Compound Drought-heatwave Events are Under-recognized in Global Soils

The soil is essential for life and plays a crucial role in the Earth's ecosystem, providing support for plant roots and hosting countless microorganisms. As the atmosphere warms up, it is important to understand how soil hydrothermal conditions, particularly dry-hot extremes, have changed and will respond.Recently, researchers led by Prof. ZHANG Yunlin from the Nanjing Institute of Geography and Limnology, Chinese Academy of Sciences (NIGLAS), along with collaborators from the Helmholtz-Centre for Environmental Research (UFZ) and Bangor University, have quantified global soil compound drought-heatwave (SCDHW) events from 1980 to 2023 and predicted their evolution until the end of this century.The study was published in Proceedings of the National Academy of Sciences (PNAS) on October 7.In the study, researchers combined three state-of-the-art reanalysis datasets and four Earth System Model datasets to analyze global SCDHW trends and variabilities in the past and future. They also incorporated long-term observational data to enhance their conclusions.The authors showed a global increase in the occurrence, duration, extremeness, severity, and affected area of SCDHWs over the past 44 years. "We observed a notable escalation of SCDHWs from 1980 to 2023, particularly in this century. Global warming took the major responsibility, and the situation worsened in El Niño years. More importantly, the escalation of SCDHWs was concentrated in summer, posing a significant challenge to water security," said Prof. ZHANG Yunlin, corresponding author of the study.They found compound drought-heatwaves in soils were stronger and increased faster than those in the air. "For the sake of data accessibility, we used to express compound drought-heatwaves in terms of meteorological measures such as air temperature. However, this common practice might underestimate the severity of SCDHWs, and the adverse impact on carbon cycle," said Dr. Fan Xingwang, first author of the study.In general, SCDHWs were more intense in the northern hemisphere and longer-lasting in the southern hemisphere. The severity of SCDHWs increased rapidly in the northern high-latitudes, where soil temperatures were typically low and warming was highly pronounced. These events may threaten carbon neutrality goals in the north and food security goals in the south.The degradation of forests and conversion of wetlands to croplands will worsen the severity of SCDHWs. Integrated watershed management requires sustainable policies and actions to protect soils from the risks of desiccation and overheating. "We must continue our efforts to preserve natural ecosystems," said ZHANG.If no action is taken, formidable global SCDHWs will occur by the end of this century, with a mean duration exceeding 70 days and a soil temperature anomaly reaching 10 °C under the SSP5-8.5 emission scenario. “The mean duration of individual SCDHWs will increase substantially, which means that soil biota and plant root systems will struggle to recover from extreme water and heat stresses," said FAN.JOURNALProceedings of the National Academy of SciencesDOI10.1073/pnas.2410294121ARTICLE TITLESurging compound drought-heatwaves underrated in global soilsARTICLE PUBLICATION DATE07-Oct-2024

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Study unveils positive social-ecological transition in Yangtze River Delta, China
2024-04-21

  Social-ecological systems (SES) are complex, dynamic systems with interdependencies between their ecological components and social actors. Studying the transient (e.g., nonlinear) dynamics of interlinked SES can provide valuable insights into achieving the UN Sustainable Development Goals for a more desirable future. 
  However, identifying critical transitions in real-world SES remains a major challenge. A significant knowledge gap exists in index framework for characterizing dynamic behaviors within SES changes. This issue is also compounded by the scarcity of long-term datasets spanning entire transition periods, which together limits our comprehension of the Anthropocene landscape changes. 
  Recently, an international research team led by Dr. LIN Qi and Prof. ZHANG Ke from the Nanjing Institute of Geography and Limnology, Chinese Academy of Sciences made some progresses by advancing an evolutionary framework that utilizes a dynamic metric based on Rate of Change (RoC) derived from multidecadal socioeconomic and geobiophysical (lake sediment) records. These researchers from China, France, Netherlands, Sweden, Italy, United Kingdom, and South Africa worked together, and applied the co-evolutionary framework to Lake Taihu watershed from China’s Yangtze River Delta region. 
  The study was published in Proceedings of the National Academy of Sciences of the United States of America. 
  By integrating sedimentary ancient DNA (sedaDNA) metabarcoding, multi-proxy paleoenvironmental analyses, and socioeconomic data, the researchers elucidated the temporal dynamics of regional SES over several centuries. Starting in the 1950s, the SES underwent a shift towards an interconnected and ecologically unsustainable state, driven by a series of deleterious positive feedbacks. These process exacerbated water eutrophication, soil erosion, air pollution, and ecosystem resilience loss under human stressors. More interestingly, the study revealed a decoupling of socioeconomic development from eco-environmental degradation since the early 2000s, signifying a potentially more sustainable reconfiguration of the regional SES. 
  “Thanks to the wide-ranging environmental laws and policies, conservation and ecological engineering projects, and institutional innovations, the recent decoupling signal discloses a sustainable development pattern not observed over the past millennium in this iconic region”, said Dr. LIN Qi, first author of the study. The signal highlights the crucial role of adaptive management and policy intervention in fostering positive transformations. 
  This case study also provides insights into the resilience and adaptability of regional SES facing similar ecological and environmental stressors. It demonstrates potential strategies for transformative action as outlined under the UN Sustainable Development Goals. “Adopting the co-evolutionary framework to address the complexities of SES dynamics, just like in Lake Taihu case, can offer a blueprint for where and how transformative steps can be taken to achieve a good Anthropocene”, said Prof. ZHANG Ke, corresponding author of the study.
   
  IMAGE: Dynamic changes of intertwined SES from a historical evolutionary perspective. 
  CREDIT by ZHANG KE  
  Website linkage: https://www.pnas.org/doi/10.1073/pnas.2321303121 
  Contact Information 
  Ke Zhang at the Nanjing Institute of Geography and Limnology, Chinese Academy of Sciences
  Email: kzhang@niglas.ac.cn
Researchers Discover “Iron Mesh” Effect to Increase Inorganic Carbon Sequestration
2024-03-29

  Iron (Fe), a crucial component of the Earth's biogeochemical cycle, has a significant impact on global ecology and carbon cycling. Understanding the effect of Fe on the carbon cycle is essential for comprehending biogeochemical processes of carbon and climate change. 
  The traditional view suggests that dissimilatory iron reduction (DIR) can drive the release of organic carbon (OC) as carbon dioxide (CO2) by mediating electron transfer between organic compounds and microbes. However, it is important to note that this view may be subjective and requires further investigation to confirm its validity. 
  A recent study led by Prof. XING Peng from the Nanjing Institute of Geography and Limnology, Chinese Academy Sciences, found that dissolved inorganic carbon (DIC) was crucial for carbon sequestration. DIC affected inorganic-carbon redistribution via iron abiotic-phase transformation. The study was published in Global Change Biology on 18 March. 
  The study discovered that the abiotic and biotic processes at the organic carbon-microbe-mineral interface facilitated CO2 sequestration and reduced its emission by half. The redistribution of inorganic carbon within or among the atmosphere, lithosphere, and hydrosphere is critical for the fate of elevated CO2. 
  Additionally, researchers found that high porosity promoted electron transport and DIR bacteria activity, which can increase the rate of iron reduction. The presence of iron, calcium, and organic carbon in the environment can create a porous sediment structure that facilitates rapid DIR. This environment is conducive to the formation and growth of iron minerals that contain carbonate (ICFe), which can sequester inorganic carbon. The researchers also found that a minimum DIR threshold of 6.65 μmol g-1 dw day-1 was necessary for ICFe formation. 
   The 'OC-microbe-mineral reactions' involved both biotic and abiotic reactions, which improve our understanding of the processes that mediate CO2 sequestration in anoxic subsurface environments such as soils, wetlands, and sediments. Furthermore, modelling studies suggested that microbial iron reduction was more thermodynamically favorable under elevated CO2, which could mitigate the negative impact of elevated CO2 on global warming. 
   "The information can help assess the sequestration of DIC resulting from both abiotic and biotic processes working together. It is also useful for monitoring and managing CO2 sequestration, as well as developing appropriate engineering strategies to remediate CO2 sequestration in these environments," said Prof. XING Peng, corresponding author of the study.
  http://doi.org/10.1111/gcb.17239
   
   Contact TAN Lei Nanjing Institute of Geography and Limnology E-mail: ltan@niglas.ac.cn
Scientists Revealed the Molecular-level Impacts of Global Change on Natural Organic Matter for the First Time
2024-01-18

  Dissolved organic matter (DOM) is the main form and active component of natural organic matter in lakes. DOM acts as a large reservoir of carbon. Furthermore, the processing of different organic compounds in DOM by aquatic organisms can be impacted by changes in temperature, which represents a potential climate feedback loop as the rate of carbon dioxide released into the atmosphere may be slowed or accelerated under higher temperatures. 
  Previous study simplified this complex issue in computational models by classifying different types of DOM into a few categories based on its response (or lack of response) to changing environmental conditions. 
  However, researchers led by Prof. WANG Jianjun from the Nanjing Institute of Geography and Limnology, Chinese Academy Sciences, recently developed an indicator that can be used to quantify the response of individual DOM constituents to changing environmental conditions. The indicator could allow for a more realistic and nuanced representation of DOM environmental responses, as opposed to a simple classification. 
  The study was published in Nature Communications on 17 January. 
  The researchers conducted field experiments on mountainsides of three distinct climate zones in Eurasian continent to assess how temperature affects the composition of DOM. The mountainsides ranged from a subtropical wet environment on the southeastern edge of the Tibetan Plateau, through a temperate arid environment in the northern Tibetan Plateau, to a subarctic environment in Northern Europe. 
  They discovered that individual DOM constituents showed a wide range of temperature responses. The thermal responses of DOM were further found to increase towards warmer conditions such as at low elevations. 
  Also, this warming effect could be strengthened by nutrient enrichment. The warming effect was strengthened by eutrophication, with increased sensitivity of up to 22% for each additional 1 mg L-1 of nitrogen loading. This suggests that the temperature responses of organic matter can be affected by other global change drivers, especially nutrient enrichment in complex ways. 
  Moreover, the research indicated that the thermal responses of individual organic molecules were associated with their chemical properties. Additionally, despite the differences in climate zones, the thermal responses of these molecules showed a remarkable level of consistency. Organic carbon molecules with lower thermodynamic favorability for microbial decomposition exhibited a higher positive response to temperature. Each organic carbon molecule exhibited similar thermal response across the three highly divergent mountain environments. The findings revealed that the responses of molecules to temperature were transferable and generalizable across regional and continental scales. 
  This is the very first application of molecular-level methods to assess the responses of organic matter to global change. The role of DOM in climate feedbacks and the earth system can be properly understood by this work, which will allow us to better prepare for an uncertain future.
  https://doi.org/10.1038/s41467-024-44813-2
  Contact TAN Lei Nanjing Institute of Geography and Limnology E-mail: ltan@niglas.ac.cn
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Synergistic effects of warming and internal nutrient loading interfere with the long-term stability of lake restoration and induce sudden re-eutrophication
2023-02-27

  Urban lakes are globally ubiquitous and are usually highly eutrophic, pointing to an increase in frequency, duration and magnitude of harmful algal blooms as wide-spread threats to ecological and human health. 
  Over half a century, phosphate (P) precipitation is among the most effective treatments to mitigate eutrophication in these lakes. However, after a period of high effectiveness, re-eutrophication would possibly occur leading to the return of harmful algal blooms. While such abrupt ecological changes were presumably attributed to internal P loading, the role of lake warming and its potential synergistic effects with the internal loading, thus far, has been largely understudied. 
  Researchers led by Dr. KONG Xiangzhen and Prof. Dr. XUE Bin from the Nanjing Institute of Geography and Limnology of the Chinese Academy of Sciences, along with their international collaborators, have addressed the question by quantifying the contributions of lake warming and the potential synergistic effects with internal P loading in an urban lake located in central Germany, which suffered from the abrupt re-eutrophication and cyanobacterial blooms in 2016 (30 years after the first P precipitation). 
  Their findings were published in Environmental Science & Technology on Feb. 20. 
  In this study, a process-based lake ecosystem model (GOTM-WET) was established using a high-frequency monitoring dataset covering eutro-/oligo-trophic states over 30 years. 
  Model analyses suggested that, for the abrupt occurrence of cyanobacterial blooms, internal P release accounts for 68% of the biomass proliferation, while lake warming contributed to 32%, including both direct effects via promoting growth (18%) and synergistic effects via intensifying internal P loading (14%). The model further revealed that the synergy was attributed to prolonged lake hypolimnion warming and oxygen depletion. 
  “Our study exemplifies how process-based mechanistic modeling could help to tease apart important drivers of abrupt shifts and cyanobacterial blooms in lakes, particularly in an era of rapid global changes including climate change and human activities.” said Dr. Kong. 
  This study unravels the substantial role of lake warming in promoting cyanobacterial blooms in re-eutrophicated lakes. The indirect effects of warming on cyanobacteria via promoting internal loading need more attention in future lake research and management. 
  “Our findings will have far-reaching consequences for lake restoration and management as the nutrient targets we applied so far to reach or maintain a certain trophic state will not work in a far warmer future and need to be adjusted, i.e. stronger nutrient level reduction and higher efforts in restoration are demanded.” said Dr. Kong.
   
  link: https://pubs.acs.org/doi/10.1021/acs.est.2c07181
   
   
  Contact 
  TAN Lei 
  Nanjing Institute of Geography and Limnology 
  E-mail: ltan@niglas.ac.cn
Sediment organic matter properties facilitate understanding nitrogen transformation potentials in East African lakes
2022-10-20

  East African lakes include the most productive and alkaline lake group in the world. Yet, they generally receive fewer nutrient inputs than the densely populated subtropical and temperate lakes in the northern hemisphere. In these lakes with insufficient supplies of inorganic nitrogen, the mineralization of benthic organic matter can play an important role in driving the nutrient cycle and nitrogen loss. Using a suite of stable 15N isotope dilution and tracer techniques, we examined five main processes of the sediment nitrogen cycle in 16 lakes and reservoirs of Tanzania and Kenya, East Africa: gross nitrogen mineralization, ammonium immobilization, dissimilatory nitrate reduction to ammonium (DNRA), and the dinitrogen (N2) production via denitrification and anaerobic ammonium oxidation (anammox). Gross nitrogen mineralization and ammonium immobilization showed the maximum values of 9.84 and 12.39 μmol N kg-1 h-1 , respectively. Potential DNRA rates ranged from 0.22 to 8.15 μmol N kg-1 h-1 and accounted for 10 %–74 % (average 25 %) of the total dissimilatory nitrate reduction. Potential nitrate reduction rates in most lakes were dominated by denitrification with a contribution of 26 %–85 % and a mean of 65 %. We further found that the sediment nitrogen transformations were driven mainly by benthic organic matter properties and water column phosphate concentrations, reflecting microbial metabolic responses to the changing carbon and nutrients availability. For instance, autochthonous production of protein-like organic matter attributed to active sediment nitrogen mineralization, DNRA, and denitrification. In contrast, the high degree of humification caused by the inputs of terrestrial humic-like substances slowed down the sediment nitrogen transformations. The contribution of DNRA to total dissimilatory nitrate reduction was significantly positively correlated to sediment C: N ratios. These results indicate that predictions of sediment N supply and loss in East African lakes can be improved by incorporating sediment organic matter properties.
  Xiaolong Yao, Zhonghua Zhao, Jianjun Wang, Qiqi Ding, Minglei Ren, Ismael Aaron Kimirei, Lu Zhang, Sediment organic matter properties facilitate understanding nitrogen transformation potentials in East African lakes, Science of The Total Environment, 841, 2022, 156607, https://doi.org/10.1016/j.scitotenv.2022.156607.
A comprehensive evaluation of organic micropollutants (OMPs) pollution and prioritization in equatorial lakes from mainland Tanzania, East Africa
2022-05-17

  A lack of understanding the fate of highly toxic organic micropollutants (OMPs) in the equatorial lakes of Tanzania hinders public awareness for protecting these unique aquatic ecosystems, which are precious water resources and stunning wildlife habitats. To address this knowledge gap, the occurrence of 70 anthropogenically-sourced OMPs, including phthalates (PAEs), polycyclic aromatic hydrocarbons (PAHs), polychlorinated biphenyls (PCBs) and organochlorine pesticides (OCPs), was investigated in the water and sediment of 18 lakes in Tanzania. Similar residue concentrations were found in both compartments, showing higher pollution of PAEs ranging from 835.0 to 13,153.1 ng/L in water and 244.6–8691.8 ng/g dw in sediment, followed by PAHs, while OCPs and PCBs were comparatively lower. According to the multi-criteria scoring method for prioritization, the final OMP priority list for the lake environment in Tanzania comprised 25 chemicals, specifically 5 PAEs (DEHP, DIBP, DBP, DCHP and DMPP), 6 PCBs (PCB153, PCB105, PCB28, PCB156, PCB157 and PCB167), 6 PAHs (BaP, BaA, BbF, Pyr, DahA and InP) and 8 OCPs (cis-chlordane, trans-chlordane, p,p’-DDD, p,p’-DDE, p,p’-DDT, endrin, methoxychlor and heptachlor epoxide), suggesting the key substances for conventional monitoring and pollution control in these equatorial lakes, with an emphasis on PAEs, especially DEHP, due to the top priority and endocrine disruptor properties.
  Zhonghua Zhao, Xiaolong Yao, Qiqi Ding, Xionghu Gong, Jianjun Wang, Saadu Tahir, Ishmael Aaron Kimirei, Lu Zhang, A comprehensive evaluation of organic micropollutants (OMPs) pollution and prioritization in equatorial lakes from mainland Tanzania, East Africa, Water Research, Volume 217, 2022, 118400, ISSN 0043-1354, https://doi.org/10.1016/j.watres.2022.118400.
Re-evaluation of Wetland Carbon Sink Mitigation
2022-03-22

  A new review of coastal and inland wetland carbon sink services reveals current mitigation concepts for greenhouse gas emissions and measurements are not what they seem. Accumulation of buried organic carbon is not a measure of carbon sequestration; stable organic carbon inputs require subtraction and are undervalued; and carbon mitigation from wetland restoration is less than their preservation. 
  The study was published in the journal Wetlands as a flagship Mark Brison Review, from Nanjing Institute of Geography and Limnology, Chinese Academy of Sciences (NIGLAS) in collaboration with Borneo Marine Research Institute (BMRI) Universiti Malaysia Sabah (UMS), and lead by the Institute for Marine and Antarctic Studies (IMAS) University of Tasmania (UTAS).  
  Associate Reseacher Dr John Barry Gallagher (IMAS) said that the sediment organic carbon accumulation down inland and coastal wetlands has always been regarded as a convenient means of measuring trends and average rates of sequestration over climatic scales. Wetlands, however, are open to organic inputs from catchments and adjacent water bodies. These can be labile and easily consumed or decomposed, and recalcitrant outside the carbon loop that is not consumed or decomposed. 
  Consequently, what is required from the sediment record is not the total organic burial, but the burial rate of what remains of the wetlands plant production from the amount of the labile organics inputs consumed, and the remains of those recalcitrants inputs, largely black or pyrogenic carbon. To estimate this we modified a general decomposition model to hindcast the original input rate and to project what remains for all organic sources after 100 years of burial. 
  For a mangrove and a seagrass ecosystem, we found that carbon accumulation was on average 33.5 and 7.2 times greater than their respective sequestration rates. We also noted that sequestration relative to its non-canopy replacement or alternative stable state is not included for voluntary or compliance carbon markets, instead, only the rate of loss and gain of organic stocks for wetlands likely be disturbed or restored. This limitation would otherwise undervalue the wetlands systems mitigation potential with one caveat: the rate of gain in sediment stocks for a restored system is similarly constrained as a mitigation service by consumption and decomposition of those external organic inputs. 
  Dr Gallagher says that the review is important from two standpoints. Firstly, natural carbon sequestration solutions require re-evaluation. This is required to avoid GHG emissions above their capacity or indeed reduce the ability to fulfil Nations’emission targets, as set by COP26. Secondly, the model provides a new Paleoecological tool. It has the potential to measure and predict how wetlands' ability to function as a carbon sink can change with both climate and catchment agricultural and industrial development from changes to government policy.
  Paper link: https://link.springer.com/article/10.1007/s13157-022-01539-5 
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