New study reveals hidden ocean heatwaves threatening South China Sea ecosystems

Institute of Atmospheric Physics, Chinese Academy of Sciences

FacebookXLinkedInWeChatBlueskyMessageWhatsAppEmail

 

image: 

Subsurface MHW impacts on deep ecosystems in the SCS

view more 

Credit: Ning Cao

The South China Sea (SCS), a vital marine region supporting rich biodiversity, productive fisheries, and extensive coral reefs, faces growing threats from marine heatwaves (MHWs). While surface MHWs have drawn attention, subsurface events—intense warming below the ocean surface—during boreal winter have been less studied, yet they can disrupt deeper-dwelling species and ecosystem stability in this semi-enclosed sea.

 

A research team from Guangdong Ocean University has uncovered the key mechanisms driving these winter subsurface MHWs in the SCS, pinpointing the northeastern basin west of the Luzon Strait as a persistent hotspot. Their analysis shows that heat transport from the Kuroshio through the Luzon Strait, combined with swirling mesoscale eddies, significantly amplifies subsurface warming at depths of 70–300 m, making events deeper, more intense, and more frequent than in other parts of the sea. The study has been recently published in the journal Atmospheric and Oceanic Science Letters.

 

Using long-term high-resolution ocean reanalysis data spanning 1994–2023, the scientists mapped the patterns and vertical structures of these hidden heatwaves. They found that MHW intensity often peaks at a depth of around 130 m, with the strongest zones shifting northeastward as depth increases. In the Luzon Strait–influenced area, subsurface MHWs penetrate deeper and occur more often compared to the broader SCS.

 

Heat budget calculations revealed that ocean currents dominate the process: steady vertical movement brings heat downward, while horizontal flows from the Luzon Strait counteract winter surface cooling. Crucially, anticyclonic eddies—those spinning clockwise with negative vorticity—trigger downwelling, trapping and enhancing warm water below the surface during peak years.

 

“These findings highlight the northeastern South China Sea as a winter MHW hotspot and provide a basis for assessing ecological risks to vulnerable marine ecosystems,” says Dr. Ning Cao, the corresponding author of the study.

 

This local focus is especially relevant for the SCS, where subsurface warming can stress fisheries by affecting fish stocks at greater depths and threaten coral reefs through prolonged thermal stress on deeper layers. By clarifying the role of Luzon Strait inflow and eddies, the work offers valuable insights for improved prediction and monitoring of these events in this economically and ecologically critical region.

 

In the future, the researchers aim to refine models incorporating these dynamics for better forecasting of subsurface MHWs, helping support sustainable management of the SCS’ marine resources amid ongoing climate pressures.

---

Journal

Atmospheric and Oceanic Science Letters

DOI

10.1016/j.aosl.2026.100789 

 

'Unprecedented' wildfires in tropical peatlands during 20th century

A new study reveals an unprecedented increase in wildfires in tropical peatlands during the 20th century.  

University of Exeter

FacebookXLinkedInWeChatBlueskyMessageWhatsAppEmail

A new study reveals an unprecedented increase in wildfires in tropical peatlands during the 20th century.  

Peatlands store vast quantities of carbon below the Earth’s surface – more than all the world’s forest biomass combined – but when they catch fire large amounts of the stored carbon is released into the atmosphere.  

Wildfires in tropical regions have been on the rise in recent decades, but the history and characteristics of wildfires in tropical peatlands remain largely unknown.  

Researchers therefore analysed charcoal records preserved in peat deposits across Central and South America, Africa, Southeast Asia and Australasia to reconstruct wildfire activity stretching back more than two millennia.  

Historically, peatland fire patterns are closely linked to climate fluctuations, particularly the length and severity of droughts.  

The researchers found that wildfire activity in tropical peatlands declined for more than 1,000 years, in line with changes in global temperatures and other natural climate variables. 

But in the last century, there was a dramatic increase in the number of wildfires, and regional differences in the results point to human activities being the root cause.  

The increase in wildfires was mainly confined to the Southeast Asia and Australasian regions, where drainage for agriculture, deforestation and land conversion has left peat soils more vulnerable to ignition.  

But in less accessible peatland regions across South America and Africa, there were no such increases, although lead author Dr Yuwan Wang warns these regions could experience more wildfires too as population density increases and commercial agriculture and infrastructure expands.  

“To avoid large carbon emissions that further contribute to global warming we urgently need to protect these carbon-dense ecosystems,” said Dr Wang from the University of Exeter. 

“A reduction in tropical peatland burning could be achieved through peatland conservation, and promoting sustainable resource management and ecosystem restoration, but this requires the collaboration of multiple groups and has to be carried out at sufficiently large scale.” 

“Unprecedented burning in tropical peatlands during the 20th century compared to the previous two millennia” is published in Global Change Biology. 

 

---

Journal

Global Change Biology

DOI

10.1111/gcb.70717 

Method of Research

Observational study

Subject of Research

Not applicable

Article Title

Unprecedented burning in tropical peatlands during the 20th century compared to the previous two millennia

Article Publication Date

17-Mar-2026

 

Sunlight-driven “schottky” catalyst quickly removes fulvic acid—a tough drinking-water pollutant precursor

Maximum Academic Press

FacebookXLinkedInWeChatBlueskyMessageWhatsAppEmail

FA contains complex aromatic and oxygen-containing functional groups, making it chemically stable and difficult to degrade. Although photocatalysis can generate reactive oxygen species under light irradiation, its efficiency is often limited by poor visible-light utilization and rapid charge recombination.

FA, a major humic-substance fraction, forms from long-term transformation of plant residues and microbial metabolites and is widespread in soils, sediments, and surface waters. Its heterogeneous macromolecules contain aromatic moieties, carboxyls, and phenolic hydroxyls that complex metals and co-contaminants, altering their mobility and bioavailability. In drinking-water treatment, FA is troublesome because chlorination can convert it into disinfection by-products such as trihalomethanes and haloacetic acids, raising health concerns and hindering purification. Although photocatalysis generates electron–hole pairs and reactive oxygen species, limited visible-light absorption and fast charge recombination restrict FA removal. Coupling photocatalysis with persulfate AOPs (e.g., PMS) can add oxidants to accelerate degradation and improve mineralization of organics.

A study (DOI:10.48130/aee-0025-0014) published in Agricultural Ecology and Environment on 20 January 2026 by Guangshan Zhang & Chunyan Yang’s team, Qingdao Agricultural University, offers a promising strategy to enhance radical generation and achieve faster, deeper FA degradation in water treatment systems.

Using integrated structural and catalytic diagnostics, the researchers first characterized the BiOCl/MXene photocatalyst by SEM/EDS mapping, TEM/HRTEM, XRD, N₂ adsorption–desorption (BET), and XPS to elucidate morphology, crystallinity, surface area, and interfacial electron transfer. They then evaluated visible-light/PMS performance through synthesis optimization (hydrothermal temperature/time and MXene loading), comparative degradation experiments, kinetic modeling, quantum-yield estimation, and robustness tests across catalyst dosage, FA concentration, pH, coexisting anions, water matrices, recycling cycles, and pollutant types. Photoelectrochemical analyses (UV–vis, PL, EIS, TRPL, Mott–Schottky, photocurrent), radical quenching, and EPR identified charge-transfer behavior and active species, while SUVA, 3D-EEM fluorescence, and TOC tracked structural breakdown and mineralization. SEM and TEM confirmed that BiOCl nanosheets were uniformly anchored on layered MXene with tight interfacial contact, and EDS showed homogeneous Bi/O/Ti/C/Cl distribution. HRTEM resolved BiOCl (101)/(110) and MXene (002) planes, while XRD verified phase coexistence. BET revealed mesoporosity (2–10 nm) and a marked surface-area increase to 41.73 m² g⁻¹ (vs 9.17 m² g⁻¹ for BiOCl), indicating more active sites and improved mass transfer. XPS peak shifts and Bi–O–C bond formation evidenced electron transfer and Schottky-junction construction, promoting carrier separation. Under visible light with PMS, the optimized composite (160 °C, 10 h, 15% MXene) achieved 98.43% FA removal in 30 min, with k = 0.1388 min⁻¹ (3.27× BiOCl) and a synergy factor of 5.28; the apparent quantum yield was ~1.33%, reflecting PMS-assisted electron trapping. High efficiency persisted across pH 3–9 and FA 20–100 mg L⁻¹, with optimal performance at 0.8 g L⁻¹ catalyst and ~2 mM PMS. The catalyst retained >80% activity after five cycles, removed >70% FA in lake water, and effectively degraded antibiotics, dyes, and phenols. Photoelectrochemical data confirmed enhanced visible absorption and faster charge transfer, quenching/EPR identified h⁺ and O₂•⁻ as dominant oxidants, and spectroscopic plus TOC analyses showed rapid chromophore destruction but partial mineralization (49.95%).

FA control is crucial for reducing DBP formation potential before chlorination and improving overall drinking-water safety. This work suggests a practical route: a recyclable visible-light catalyst that activates PMS efficiently, tolerates varied pH and ionic conditions, and performs in complex waters. Beyond FA, the system showed broad activity against different pollutant classes (e.g., antibiotics, dyes, phenols), implying potential use as a flexible AOP platform for mixed-contaminant waters.

###

References

DOI

10.48130/aee-0025-0014

Original Souce URL

https://doi.org/10.48130/aee-0025-0014

Funding information

The work was supported by the National Natural Science Foundation of China (Grant Nos 52370174, 52500009), Natural Science Foundation of Shandong Province, China (Grant No. ZR2022ME128), and Harbin Institute of Technology (Weihai) Qingdao Research Institute (Grant No. IQTA10100026).

About Agricultural Ecology and Environment

Agricultural Ecology and Environment (e-ISSN 3070-0639) is a multidisciplinary platform for communicating advances in fundamental and applied research on the agroecological environment, focusing on the interactions between agroecosystems and the environment. It is dedicated to advancing the understanding of the complex interactions between agricultural practices and ecological systems. The journal aims to provide a comprehensive and cutting-edge forum for researchers, practitioners, policymakers, and stakeholders from diverse fields such as agronomy, ecology, environmental science, soil science, and sustainable development.

---

DOI

10.48130/aee-0025-0014 

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

Synergistic photocatalysis of BiOCl/MXene activates peroxymonosulfate for enhanced fulvic acid degradation: performance and mechanism insights

 

Microwave vegetation monitoring gets a climate upgrade

Journal of Remote Sensing

FacebookXLinkedInWeChatBlueskyMessageWhatsAppEmail

 

image: 

 Correlations between the growing-season VPD anomaly and VOD anomalies in China for 2012 to 2022. Correlations of the growing-season anomaly from MODIS NDVI (A), AMSR-E/AMSR2 LPDR X-band (LPDR-X; B), AMSR2 LPRM X-band (LPRM-X; C), AMSR2 LPRM C2-band (LPRM-C2; D), AMSR2 LPRM C1-band (LPRM-C1; E), SMAP operational L-band DCA product (SMAP-DCA; F), SMAP MCCA L-band (MCCA-SMAP; G), and SMOS/SMAP fused L-band VOD product (SMOSMAP-IB; H), with VPD anomaly are shown. Pixels with black dots indicate significant (P < 0.05) correlations. Correlations are estimated from 2012 to 2022, except for SMAP-DCA and MCCA-SMAP, for which correlations are calculated from 2015 to 2022.

view more 

Credit: Journal of Remote Sensing

A new study shows that satellite-based vegetation optical depth, or Vegetation optical depth (VOD), can reveal how plants across China respond to climate stress in very different ways depending on the microwave frequency used. By comparing seven VOD products from 2012 to 2022, researchers found that these signals respond more strongly to water stress than to temperature, and that higher-frequency products are especially effective for detecting short-term vegetation changes. 

Vegetation health is closely tied to climate, but tracking its response over large areas remains difficult. Traditional optical indices such as Normalized Difference Vegetation Index (NDVI) can be affected by cloud cover and atmospheric conditions, while microwave-based Vegetation optical depth (VOD) is more sensitive to changes in vegetation water content and biomass. Even so, scientists have not fully understood how VOD products from different frequencies and retrieval algorithms compare under changing climate conditions. This question is especially important in China, where vegetation greening has accelerated since 2000 and where ecosystems range from humid forests to arid and semiarid landscapes. Based on these challenges, deeper research is needed into how multi-frequency VOD products capture vegetation responses to climate change.

Researchers from Beijing Normal University, Tongji University, INRAE, the University of Montana, NASA Goddard Space Flight Center, Southwest University, and Chalmers University of Technology published the study (DOI: 10.34133/remotesensing.1028) on February 2, 2026, in the Journal of Remote Sensing. The work tackles a practical challenge in Earth observation: selecting the right microwave vegetation signal to monitor how ecosystems respond to heat, atmospheric dryness, and soil water shortage. The findings offer a clearer basis for choosing remote-sensing tools for drought assessment, ecosystem monitoring, and climate-impact studies across China.

The team analyzed seven VOD products spanning X-, C-, and L-band microwave frequencies and found that retrieval frequency mattered more than algorithm choice in explaining differences among products. Across plant functional types, all seven products showed stronger responses to atmospheric and soil water stress than to air temperature, highlighting VOD’s strength for monitoring vegetation water status. X- and C-band VOD products generally captured faster canopy responses and stronger seasonal variation, while L-band products, which penetrate deeper into vegetation, were more sensitive to woody structure and longer-term biomass-related signals. The study also showed that VOD could detect climate carry-over effects, especially in water-limited ecosystems.

The analysis covered China from 2012 to 2022 and focused on seven major plant functional types, including temperate forests, subtropical forests, temperate non-forests, alpine grassland, and three cropland classes. The researchers compared two X-band products, two C-band products, and three L-band products using growing-season anomalies against air temperature, vapor pressure deficit, and surface soil moisture. Among all vegetation types, temperate non-forests stood out as especially water-limited and showed strong positive soil-moisture relationships in X- and C-band VOD products. Across China as a whole, LPDR-X showed the highest positive correlation with soil moisture at r = 0.16, while MCCA-SMAP showed the strongest negative response at r = −0.40, underscoring how differently products can behave. The team also found that including climate conditions from the previous month improved many VOD–climate relationships, particularly for soil moisture, revealing clear one-month carry-over effects in arid and semiarid regions.

Suggested expert quote for press use: “Our results show that VOD is not a single universal indicator. Different frequencies capture different parts of vegetation behavior, and the strongest signal often comes from water stress rather than temperature alone. This means future climate and ecosystem studies can be more precise if they choose the VOD product that best matches the ecological question.” This wording is adapted from the authors’ conclusions.

The study combined seven freely available satellite VOD datasets from AMSR-E, AMSR2, SMAP, and SMOS, covering X-, C-, and L-band microwave observations. All datasets were resampled to 25 km and analyzed during the growing season from April to September. The researchers calculated anomalies relative to monthly climatology and used Pearson correlations to test how VOD changed with temperature, vapor pressure deficit, and soil moisture. They also added a one-month lag analysis to detect carry-over effects from previous climate conditions.

The findings could improve how scientists monitor drought, vegetation water stress, ecosystem resilience, and climate impacts using satellite data. They also suggest that no single VOD product should be used for every application: higher-frequency signals may be better for rapid canopy stress detection, while lower-frequency signals may be more useful for deeper structural changes. As climate extremes intensify, selecting the right microwave product could help refine regional ecological assessment, carbon-cycle research, and early warning systems in vulnerable drylands and agricultural zones.

###

References

DOI

10.34133/remotesensing.1028

Original Source URL

https://spj.science.org/doi/10.34133/remotesensing.1028

Funding Information

This work was funded by the Major Program of the Natural Science Foundation of China (42090013) and the General Programs of the Natural Science Foundation of China (42471352).

About Journal of Remote Sensing

The Journal of Remote Sensing, an online-only Open Access journal published in association with AIR-CAS, promotes the theory, science, and technology of remote sensing, as well as interdisciplinary research within earth and information science.

---

Journal

Journal of Remote Sensing

DOI

10.34133/remotesensing.1028 

Subject of Research

Not applicable

Article Title

Divergent Responses of Multi-frequency Vegetation Optical Depth Products to Climate Variations in China