Showing total 3,814 results

1. Twenty years of successful papers in Global Change Biology.

Author

Menzel, Annette, Matiu, Michael, and Sparks, Tim H.

Subjects

BIOLOGICAL periodicals, ANNIVERSARIES

Abstract

The article mentions the anniversary of the journal "Global Change Biology (GCB)," which has been publishing successful papers related to biology for 20 years.

Published

2014

2. Response to Editor to the comment by Schipper & Smith to our paper entitled "Continuous soil carbon storage of old permanent pastures in Amazonia".

Author

Fontaine S, Stahl C, Klumpp K, Picon-Cochard C, Grise MM, Dezécache C, Ponchant L, Freycon V, Blanc L, Bonal D, Burban B, Soussana JF, Blanfort V, and Alvarez G

Subjects

China, Grassland, Carbon analysis, Soil

Published

2018

3. Response to Editor to the comment by Delarue (2016) to our paper entitled 'Persistent high temperature and low precipitation reduce peat carbon accumulation'.

Author

Bragazza L, Buttler A, Robroek BJM, Albrecht R, Zaccone C, Jassey VEJ, and Signarbieux C

Subjects

Carbon Cycle, Temperature, Wetlands, Carbon, Soil

Published

2017

4. Decomposition ofBetula papyriferaleaf litter under the independent and interactive effects of elevated CO2 and O3.

Author

Parsons, William F. J., Lindroth, Richard L., and Bockheim, James G.

Subjects

*PAPER birch, *BIOTIC communities, *ECOLOGY, *BIOLOGY, *BIODEGRADATION, *CARBON dioxide

Abstract

Litter decay dynamics of paper birch (Betula papyrifera) were assessed at the Aspen free-air CO2 enrichment (FACE) facility in northern Wisconsin, USA. Leaf litter was decomposed for 12 months under factorial combinations of 360 vs. 560 μL CO2 L−1, crossed with 36 vs. 55 nL O3 L−1. To differentiate between substrate quality and environment effects, litterbags were placed in their Native Plots of origin or transplanted into the other treatments. CO2 enrichment, regardless of O3 concentration, produced poorer quality litter (high C/N, lignin/N and condensed tannins) than did ambient CO2 (low C/N, lignin/N and condensed tannins). Substrate quality differences were reflected in the mass loss rates (k-values), which were high for litter generated under ambient CO2 (0.887 year−1) and low for litter generated under elevated CO2 (0.674 year−1). The rate-retarding effects of CO2 enrichment were neither alleviated nor exacerbated by O3 exposure. Decay rates varied, however, depending on whether litter was placed back into its plot of origin or transplanted to Common Gardens. The results of this study are species specific, but they have important implications for understanding the processes regulating storage of fixed C and the release of CO2 from northern forest ecosystems. [ABSTRACT FROM AUTHOR]

Published

2004

5. Elevated CO2 influences the responses of two birch species to soil moisture: implications for forest community structure.

Author

Catovsky, S. and Bazzaz, F. A.

Subjects

CARBON dioxide & the environment, EFFECT of soil moisture on plants, PAPER birch, YELLOW birch

Abstract

AbstractIncreased levels of atmospheric CO2 may alter the structure and composition of plant communities by affecting how species respond to their physical and biological environment. We investigated how elevated CO2 influenced the response of paper birch ( Betula papyrifera Marsh.) and yellow birch (Betula alleghaniensis Britt.) seedlings to variation in soil moisture. Seedlings were grown for four months on a soil moisture gradient, individually and in mixed species stands, in controlled environment facilities at ambient (375 μL L–1) and elevated (700 μL L–1) atmospheric CO2. For both individually and competitively grown paper birch seedlings, there was a greater CO2 growth enhancement for seedlings watered less frequently than for well-watered seedlings. This differential change in CO2 responsiveness across the moisture gradient reduced the difference in seedling growth between high and low water levels and effectively broadened the regeneration niche of paper birch. In contrast, for yellow birch seedlings, elevated CO2 only produced a significant growth enhancement at the wet end of the soil moisture gradient, and increased the size difference between seedlings at the two ends of the gradient. Gas exchange measurements showed that paper birch seedlings were more sensitive than yellow birch seedlings to declines in soil moisture, and that elevated CO2 reduced this sensitivity. Additionally, elevated CO2 improved survival of yellow birch seedlings growing in competition with paper birch in dry stands. Thus, elevated CO2 may influence regeneration patterns of paper birch and yellow birch on sites of differing soil moisture. In the future, as atmospheric CO2 levels rise, growth of paper birch seedlings and survival of yellow birch seedlings may be enhanced on xeric sites, while yellow birch may show improved growth on mesic sites. [ABSTRACT FROM AUTHOR]

Published

1999

6. Progress and opportunities in advancing near‐term forecasting of freshwater quality.

Author

Lofton, Mary E., Howard, Dexter W., Thomas, R. Quinn, and Carey, Cayelan C.

Subjects

WATER quality, CLIMATE change, FORECASTING methodology, WATER quality management, FORECASTING

Abstract

Near‐term freshwater forecasts, defined as sub‐daily to decadal future predictions of a freshwater variable with quantified uncertainty, are urgently needed to improve water quality management as freshwater ecosystems exhibit greater variability due to global change. Shifting baselines in freshwater ecosystems due to land use and climate change prevent managers from relying on historical averages for predicting future conditions, necessitating near‐term forecasts to mitigate freshwater risks to human health and safety (e.g., flash floods, harmful algal blooms) and ecosystem services (e.g., water‐related recreation and tourism). To assess the current state of freshwater forecasting and identify opportunities for future progress, we synthesized freshwater forecasting papers published in the past 5 years. We found that freshwater forecasting is currently dominated by near‐term forecasts of water quantity and that near‐term water quality forecasts are fewer in number and in the early stages of development (i.e., non‐operational) despite their potential as important preemptive decision support tools. We contend that more freshwater quality forecasts are critically needed and that near‐term water quality forecasting is poised to make substantial advances based on examples of recent progress in forecasting methodology, workflows, and end‐user engagement. For example, current water quality forecasting systems can predict water temperature, dissolved oxygen, and algal bloom/toxin events 5 days ahead with reasonable accuracy. Continued progress in freshwater quality forecasting will be greatly accelerated by adapting tools and approaches from freshwater quantity forecasting (e.g., machine learning modeling methods). In addition, future development of effective operational freshwater quality forecasts will require substantive engagement of end users throughout the forecast process, funding, and training opportunities. Looking ahead, near‐term forecasting provides a hopeful future for freshwater management in the face of increased variability and risk due to global change, and we encourage the freshwater scientific community to incorporate forecasting approaches in water quality research and management. [ABSTRACT FROM AUTHOR]

Published

2023

7. Ectomycorrhizal fungal response to warming is linked to poor host performance at the boreal-temperate ecotone.

Author

Fernandez, Christopher W., Nguyen, Nhu H., Stefanski, Artur, Han, Ying, Hobbie, Sarah E., Montgomery, Rebecca A., Reich, Peter B., and Kennedy, Peter G.

Subjects

ECTOMYCORRHIZAL fungi, ECOTONES, PAPER birch, BALSAM fir, TAIGAS

Abstract

Rising temperatures associated with climate change have been shown to negatively affect the photosynthetic rates of boreal forest tree saplings at their southern range limits. To quantify the responses of ectomycorrhizal ( EM) fungal communities associated with poorly performing hosts, we sampled the roots of Betula papyrifera and Abies balsamea saplings growing in the B4Warmed (Boreal Forest Warming at an Ecotone in Danger) experiment. EM fungi on the root systems of both hosts were compared from ambient and +3.4 °C air and soil warmed plots at two sites in northern Minnesota. EM fungal communities were assessed with high-throughput sequencing along with measures of plant photosynthesis, soil temperature, moisture, and nitrogen. Warming selectively altered EM fungal community composition at both the phylum and genus levels, but had no significant effect on EM fungal operational taxonomic unit ( OTU) diversity. Notably, warming strongly favored EM Ascomycetes and EM fungi with short-contact hyphal exploration types. Declining host photosynthetic rates were also significantly inversely correlated with EM Ascomycete and EM short-contact exploration type abundance, which may reflect a shift to less carbon demanding fungi due to lower photosynthetic capacity. Given the variation in EM host responses to warming, both within and between ecosystems, better understanding the link between host performance and EM fungal community structure will to clarify how climate change effects cascade belowground. [ABSTRACT FROM AUTHOR]

Published

2017

8. Radial growth response of four dominant boreal tree species to climate along a latitudinal gradient in the eastern Canadian boreal forest.

Author

JIANGUO HUANG, TARDIF, JACQUES C., BERGERON, YVES, DENNELER, BERNHARD, BERNINGER, FRANK, and GIRARDIN, MARTIN P.

Subjects

TREE growth, CLIMATE change, GLOBAL warming, HIGH temperatures, STATISTICAL correlation, TAIGAS, PAPER birch, FORESTS & forestry

Abstract

To address the central question of how climate change influences tree growth within the context of global warming, we used dendroclimatological analysis to understand the reactions of four major boreal tree species – Populus tremuloides, Betula papyrifera, Picea mariana, and Pinus banksiana– to climatic variations along a broad latitudinal gradient from 46 to 54°N in the eastern Canadian boreal forest. Tree-ring chronologies from 34 forested stands distributed at a 1° interval were built, transformed into principal components (PCs), and analyzed through bootstrapped correlation analysis over the period 1950–2003 to identify climate factors limiting the radial growth and the detailed radial growth–climate association along the gradient. All species taken together, previous summer temperature (negative influences), and current January and March–April temperatures (positive influences) showed the most consistent relationships with radial growth across the gradient. Combined with the identified species/site-specific climate factors, our study suggested that moisture conditions during the year before radial growth played a dominant role in positively regulating P. tremuloides growth, whereas January temperature and growing season moisture conditions positively impacted growth of B. papyrifera. Both P. mariana and P. banksiana were positively affected by the current-year winter and spring or whole growing season temperatures over the entire range of our corridor. Owing to the impacts of different climate factors on growth, these boreal species showed inconsistent responsiveness to recent warming at the transition zone, where B. papyrifera, P. mariana, and P. banksiana would be the most responsive species, whereas P. tremuloides might be the least. Under continued warming, B. papyrifera stands located north of 49°N, P. tremuloides at northern latitudes, and P. mariana and P. banksiana stands located north of 47°N might benefit from warming winter and spring temperatures to enhance their radial growth in the coming decades, whereas other southern stands might be decreasing in radial growth. [ABSTRACT FROM AUTHOR]

Published

2010

9. Trends in seedling growth and carbon-use efficiency vary among broadleaf tree species along a latitudinal transect in eastern North America.

Author

Dillaway, Dylan N. and Kruger, Eric L.

Subjects

SEEDLINGS, POPULUS tremuloides, PAPER birch, COTTONWOOD, SWEETGUM, TAIGAS, DECIDUOUS plants

Abstract

Factors constraining the geographic ranges of broadleaf tree species in eastern North America were examined in common gardens along a ~1500 km latitudinal transect travers in grange boundaries of four target species: trembling aspen ( Populus tremuloides) and paper birch ( Betula papyrifera) to the north vs. eastern cottonwood ( Populus deltoides) and sweet gum ( Liquidambar styraciflua) to the south. In 2006 and 2007, carbon-use efficiency ( CUE), the proportion of assimilated carbon retained in biomass, was estimated for seedlings of the four species as the quotient of relative growth rate ( RGR) and photosynthesis per unit tree mass ( Atree). In aspen and birch, CUE and RGR declined significantly with increasing growth temperature, which spanned 9 °C across gardens and years. The 37% (relative) CUE decrease from coolest to warmest garden correlated with increases in leaf nighttime respiration ( Rleaf) and the ratio of Rleaf to leaf photosynthesis ( R%A). For cottonwood and sweet gum, however, similar increases in Rleaf and R%A accompanied modest CUE declines, implying that processes other than Rleaf were responsible for species differences in CUE's temperature response. Our findings illustrate marked taxonomic variation, at least among young trees, in the thermal sensitivity of CUE, and point to potentially negative consequences of climate warming for the carbon balance, competitive ability, and persistence of two foundation species in northern temperate and boreal forests. [ABSTRACT FROM AUTHOR]

Published

2014

10. Decomposition ofBetula papyriferaleaf litter under the independent and interactive effects of elevated CO2 and O3.

Author

Parsons, William F. J., Lindroth, Richard L., and Bockheim, James G.

Subjects

PAPER birch, BIOTIC communities, ECOLOGY, BIOLOGY, BIODEGRADATION, CARBON dioxide

Abstract

Litter decay dynamics of paper birch (Betula papyrifera) were assessed at the Aspen free-air CO2 enrichment (FACE) facility in northern Wisconsin, USA. Leaf litter was decomposed for 12 months under factorial combinations of 360 vs. 560 μL CO2 L−1, crossed with 36 vs. 55 nL O3 L−1. To differentiate between substrate quality and environment effects, litterbags were placed in their Native Plots of origin or transplanted into the other treatments. CO2 enrichment, regardless of O3 concentration, produced poorer quality litter (high C/N, lignin/N and condensed tannins) than did ambient CO2 (low C/N, lignin/N and condensed tannins). Substrate quality differences were reflected in the mass loss rates (k-values), which were high for litter generated under ambient CO2 (0.887 year−1) and low for litter generated under elevated CO2 (0.674 year−1). The rate-retarding effects of CO2 enrichment were neither alleviated nor exacerbated by O3 exposure. Decay rates varied, however, depending on whether litter was placed back into its plot of origin or transplanted to Common Gardens. The results of this study are species specific, but they have important implications for understanding the processes regulating storage of fixed C and the release of CO2 from northern forest ecosystems. [ABSTRACT FROM AUTHOR]

Published

2004

11. Stem wood properties ofPopulus tremuloides,Betula papyriferaandAcer saccharumsaplings after 3 years of treatments to elevated carbon dioxide and ozone.

Author

Kaakinen, Seija, Kostiainen, Katri, Ek, Fredrik, Saranpää, Pekka, Kubiske, Mark E., Sober, Jaak, Karnosky, David F., and Vapaavuori, Elina

Subjects

CARBON dioxide, OZONE, WOOD chemistry, POPULUS tremuloides, PAPER birch, SUGAR maple, LIGNINS

Abstract

The aim of this study was to examine the effects of elevated carbon dioxide [CO2] and ozone [O3] and their interaction on wood chemistry and anatomy of five clones of 3-year-old trembling aspen (Populus tremuloides Michx.). Wood chemistry was studied also on paper birch (Betula papyrifera Marsh.) and sugar maple (Acer saccharum Marsh.) seedling-origin saplings of the same age. Material for the study was collected from the Aspen Free-Air CO2 Enrichment (FACE) experiment in Rhinelander, WI, USA, where the saplings had been exposed to four treatments: control (C; ambient CO2, ambient O3), elevated CO2 (560ppm during daylight hours), elevated O3 (1.5 × ambient during daylight hours) and their combination (CO2 + O3) for three growing seasons (1998–2000). Wood chemistry responses to the elevated CO2 and O3 treatments differed between species. Aspen was most responsive, while maple was the least responsive of the three tree species. Aspen genotype affected the responses of wood chemistry and, to some extent, wood structure to the treatments. The lignin concentration increased under elevated O3 in four clones of aspen and in birch. However, elevated CO2 ameliorated the effect. In two aspen clones, nitrogen in wood samples decreased under combined exposure to CO2 and O2. Soluble sugar concentration in one aspen clone and starch concentration in two clones were increased by elevated CO2. In aspen wood, α-cellulose concentration changed under elevated CO2, decreasing under ambient 03 and slightly increasing under elevated O3. Hemicellulose concentration in birch was decreased by elevated CO2 and increased by elevated O3. In aspen, elevated O3 induced statistically significant reductions in distance from the pith to the bark and vessel lumen diameter, as well as increased wall thickness and wall percentage, and in one clone, decreased fibre lumen diameter. Our results show that juvenile wood properties of broadleaves, depending on species and genotype, were altered by atmospheric gas concentrations predicted for the year 2050 and that CO2 ameliorates some adverse effects of elevated O3 on wood chemistry. [ABSTRACT FROM AUTHOR]

Published

2004

12. Enhanced summer warming reduces fungal decomposer diversity and litter mass loss more strongly in dry than in wet tundra.

Author

Christiansen, Casper T., Haugwitz, Merian S., Priemé, Anders, Nielsen, Cecilie S., Elberling, Bo, Michelsen, Anders, Grogan, Paul, and Blok, Daan

Subjects

WINTER, CARBON, FUNGI, PAPER birch, ECOSYSTEM dynamics

Abstract

Many Arctic regions are currently experiencing substantial summer and winter climate changes. Litter decomposition is a fundamental component of ecosystem carbon and nutrient cycles, with fungi being among the primary decomposers. To assess the impacts of seasonal climatic changes on litter fungal communities and their functioning, Betula glandulosa leaf litter was surface-incubated in two adjacent low Arctic sites with contrasting soil moisture regimes: dry shrub heath and wet sedge tundra at Disko Island, Greenland. At both sites, we investigated the impacts of factorial combinations of enhanced summer warming (using open-top chambers; OTCs) and deepened snow (using snow fences) on surface litter mass loss, chemistry and fungal decomposer communities after approximately 1 year. Enhanced summer warming significantly restricted litter mass loss by 32% in the dry and 17% in the wet site. Litter moisture content was significantly reduced by summer warming in the dry, but not in the wet site. Likewise, fungal total abundance and diversity were reduced by OTC warming at the dry site, while comparatively modest warming effects were observed in the wet site. These results suggest that increased evapotranspiration in the OTC plots lowered litter moisture content to the point where fungal decomposition activities became inhibited. In contrast, snow addition enhanced fungal abundance in both sites but did not significantly affect litter mass loss rates. Across sites, control plots only shared 15% of their fungal phylotypes, suggesting strong local controls on fungal decomposer community composition. Nevertheless, fungal community functioning (litter decomposition) was negatively affected by warming in both sites. We conclude that although buried soil organic matter decomposition is widely expected to increase with future summer warming, surface litter decay and nutrient turnover rates in both xeric and relatively moist tundra are likely to be significantly restricted by the evaporative drying associated with warmer air temperatures. [ABSTRACT FROM AUTHOR]

Published

2017

13. Corrigendum.

Subjects

ATTENUATION coefficients, ABSOLUTE value

Published

2020

14. Land‐use change and biodiversity: Challenges for assembling evidence on the greatest threat to nature.

Author

Davison, Charles W., Rahbek, Carsten, and Morueta‐Holme, Naia

Subjects

ENDANGERED species, ECOSYSTEM health, RESEARCH methodology, VITAL statistics, WILDLIFE conservation, BIODIVERSITY, SPECIES diversity

Abstract

Land‐use change is considered the greatest threat to nature, having caused worldwide declines in the abundance, diversity, and health of species and ecosystems. Despite increasing research on this global change driver, there are still challenges to forming an effective synthesis. The estimated impact of land‐use change on biodiversity can depend on location, research methods, and taxonomic focus, with recent global meta‐analyses reaching disparate conclusions. Here, we critically appraise this research body and our ability to reach a reliable consensus. We employ named entity recognition to analyze more than 4000 abstracts, alongside full reading of 100 randomly selected papers. We highlight the broad range of study designs and methodologies used; the most common being local space‐for‐time comparisons that classify land use in situ. Species metrics including abundance, distribution, and diversity were measured more frequently than complex responses such as demography, vital rates, and behavior. We identified taxonomic biases, with vertebrates well represented while detritivores were largely missing. Omitting this group may hinder our understanding of how land‐use change affects ecosystem feedback. Research was heavily biased toward temperate forested biomes in North America and Europe, with warmer regions being acutely underrepresented despite offering potential insights into the future effects of land‐use change under novel climates. Various land‐use histories were covered, although more research in understudied regions including Africa and the Middle East is required to capture regional differences in the form of current and historical land‐use practices. Failure to address these challenges will impede our global understanding of land‐use change impacts on biodiversity, limit the reliability of future projections and have repercussions for the conservation of threatened species. Beyond identifying literature biases, we highlight the research priorities and data gaps that need urgent attention and offer perspectives on how to move forward. [ABSTRACT FROM AUTHOR]

Published

2021

15. Challenging claimed benefits of soil carbon sequestration for mitigating climate change and increasing crop yields: Heresy or sober realism?

Author

Powlson, David S. and Galdos, Marcelo V.

Subjects

CARBON sequestration, CROP yields, CARBON in soils, CLIMATE change mitigation, CLIMATE change, NO-tillage

Abstract

This is a commentary on the paper in GCB by Moinet et al. (2023) entitled "Carbon for soils, not soils for carbon". The paper challenges two claims often made for soil carbon sequestration: (1) Sequestration of C in agricultural soils can make a substantial contribution to climate change mitigation. (2) Increasing SOC will routinely lead to increased crop yields and contribute to global food security. [ABSTRACT FROM AUTHOR]

Published

2023

16. How ecologists define drought, and why we should do better.

Author

Slette, Ingrid J., Post, Alison K., Awad, Mai, Even, Trevor, Punzalan, Arianna, Williams, Sere, Smith, Melinda D., and Knapp, Alan K.

Subjects

DROUGHT management, DROUGHTS, ECOLOGISTS, ECOSYSTEM dynamics, SOIL moisture, LITERATURE reviews, DROUGHT forecasting

Abstract

Drought, widely studied as an important driver of ecosystem dynamics, is predicted to increase in frequency and severity globally. To study drought, ecologists must define or at least operationalize what constitutes a drought. How this is accomplished in practice is unclear, particularly given that climatologists have long struggled to agree on definitions of drought, beyond general variants of "an abnormal deficiency of water." We conducted a literature review of ecological drought studies (564 papers) to assess how ecologists describe and study drought. We found that ecologists characterize drought in a wide variety of ways (reduced precipitation, low soil moisture, reduced streamflow, etc.), but relatively few publications (~32%) explicitly define what are, and are not, drought conditions. More troubling, a surprising number of papers (~30%) simply equated "dry conditions" with "drought" and provided little characterization of the drought conditions studied. For a subset of these, we calculated Standardized Precipitation Evapotranspiration Index values for the reported drought periods. We found that while almost 90% of the studies were conducted under conditions quantifiable as slightly to extremely drier than average, ~50% were within the range of normal climatic variability. We conclude that the current state of the ecological drought literature hinders synthesis and our ability to draw broad ecological inferences because drought is often declared but is not explicitly defined or well characterized. We suggest that future drought publications provide at least one of the following: (a) the climatic context of the drought period based on long‐term records; (b) standardized climatic index values; (c) published metrics from drought‐monitoring organizations; (d) a quantitative definition of what the authors consider to be drought conditions for their system. With more detailed and consistent quantification of drought conditions, comparisons among studies can be more rigorous, increasing our understanding of the ecological effects of drought. [ABSTRACT FROM AUTHOR]

Published

2019

17. Interface processes between protected and unprotected areas: A global review and ways forward.

Author

Blanco, Julien, Bellón, Beatriz, Fabricius, Christo, O. Roque, Fabio, Pays, Olivier, Laurent, François, Fritz, Hervé, and Renaud, Pierre‐Cyril

Subjects

SCIENTIFIC literature, PROTECTED areas, KNOWLEDGE gap theory, LITERATURE reviews, ECOSYSTEM services, BIODIVERSITY conservation, FOREST canopy gaps

Abstract

Land‐use changes and the expansion of protected areas (PAs) have amplified the interaction between protected and unprotected areas worldwide. In this context, 'interface processes' (human–nature and cross‐boundary interactions inside and around PAs) have become central to issues around the conservation of biodiversity and ecosystem services. This scientific literature review aimed to explore current knowledge and research gaps on interface processes regarding terrestrial PAs. At first, 3,515 references related to the topic were extracted through a standardized search on the Web of Science and analyzed with scientometric techniques. Next, a full‐text analysis was conducted on a sample of 240 research papers. A keyword analysis revealed a wide diversity of research topics, from 'pure' ecology to sociopolitical research. We found a bias in the geographical distribution of research, with half the papers focusing on eight countries. Additionally, we found that the spatial extent of cross‐boundary interactions was rarely assessed, preventing any clear delimitation of PA interactive zones. In the 240 research papers we scanned, we identified 403 processes that were studied. The ecological effects of PAs were well documented and appeared to be positive overall. In contrast, the effects of PAs on local communities were understudied and, according to the literature focusing on these, were very variable according to local contexts. Our findings highlight key research advances on interface processes, especially regarding the ecological outcomes of PAs, the influence of human activities on biodiversity, and PA governance issues. In contrast, main knowledge gaps concern the spatial extent of interactive zones, as well as the interactions between local people and conservation actions and how to promote synergies between them. While the review was limited to terrestrial PAs, its findings allow us to propose research priorities for tackling environmental and socioeconomic challenges in the face of a rapidly changing world. [ABSTRACT FROM AUTHOR]

Published

2020

18. Carbon sequestration in soils and climate change mitigation—Definitions and pitfalls.

Author

Don, Axel, Seidel, Felix, Leifeld, Jens, Kätterer, Thomas, Martin, Manuel, Pellerin, Sylvain, Emde, David, Seitz, Daria, and Chenu, Claire

Subjects

*CLIMATE change mitigation, *CARBON sequestration, *CARBON in soils, *GREENHOUSE gases, *CLIMATE change, *GAS leakage

Abstract

The term carbon (C) sequestration has not just become a buzzword but is something of a siren's call to scientific communicators and media outlets. Carbon sequestration is the removal of C from the atmosphere and the storage, for example, in soil. It has the potential to partially compensate for anthropogenic greenhouse gas emissions and is, therefore, an important piece in the global climate change mitigation puzzle. However, the term C sequestration is often used misleadingly and, while likely unintentional, can lead to the perpetuation of biased conclusions and exaggerated expectations about its contribution to climate change mitigation efforts. Soils have considerable potential to take up C but many are also in a state of continuous loss. In such soils, measures to build up soil C may only lead to a reduction in C losses (C loss mitigation) rather than result in real C sequestration and negative emissions. In an examination of 100 recent peer‐reviewed papers on topics surrounding soil C, only 4% were found to have used the term C sequestration correctly. Furthermore, 13% of the papers equated C sequestration with C stocks. The review, further, revealed that measures leading to C sequestration will not always result in climate change mitigation when non‐CO2 greenhouse gases and leakage are taken into consideration. This paper highlights potential pitfalls when using the term C sequestration incorrectly and calls for accurate usage of this term going forward. Revised and new terms are suggested to distinguish clearly between C sequestration in soils, SOC loss mitigation, negative emissions, climate change mitigation, SOC storage, and SOC accrual to avoid miscommunication among scientists and stakeholder groups in future. [ABSTRACT FROM AUTHOR]

Published

2024

19. Climate change and deer in boreal and temperate regions: From physiology to population dynamics and species distributions.

Author

Felton, Annika M., Wam, Hilde Karine, Borowski, Zbigniew, Granhus, Aksel, Juvany, Laura, Matala, Juho, Melin, Markus, Wallgren, Märtha, and Mårell, Anders

Subjects

*FALLOW deer, *ROE deer, *RED deer, *SIKA deer, *EXTREME weather, *MULE deer, *DEER

Abstract

Climate change causes far‐reaching disruption in nature, where tolerance thresholds already have been exceeded for some plants and animals. In the short term, deer may respond to climate through individual physiological and behavioral responses. Over time, individual responses can aggregate to the population level and ultimately lead to evolutionary adaptations. We systematically reviewed the literature (published 2000–2022) to summarize the effect of temperature, rainfall, snow, combined measures (e.g., the North Atlantic Oscillation), and extreme events, on deer species inhabiting boreal and temperate forests in terms of their physiology, spatial use, and population dynamics. We targeted deer species that inhabit relevant biomes in North America, Europe, and Asia: moose, roe deer, wapiti, red deer, sika deer, fallow deer, white‐tailed deer, mule deer, caribou, and reindeer. Our review (218 papers) shows that many deer populations will likely benefit in part from warmer winters, but hotter and drier summers may exceed their physiological tolerances. We found support for deer expressing both morphological, physiological, and behavioral plasticity in response to climate variability. For example, some deer species can limit the effects of harsh weather conditions by modifying habitat use and daily activity patterns, while the physiological responses of female deer can lead to long‐lasting effects on population dynamics. We identified 20 patterns, among which some illustrate antagonistic pathways, suggesting that detrimental effects will cancel out some of the benefits of climate change. Our findings highlight the influence of local variables (e.g., population density and predation) on how deer will respond to climatic conditions. We identified several knowledge gaps, such as studies regarding the potential impact on these animals of extreme weather events, snow type, and wetter autumns. The patterns we have identified in this literature review should help managers understand how populations of deer may be affected by regionally projected futures regarding temperature, rainfall, and snow. [ABSTRACT FROM AUTHOR]

Published

2024

20. Adaptation to climate change and limits in food production systems: Physics, the chemistry of biology, and human behavior.

Author

Nelson, Gerald C., Cheung, William W. L., Bezner Kerr, Rachel, Franke, James, Meza, Francisco, Oyinlola, Muhammed A., Thornton, Philip, and Zabel, Florian

Subjects

*CLIMATE change adaptation, *AGRICULTURAL climatology, *POLITICAL ecology, *CLIMATE change, *HUMAN behavior

Abstract

Are there limits to our ability to adapt food systems to climate change? This overview paper for the special issue highlights results of research on potential limits and responses by food system actors. Responses are shaped by the critical interactions among the physical, chemical, biological, and social impacts in food systems arising from climate change. Food grains, temperate perennials, livestock, and oceanic capture fisheries and farming are covered. Climate change impacts on the biology of plants, animals, and humans, as well as the options for societal responses are explored. The results show where and how possible adaptations will be limited. [ABSTRACT FROM AUTHOR]

Published

2024

21. Correction to "Simulating carbon accumulation and loss in the central Congo peatlands".

Subjects

*PEATLANDS, *PALMS, *CARBON, *WOOD decay, *MATERIALS testing, *WATER levels

Abstract

The article titled "Correction to 'Simulating carbon accumulation and loss in the central Congo peatlands'" by Young et al. (2023) acknowledges a coding error in the indexing of peat decay parameters in their model. The error resulted in incorrect values being assigned to some parameters. The authors provide the corrected values in Table 1 and state that the discussion and conclusion of their paper remain unchanged. The revised main simulation shows that 56% of the peat accumulated before the climatic dry phase was lost, compared to the previously reported 57%. The updated simulation also aligns well with the age-depth curve from Garcin et al. (2022). The revised paper includes updated figures and values in the abstract, table, results, and discussion sections. [Extracted from the article]

Published

2024

22. Correction to "Cover crops do not increase soil organic carbon stocks as much as has been claimed: What is the way forward?".

Subjects

*COVER crops, *CATCH crops, *CARBON in soils, *CASH crops, *ORGANIC farming, *NITROGEN in soils

Abstract

The article titled "Correction to 'Cover crops do not increase soil organic carbon stocks as much as has been claimed: What is the way forward?'" by Chaplot and Smith discusses an error in their previous paper regarding the impact of cover crops on soil organic carbon stocks. They maintain their central conclusion that current studies do not provide sufficient reliable data to determine the impact of cover crops on soil organic carbon stocks. They also provide suggestions for future experiments in this area. The article includes a table listing research papers on the impact of cover crops on organic carbon stocks, with details about the authors, publication year, and additional notes about each paper. The authors acknowledge an error in the table and apologize for it. [Extracted from the article]

Published

2024

23. It's time to broaden what we consider a 'blue carbon ecosystem'.

Author

James, Kelly, Macreadie, Peter I., Burdett, Heidi L., Davies, Ian, and Kamenos, Nicholas A.

Subjects

*CORAL reefs & islands, *TIDAL flats, *ECOSYSTEMS, *SALT marshes, *CARBON cycle, *MANGROVE forests, *MARINE ecology, *SEAGRASSES

Abstract

Photoautotrophic marine ecosystems can lock up organic carbon in their biomass and the associated organic sediments they trap over millennia and are thus regarded as blue carbon ecosystems. Because of the ability of marine ecosystems to lock up organic carbon for millennia, blue carbon is receiving much attention within the United Nations' 2030 Agenda for Sustainable Development as a nature‐based solution (NBS) to climate change, but classically still focuses on seagrass meadows, mangrove forests, and tidal marshes. However, other coastal ecosystems could also be important for blue carbon storage, but remain largely neglected in both carbon cycling budgets and NBS strategic planning. Using a meta‐analysis of 253 research publications, we identify other coastal ecosystems—including mud flats, fjords, coralline algal (rhodolith) beds, and some components or coral reef systems—with a strong capacity to act as blue carbon sinks in certain situations. Features that promote blue carbon burial within these 'non‐classical' blue carbon ecosystems included: (1) balancing of carbon release by calcification via carbon uptake at the individual and ecosystem levels; (2) high rates of allochthonous organic carbon supply because of high particle trapping capacity; (3) high rates of carbon preservation and low remineralization rates; and (4) location in depositional environments. Some of these features are context‐dependent, meaning that these ecosystems were blue carbon sinks in some locations, but not others. Therefore, we provide a universal framework that can evaluate the likelihood of a given ecosystem to behave as a blue carbon sink for a given context. Overall, this paper seeks to encourage consideration of non‐classical blue carbon ecosystems within NBS strategies, allowing more complete blue carbon accounting. [ABSTRACT FROM AUTHOR]

Published

2024

24. Spatially explicit estimate of nitrogen effects on soil respiration across the globe.

Author

Liu, Yang, Men, Mingxin, Peng, Zhengping, Chen, Han Y. H., Yang, Yuanhe, and Peng, Yunfeng

Subjects

SOIL respiration, NITROGEN in soils, MICROBIAL respiration, AGRICULTURE, ATMOSPHERIC deposition

Abstract

Soil respiration (Rs), as the second largest flux of carbon dioxide (CO2) between terrestrial ecosystems and the atmosphere, is vulnerable to global nitrogen (N) enrichment. However, the global distribution of the N effects on Rs remains uncertain. Here, we compiled a new database containing 1282 observations of Rs and its heterotrophic component (Rh) in field N manipulative experiments from 317 published papers. Using this up‐to‐date database, we first performed a formal meta‐analysis to explore the responses of Rs and Rh to N addition, and then presented a global spatially explicit quantification of the N effects using a Random Forest model. Our results showed that experimental N addition significantly increased Rs but had a minimal impact on Rh, not supporting the prevailing view that N enrichment inhibits soil microbial respiration. For the major biomes, the magnitude of N input was the main determinant of the spatial variation in Rs response, while the most important predictors for Rh response were biome specific. Based on the key predictors, global mapping visually demonstrated a positive N effect in the regions with higher anthropogenic N inputs (i.e., atmospheric N deposition and agricultural fertilization). Overall, our analysis not only provides novel insight into the N effects on soil CO2 fluxes, but also presents a spatially explicit assessment of the N effects at the global scale, which are pivotal for understanding ecosystem carbon dynamics in future scenarios with more frequent anthropogenic activities. [ABSTRACT FROM AUTHOR]

Published

2023

25. Global variations and controlling factors of anammox rates.

Author

Yao, Yanzhong, Han, Bingbing, Liu, Bin, Wang, Yini, Su, Xiaoxuan, Ma, Lihua, Zhang, Tong, Niu, Shuli, Chen, Xinping, and Li, Zhaolei

Subjects

WETLAND soils, STRUCTURAL equation modeling, EARTH currents, SOIL moisture, NITROUS oxide

Abstract

Soil anammox is an environmentally friendly way to eliminate reactive nitrogen (N) without generating nitrous oxide. Nevertheless, the current earth system models have not incorporated the anammox due to the lack of parameters in anammox rates on a global scale, limiting the accurate projection for N cycling. A global synthesis with 1212 observations from 89 peer‐reviewed papers showed that the average anammox rate was 1.60 ± 0.17 nmol N g−1 h−1 in terrestrial ecosystems, with significant variations across different ecosystems. Wetlands exhibited the highest rate (2.17 ± 0.31 nmol N g−1 h−1), followed by croplands at 1.02 ± 0.09 nmol N g−1 h−1. The lowest anammox rates were observed in forests and grasslands. The anammox rates were positively correlated with the mean annual temperature, mean annual precipitation, soil moisture, organic carbon (C), total N, as well as nitrite and ammonium concentrations, but negatively with the soil C:N ratio. Structural equation models revealed that the geographical variations in anammox rates were primarily influenced by the N contents (such as nitrite and ammonium) and abundance of anammox bacteria, which collectively accounted for 42% of the observed variance. Furthermore, the abundance of anammox bacteria was well simulated by the mean annual precipitation, soil moisture, and ammonium concentrations, and 51% variance of the anammox bacteria was accounted for. The key controlling factors for soil anammox rates differed from ecosystem type, for example, organic C, total N, and ammonium contents in croplands, versus soil C:N ratio and nitrite concentrations in wetlands. The controlling factors in soil anammox rate identified by this study are useful to construct an accurate anammox module for N cycling in earth system models. [ABSTRACT FROM AUTHOR]

Published

2023

26. Stochastic resonance in climate reddening increases the risk of cyclic ecosystem extinction via phase‐tipping.

Author

Alkhayuon, Hassan, Marley, Jessa, Wieczorek, Sebastian, and Tyson, Rebecca C.

Subjects

STOCHASTIC resonance, LYNX, PREDATION, MATHEMATICAL variables, TAIGAS, ECOSYSTEMS

Abstract

Human activity is leading to changes in the mean and variability of climatic parameters in most locations around the world. The changing mean has received considerable attention from scientists and climate policy makers. However, recent work indicates that the changing variability, that is, the amplitude and the temporal autocorrelation of deviations from the mean, may have greater and more imminent impact on ecosystems. In this paper, we demonstrate that changes in climate variability alone could drive cyclic predator–prey ecosystems to extinction via so‐called phase‐tipping (P‐tipping), a new type of instability that occurs only from certain phases of the predator–prey cycle. We construct a mathematical model of a variable climate and couple it to two self‐oscillating paradigmatic predator–prey models. Most importantly, we combine realistic parameter values for the Canada lynx and snowshoe hare with actual climate data from the boreal forest. In this way, we demonstrate that critically important species in the boreal forest have increased likelihood of P‐tipping to extinction under predicted changes in climate variability, and are most vulnerable during stages of the cycle when the predator population is near its maximum. Furthermore, our analysis reveals that stochastic resonance is the underlying mechanism for the increased likelihood of P‐tipping to extinction. [ABSTRACT FROM AUTHOR]

Published

2023

27. From remotely sensed solar‐induced chlorophyll fluorescence to ecosystem structure, function, and service: Part I—Harnessing theory.

Author

Sun, Ying, Gu, Lianhong, Wen, Jiaming, van der Tol, Christiaan, Porcar‐Castell, Albert, Joiner, Joanna, Chang, Christine Y., Magney, Troy, Wang, Lixin, Hu, Leiqiu, Rascher, Uwe, Zarco‐Tejada, Pablo, Barrett, Christopher B., Lai, Jiameng, Han, Jimei, and Luo, Zhenqi

Subjects

CHLOROPHYLL spectra, PLANT physiology, REMOTE sensing, SPATIAL resolution, ECOSYSTEMS, CLIMATE change, SENSES

Abstract

Solar‐induced chlorophyll fluorescence (SIF) is a remotely sensed optical signal emitted during the light reactions of photosynthesis. The past two decades have witnessed an explosion in availability of SIF data at increasingly higher spatial and temporal resolutions, sparking applications in diverse research sectors (e.g., ecology, agriculture, hydrology, climate, and socioeconomics). These applications must deal with complexities caused by tremendous variations in scale and the impacts of interacting and superimposing plant physiology and three‐dimensional vegetation structure on the emission and scattering of SIF. At present, these complexities have not been overcome. To advance future research, the two companion reviews aim to (1) develop an analytical framework for inferring terrestrial vegetation structures and function that are tied to SIF emission, (2) synthesize progress and identify challenges in SIF research via the lens of multi‐sector applications, and (3) map out actionable solutions to tackle these challenges and offer our vision for research priorities over the next 5–10 years based on the proposed analytical framework. This paper is the first of the two companion reviews, and theory oriented. It introduces a theoretically rigorous yet practically applicable analytical framework. Guided by this framework, we offer theoretical perspectives on three overarching questions: (1) The forward (mechanism) question—How are the dynamics of SIF affected by terrestrial ecosystem structure and function? (2) The inference question: What aspects of terrestrial ecosystem structure, function, and service can be reliably inferred from remotely sensed SIF and how? (3) The innovation question: What innovations are needed to realize the full potential of SIF remote sensing for real‐world applications under climate change? The analytical framework elucidates that process complexity must be appreciated in inferring ecosystem structure and function from the observed SIF; this framework can serve as a diagnosis and inference tool for versatile applications across diverse spatial and temporal scales. [ABSTRACT FROM AUTHOR]

Published

2023

28. Assessing temperature‐based adaptation limits to climate change of temperate perennial fruit crops.

Author

Meza, Francisco, Darbyshire, Rebecca, Farrell, Aidan, Lakso, Alan, Lawson, James, Meinke, Holger, Nelson, Gerald, and Stockle, Claudio

Subjects

CLIMATE change, EDIBLE fats & oils, CROPS, TEMPERATE climate, TREE crops, ORCHARDS, ALMOND

Abstract

Temperate perennial fruit and nut trees play varying roles in world food diversity—providing edible oils and micronutrient, energy, and protein dense foods. In addition, perennials reuse significant amounts of biomass each year providing a unique resilience. But they also have a unique sensitivity to seasonal temperatures, requiring a period of dormancy for successful growing season production. This paper takes a global view of five temperate tree fruit crops—apples, cherries, almonds, olives, and grapes—and assesses the effects of future temperature changes on thermal suitability. It uses climate data from five earth system models for two CMIP6 climate scenarios and temperature‐related indices of stress to indicate potential future areas where crops cannot be grown and highlight potential new suitable regions. The loss of currently suitable areas and new additions in new locations varies by scenario. In the southern hemisphere (SH), end‐century (2081–2100) suitable areas under the SSP 5–8.5 scenario decline by more than 40% compared to a recent historical period (1991–2010). In the northern hemisphere (NH) suitability increases by 20% to almost 60%. With SSP1‐2.6, however, the changes are much smaller with SH area declining by about 25% and NH increasing by about 10%. The results suggest substantial restructuring of global production for these crops. Essentially, climate change shifts temperature‐suitable locations toward higher latitudes. In the SH, most of the historically suitable areas were already at the southern end of the landmass limiting opportunities for adaptation. If breeding efforts can bring chilling requirements for the major cultivars closer to that currently seen in some cultivars, suitable areas at the end of the century are greater, but higher summer temperatures offset the extent. The high value of fruit crops provides adaptation opportunities such as cultivar selection, canopy cooling using sprinklers, shade netting, and precision irrigation. [ABSTRACT FROM AUTHOR]

Published

2023

29. Release of a "forever material" from end‐of‐life boats and glass‐reinforced composite boats is pervasive and entering food chains.

Author

Ciocan, Corina, Jha, Kethan, Annels, Claude, Kozloski, Rachel, Steyl, Ilse, and Bray, Simon

Subjects

*GLASS fibers, *FOOD chains, *BOATING industry, *MARINE biology, *COMPOSITE materials

Abstract

Building boats of sufficient strength and durability to withstand the harsh water environment has always been a challenge. Composites, particularly glass‐reinforced plastic (GRP), historically provided one of the best low maintenance solutions. Over the past 80 years, GRP boats have become a mainstay of the boating industry while little attention has been given to the consequences of GRP degradation, lack of recycling solutions, and boat abandonment. This paper highlights the widespread glass fiber pollution and alarming levels of glass microparticles entering aquatic food chains. Prospective legal and policy measures are, therefore, required to manage risks to human and marine life. [ABSTRACT FROM AUTHOR]

Published

2024

30. Antibiotic resistance genes: A global change factor.

Author

Yang, Yuyi and Grossart, Hans‐Peter

Subjects

*GLOBAL environmental change, *DRUG resistance in bacteria, *GENES

Abstract

This invited commentary paper discusses the concept of elevated antibiotic resistance genes as a global change factor. [ABSTRACT FROM AUTHOR]

Published

2024

31. Significant effects of precipitation frequency on soil respiration and its components—A global synthesis.

Author

Yue Du, Ying-Ping Wang, Dafeng Hui, Fanglong Su, and Junhua Yan

Subjects

CARBON cycle, SOIL respiration, HYDROLOGIC cycle, HETEROTROPHIC respiration, BIOMASS, GLOBAL warming

Abstract

Global warming intensifies the hydrological cycle, which results in changes in precipitation regime (frequency and amount), and will likely have significant impacts on soil respiration (Rs). Although the responses of Rs to changes in precipitation amount have been extensively studied, there is little consensus on how Rs will be affected by changes in precipitation frequency (PF) across the globe. Here, we synthesized the field observations from 296 published papers to quantify the effects of PF on Rs and its components using meta-analysis. Our results indicated that the effects of PF on Rs decreased with an increase in background mean annual precipitation. When the data were grouped by climate conditions, increased PF showed positive effects on Rs under the arid condition but not under the semi-humid or humid conditions, whereas decreased PF suppressed Rs across all the climate conditions. The positive effects of increased PF mainly resulted from the positive response of heterotrophic respiration under the arid condition while the negative effects of decreased PF were mainly attributed to the reductions in root biomass and respiration. Overall, our global synthesis provided for the first time a comprehensive analysis of the divergent effects of PF on Rs and its components across climate regions. This study also provided a framework for understanding and modeling responses of ecosystem carbon cycling to global precipitation change. [ABSTRACT FROM AUTHOR]

Published

2023

32. Do not ignore the effects of phosphorus and potassium addition on microbial carbon use efficiency.

Author

Zhang, Chenyang, Sun, Liyang, Rui, Yichao, Li, Yue, Luo, Yiqi, Xu, Minggang, and Cai, Andong

Subjects

POTASSIUM, RANDOM effects model, FIXED effects model, PHOSPHORUS, SOIL biology, SOIL microbial ecology, CARBON

Abstract

P or PK addition significantly affected microbial CUE. The pure N addition was used to analyze the N effect on microbial CUE, but the data of N addition rate was not entirely correct in the dataset of Hu et al. ([2]). [Extracted from the article]

Published

2023

33. A claim for a 'next generation' of multisite range‐wide forest genetic trials built on the legacy of ecological genetics to anticipate responses to climate.

Author

Sampedro, Luis and Alía, Ricardo

Subjects

ECOLOGICAL genetics, FOREST resilience, GENETIC variation, SPECIES distribution, PHENOTYPIC plasticity, CLIMATE change

Abstract

Copyright of Global Change Biology is the property of Wiley-Blackwell and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

34. Floating debris and organisms can raft to Antarctic coasts from all major Southern Hemisphere landmasses.

Author

Dawson HRS, England MH, Morrison AK, Tamsitt V, and Fraser CI

Subjects

Antarctic Regions, Ecosystem, Models, Theoretical, Aquatic Organisms physiology, Animals, Oceans and Seas, Introduced Species

Abstract

Antarctica's unique marine ecosystems are threatened by the arrival of non-native marine species on rafting ocean objects. The harsh environmental conditions in Antarctica prevent the establishment of many such species, but warming around the continent and the opening up of ice-free regions may already be reducing these barriers. Although recent genomic work has revealed that rafts-potentially carrying diverse coastal passengers-reach Antarctica from sub-Antarctic islands, Antarctica's vulnerability to incursions from Southern Hemisphere continents remains unknown. Here we use 0.1° global ocean model simulations to explore whether drift connections exist between more northern, temperate landmasses and the Antarctic coastline. We show that passively floating objects can drift to Antarctica not only from sub-Antarctic islands, but also from continental locations north of the Subtropical Front including Australia, South Africa, South America and Zealandia. We find that the Antarctic Peninsula is the region at highest risk for non-native species introductions arriving by natural oceanic dispersal, highlighting the vulnerability of this region, which is also at risk from introductions via ship traffic and rapid warming. The widespread connections with sub-Antarctic and temperate landmasses, combined with an increasing abundance of marine anthropogenic rafting vectors, poses a growing risk to Antarctic marine ecosystems, especially as environmental conditions around Antarctica are projected to become more suitable for non-native species in the future., (Global Change Biology© 2024 The Author(s). Global Change Biology published by John Wiley & Sons Ltd.)

Published

2024

35. Wetness severity increases abrupt shifts in ecosystem functioning in arid savannas.

Author

Vermeulen, L. M., Verbist, B., Van Meerbeek, K., Slingsby, J., Bernardino, P. N., and Somers, B.

Subjects

*SAVANNAS, *BIOMES, *TIME series analysis, *RAINFALL frequencies, *ECOSYSTEMS, *DROUGHTS, *ECOSYSTEM health

Abstract

The accelerating pace of climate change has led to unprecedented shifts in surface temperature and precipitation patterns worldwide, with African savannas being among the most vulnerable regions. Understanding the impacts of these extreme changes on ecosystem health, functioning and stability is crucial. This paper focuses on the detection of breakpoints, indicative of shifts in ecosystem functioning, while also determining relevant ecosystem characteristics and climatic drivers that increase susceptibility to these shifts within the semi‐arid to arid savanna biome. Utilising a remote sensing change detection approach and rain use efficiency (RaUE) as a proxy for ecosystem functioning, spatial and temporal patterns of breakpoints in the savanna biome were identified. We then employed a novel combination of survival analysis and remote sensing time series analysis to compare ecosystem characteristics and climatic drivers in areas experiencing breakpoints versus areas with stable ecosystem functioning. Key ecosystem factors increasing savanna breakpoint susceptibility were identified, namely higher soil sand content, flatter terrain and a cooler long‐term mean temperature during the wet summer season. Moreover, the primary driver of changes in ecosystem functioning in arid savannas, as opposed to wetter tropical savannas, was found to be the increased frequency and severity of rainfall events, rather than drought pressures. This research highlights the importance of incorporating wetness severity metrics alongside drought metrics to comprehensively understand climate–ecosystem interactions leading to abrupt shifts in ecosystem functioning in arid biomes. The findings also emphasise the need to consider the underlying ecosystem characteristics, including soil, topography and vegetation composition, in assessing ecosystem responses to climate change. While this research primarily concentrated on the southern African savanna as a case study, the methodological robustness of this approach enables its application to diverse arid and semi‐arid biomes for the assessment of climate–ecosystem interactions that contribute to abrupt shifts. [ABSTRACT FROM AUTHOR]

Published

2024

36. Savanna vegetation increase triggers freshwater community shifts.

Author

Demare, Guillaume, Spieler, Marko, Grabow, Karsten, and Rödel, Mark‐Oliver

Subjects

COMMUNITIES, SAVANNAS, FRESH water, AMPHIBIAN larvae, LIFE history theory, ECOSYSTEMS

Abstract

Copyright of Global Change Biology is the property of Wiley-Blackwell and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

37. Global biodiversity conservation requires traditional Chinese medicine trade to be sustainable and well regulated.

Author

Wang, Yifu, Turvey, Samuel T., and Leader‐Williams, Nigel

Subjects

CHINESE medicine, BIODIVERSITY conservation, BIODIVERSITY, TRADE regulation, SUSTAINABILITY, ANIMAL species, COMMUNITIES

Abstract

Traditional Chinese medicine (TCM) is highlighted by conservation practitioners as an ongoing threat to many overharvested plant and animal species, including several charismatic threatened vertebrates. However, studies that provide evidence‐based and practical recommendations on how to better regulate the TCM trade for sustainability and biodiversity conservation remain limited. China is the biggest promotor of and market for TCM and understanding the TCM trade in China is important for global biodiversity conservation. In particular, conservation researchers need to better understand how the TCM trade and its regulations interact with China's development needs and should collaborate with TCM communities to propose locally adapted suggestions to decision makers. However, progress in these areas has been restricted by language, cultural, and knowledge barriers. In this paper, we provide an overview of the current status of TCM‐related regulations in China, identify weaknesses in regulation frameworks, and highlight issues that currently limit our understanding of the magnitude, dynamics, and impact of the trade. We propose changes in trade regulations, actions to enhance law enforcement, and future research directions to encourage a more sustainable TCM trade that benefits both global biodiversity conservation and TCM development. [ABSTRACT FROM AUTHOR]

Published

2022

38. A phylogenetic study to assess the link between biome specialization and diversification in swallowtail butterflies.

Author

Gamboa, Sara, Condamine, Fabien L., Cantalapiedra, Juan L., Varela, Sara, Pelegrín, Jonathan S., Menéndez, Iris, Blanco, Fernando, and Hernández Fernández, Manuel

Subjects

PAPILIONIDAE, GEODATABASES, BIOMES, FRAGMENTED landscapes, BIOLOGICAL extinction

Abstract

The resource‐use hypothesis, proposed by E.S. Vrba, states that habitat fragmentation caused by climatic oscillations would affect particularly biome specialists (species inhabiting only one biome), which might show higher speciation and extinction rates than biome generalists. If true, lineages would accumulate biome‐specialist species. This effect would be particularly exacerbated for biomes located at the periphery of the global climatic conditions, namely, biomes that have high/low precipitation and high/low temperature such as rainforest (warm‐humid), desert (warm‐dry), steppe (cold‐dry) and tundra (cold‐humid). Here, we test these hypotheses in swallowtail butterflies, a clade with more than 570 species, covering all the continents but Antarctica, and all climatic conditions. Swallowtail butterflies are among the most studied insects, and they are a model group for evolutionary biology and ecology studies. Continental macroecological rules are normally tested using vertebrates, this means that there are fewer examples exploring terrestrial invertebrate patterns at global scale. Here, we compiled a large Geographic Information System database on swallowtail butterflies' distribution maps and used the most complete time‐calibrated phylogeny to quantify diversification rates (DRs). In this paper, we aim to answer the following questions: (1) Are there more biome‐specialist swallowtail butterflies than biome generalists? (2) Is DR related to biome specialization? (3) If so, do swallowtail butterflies inhabiting extreme biomes show higher DRs? (4) What is the effect of species distribution area? Our results showed that swallowtail family presents a great number of biome specialists which showed substantially higher DRs compared to generalists. We also found that biome specialists are unevenly distributed across biomes. Overall, our results are consistent with the resource‐use hypothesis, species climatic niche and biome fragmentation as key factors promoting isolation. [ABSTRACT FROM AUTHOR]

Published

2022

39. It's a wormy world: Meta‐analysis reveals several decades of change in the global abundance of the parasitic nematodes Anisakis spp. and Pseudoterranova spp. in marine fishes and invertebrates.

Author

Fiorenza, Evan A., Wendt, Catrin A., Dobkowski, Katie A., King, Teri L., Pappaionou, Marguerite, Rabinowitz, Peter, Samhouri, Jameal F., and Wood, Chelsea L.

Subjects

MARINE invertebrates, MARINE mammals, MARINE fishes, NEMATODES, ANISAKIS, ZOONOSES, META-analysis

Abstract

The Anthropocene has brought substantial change to ocean ecosystems, but whether this age will bring more or less marine disease is unknown. In recent years, the accelerating tempo of epizootic and zoonotic disease events has made it seem as if disease is on the rise. Is this apparent increase in disease due to increased observation and sampling effort, or to an actual rise in the abundance of parasites and pathogens? We examined the literature to track long‐term change in the abundance of two parasitic nematode genera with zoonotic potential: Anisakis spp. and Pseudoterranova spp. These anisakid nematodes cause the disease anisakidosis and are transmitted to humans in undercooked and raw marine seafood. A total of 123 papers published between 1967 and 2017 met our criteria for inclusion, from which we extracted 755 host–parasite–location–year combinations. Of these, 69.7% concerned Anisakis spp. and 30.3% focused on Pseudoterranova spp. Meta‐regression revealed an increase in Anisakis spp. abundance (average number of worms/fish) over a 53 year period from 1962 to 2015 and no significant change in Pseudoterranova spp. abundance over a 37 year period from 1978 to 2015. Standardizing changes to the period of 1978–2015, so that results are comparable between genera, we detected a significant 283‐fold increase in Anisakis spp. abundance and no change in the abundance of Pseudoterranova spp. This increase in Anisakis spp. abundance may have implications for human health, marine mammal health, and fisheries profitability. [ABSTRACT FROM AUTHOR]

Published

2020

40. Global reductions in manual agricultural work capacity due to climate change.

Author

Nelson, Gerald C., Vanos, Jennifer, Havenith, George, Jay, Ollie, Ebi, Kristie L., and Hijmans, Robert J.

Subjects

*MANUAL labor, *CLIMATE change, *GROWING season, *SOLAR radiation, *SHIFT systems, *HIGH-income countries

Abstract

Manual outdoor work is essential in many agricultural systems. Climate change will make such work more stressful in many regions due to heat exposure. The physical work capacity metric (PWC) is a physiologically based approach that estimates an individual's work capacity relative to an environment without any heat stress. We computed PWC under recent past and potential future climate conditions. Daily values were computed from five earth system models for three emission scenarios (SSP1‐2.6, SSP3‐7.0, and SSP5‐8.5) and three time periods: 1991–2010 (recent past), 2041–2060 (mid‐century) and 2081–2100 (end‐century). Average daily PWC values were aggregated for the entire year, the growing season, and the warmest 90‐day period of the year. Under recent past climate conditions, the growing season PWC was below 0.86 (86% of full work capacity) on half the current global cropland. With end‐century/SSP5‐8.5 thermal conditions this value was reduced to 0.7, with most affected crop‐growing regions in Southeast and South Asia, West and Central Africa, and northern South America. Average growing season PWC could falls below 0.4 in some important food production regions such as the Indo‐Gangetic plains in Pakistan and India. End‐century PWC reductions were substantially greater than mid‐century reductions. This paper assesses two potential adaptions—reducing direct solar radiation impacts with shade or working at night and reducing the need for hard physical labor with increased mechanization. Removing the effect of direct solar radiation impacts improved PWC values by 0.05 to 0.10 in the hottest periods and regions. Adding mechanization to increase horsepower (HP) per hectare to levels similar to those in some higher income countries would require a 22% increase in global HP availability with Sub‐Saharan Africa needing the most. There may be scope for shifting to less labor‐intensive crops or those with labor peaks in cooler periods or shift work to early morning. [ABSTRACT FROM AUTHOR]

Published

2024

41. Misconceptions of the marine biological carbon pump in a changing climate: Thinking outside the "export" box.

Author

Frenger, Ivy, Landolfi, Angela, Kvale, Karin, Somes, Christopher J., Oschlies, Andreas, Yao, Wanxuan, and Koeve, Wolfgang

Subjects

*ATMOSPHERIC carbon dioxide, *EFFECT of human beings on climate change, *CLIMATE change, *ATMOSPHERIC models, *CARBON emissions, *CARBON cycle, *ATMOSPHERE

Abstract

The marine biological carbon pump (BCP) stores carbon in the ocean interior, isolating it from exchange with the atmosphere and thereby coregulating atmospheric carbon dioxide (CO2). As the BCP commonly is equated with the flux of organic material to the ocean interior, termed "export flux," a change in export flux is perceived to directly impact atmospheric CO2, and thus climate. Here, we recap how this perception contrasts with current understanding of the BCP, emphasizing the lack of a direct relationship between global export flux and atmospheric CO2. We argue for the use of the storage of carbon of biological origin in the ocean interior as a diagnostic that directly relates to atmospheric CO2, as a way forward to quantify the changes in the BCP in a changing climate. The diagnostic is conveniently applicable to both climate model data and increasingly available observational data. It can explain a seemingly paradoxical response under anthropogenic climate change: Despite a decrease in export flux, the BCP intensifies due to a longer reemergence time of biogenically stored carbon back to the ocean surface and thereby provides a negative feedback to increasing atmospheric CO2. This feedback is notably small compared with anthropogenic CO2 emissions and other carbon‐climate feedbacks. In this Opinion paper, we advocate for a comprehensive view of the BCP's impact on atmospheric CO2, providing a prerequisite for assessing the effectiveness of marine CO2 removal approaches that target marine biology. [ABSTRACT FROM AUTHOR]

Published

2024

42. The Coastal Carbon Library and Atlas: Open source soil data and tools supporting blue carbon research and policy.

Author

Holmquist, James R., Klinges, David, Lonneman, Michael, Wolfe, Jaxine, Boyd, Brandon, Eagle, Meagan, Sanderman, Jonathan, Todd‐Brown, Kathe, Belshe, E. Fay, Brown, Lauren N., Chapman, Samantha, Corstanje, Ron, Janousek, Christopher, Morris, James T., Noe, Gregory, Rovai, André, Spivak, Amanda, Vahsen, Megan, Windham‐Myers, Lisamarie, and Kroeger, Kevin

Subjects

*DATA structures, *SOIL formation, *SOIL profiles, *CARBON, *DATABASES

Abstract

Quantifying carbon fluxes into and out of coastal soils is critical to meeting greenhouse gas reduction and coastal resiliency goals. Numerous 'blue carbon' studies have generated, or benefitted from, synthetic datasets. However, the community those efforts inspired does not have a centralized, standardized database of disaggregated data used to estimate carbon stocks and fluxes. In this paper, we describe a data structure designed to standardize data reporting, maximize reuse, and maintain a chain of credit from synthesis to original source. We introduce version 1.0.0. of the Coastal Carbon Library, a global database of 6723 soil profiles representing blue carbon‐storing systems including marshes, mangroves, tidal freshwater forests, and seagrasses. We also present the Coastal Carbon Atlas, an R‐shiny application that can be used to visualize, query, and download portions of the Coastal Carbon Library. The majority (4815) of entries in the database can be used for carbon stock assessments without the need for interpolating missing soil variables, 533 are available for estimating carbon burial rate, and 326 are useful for fitting dynamic soil formation models. Organic matter density significantly varied by habitat with tidal freshwater forests having the highest density, and seagrasses having the lowest. Future work could involve expansion of the synthesis to include more deep stock assessments, increasing the representation of data outside of the U.S., and increasing the amount of data available for mangroves and seagrasses, especially carbon burial rate data. We present proposed best practices for blue carbon data including an emphasis on disaggregation, data publication, dataset documentation, and use of standardized vocabulary and templates whenever appropriate. To conclude, the Coastal Carbon Library and Atlas serve as a general example of a grassroots F.A.I.R. (Findable, Accessible, Interoperable, and Reusable) data effort demonstrating how data producers can coordinate to develop tools relevant to policy and decision‐making. [ABSTRACT FROM AUTHOR]

Published

2024

43. Too hot to handle? An urgent need to understand climate change impacts on the biogeochemistry of tropical coastal waters.

Author

Carreira, Cátia, Joyce, Patrick W. S., Morán, Xosé Anxelu G., Carvalho, Susana, Falkenberg, Laura, and Lønborg, Christian

Subjects

*TERRITORIAL waters, *CLIMATE change, *BIOGEOCHEMISTRY, *ACCLIMATIZATION, *TEMPERATE climate, *TIME series analysis

Abstract

Tropical regions contain ecologically and socio‐economically important habitats, and are home to about 3.8 billion people, many of which directly depend on tropical coastal waters for their well‐being. At the basis of these ecosystems are biogeochemical processes. Climate change is expected to have a greater impact in the tropics compared to temperate regions because of the relatively stable environmental conditions found there. However, it was surprising to find only 660 research articles published focusing on the impact of climate change on the biogeochemistry of coastal tropical waters compared to 4823 for temperate waters. In this perspective, we highlight important topics in need of further research. Specifically, we suggest that in tropical regions compared to temperate counterparts climate change stressors will be experienced differently, that organisms have a lower acclimation capacity, and that long‐term baseline biogeochemical datasets useful for quantifying future changes are lacking. The low number of research papers on the impacts of climate change in coastal tropical regions is likely due to a mix of reasons including limited resources for research and limited number of long time series in many developing tropical countries. Finally, we propose some action points that we hope will stimulate more studies in tropical coastal waters. [ABSTRACT FROM AUTHOR]

Published

2024

44. Winter is coming: Interactions of multiple stressors in winter and implications for the natural world.

Author

Dinh, Khuong V., Albini, Dania, Orr, James A., Macaulay, Samuel J., Rillig, Matthias C., Borgå, Katrine, and Jackson, Michelle C.

Subjects

*ECOLOGICAL risk assessment, *EFFECT of human beings on climate change, *WINTER, *MARINE ecology, *PSYCHOLOGICAL adaptation

Abstract

Winter is a key driver of ecological processes in freshwater, marine and terrestrial ecosystems, particularly in higher latitudes. Species have evolved various adaptive strategies to cope with food limitations and the cold and dark wintertime. However, human‐induced climate change and other anthropogenic stressors are impacting organisms in winter in unpredictable ways. In this paper, we show that global change experiments investigating multiple stressors have predominantly been conducted during summer months. However, effects of anthropogenic stressors sometimes differ between winter and other seasons, necessitating comprehensive investigations. Here, we outline a framework for understanding the different effects of anthropogenic stressors in winter compared to other seasons and discuss the primary mechanisms that will alter ecological responses of organisms (microbes, animals and plants). For instance, while the magnitude of some anthropogenic stressors can be greater in winter than in other seasons (e.g. some pollutants), others may alleviate natural winter stress (e.g. warmer temperatures). These changes can have immediate, delayed or carry‐over effects on organisms during winter or later seasons. Interactions between stressors may also vary with season. We call for a renewed research direction focusing on multiple stressor effects on winter ecology and evolution to fully understand, and predict, how ecosystems will fare under changing winters. We also argue the importance of incorporating the interactions of anthropogenic stressors with winter into ecological risk assessments, management and conservation efforts. [ABSTRACT FROM AUTHOR]

Published

2023

45. Influence of offshore oil and gas structures on seascape ecological connectivity.

Author

McLean, Dianne L., Ferreira, Luciana C., Benthuysen, Jessica A., Miller, Karen J., Schläppy, Marie‐Lise, Ajemian, Matthew J., Berry, Oliver, Birchenough, Silvana N. R., Bond, Todd, Boschetti, Fabio, Bull, Ann S., Claisse, Jeremy T., Condie, Scott A., Consoli, Pierpaolo, Coolen, Joop W. P., Elliott, Michael, Fortune, Irene S., Fowler, Ashley M., Gillanders, Bronwyn M., and Harrison, Hugo B.

Subjects

NATURAL gas in submerged lands, PETROLEUM industry, SPECIES distribution, MARINE habitats, ANIMAL mechanics, DISPERSAL (Ecology), FISH larvae

Abstract

Offshore platforms, subsea pipelines, wells and related fixed structures supporting the oil and gas (O&G) industry are prevalent in oceans across the globe, with many approaching the end of their operational life and requiring decommissioning. Although structures can possess high ecological diversity and productivity, information on how they interact with broader ecological processes remains unclear. Here, we review the current state of knowledge on the role of O&G infrastructure in maintaining, altering or enhancing ecological connectivity with natural marine habitats. There is a paucity of studies on the subject with only 33 papers specifically targeting connectivity and O&G structures, although other studies provide important related information. Evidence for O&G structures facilitating vertical and horizontal seascape connectivity exists for larvae and mobile adult invertebrates, fish and megafauna; including threatened and commercially important species. The degree to which these structures represent a beneficial or detrimental net impact remains unclear, is complex and ultimately needs more research to determine the extent to which natural connectivity networks are conserved, enhanced or disrupted. We discuss the potential impacts of different decommissioning approaches on seascape connectivity and identify, through expert elicitation, critical knowledge gaps that, if addressed, may further inform decision making for the life cycle of O&G infrastructure, with relevance for other industries (e.g. renewables). The most highly ranked critical knowledge gap was a need to understand how O&G structures modify and influence the movement patterns of mobile species and dispersal stages of sessile marine species. Understanding how different decommissioning options affect species survival and movement was also highly ranked, as was understanding the extent to which O&G structures contribute to extending species distributions by providing rest stops, foraging habitat, and stepping stones. These questions could be addressed with further dedicated studies of animal movement in relation to structures using telemetry, molecular techniques and movement models. Our review and these priority questions provide a roadmap for advancing research needed to support evidence‐based decision making for decommissioning O&G infrastructure. [ABSTRACT FROM AUTHOR]

Published

2022

46. Interplays between changing biophysical and social dynamics under climate change: Implications for limits to sustainable adaptation in food systems.

Author

Bezner Kerr, Rachel, Naess, Lars Otto, Allen‐O'Neil, Bridget, Totin, Edmond, Nyantakyi‐Frimpong, Hanson, Risvoll, Camilla, Rivera Ferre, Marta G., López‐i‐Gelats, Feliu, and Eriksen, Siri

Subjects

CLIMATE change, SOCIAL dynamics, SOCIAL change, SOCIAL factors, DIFFERENTIATION (Sociology), LOCAL foods

Abstract

Climate change scenarios have significant implications for the livelihoods and food security of particular groups in society and will necessitate a range of adaptation actions. While there is a significant literature on the social as well as biophysical factors and limits to adaptation, less is known about the interactions between these, and what such interactions mean for the prospects of achieving sustainable and resilient food systems. This paper is an attempt at addressing this gap by examining changing biophysical and social factors, with specific consideration of vulnerable groups, across four case studies (Ghana, Malawi, Norway and Spain). In each case, future climate change scenarios and associated biophysical limits are mapped onto four key social factors that drive vulnerability and mediate adaptation, namely, scale, history, power and politics, and social differentiation. We then consider what the interaction between biophysical limits and socio‐political dynamics means for the options for and limits to future adaptation, and how climate may interact with, and reshape, socio‐political elements. We find that biophysical limits and socio‐political factors do not operate in isolation, but interact, with dynamic relationships determining the 'space' or set of options for sustainable adaptation. By connecting the perspectives of biophysical and social factors, the study illuminates the risks of unanticipated outcomes that result from the disregard of local contexts in the implementation of adaptation measures. We conclude that a framework focusing on the space for sustainable adaptation conditioned by biophysical and social factors, and their interactions, can help provide evidence on what does and does not constitute sustainable adaptation, and help to counter unhelpful narratives of climate change as a sole or dominant cause of challenges in food systems. [ABSTRACT FROM AUTHOR]

Published

2022

47. Steps forward in biomonitoring 2.0: eDNA Metabarcoding and community‐level modelling allow the assessment of complex drivers of Neotropical fish diversity.

Author

Carvalho, Daniel C. and Leal, Cecília G.

Subjects

GENETIC barcoding, BIOLOGICAL monitoring, FRESHWATER fishes, SPECIES distribution, BIODIVERSITY

Abstract

The Neotropical realm still represents a great challenge to our understanding of species distribution patterns and the role played by different drivers of biodiversity. The paper by Coutant et al. (2022) is a great advance towards a holistic approach to quantifying the contribution of environmental and anthropogenic factors that drive community assembly in the Amazon, and how we can apply such knowledge to guide future monitoring programmes. Disentangling the relative roles played by multiple drivers of biodiversity allowed them to also highlight hotspot areas hosting unique freshwater fish diversity and to pinpoint conservation priorities. [ABSTRACT FROM AUTHOR]

Published

2023

48. Tree contributions to climate change adaptation through reduced cattle heat stress and benefits to milk and beef production.

Author

Richards D, Dewhurst Z, Giltrap D, and Lavorel S

Subjects

Animals, Cattle physiology, New Zealand, Heat-Shock Response, Models, Theoretical, Climate Change, Milk, Trees

Abstract

Cattle heat stress causes billions of dollars' worth of losses to meat and milk production globally, and is projected to become more severe in the future due to climate change. Tree establishment in pastoral livestock systems holds potential to reduce cattle heat stress and thus provide nature-based adaptation. We developed a general model for the impact of trees on cattle heat stress, which can project milk and meat production under future climate scenarios at varying spatial scales. The model incorporates the key microclimate mechanisms influenced by trees, including shade, air temperature, humidity, and wind speed. We conducted sensitivity analyses to demonstrate the relative influence of different mechanisms through which trees can impact cattle heat stress, and how tree impacts are influenced by climatic context globally. Trees hold the greatest potential to reduce cattle heat stress in higher latitudes and altitudes, with minor benefits in the lowland tropics. We projected the future contributions of current trees in mitigating climate change impacts on the dairy and beef herds of Aotearoa-New Zealand (A-NZ) in 2070-2080. Trees were simulated to contribute to A-NZ milk yields by over 491 million liters (lower CI = 112 million liters, upper CI = 850 million liters), and meat yields by over 8316 tonnes (lower CI = 2431 tonnes, upper CI = 13,668 tonnes) annually. The total economic contribution of existing trees in mitigating future cattle heat stress was valued at $US 244 million (lower CI = $US 58 million, upper CI = $US 419 million). Our findings demonstrate the importance of existing trees in pastoral landscapes and suggest that strategic tree establishment can be a valuable adaptation option for reducing cattle heat stress under climate change. Tree establishment in the next few years is critical to provide adaptation capacity and economic benefit in future decades., (© 2024 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published

2024

49. Distinct responses to warming within picoplankton communities across an environmental gradient.

Author

Stevens BLF, Peacock EE, Crockford ET, Shalapyonok A, Neubert MG, and Sosik HM

Subjects

Seawater chemistry, Temperature, Synechococcus physiology, Synechococcus growth & development, Climate Change, Phytoplankton physiology, Seasons

Abstract

Picophytoplankton are a ubiquitous component of marine plankton communities and are expected to be favored by global increases in seawater temperature and stratification associated with climate change. Eukaryotic and prokaryotic picophytoplankton have distinct ecology, and global models predict that the two groups will respond differently to future climate scenarios. At a nearshore observatory on the Northeast US Shelf, however, decades of year-round monitoring have shown these two groups to be highly synchronized in their responses to environmental variability. To reconcile the differences between regional and global predictions for picophytoplankton dynamics, we here investigate the picophytoplankton community across the continental shelf gradient from the nearshore observatory to the continental slope. We analyze flow cytometry data from 22 research cruises, comparing the response of picoeukaryote and Synechococcus communities to environmental variability across time and space. We find that the mechanisms controlling picophytoplankton abundance differ across taxa, season, and distance from shore. Like the prokaryote, Synechococcus, picoeukaryote division rates are limited nearshore by low temperatures in winter and spring, and higher temperatures offshore lead to an earlier spring bloom. Unlike Synechococcus, picoeukaryote concentration in summer decreases dramatically in offshore surface waters and exhibits deeper subsurface maxima. The offshore picoeukaryote community appears to be nutrient limited in the summer and subject to much greater loss rates than Synechococcus. This work both produces and demonstrates the necessity of taxon- and site-specific knowledge for accurately predicting the responses of picophytoplankton to ongoing environmental change., (© 2024 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published

2024

50. Correction to "A new empirical framework to quantify the hydraulic effects of soil and atmospheric drivers on plant water status".

Subjects

*PLANT-water relationships, *AQUATIC plants, *SOILS, *SUMMER

Abstract

The article titled "Correction to 'A new empirical framework to quantify the hydraulic effects of soil and atmospheric drivers on plant water status'" discusses a correction that needs to be made to Figure 1 of the paper. The numerical scale on the X axis of Figure 1 was mistakenly multiplied by a factor of 2, which does not affect the rest of the paper. The figure presents a conceptual diagram of the relationships between leaf water potential and the combined hydraulic effects caused by soil and atmospheric drivers. The correction is necessary to ensure the accuracy of the plot. [Extracted from the article]

Published

2024