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\t\t\t\t\t\t18\/02\/2026<\/span> Each year, the world\u2019s leading climate scientists evaluate the most critical evidence on how our planet is changing. Their assessments draw heavily on data from Earth-observing satellites \u2013 and the latest report delivers a stark warning: the planet\u2019s energy balance is drifting further out of alignment, ocean warming is now accelerating, and the land\u2019s capacity to absorb carbon is declining, along with other troubling trends.<\/p>\n<\/div>\n Global climate indicators show growing cause for alarm. The World Meteorological Organization confirmed that 2024 was the warmest year on record. This warming coincided with record ocean temperatures and sea-level rise, rapid glacier loss, low Antarctic sea ice, and more frequent extreme weather.<\/p>\n Against this backdrop of intensifying change, scientists are racing not only to document what is happening, but to understand the implications and communicate them to decision-makers.<\/p>\n Each year, Future Earth, the Earth League and the World Climate Research Programme bring together leading researchers from around the world to assess the most urgent advances in climate research. Their mission is to curate and synthesise key messages across diverse fields of climate-change research, based on the latest relevant peer-reviewed literature to produce 10 New Insights in Climate Science<\/i>.<\/p>\n<\/p><\/div>\n The 2025 edition, released as both an academic paper and a science\u2013policy report, draws on research published between January 2024 and June 2025.<\/p>\n This new easy-to-read guide reflects the collective effort of more than 70 researchers, incorporating input from over 150 experts worldwide \u2013 distilling the latest findings into clear, policy-relevant insights designed to support the timely uptake of new scientific evidence in decision-making through 2026 and beyond.<\/p>\n<\/p><\/div>\n Sophie Hebden, ESA Climate Applications Scientist, said, \u201cThese findings are based on robust empirical data published in leading scientific journals, including data generated through ESA\u2019s Climate Change Initiative \u2013 a major research and development programme that produces long-term global satellite data records to monitor key components of Earth\u2019s climate system, known as Essential Climate Variables.<\/p>\n \u201cThrough the initiative, we transform satellite observations into high-quality data products to assess the state of the climate and know where we currently stand, to validate and improve climate models so we know where we\u2019re heading, and to support ESA Member States with transparent information to help track progress in climate action and Paris Agreement reporting.<\/p>\n \u201cSatellite datasets are a major source of information for climate scientists from around the world, with authoritative scientific assessments published periodically by the UNFCCC Intergovernmental Panel on Climate Change, and annually in the 10 New Insights in Climate Science<\/i> report.\u201d<\/p>\n In brief, the new insights are as follows:<\/p>\n \n1. Record-breaking warmth in 2023\u20132024 raises new questions<\/b> In this context, the\u00a0MOTECUSOMA\u00a0project from ESA\u2019s Climate Change Initiative quantifies changes to Earth\u2019s energy imbalance using Essential Climate Variables to examine changes in climate system processes in response to rising greenhouse gas emissions.<\/p>\n \n2. Rapid ocean warming and intensifying marine heatwaves<\/b> This insight is supported by data available through the Climate Change Initiative\u2019s\u00a0Sea Surface Temperature project.<\/p>\n The image below shows data over the last 40 years, highlighting when and where the most recent maximum sea-surface temperature was recorded. Marine heatwaves have been widespread but have hit the Atlantic, Indian and West Pacific oceans particularly hard in the last few years. The insight also summarised regional oceanic impacts, such as Mediterranean species loss in the record-breaking hot year of 2023.<\/p>\n<\/p><\/div>\n \n3. The global land carbon sink is weakening<\/b> This insight is largely based on datasets available through the Climate Change Initiative\u2019s RECCAP-2 project which clarifies global carbon sources and sinks.<\/p>\n The image below shows carbon storage change in northern ecosystems relative to 2010, with a drop in biomass from 2016 onwards. This could signal more carbon release from vegetation to the atmosphere.<\/p>\n<\/p><\/div>\n \n4. Climate change and biodiversity loss amplify one another<\/b> Satellite observations make substantial contributions in this area by tracking ecosystem types, extent, and dynamics through various initiatives such as ESA WEED, as well as ecosystem functioning under climate change such as ESA FORTRACK and ECOMOSAIC. The effective use of these capabilities depends on their integration with diverse complementary data sources.<\/p>\n \n5. Climate change is intensifying groundwater depletion<\/b> This insight is largely based on data from the US-German GRACE mission, with more regional supporting studies using Copernicus Sentinel-1 to obtain high-resolution subsidence information.<\/p>\n<\/p><\/div>\n \n6. Climate change is driving the global surge in dengue<\/b> The sixth phase of the Coupled Model Intercomparison Project (whose international project office is hosted by ESA) supports work to understand the climate-related risk factors of vector-borne diseases, and predict future outbreak likelihoods.<\/p>\n \n7. Heat stress is reducing labour productivity and incomes<\/b> \n8. Carbon dioxide removal must scale up safely and responsibly<\/b> \n9. Strengthening integrity in carbon credit markets<\/b> \n10. Policy packages outperform single measures<\/b>
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Although the shift to El Ni\u00f1o conditions amplified recent temperature extremes, natural variability alone cannot explain the scale of the anomalies. A sharp rise in Earth\u2019s energy imbalance suggests that global warming may be accelerating.<\/p>\n
Sea-surface temperatures are rising at an unprecedented rate, and marine heatwaves are becoming more intense and prolonged. These changes are causing severe ecosystem damage, undermining coastal livelihoods, increasing extreme weather risks and weakening the ocean\u2019s capacity to absorb carbon.<\/p>\n<\/p><\/div>\n
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A significant decline in land-based carbon uptake in 2023 raises concerns that more carbon may remain in the atmosphere, shrinking the remaining carbon budget. Northern hemisphere ecosystems \u2013 once considered relatively resilient \u2013 are increasingly affected by wildfires and permafrost thaw.<\/p>\n
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Growing evidence shows that climate change and biodiversity decline interact in a destabilising feedback loop, threatening ecosystem resilience and carbon storage. Stronger coordination across the Rio Conventions could maximise synergies, avoid fragmented policies, and prioritise the protection and restoration of biodiverse ecosystems and natural carbon sinks.<\/p>\n
Groundwater is being depleted faster than in previous decades, as climate change disrupts aquifer recharge and rising socioeconomic demands increase extraction. The consequences include heightened risks to agriculture and food security, land subsidence and seawater intrusion in coastal regions.<\/p>\n
Dengue fever has surged to its largest global outbreak on record. Rising temperatures are expanding mosquito habitats and extending transmission seasons, compounding the effects of urbanisation, global travel and poor waste management. Health systems are already under strain, and projections indicate further increases in risk this century.<\/p>\n
Climate-driven heat stress is eroding labour productivity and income, particularly in developing countries. However, the economic impacts ripple through global supply chains and trade networks. Projected annual gross domestic product losses are substantially lower under low-emissions pathways, underscoring the economic case for more ambitious mitigation.<\/p>\n
Carbon dioxide removal will be needed to address residual emissions and manage climate risks. However, it must complement, not replace, emission reductions. Clear international governance frameworks, sustained research and innovation, and strong environmental and social safeguards are essential to close the growing carbon dioxide removal gap and support long-term climate stability.<\/p>\n
The rapid expansion of carbon credit markets has exposed serious integrity concerns, including overestimated sequestration and weak additionality. Reliance on low-quality credits risks delaying real decarbonisation. Emerging improvements in standards, transparency and benchmarking, along with a shift toward framing credits as contributions rather than offsets, offer a pathway to more credible markets.<\/p>\n
Integrated policy mixes consistently achieve greater emissions reductions than stand-alone interventions. Approaches that combine measures such as carbon pricing and fossil fuel subsidy reform tend to be particularly effective, though policy design must reflect national contexts. Coordinated cross-sector strategies and harmonised reporting can further enhance impact and shared learning.<\/p>\n<\/p><\/div>\n