In the midst of a rapidly warming planet, the ocean has long served as a vital buffer, absorbing a substantial portion of the anthropogenic carbon dioxide emissions that would otherwise exacerbate atmospheric warming. However, new research reveals a disturbing trend: the ocean’s ability to act as a carbon sink has experienced an unexpected and pronounced decline in 2023, coinciding with record-high sea surface temperatures. This finding, detailed in a groundbreaking study published in Nature Climate Change, signals a critical turning point in our understanding of the Earth’s carbon cycle and its feedback mechanisms, with profound implications for the future trajectory of global climate change.
The oceans cover more than 70% of our planet’s surface and have historically absorbed approximately 25 to 30% of human-made CO₂ emissions annually. This natural absorption mitigates the pace of atmospheric warming, acting as a vital stabilizer against the intensifying effects of climate change. Yet, the new data highlight an alarming vulnerability: the ability of the ocean to continue soaking up carbon is not infinite, nor is it guaranteed under extreme environmental stressors. The record-high sea surface temperatures (SSTs) observed globally in 2023 have pushed the ocean carbon sink to a precipice, resulting in a marked reduction in carbon uptake.
At the core of this shift is the interplay between physical and biological processes that govern oceanic carbon sequestration. Warmer sea surface temperatures affect the solubility of CO₂ in seawater: as water warms, its capacity to dissolve gases diminishes. This thermodynamic principle means that the ocean’s surface layers are less capable of absorbing CO₂ from the atmosphere when SSTs increase dramatically. Moreover, elevated temperatures can alter ocean stratification, reducing the vertical mixing that usually transports carbon-rich surface waters to the ocean interior. Such stratification inhibits the deeper, more permanent sequestration of carbon, leading to a build-up of CO₂ in near-surface waters and ultimately decreasing net carbon uptake.
Beyond these physical limitations, biological feedbacks offer additional complexity. Phytoplankton, the microscopic photosynthetic organisms responsible for approximately half of global primary production and a critical component of the biological carbon pump, are sensitive to temperature changes. The study points to a significant reduction in phytoplankton biomass during 2023, particularly in key regions known for their high productivity and carbon export potential. Warmer waters tend to favor smaller phytoplankton species, which are less efficient at exporting carbon to the deep ocean. This shift diminishes the biological sequestration pathway that moves carbon from surface waters to abyssal depths on timescales of decades to centuries.
Compounding these effects, the ocean carbon sink decline aligns with an array of unprecedented oceanographic phenomena recorded in 2023. Heatwaves affected vast oceanic expanses, with surface temperatures soaring to levels unseen in the historical record. These heat extremes not only influence chemical and biological processes but also stress marine ecosystems, inducing harmful algal blooms and altering food web dynamics. Such stressors could further suppress phytoplankton productivity or change the community structure in ways unfavorable to carbon export mechanisms.
The researchers employed an integrative approach, harnessing satellite observations, in situ measurements, and sophisticated Earth system models to unravel the complex drivers behind the weakening carbon sink. This multidisciplinary methodology allowed for robust attribution of the decline to temperature anomalies while quantifying the consequent decrease in oceanic carbon uptake. Model simulations further suggest that if SSTs persist or continue to climb along current trajectories, the ocean carbon sink may experience additional reductions, destabilizing a critical planetary carbon buffer.
Intriguingly, the study underscores regional disparities in the response of the ocean carbon sink to warming. While some areas exhibited pronounced declines in carbon uptake, others showed resilience or even localized increases. These spatial heterogeneities relate to differences in ocean circulation, nutrient availability, and ecosystem composition among ocean provinces. The patchwork nature of these responses complicates global predictions and highlights the pressing need for enhanced monitoring networks tailored to capture fine-scale variability.
The implications of this unexpected decline extend far beyond oceanography, reverberating through climate policy and mitigation strategies. The ocean’s role as a carbon sink has often been considered a stable, albeit slow-reacting, component of the Earth system. The identification of rapid declines linked to temperature extremes challenges this assumption and emphasizes the urgency of curbing greenhouse gas emissions. If the ocean’s mitigation capacity falters, atmospheric CO₂ concentrations could rise more swiftly, thereby accelerating global warming and intensifying extreme weather, sea level rise, and ecological disruptions.
Moreover, the findings raise critical questions regarding the long-term feedback loops in the climate system. Reduced ocean carbon uptake could induce a positive feedback mechanism, wherein warming diminishes oceanic absorption, which in turn exacerbates atmospheric CO₂ accumulation and further warming. This cycle threatens to spiral, potentially complicating efforts to stabilize global temperatures under international goals such as those outlined in the Paris Agreement.
The study also pinpoints opportunities for future research aimed at refining climate projections and adaptation measures. Improved understanding of the thresholds and tipping points for ocean carbon sink decline is essential to predict the timeline and magnitude of potential feedbacks. Additionally, investigating how anthropogenic factors such as pollution, overfishing, and habitat degradation interact with warming to affect marine carbon cycling will be critical for comprehensive ecosystem management.
In practical terms, these insights necessitate an expansion of ocean observing capabilities globally. Continuous and detailed monitoring of SSTs, biogeochemical parameters, and biological productivity must be prioritized to identify emerging trends and anomalies in real-time. Coupled with enhanced model fidelity, this will empower the scientific community and policymakers to formulate adaptive strategies that mitigate risks associated with declining ocean carbon sequestration.
The unexpected decline in ocean carbon storage amid record-breaking temperatures serves as a stark reminder of the fragile balance underpinning Earth’s climate system. It emphasizes how interconnected and delicate the marine carbon cycle is, and how susceptible it is to disturbances induced by human influence. The ocean, often perceived as an inexhaustible absorber of CO₂, now appears vulnerable to rapid shifts that could undermine decades of climate stabilization efforts.
As the study’s authors eloquently summarize, these revelations call for urgent international collaboration to reduce emissions and to protect ocean health comprehensively. Mitigation strategies must integrate not only terrestrial but also marine ecosystem conservation and restoration to preserve the ocean’s capacity to buffer climate change. Recognizing and responding to this early-warning signal is paramount if humanity is to avoid cascading environmental consequences.
Ultimately, the 2023 ocean carbon sink decline harbingers a new era in climate dynamics, where the resilience of natural systems may be dwarfed by unprecedented anthropogenic pressures. This watershed moment challenges scientists, policymakers, and society at large to heed the ocean’s distress signals and bolster global efforts toward a sustainable climate future.
Subject of Research: Ocean carbon sink variability and its response to record-high sea surface temperatures
Article Title: Unexpected decline in the ocean carbon sink under record-high sea surface temperatures in 2023
Article References:
Müller, J.D., Gruber, N., Schneuwly, A. et al. Unexpected decline in the ocean carbon sink under record-high sea surface temperatures in 2023. Nat. Clim. Chang. (2025). https://doi.org/10.1038/s41558-025-02380-4
Image Credits: AI Generated