on supply-side technology solutions. A better understanding of demand-side solutions is missing. We propose a transdisciplinary approach to identify demand-side climate solutions, investigate their mitigation potential, detail policy measures and assess their implications for well-being.
The health impacts of climate change are being increasingly recognized, but mental health is often excluded from this discussion. In this issue we feature a collection of articles on climate change and mental health that highlight important directions for future research.
The new rules of the EU ETS will fundamentally change its character. The long-term cap on emissions will become a function of past and future market outcomes, temporarily puncturing the waterbed and having retroactive impacts on GHG abatement from overlapping policies.
China recently announced its national emissions trading scheme, advancing market-based approaches to cutting greenhouse gas emissions. Its evolution over coming years will determine whether it becomes an effective part of China’s portfolio of climate policies.
This Perspective reviews the literature on climate change and mental health, and advocates for a systems approach, which considers the complex set of interacting distal, intermediate and proximate factors that influence mental health risk, in future research.
Climate change has a gradual influence on landscapes and ecosystems that may lead to feelings of loss for those with close ties to the natural environment. This Perspective describes existing research on ecological grief and outlines directions for future inquiry.
Arctic sea ice cover has declined significantly in recent years. Model simulations suggest the probability of an ice-free Arctic will be 100% under 2 °C, but 30% under 1.5 °C, motivating efforts to constrain anthropogenic warming.
Limiting warming to 1.5 °C requires staying within an allowable carbon budget. An analysis of warming and carbon budgets from the past decade shows that the median remaining budget is 208 PgC, corresponding to about 20 years of emissions at the 2015 rate.
In the Paris Agreement, nations committed to a more ambitious climate policy target, aiming to limit global warming to 1.5 °C rather than 2 °C above pre-industrial levels. Climate models now show that achieving the 1.5 °C goal would make a big difference for Arctic sea ice.
Nations are currently pursuing efforts to constrain anthropogenic warming to 1.5 °C. In such a world, model projections suggest the Arctic will be ice-free every one in forty years, compared to one in every five under stabilized 2 °C warming.
Fisheries generated a total of 179 million tonnes of CO2-equivalent GHG emissions in 2011 (4% of global food production). Emissions grew by 28% between 1990 and 2011, primarily driven by increased harvests from fuel-intensive crustacean fisheries.
Time of reproduction may be altered as the climate changes. For seabirds, it is shown that there has not been an adjustment in timing as the climate changes and the sea surface warms. This lack of plasticity could result in a mismatch with food resources.
While well-known for its temperature targets, the Paris Agreement also aims for net zero GHG emissions. IAM results reveal net zero GHG emissions are not always required to meet the temperature targets, and that net zero CO2 emissions are a more suitable aim.
The 2010 Russia heatwave had devastating impacts, including loss of life, wildfire and drought. Model simulations reveal similar heatwaves may be amplified by up to 8 °C in the future as soil moisture becomes less able to suppress maximum temperatures.
Permafrost soils store vast quantities of organic matter that are vulnerable to decomposition under a warming climate. Recent research finds that methane release from thawing permafrost may outpace carbon dioxide as a major contributor to global warming over the next century.
Emission mitigation is required to achieve global climate ambitions but can also offer local benefits. Reduction in air pollution because of low-carbon emission trajectories is shown to result in approximately 150 million fewer premature deaths worldwide.
An organic carbon decomposition model, calibrated with laboratory incubations, indicates a greater production rate of CO2-C equivalents from waterlogged (compared to drained) permafrost soils, when the higher global warming potential of methane is factored in.
Glaciers outside Greenland and Antarctica have been rapidly losing mass. Contemporary ice declines are shown to be a response to past greenhouse gas emissions, with present mitigation efforts unlikely to be beneficial in preventing future short-term ice loss.
Marine ecosystems and their stored carbon are threatened by warming and marine heatwaves. During a 2010–2011 heatwave, around a third of a Western Australian seagrass ecosystem suffered damage, potentially releasing 2–9 Tg CO2 in the following years.
