Your search keyword '"Chronosequence"' showing total 5,294 results

1. Soil phosphorus cycling across a 100‐year deforestation chronosequence in the Amazon rainforest

Author

Xu, Suwei, Gu, Chunhao, Rodrigues, Jorge LM, Li, Chongyang, Bohannan, Brendan, Nüsslein, Klaus, and Margenot, Andrew J

Subjects

Earth Sciences, Biological Sciences, Environmental Sciences, Life on Land, Amazon, chronosequence, deforestation, phosphatase, phosphorus, phosphorus fractionation, reforestation, XANES, Phosphorus, Soil, Conservation of Natural Resources, Ecosystem, Forests, Rainforest, Ecology, Biological sciences, Earth sciences, Environmental sciences

Abstract

Deforestation of tropical rainforests is a major land use change that alters terrestrial biogeochemical cycling at local to global scales. Deforestation and subsequent reforestation are likely to impact soil phosphorus (P) cycling, which in P-limited ecosystems such as the Amazon basin has implications for long-term productivity. We used a 100-year replicated observational chronosequence of primary forest conversion to pasture, as well as a 13-year-old secondary forest, to test land use change and duration effects on soil P dynamics in the Amazon basin. By combining sequential extraction and P K-edge X-ray absorption near edge structure (XANES) spectroscopy with soil phosphatase activity assays, we assessed pools and process rates of P cycling in surface soils (0-10 cm depth). Deforestation caused increases in total P (135-398 mg kg-1 ), total organic P (Po ) (19-168 mg kg-1 ), and total inorganic P (Pi ) (30-113 mg kg-1 ) fractions in surface soils with pasture age, with concomitant increases in Pi fractions corroborated by sequential fractionation and XANES spectroscopy. Soil non-labile Po (10-148 mg kg-1 ) increased disproportionately compared to labile Po (from 4-5 to 7-13 mg kg-1 ). Soil phosphomonoesterase and phosphodiesterase binding affinity (Km ) decreased while the specificity constant (Ka ) increased by 83%-159% in 39-100y pastures. Soil P pools and process rates reverted to magnitudes similar to primary forests within 13 years of pasture abandonment. However, the relatively short but representative pre-abandonment pasture duration of our secondary forest may not have entailed significant deforestation effects on soil P cycling, highlighting the need to consider both pasture duration and reforestation age in evaluations of Amazon land use legacies. Although the space-for-time substitution design can entail variation in the initial soil P pools due to atmospheric P deposition, soil properties, and/or primary forest growth, the trend of P pools and process rates with pasture age still provides valuable insights.

Published

2024

2. Evaluation of soil properties and bulk δ15N to assess decadal changes in floodplain denitrification following restoration.

Author

Galella, Joseph G., Rahman, Md. Moklesur, Yaculak, Alexis M., Peipoch, Marc, Kan, Jinjun, Sena, Matthew, Joshi, Bisesh, Kaushal, Sujay S., and Inamdar, Shreeram

Subjects

*NUTRIENT pollution of water, *STREAM restoration, *NITROGEN isotopes, *SOIL moisture, *CARBON in soils

Abstract

Stream and floodplain restoration is a popular billion‐dollar industry in the United States, with many restorations being conducted to satisfy water pollution regulations and nutrient reduction goals. The long‐term efficacy of these restorations is, however, not well studied, and key soil metrics that can be used for performance assessments have not been developed. We evaluated a chronosequence of 12 restoration sites spanning an age range of 0–22 years to assess changes in denitrification rates and associated soil parameters. Restored versus unrestored reaches were compared for denitrification rate and functional gene nosZ, bulk soil δ15N, soil organic carbon (SOC), soil organic matter (SOM), bulk density, and soil moisture. Denitrification, SOM, SOC, and soil moisture were all found to increase with site age at restored sites, with the largest increase for the 10–22 age category. Bulk density decreased with time, with a significant decrease in restored floodplain soils. Bulk soil δ15N was highest immediately after restoration, decreased with restoration age, and was not positively correlated with denitrification. This may reduce its potential as a proxy for denitrification. Overall, this study reveals that selected soil metrics (SOC, SOM, soil moisture, and bulk density) could serve as a valuable proxy for denitrification and could help assess the denitrification effectiveness of floodplain restorations at the decadal time scales. Ideally, the soil metrics should be combined with other short‐term assessment measures, such as those for stream and groundwaters, for a robust performance assessment of restored floodplains. [ABSTRACT FROM AUTHOR]

Published

2024

3. Space‐for‐time substitution misleads projections of plant community and stand‐structure development after disturbance in a slow‐growing environment.

Author

Kreyling, Juergen

Abstract

Understanding and projecting ecosystem dynamics is a key goal for both basic science and applied ecosystem management. In ecosystems dominated by long‐lived organisms such as forests, space‐for‐time substitutions (SFT) inferring temporal development from observations of study objects differing in age across space at a given time, also called chronosequences, are widely used as an alternative approach for long‐term monitoring, in particular to understand forest dynamics after stand‐replacing disturbances. Uncertainties and challenges of SFT substitution, however, arise from violations of the underlying assumption that everything but time since disturbance is identical among the spatial sampling sites. Direct comparisons between true time series and SFT substitutions are still surprisingly rare. I resampled a 20‐year‐old SFT substitution study to check if this method accurately projects vegetation changes after major disturbances in primary subalpine conifer forests, and to evaluate its conclusions for forest management. Two decades and a spatial scale of about 600 km2 constitutes spatial and temporal conditions for which little empirical evidence for the validity of SFT substitution exists. SFT suggested a strong shift away from old‐growth plant community compositions after clearcutting with, misleadingly, no trend back over two decades. True temporal development, however, differed significantly from this expectation as it showed a directional trend back towards old‐growth plant community compositions after the initial displacement. Compositional recovery is predicted to take 100–200 years in the studied ecosystem. Accordingly, several late seral forest floor herbs and bryophytes were still missing completely even 50 years after clearcutting. Synthesis. Non‐constant climate, species pools and management actions compromise the ability to reliably project temporal dynamics in plant community composition and stand structure by space‐for‐time substitutions, likely also for other scenarios than the studied subalpine conifer forests after stand‐replacing disturbance. Long‐term monitoring therefore is indispensable for understanding ecosystem dynamics, in particular in slow‐growing and stressful environments. Management needs to consider the slow regeneration in its planning of rotation times and is advised to monitor and retain species indicative of old‐growth conditions at the landscape level. [ABSTRACT FROM AUTHOR]

Published

2024

4. Revegetating Mine Soils with Different Tree Species Influences Molecular Characteristics of Soil Organic Matter.

Author

Singh, Preeti, Ghosh, A. K., Kumar, Santosh, Kumar, Manoj, Yadav, Sunita, Nagargade, Mona, and Seema

Subjects

*MINE soils, *SOIL chronosequences, *CARBON in soils, *SOIL dynamics, *SOIL composition

Abstract

Although molecular characterization of soil organic carbon is crucial for understanding its dynamics, studies on reclaimed coal mine soil are comparatively limited. Therefore, the primary objective of this study was to ascertain the influence of tree species on the soil organic carbon content and molecular characteristics of soil organic carbon in a chronosequence of reclaimed coal mine soil. To investigate the effects of reclamation time on soil organic carbon characteristics, a chronosequence of three coal mine soil was used, each exhibiting different ages of reclamation: 8, 14, and 25 years. Along a re-vegetation age gradient of 8 to 25 years, the total soil organic carbon content increased. Within the 25 years of restored soil, the FTIR absorption intensities were lowest within the range of 2,920 and 2,850 cm−1, while they were highest within the range of 1,685, 1,425, and 1,285 cm−1which indicates presence of aromatic C=C. This shows that aromatic compounds contributed more significantly to the composition of soil organic carbon compared to aliphatic structures. Based on molecular characteristics, it is suggested that the soil organic carbon in 25-year old revegetated coal mine soil consists of aromatic and recalcitrant carbon. Among three tree species Dalbergia sissoo can be used for reclamation as quality and quantity of carbon found was higher under this tree species. In conclusion, the results indicated that the molecular properties of soil organic carbon were extremely important for understanding the dynamics of soil organic carbon in a restored coal mine soil chronosequence. [ABSTRACT FROM AUTHOR]

Published

2024

5. Effect of vegetation introduction versus natural recovery on topsoil properties in the dried Aral Sea bed.

Author

Kim, Gaeun, Ahn, Jieun, Chang, Hanna, An, Jiae, Khamzina, Asia, Kim, Gwangeun, and Son, Yowhan

Subjects

OCEAN bottom, PLANT exudates, SANDSTORMS, DUST storms, AGRICULTURE

Abstract

Desiccation of the Aral Sea has resulted in the emergence of vast saline and flat terrains, jeopardizing human health and agricultural activities because of sand and dust storms. Vegetation, mainly indigenous Haloxylon species, has been introduced to ameliorate the soil. As a critical indicator of rehabilitation, the physicochemical properties of soil after the introduction of vegetation remain poorly understood. This study examined (1) the changes in topsoil properties after vegetation establishment based on a 30‐year chronosequence and employed (2) site comparisons of topsoil properties between two cases of natural versus introduced vegetation on a dried Aral Sea bed. Twelve paired areas that were naturally or artificially vegetated during 1990, 2000, 2005, 2008, 2013, and 2017 were selected for examination. Irrespective of vegetation type, increases in organic matter and nutrients (TOC >90%, TN >143%, and P2O5 >23%) were detected in the surface soil (0–10 cm) along the 30‐year chronosequence. In addition, decreases in ECe (92% and 69%), CEC (41% and 11%), Ca2+ (38% and 12%), and TIC (81% and 11%) were observed in both natural and introduced vegetation, respectively. The introduced vegetation was associated with a slightly greater accumulation of soil K+ and TN than the natural vegetation. Our results indicate vegetation‐derived nutrient and organic matter accumulation as well as the possible removal of salts by root exudates in the surface soil. Overall, vegetation contributed to soil amelioration, with similar effects observed at naturally and artificially vegetated sites. [ABSTRACT FROM AUTHOR]

Published

2024

6. Diversity and Distribution of Monocot Understory Herbs during Tropical Forest Succession in Northeastern Costa Rica.

Author

Sun, Jennifer W. C., Chazdon, Robin L., and Rundel, Philip W.

Subjects

*SECONDARY forests, *FOREST succession, *RAIN forests, *FOREST regeneration, *NUMBERS of species

Abstract

Broad-leaved monocot herbs form one of the most common and diverse growth forms of Neotropical plants. Their significance and frequency of occurrence is particularly notable in the understories of tropical rainforests, where they form a dominant element. We assessed and quantified changes in the cover and diversity of understory herb communities in a chronosequence of 1 ha permanent plots established as part of a multidisciplinary study on tropical forest regeneration in the Atlantic lowlands of northeastern Costa Rica. Sampled were two young stands cleared 12 years ago, two secondary forests with 21 and 39 of years of recovery since clearance, and two stands in old-growth primary forest. Changes in species composition during succession were assessed using Chao's Jaccard similarity index. Observed species richness ranged from 15 to 26 species in individual plots, with the greatest number of species in the 21-year intermediate-age and fewest in the young 12-year plots. Herb species sampled represented 6 families, 15 genera, and 39 species, with the Araceae contributing the largest number of species. Ten species were sampled in all six stands, while fourteen species were found exclusively in one plot. Herb density (ramets m−2) showed a hump-shade trend, with peak density in the intermediate stands and a lower level in mature and young secondary forests. Mean herb cover in 25 m2 quadrats ranged from 2.0% (young stand) to 22.7% (intermediate-age stand) and differed significantly both among stand types and among sites. Both observed and estimated species richness increased along the chronosequence as a whole, with the highest number of species in primary forest, although only slightly higher than in intermediate-age stands. Over half of the species exhibited some degree of clonal growth, with the extent of clonal spread varying among species and forest stands. Although we did not find a clear pattern between clonality and forest age, we observed a greater number of clonal patches in secondary over primary forest stands. [ABSTRACT FROM AUTHOR]

Published

2024

7. Comparative Assessment of Nutrient Mobilisation and Heavy Metal Indices in Chronosequence of Manganese Mine Spoil.

Author

DASH, SAMAPIKA and KUJUR, MONTY

Abstract

Mine tailings are generated during mineral extraction that greatly influence soil properties and provide a least opportunity for vegetation. In current study, accumulation of available nutrients and their effect on concentration of heavy metals were assessed from a chronosequence of manganese mine spoil (MBO0, MBO2, MBO4, MBO6, MBO8, MBO10) and compared it with native forest soil. In mine spoil, required level of nutrients were less than those in native forest soil. Heavy metal content was found to be high in fresh overburden spoil as compared to native forest soil. Fresh overburden mine spoil id acidic in nature due to high accumulation of Mn and Fe metals. However, in course of time, the acidic nature of mine spoil turns into basic due to the improvement in the soil physico-chemical characters. In chronosequence overburden spoil shows increasing trend in soil organic carbon, electrical conductivity and cation exchange capacity leading towards rapid reclamation. [ABSTRACT FROM AUTHOR]

Published

2024

8. Succession as a Natural Tool for Restoration of Oak—Lime Forests on Aspen-Covered Clearcuts.

Author

Nasibullina, Alina, Tiebel, Katharina, and Wagner, Sven

Subjects

*EUROPEAN aspen, *ENGLISH oak, *FOREST restoration, *LIME (Fruit), *MIXED forests

Abstract

The genus Quercus, including species like pedunculate oak (Quercus robur L.), can play a key role in maintaining climate-resistant mixed forests due to its broad ecological spectrum and drought tolerance. Unfortunately, in some parts of Europe, clearcutting has drastically reduced the oak population. An example of this event is our survey of heritage Oak—Lime forests in European Russia, which were transformed into pure aspen stands. The aim of our study was to provide forecasts and silvicultural recommendations for the passive restoration of these forests. We took a chronosequence approach to assess changes associated with natural succession over 60 years. In our survey of the development of oaks, limes and accompanying tree species (aspen, birches, maples, elms), we used 190 plots ranging across a wide spectrum of forest disturbance due to clearcutting. We demonstrate that aspen reproduce rapidly by root suckers after cutting and occupy more than 60% of the space. But the dominance of aspen decreases continuously from the age of 30, and then the lime trees begin to dominate. Oak does not show successful natural regeneration. Therefore, we recommend planting oak seedlings or sowing acorns, i.e., active restoration, in combination with the natural restoration of lime. [ABSTRACT FROM AUTHOR]

Published

2024

9. Tracking the long‐term vegetation and soil characteristics of restored mangroves: a case study from Guyana's coast.

Author

Ram, Mark, Sheaves, Marcus, and Waltham, Nathan J.

Subjects

*MANGROVE plants, *BIOTIC communities, *CLIMATE change, *SOILS, *VEGETATION dynamics, *TREE height, *COASTS

Abstract

The global urgency to halt and reverse mangrove loss has led to the implementation of numerous initiatives to protect and restore mangroves and recover critical ecological functions and services. Restoration success is assessed by estimating mangrove survival, while diversity, vegetation structure, and soil characteristics are often overlooked with no long‐term monitoring. Here, we investigated long‐term changes in vegetation and soil characteristics of Avicennia germinans‐dominated stands planted along Guyana's coast between 5 and 11 years old. A chronosequence approach was used to examine changes in vegetation and soil parameters in restored mangrove stands of different ages compared to natural stands of the same ages. Tree height, diameter, and aboveground biomass were inconsistent between restored and natural mangrove stands. Redundancy analysis (RDA) revealed that the soil properties were the important factors influencing both the restored and natural mangrove communities. There were no clear trajectories between the vegetation and soil characteristics with age, possibly due to site‐specific and hydrodynamic environmental factors, such as tidal dynamics, riverine inputs, and climatic variations. While there were some equivalent vegetation and soil characteristics at the end of the first decade after restoration, the restored mangroves may require a longer timespan (approximately 25 years) than the period overserved in our study to be entirely identical to the natural mangroves. This case study from Guyana provides valuable insights into the ecological processes driving mangrove recovery dynamics, growth patterns, and restoration effectiveness and offers reliable data needed to inform future restoration projects. [ABSTRACT FROM AUTHOR]

Published

2024

10. The Temporal and Spatial Dynamics of Succession in a Glacial Foreland in Southern Iceland: The Effects of Landscape Heterogeneity.

Author

Tanner, Lawrence, Kikukawa, Genevieve, and Weits, Kaylyn

Subjects

EFFECT of human beings on climate change, COLONIZATION (Ecology), SPECIES diversity, COMMUNITY development, MORAINES

Abstract

One of the more visible consequences of anthropogenic climate change is the ongoing retreat of glaciers worldwide. Rates of primary succession in the resulting glacial forelands are commonly calculated from a single measurement set using a single set of measurements across a landscape of varying age, but repeated measurements over decadal scales may be a more effective means of examining the rates and trends of colonization and community development. Repeated measurements of vegetation groups in a glacial foreland in southern Iceland demonstrate that successional changes are measurable, as shown by the calculation of the dissimilarity index at sites over a 15 year interval. Inter-site dissimilarity validates the essential paradigm of primary succession, where vegetative coverage increases in the glacial foreland as a function of time and supports earlier interpretations saying that species richness decreases on older surfaces, even as the total vegetation cover increases. However, successional processes are subject to major abiotic factors, such as aspect, which is controlled by landscape topography, and the substrate composition. The glacial moraines and outwash plain are underlain by different substrates which produce separate successional trajectories. Succession on the moraines ultimately produces a birch-shrub-heath community, while the outwash deposits promote development of a moss-heath community. [ABSTRACT FROM AUTHOR]

Published

2024

11. Crayfish communities converge over succession in beaver pond metacommunities.

Author

Howeth, Jennifer G., Lozier, Jeffrey D., Olinger, Charles Thomas, Dedmon, Mark L., Matthews, Joseph M., and Cardoza, Sydney J.

Subjects

*CRAYFISH, *ECOLOGICAL succession, *PONDS, *BIOTIC communities, *BEAVERS, *FRESHWATER habitats, *FRESHWATER ecology, *SPECIES diversity

Abstract

Metacommunity theory predicts that the relative importance of regional and local processes structuring communities will change over ecological succession. Determining effects of these processes on taxonomic and evolutionary diversity in spatially structured freshwater habitats of different successional stages may greatly improve understanding of the maintenance of diversity across temporal and spatial scales. In this study, we evaluated crayfish diversity at local and regional scales in pond metacommunities undergoing secondary succession from beaver (Castor canadensis) disturbance. Following theoretical predictions from metacommunity ecology of the increasing importance of local processes over succession, we hypothesised a decline in crayfish local and β diversity over succession from stronger local structuring as the older ponds may provide less suitable habitat than streams.Crayfish species and phylogenetic diversity were evaluated in beaver pond metacommunities and reference headwater streams located in three catchment regions. DNA sequences from the mitochondrial cytochrome oxidase I gene were used to assign crayfish to species for community and phylogenetic diversity tests. Local and β diversity were contrasted across beaver ponds ranging in age from 24 to 70 years and as a function of metacommunity processes.Counter to predictions, local species diversity among streams and the successional stages of ponds categorised by age class (24–39 years; 42–57 years; 60–70 years) did not differ, but community and phylogenetic convergence occurred in the oldest pond ecosystems. Crayfish community composition differed between the youngest and oldest ponds, resulting from higher abundance in the youngest ponds and community convergence in the oldest ponds. The association between community composition and the environment was strongest in streams and decoupled with pond age. In contrast, the correlation between intraspecific haplotype composition and the environment increased over succession. Among the three metacommunities, the regional crayfish species diversity arose from a combination of the temporal and environmental drivers from beaver‐constructed ecosystems and dispersal limitation within catchments.This study represents the first investigation of the taxonomic and phylogenetic diversity response to the successional stages of beaver pond metacommunities. The detection of differential crayfish composition and haplotype sorting to pond age suggests a role for local structuring and further indicates that future studies should acknowledge succession in shaping species diversity at local and regional scales. Dispersal limitation within catchment regions probably contributes to the evolution of crayfish species diversity in metacommunities and the overall maintenance of biodiversity.The results support a transition in community and freshwater ecology from a recent emphasis on spatial processes towards the integration of temporal drivers to better identify regulators of taxonomic and phylogenetic diversity across scales. [ABSTRACT FROM AUTHOR]

Published

2024

12. Carbon and nitrogen, humic and labile fractions in soil under clonal eucalyptus stands from cerrado.

Author

Moraes, Wendel dos Santos, Dionisio, Luiz Fernandes Silva, Schwartz, Gustavo, Pereira, Juliana Andrade, Damascena, Jossimara Ferreira, Rizzo, Felipe Alexandre, Neto, Alberto Bentes Brasil, de Almeida Milhomem, Camila, Alves, José Maria Arcanjo, Araujo Filho, Renisson Neponuceno, de Almeida Sarmento, Renato, da Silva, Alinne, and Moraes, Cristiano Bueno de

Subjects

*EUCALYPTUS, *CERRADOS, *SOIL chronosequences, *NATIVE plants, *SOILS, *SOIL sampling

Abstract

The objective of this study was to evaluate carbon and (C) and nitrogen (N) of the light organic matter in labile and humic fractions of the soil in a chronosequence of clonal Eucalyptus urophylla. The study was carried out on six different sites in the South-Central region of Maranhão state, northeastern Brazil, inserted in the Cerrado biome. Soil was sampled in five clonal Eucalyptus urophylla S.T. Blake stands of different ages and one in the area with old-growth forest (OG), which represents the native vegetation area. Soil samples were collected in the 0–20, 20–40, and 40–60 cm layers to determine textural class, bulk density, C, and N in the light organic matter of labile and humic fractions. Eucalyptus plantations can have great capacity to increase stocks of soil C and N, humic, and labile fractions over the years, presenting results equal or higher than a native Cerrado forest. Thus, Eucalyptus plantations come as an effective lad use to sink C and increase soil nutrient levels. [ABSTRACT FROM AUTHOR]

Published

2024

13. Chronosequence Changes of Soil Organic Carbon in Salt Marshes under Artificial Intervention: A Case Study of Hengsha Island in the Yangtze Estuary.

Author

Zhang, Jing, Sha, Chenyan, Li, Songshuo, Wang, Min, Wang, Qiang, Wang, Qing, Su, Jinghua, Shen, Cheng, and Huang, Shenfa

Abstract

Land formation seriously disturbs coastal salt marsh wetland ecosystems, while its influences on soil organic carbon (SOC) under chronosequences remain unclear. In this study, the impacts of the land formation time (from one to fourteen years) and soil properties on the chronosequences changes of SOC in the nascent wetland of Hengsha Island were investigated. The study results showed the following. (1) As the land-formation time extended, the SOC experienced a significant increase, tripling after a period of 14 years. The changes in SOC occurred mainly in the surface layer but not in the deep soil layer. Specifically, the surface layer's average SOC reached 5.52 g·kg−1, markedly higher than 3.17 g·kg−1 in the deeper layer. (2) Spearman correlation analysis revealed that the ammonium nitrogen ( N H 4 + -N), aboveground biomass (AGB), and soil water content (SWC) were positively correlated with the SOC. Methane emissions (CH4) and SOC exhibited a negative correlation. (3) The structural equation model (SEM) illustrated that the duration of soil deformation directly impacted the vegetation growth and affected the distribution characteristics of the SOC by modifying the soil environmental conditions. Changes in SOC following land formation influenced the rapid succession of soil properties and vegetation, with the modification of carbon sinks in the ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

14. Habitat niches of bird species along a recovery gradient in the Chocó tropical forest

Author

Ana Falconí-López, Oliver Mitesser, H. Martin Schaefer, Nico Blüthgen, Annika Busse, Heike Feldhaar, Juan Freile, Rudy Gelis, Nina Grella, Christoph Heibl, Mareike Kortmann, Felicity L. Newell, Dominik Rabl, Matthias Schleuning, Sebastian Seibold, Çağan H. Şekercioğlu, Boris A. Tinoco, Constance J. Tremlett, Jörg Müller, and David A. Donoso

Subjects

Conservation, Canandé, Chronosequence, Niche Position, Niche Breadth, Ornithology, Ecology, QH540-549.5

Abstract

Conservation programs need improved tools to measure the recovery of animal diversity across restoration gradients. We used soundscapes and expert identifications of bird species to calculate niche position (i.e., mean of environmental conditions across all areas a species occupies) and niche breadth (i.e., the standard deviation of the species distribution) along a recovery gradient; from agriculture to early (up to 20 yrs) and late (up to 38 yrs) recovery, to old-growth forests. Our survey included 323 bird species and was conducted in 66 plots in the lowland Chocoan tropical rainforest in Ecuador where less than 11% of the forest remains intact, and large areas are currently undergoing regeneration post-abandonment. First, we validated our niche metrics by contrasting them against independent global categories of forest density dependency. We then explained the niche metrics of the bird species with different ecological traits, gathered from the literature, reflecting species-specific primary diet, morphology and distribution, and accounting for the phylogenetic relatedness of species. Finally, we explored the phylogenetic signal present in bird species’ ecological traits and recovery niche metrics. Niche position and breadth across the recovery gradient closely followed global categories of forest density dependency. However, our approach provided a more fine-scaled sorting of bird species in forest plots categorized as late recovery and old-growth. Granivorous birds occupied niche positions in active cacao and pasture plots and were replaced by frugivorous birds in older regeneration plots. Along the recovery gradient, tail length and handwing index decreased with niche position, supporting previous observations that birds in old-growth forests are less mobile. Birds in old-growth forests had smaller global distribution ranges than birds in agricultural plots. Finally, the latitudinal distribution of birds in the study area averaged south of the equator, with birds in old-growth plots averaging latitudinal centroids in wet forests north of the equator, whereas birds in agriculture plots averaged latitudinal centroids further south of the country, towards the dry and open Tumbesian forest. Frugivores, invertivores and vertivores had broader niche breadths, but these decreased (marginally) with tail length. We suggest these recovery niche metrics as a potentially powerful tool for the rapid assessment of the recovery process, which might support conservation strategies such as biodiversity credits, compensation payments, and strategic land purchases. With the increasing availability of information-intensive models for bird species identification, such as deep learning artificial intelligence, our new niche metrics open the avenue for rapid assessment of tropical biodiversity and new conservation areas at larger scales.

Published

2024

15. Low-intensity logging alters species and functional composition, but does not negatively impact key ecosystem services in a Central African tropical forest

Author

Megan K. Sullivan, Jason Vleminckx, Prince Armel Mouguiama Bissiemou, Raoul Niangadouma, Manoushka Ilambi Mayoungou, Juste Lemeilleur Temba, Fabrice Bénédet, Katharine Abernethy, Simon A. Queenborough, and Liza S. Comita

Subjects

Beta diversity, Chronosequence, Functional composition, Understory plant community, Selective logging, Tropical forest, Ecology, QH540-549.5

Abstract

Selective logging can impact tree composition and the long-term sustainability of forests. Studying the ecological consequences of logging practices is crucial for guiding forest management strategies aiming at maintaining ecological integrity and supporting landscape-level conservation goals. We investigated the consequences of very low-intensity selective logging in multiple tree life stages across a logged forest chronosequence in Gabon. We found that species composition differed between logged and unlogged forests at all life stages (seedlings, saplings, and adults), which were most pronounced in the understory of older forests (logged 10 years prior) compared to unlogged areas. However, logging explained a small portion of the variation in species composition (

Published

2024

16. Resilience of Aboveground Biomass of Secondary Forests Following the Abandonment of Gold Mining Activity in the Southeastern Peruvian Amazon.

Author

Garate-Quispe, Jorge, Herrera-Machaca, Marx, Pareja Auquipata, Victor, Alarcón Aguirre, Gabriel, Baez Quispe, Sufer, and Carpio-Vargas, Edgar Eloy

Subjects

*SECONDARY forests, *ABANDONED mines, *GOLD mining, *FOREST biomass, *FOREST succession, *FOREST degradation, *INSULIN pumps

Abstract

Amazon rainforests are critical for providing a wide range of ecosystem services. In the Southeastern Peruvian Amazon; however, goldmining activities are causing severe soil degradation and forest loss. We analyzed aboveground biomass (AGB), forest structure, and species diversity recovery during secondary succession in 179 forest plots. Our study provides the first field-based quantification of AGB recovery following the abandonment by two types of goldmining (heavy machinery and suction pumping) in Madre de Dios (Peru). We found that successional secondary forests in areas subjected to suction pumping were more resilient than those in areas subjected to heavy machinery. After 20 years, mean AGB in suction pumping mining areas had reached 56% of reference forest AGB, while in areas of heavy machinery mining it was only 18%. Mining type, stand age, and distance from the forest edge had a significant effect on AGB. The influence of the distance from the forest edge on AGB varies according to mining type because the effects of species diversity on AGB are mediated by the distance from the forest edge. Our results clearly showed the dynamics of AGB recovery across a secondary succession after goldmining, and the contrasting responses of AGB between the two mining types. Our study disentangles the importance of key factors in forest recovery after mining and improves understanding of the resilience of biomass accumulation in these highly degraded ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

17. Comparing the Response of Red Spruce Plantings on Legacy Coal Mines and Old-Field Restoration Sites in the West Virginia Highlands.

Author

Rhodes, Benjamin M. and Barton, Christopher D.

Abstract

Red spruce (Picea rubens) is the keystone species of the red spruce–northern hardwood forest, a unique high-elevation plant community that supports high biodiversity in the Central Appalachian mountains. These forests were drastically reduced by the Industrial Logging Era of the late 1800s and early 1900s, and the few remaining patches of this forest type remain in a degraded and fragmented state. Efforts to restore this ecosystem in West Virginia have been ongoing for over a decade and include red spruce plantings on old-field agricultural sites and on legacy coal mines. This project seeks to examine restoration outcomes for vegetation and soils along a 10 year chronosequence of planting sites. Significant differences in seedling height were observed for each year examined with old-fields exhibiting higher early (Year 1) heights, while legacy mines were significantly taller in Years 7 and 10. Annual growth rates did not differ between the two planting treatments. Soil chemical differences between treatments may have influenced seedling response. Although comparison of soil characteristics from the reforested sites to those from relatively undisturbed reference red spruce stands exhibited some statistical similarities, it was clear that mining and agricultural practices altered the soil environment greatly. As such, additional research to further examine practices that could improve soil health on these disturbed lands is recommended. [ABSTRACT FROM AUTHOR]

Published

2024

18. Long-term Consequences on Soil Fungal Community Structure: Monoculture Planting and Natural Regeneration.

Author

Naka, Minagi, Masumoto, Shota, Nishizawa, Keita, Matsuoka, Shunsuke, Tatsumi, Shinichi, Kobayashi, Yuta, Suzuki, Kureha F., Xu, Xinyu, Kawakami, Tomoya, Katayama, Noboru, Makoto, Kobayashi, Okada, Kei-ichi, Uchida, Masaki, Takagi, Kentaro, and Mori, Akira S.

Subjects

REGENERATION (Botany), FOREST restoration, TREE planting, FOREST management, FOREST regeneration, FUNGAL communities, ECOSYSTEMS

Abstract

Understanding the regeneration and succession of belowground communities, particularly in forests, is vital for maintaining ecosystem health. Despite its importance, there is limited knowledge regarding how fungal communities change over time during ecosystem development, especially under different forest restoration strategies. In this study, we focused on two restoration methods used in northern Japan: monoculture planting and natural regeneration. We examined the responses of the fungal community to monoculture plantations (active tree planting) and naturally regenerated (passive regeneration) forests over a 50-year chronosequence, using natural forests as a reference. Based on DNA metabarcoding, we assessed the richness of fungal Operational Taxonomic Units (OTUs) and their dissimilarity. Our findings revealed that soil fungal richness remained stable after natural regeneration but declined in monoculture plantations, from 354 to 247 OTUs. While the compositional dissimilarity of fungal assemblages between monoculture plantations and natural forests remained consistent regardless of the time since tree planting, it significantly decreased after natural regeneration, suggesting recovery to a state close to the reference level. Notably, the composition of key functional fungal groups—saprotrophic and ectomycorrhizal— has increasingly mirrored that of natural forests over time following passive natural regeneration. In summary, our study suggests that monoculture plantations may not be effective for long-term ecosystem function and service recovery because of their limited support for soil fungal diversity. These results underscore the importance of natural regeneration in forest restoration and management strategies. [ABSTRACT FROM AUTHOR]

Published

2024

19. Differential Post-Fire Vegetation Recovery of Boreal Plains Bogs and Margins.

Author

Mayner, Kristyn M., Moore, Paul A., Wilkinson, Sophie L., Gage, Henry J. M., and Waddington, James Michael

Abstract

Peatland margins are a distinct ecotone especially vulnerable to deep smouldering in the Boreal Plains because they can experience greater water table drawdown during dry periods compared to peatland middles. Margin recovery trajectories have potentially important implications for wildfire behaviour as both the rate of vegetation recovery and community composition control fuel load and flammability. We compared peatland margin and middle vegetation trajectories using a chronosequence of time-since-fire in boreal Alberta, Canada. Margins had unique post-fire indicator species, with a higher broadleaf cover and limited Sphagnum moss colonization. Middles and margins became less distinct with greater time-since-fire, where both were dominated by feathermoss as canopy closure increased. High burn severity in margins can expose the seedbank in the underlying mineral soil to favourable conditions, causing rapid accumulation of broadleaf aboveground biomass and limiting Sphagnum establishment. The rapid accumulation of aboveground biomass increases potential fuel load, while exclusion of Sphagnum increases future smouldering potential given the dense peat in the margin ecotone. However, the dominance of deciduous vegetation for several decades post fire would serve to limit wildfire compared to a conifer-dominated system, particularly post leaf-out. Thus, peatland margins could represent a positive feedback to peat carbon loss for early season fires and a negative feedback for post leaf-out fires due to the interplay between fuel load, fire seasonality, and species flammability. Characterization of margins as distinct ecotones with a separate vegetation structure and species composition from peatland middles provides critical insight about wildfire vulnerability and carbon storage in the Boreal Plains. [ABSTRACT FROM AUTHOR]

Published

2024

20. Structural Shifts in the Soil Prokaryotic Communities Marking the Podzol-Forming Process on Sand Dumps.

Author

Evdokimova, Elizaveta, Ivanova, Ekaterina, Gladkov, Grigory, Zverev, Aleksei, Kimeklis, Anastasiia, Serikova, Elena, Pinaev, Alexandr, Kichko, Arina, Aksenova, Tatiana, Andronov, Evgeny, and Abakumov, Evgeny

Subjects

*SOIL horizons, *SOIL profiles, *SOILS, *SOIL restoration, *NUCLEOTIDE sequencing

Abstract

This work describes the microbial community structure of the continuously revegetated chronosequence of a former sand quarry, which demonstrates a unique example of nearly complete soil restoration in less than 100 years. Samples were collected at five time points (0, 3, 30, 70 years and mature soil) from the entire set of soil horizons, revealing the history of pedogenesis. Real-time PCR was applied to quantitatively describe the bacterial and archaeal communities. High-throughput sequencing of the bacterial and archaeal V4 variable region of the 16S rRNA gene was used to identify abundant microbial taxa. A beta-diversity analysis revealed that the prokaryotic community structure responded strongly to the processes of organic matter accumulation and the corresponding evolution of the soil into discrete horizons. Changes in soil microbiota in the course of soil profile evolution revealed three groups of prokaryotes, which tended to accumulate in the specific soil horizons and might be associated with the certain soil-forming processes, including plant roots growth. This research showed the heuristic potential of soil horizon profiling in microbiological studies as opposed to the formal depth-dependent separation of the soil layers. The results allowed us to trace the relationship between the structure of the soil prokaryotic community and the peculiarities of the evolution of the podzolic soil profile as well as to identify the microbial indicators and drivers of primary pedogenesis. [ABSTRACT FROM AUTHOR]

Published

2024

21. Seedling recruitment in response to stand composition, interannual climate variability, and soil disturbance in the boreal mixed woods of Canada.

Author

Maleki, Kobra, Marchand, Philippe, Charron, Danielle, and Bergeron, Yves

Subjects

*FOREST regeneration, *POPULUS tremuloides, *WHITE spruce, *BALSAM fir, *FOREST management, *SEEDLINGS

Abstract

Aim: Seedling recruitment is a vital process for forest regeneration and is influenced by various factors such as stand composition, climate, and soil disturbance. We conducted a long‐term field experiment (18 years) to study the effects of these factors and their interactions on seedling recruitment. Location: Our study focused on five main species in boreal mixed woods of eastern Canada: trembling aspen (Populus tremuloides), paper birch (Betula papyrifera), white spruce (Picea glauca), balsam fir (Abies balsamea), and white cedar (Thuja occidentalis). Methods: Sixteen 1‐m2 seedling monitoring subplots were set up in each of seven stands originating from different wildfires (fire years ranging from 1760 to 1944), with a soil scarification treatment applied to every other subplot. Annual new seedling counts were related to growing‐season climate (mean temperature, growing degree days and drought code), scarification, and stand effects via a Bayesian generalized linear mixed model. Results: Soil scarification had a large positive effect on seedling recruitment for three species (aspen, birch and spruce). As expected, high mean temperatures during the seed production period (two years prior to seedling emergence) increased seedling recruitment for all species but aspen. Contrary to other studies, we did not find a positive effect of dry conditions during the seed production period. Furthermore, high values of growing degree days suppressed conifer seedling recruitment. Except for white cedar, basal area was weakly correlated with seedling abundance, suggesting a small number of reproductive individuals is sufficient to saturate seedling recruitment. Conclusion: Our findings underscore the importance of considering multiple factors, such as soil disturbance, climate, and stand composition, as well as their effects on different life stages when developing effective forest management strategies to promote regeneration in boreal mixed‐wood ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

22. Introduced species infiltrate recent stages of succession after glacial retreat on sub-Antarctic South Georgia.

Author

Tichit, Pierre, Brickle, Paul, Newton, Rosemary J., Convey, Peter, and Dawson, Wayne

Subjects

*INTRODUCED species, *COLONIZATION (Ecology), *INVERTEBRATE communities, *GLOBAL warming, *INTRODUCED plants

Abstract

Biological invasions are one of the main drivers of global biodiversity decline. At the same time, glacial retreat induced by climate warming is occurring at an alarming rate across the globe, threatening unique taxa and ecosystems. However, we know little about how introduced species contribute to the dynamics of colonisation in newly-deglaciated forelands. To answer this question, detailed inventories of plant and invertebrate communities were undertaken during two summer field seasons in the forelands of three tidewater and three inland glaciers that are retreating on the sub-Antarctic Island of South Georgia. The vascular plant communities present included a large proportion of South Georgia's native flora. As expected, plant richness and cover increased with time since deglaciation along a deglaciation chronosequence. Introduced plants were well represented in the study sites and two species (Poa annua and Cerastium fontanum) were amongst the earliest and most frequent colonisers of recently-deglaciated areas (occurring on more than 75% of transects surveyed). Introduced arthropods were also present around tidewater glaciers, including an important predatory species (Merizodus soledadinus) with known detrimental impacts on native invertebrate communities. Our study provides a rare and detailed picture of developing novel communities along a deglaciation chronosequence in the sub-Antarctic. Introduced species are able to track glacial retreat on South Georgia, indicating that further local colonisation and spread are inevitable as the region's climate continues to warm. [ABSTRACT FROM AUTHOR]

Published

2024

23. Albedo‐Induced Global Warming Potential Following Disturbances in Global Temperate and Boreal Forests.

Author

Zhu, Qingsong, Chen, Jiquan, Charles P.‐A., Bourque, Sonnentag, Oliver, Montagnani, Leonardo, O'Halloran, Thomas L., Scott, Russell L., Forsythe, Jeremy, Song, Bo, Zou, Huimin, Duan, Meihui, and Li, Xianglan

Subjects

TAIGAS, GREENHOUSE gases, SURFACE of the earth, FOREST succession, ALBEDO, TEMPERATE forests, SOLAR energy, HUMAN activity recognition

Abstract

Forest disturbances can result in very different canopies that carry elevated albedo, thus causing substantial cooling effects on the climate. Unfortunately, the resulting dynamic global warming potential from altered albedo (GWPΔα) is poorly understood. We examined and modeled the changes in albedo over time after disturbances (i.e., forest age) by forest type, disturbance type and geographic location using direct measurements from 107 sites in temperate and boreal regions. Albedo in undisturbed forests was used as the reference to calculate albedo changes (Δα) and GWPΔα after a disturbance. We found that age is a significant factor for predicting albedo amid the obvious regulations from forest type and geographic locations. We found the strongest cooling GWPΔα in the first 10 years after a disturbance, but it decreased rapidly with time. The changes in GWPΔα were very different from the chronosequence of net ecosystem production (NEP). In the first decade after disturbances, GWPΔα was negative (i.e., cooling) and surprisingly larger in magnitude, with an average of −0.609 kg CO2 m−2 yr−1, compared to NEP of −0.166 kg CO2 m−2 yr−1. Albedo continued to decrease and approached pre‐disturbance levels until around 50 years, resulting in a nearly zero GWPΔα. This research illustrates that many forests in temperate and boreal regions can be considered significant cooling agents by taking into account the high albedo of young forests following disturbances. Plain Language Summary: After forest disturbances, the removal of dense canopies exposes brighter surfaces, leading to higher surface albedo. Changes in albedo, which affect the reflection of solar energy from the Earth's surface, can have different climate impacts of greenhouse gases emissions like CO2. In this study, we used in situ observations to model how albedo changes over time following forest disturbances. We also assessed the climate impacts of these albedo changes, taking into account their temporal dynamics. Our results show that the age of the forest is the most significant factor influencing albedo dynamics after disturbances. However, the trajectory of albedo dynamics also depends on the forest types and disturbance types. We found that the elevated albedo in forests after disturbances accounts for substantial cooling effects in the first 20 years that is comparable to the effect of net ecosystem production (NEP). Understanding the dynamic of albedo following forest disturbances is essential for quantifying the climate impacts, especially as more forests are experiencing disturbances induced by human activities. Key Points: Age, forest type, and disturbance type significantly influence post‐disturbance albedo dynamics, with age having the most substantial impactElevated albedo in forests after disturbances exerts a dominant cooling effect within the first 20 years of successionQuantifying the climate impact of changing albedo post‐disturbance should consider the successional trajectory, as its effects are highly time‐sensitive [ABSTRACT FROM AUTHOR]

Published

2024

24. Shrub Age and Water Dynamics Influence Primary Production, Carbon, and Nitrogen Stocks in a Coastal Environment.

Author

Wood, Lauren K., Young, Donald R., and Zinnert, Julie C.

Abstract

Drivers of shrub primary production and associated landscape impacts of encroachment are well known in drylands but have not been thoroughly studied in mesic and coastal habitats. The native, nitrogen-fixing shrub, Morella cerifera, has expanded into coastal grassland along the US Atlantic coast due to warming temperatures, but impacts on ecosystem function are not well known. Annual net primary production (ANPP) of Morella cerifera and key environmental drivers were measured long-term (1990 – 2007) across a chronosequence of shrub age on a mid-Atlantic barrier island. Soil and groundwater nutrients were compared with un-encroached grassland soil to evaluate impacts of vegetation on nutrient dynamics. Shrub ANPP declined with age at the same rate among all thickets, but there was variability from year to year. When climate variables were included in models, shrub age, precipitation, and freshwater table depth were consistent predictors of ANPP. Water table depth decreased over time, reducing ANPP. This may be due to rising sea-level, as well as to feedbacks with shrub age and evapotranspiration. Soil N and C increased with shrub age and were higher than adjacent grassland sites; however, there was a significant loss of N and C to groundwater. Our results demonstrate that drivers influencing the encroachment of shrubs in this coastal system (i.e., warming temperature) are not as important in predicting shrub primary production. Rather, interactions between shrub age and hydrological properties impact ANPP, contributing to coastal carbon storage. [ABSTRACT FROM AUTHOR]

Published

2024

25. The Evolution of Hillslope Hydrology: Links Between Form, Function and the Underlying Control of Geology.

Author

Hartmann, Anne and Blume, Theresa

Subjects

HYDROLOGY, SOIL formation, SOIL acidification, GEOLOGY, LEAD in soils, SOIL moisture, WATER storage, MICROIRRIGATION

Abstract

Form and function are two major characteristics of hydrological systems. While form summarizes the structure of the system, function represents the hydrological response. Little is known about how these characteristics evolve and how form relates to function in young hydrological systems. We investigated how form and function evolve during the first millennia of landscape evolution. We analyzed two hillslope chronosequences in glacial forelands, one developed from siliceous and the other from calcareous parent material. Variables describing hillslope form included soil physical properties, surface, and vegetation characteristics. Variables describing hydrological function included soil water response times, soil water storage, drainage, and dominant subsurface flow types. We identified links between form and hydrological function via cluster analysis. Clusters identified based on form were compared in terms of their hydrological functioning. The comparison of the two different parent materials shows how strongly landscape evolution is controlled by the underlying geology. Soil pH appears to be a key variable influencing vegetation, soil formation and subsequently hydrology. At the calcareous site, the high buffering capacity of the soil leads to less soil formation and fast, vertical subsurface water transport dominates the water redistribution even after more than 10,000 years of landscape evolution. At the siliceous site, soil acidification results in accumulation of organic material, a high water storage capacity, and in podsolization. Under these conditions water redistribution changes from vertical subsurface water transport at the young age classes to water storage in the organic surface layer and lateral subsurface water transport within 10,000 years. Key Points: The underlying geology controls landscape evolution in glacial forefieldsAfter 10,000 years of evolution, hillslope form and hydrological functioning differ between the calcareous and siliceous sitesSoil pH is a key variable indicative of differences in soil evolution and hydrological response between the two forefields [ABSTRACT FROM AUTHOR]

Published

2024

26. Directional succession and species-specific patterns observed in repeat study of vascular plants at three glacier foreland chronosequences in the Canadian High Arctic

Author

Katriina O'Kane and Greg H.R. Henry

Subjects

chronosequence, glacier foreland, High Arctic, primary succession, repeat study, tundra, Environmental sciences, GE1-350, Environmental engineering, TA170-171

Abstract

The expanding area of glacier forelands provides new terrain for ecosystem development. Plant succession facilitates this development, but this process remains poorly documented in marginal environments such as the High Arctic. This paper presents the results of the first repeat study of glacier foreland chronosequences conducted in the Canadian High Arctic. The forelands of Twin Glacier, Beitstad Glacier, and Teardrop Glacier near Alexandra Fiord, Ellesmere Island, Nunavut were first surveyed in 1995, and these surveys were repeated 21 years later using the same methods. The objectives of this study were to document the patterns of vascular plant species composition and abundance across these three forelands to (1) determine the accuracy of the hypothesis from the original study that succession on these forelands was directional, and (2) investigate the use of the chronosequence method in High Arctic succession studies. Forelands were surveyed using % cover estimates or presence/absence counts. Indicator species analysis and rates of change were used to quantify shifts in vascular plant species over time. Total plant cover increased by 2.4% in the first 100 m of the Twin Glacier foreland study area, and species richness also increased on younger terrain. Rates of peak cover and first appearance advance varied greatly between species and forelands, but were generally faster for graminoid and forb species than shrub species, and slower on species-poor Beitstad Glacier foreland. At all three forelands there was a general pattern of directional succession as all species advanced towards the retreating glacier margin. This supports the original hypothesis that directional succession is a common pattern for glacier forelands in the High Arctic. However, we also found that species-specific patterns and rates of change acted to create assemblages that differed between 1995 and 2016. Different abundances of species and successional trajectories were observed between the three forelands, pointing to the importance of local species pools and dispersal limitation. Finally, we observed that the first occurrence of most species was further from the glacier margin in 2016 compared to 1995, perhaps due to accelerating rates of glacier retreat. These species-specific patterns, differences between forelands, and the delayed response of vegetation to glacier retreat demonstrate the importance of using repeat studies over time and replication over space to confirm the results observed in High Arctic glacier foreland chronosequence studies.

Published

2024

27. Long-term post-fire recovery of oribatid mites depends on the recovery of soil properties in a fire-adapted pine forest

Author

Jitka Farská, Veronika Jílková, Lee E. Frelich, Josef Starý, and Miloslav Devetter

Subjects

Chronosequence, Prescribed burning, Minnesota, Oribatida, Functional traits, Forestry, SD1-669.5, Plant ecology, QK900-989

Abstract

Fire is a highly important factor affecting the forest structure as well as its functions. The understanding of the post-fire recovery mechanisms could be especially useful in the face of globally increasing fire frequencies. Fire-adapted forests in Minnesota provide a unique opportunity to study these recovery mechanisms due to their long and well-documented history of prescribed burnings and wildfires. We investigated oribatid mite (Acari: Oribatida) assemblages along a 126-year post-fire chronosequence, together with soil physical, chemical and microbial properties (e.g. bulk density, organic matter content, C, N and P content, microbial biomass). Whereas the effect of prescribed burning was negligible, the wildfire decreased oribatid density (–86 %) and diversity (–38 %) for at least 13 years. The recovery of oribatid mites corresponded to the changes in soil properties, being correlated negatively to bulk density and positively to organic matter content, water holding capacity and microbial activity and biomass. The recovery did not depend simply on the time elapsed since fire, but it was rather a complex response to long-term (15–20 years), fire-induced changes in the soil environment.

Published

2024

28. Soil nematodes modify interactions between nitrogen-fixing and non-fixing tree seedlings from late, but not early, successional stages

Author

Gilarte, P., Plett, J. M., Pendall, E., Carrillo, Y., and Nielsen, U. N.

Published

2024

29. Decreased soil N2O and N2 emissions during the succession of subtropical forests

Author

Yuan, Mingyue, Li, Ping, Lu, Zhiyun, and Chen, Zhe

Published

2024

30. Effect of residence time on trait evolution in invasive plants: review and meta-analysis.

Author

Gruntman, Michal and Segev, Udi

Subjects

*INVASIVE plants, *PLANT evolution, *COMPETITION (Biology), *PLANT size, *PLANT populations, *NATIVE plants, *DWELLINGS

Abstract

The success of invasive species is often attributed to rapid post-introduction evolution, due to novel selection pressures at the introduced range. However, evolutionary shifts in invasion-promoting traits can also take place within the introduced range over time. Here, we first present a review of the proposed hypotheses regarding the selection pressures and trait divergence along gradients of invasion history and the studies that examined them. In addition, we present the results of a meta-analysis aimed to provide a more general overview of current knowledge on trait evolution with time since introduction. Invasion - promoting traits, including growth, competitive ability and dispersal ability, were proposed to decline in more established populations with a long invasion history due to the attenuation of selection pressures, such as enemy release or interspecific competition, while herbivore defence was suggested to increase. Our meta-analysis results reveal a general indication for the evolution of invasive plants with residence time for most of the studied traits. However, this divergence did not have a consistent direction in most traits, except for growth, which, in contrast with our prediction, increased with residence time. The lack of empirical support for the predicted change in most of the studied traits over time suggests trait evolution might be affected by other context-dependent factors such as climatic gradients along invasion routes. Similarly, the increased allocation to size in older and more established populations may be driven by increased conspecific competition pressure experienced in these populations. The general temporal effect found in our meta-analysis stresses the need to consider population age when comparing attributes of invasive plants between native and invasive ranges. Moreover, the increased size of invasive plants in older populations, suggests that the dominance of these plants might not attenuate with time since introduc tion, thus highlighting the need to further explore the long-term dynamics between invasive plants and their recipient native communities. [ABSTRACT FROM AUTHOR]

Published

2024

31. Successional development of the phototrophic community in biological soil crusts, along with soil formation on Holocene deposits at the Baltic Sea coast.

Author

Kammann, Sandra, Leinweber, Peter, Glaser, Karin, Schiefelbein, Ulf, Dolnik, Christian, Mikhailyuk, Tatiana, Demchenko, Eduard, Heilmann, Elena, Karsten, Ulf, Elster, Josef, and Lakatos, Michael

Subjects

SAND dunes, CRUST vegetation, SOIL formation, BIOTIC communities, HOLOCENE Epoch, COASTS

Abstract

Harsh environmental conditions form habitats colonized by specialized primary microbial colonizers, e.g., biological soil crusts (biocrusts). These cryptogamic communities are well studied in drylands but much less in temperate coastal dunes, where they play a crucial role in ecological functions. Following two dune chronosequences, this study highlights the successional development of the biocrust's community composition on the Baltic Sea coast. A vegetation survey, followed by morphological species determination, was conducted. Sediment/soil cores of the different dune types were analyzed to uncover the potential impacts of the biocrust community on initial soil formation processes, with special emphasis on biogeochemical phosphorous (P) transformations. Biocrust succession was characterized by a dune type-specific community composition, shifting from thinner algae-dominated biocrusts in dynamic dunes to more stable moss-dominated biocrusts in mature dunes. The change in the biocrust community structure was accompanied by an increase in Chl a, water, and organic matter content. In total, 25 algal and cyanobacterial species, 16 mosses, and 26 lichens across all sampling sites were determined. The pedological characterization of these cores elucidated initial processes of soil genesis, such as decalcification, acidification, and the accumulation of organic matter with dune and biocrust development. Furthermore, the chemistry of iron (Fe)- containing compounds such as the Fedithionite/Fetotal ratios confirmed mineral weathering and the beginning of soil profile development. The biocrusts accumulated P over time, while the P content in the underlying sediment did not change. That implies that biocrusts take up P from the geological parent material in the dunes, thereby accumulating available P in the ecosystem, which gets transferred into subsoil horizons through leaching or redeposition. The relative proportion of the bioavailable P pool (56% to 74% of Pt) increased with dune succession. That happened at the expense of more stable bound P, which was transformed into labile P. Thus, the level of plant available P along the dune chronosequences increased due to the microbial activity of the biocrust organisms. It can be concluded that biocrusts of temperate coastal dunes play a crucial role in maintaining their habitat by accumulating nutrients and organic matter, supporting soil development and subsequent vegetation. [ABSTRACT FROM AUTHOR]

Published

2024

32. The role of the soil seed bank for the restoration potential of eroded alpine grassland.

Author

Wellstein, Camilla, Tonin, Rita, Peratoner, Giovanni, Löbmann, Michael T., Zwack, Bastian, Della Rosa, Lisa, Mayr, Andreas, Geitner, Clemens, and Zerbe, Stefan

Subjects

*SOIL seed banks, *GRASSLANDS, *RESTORATION ecology, *PLATEAUS, *MOUNTAIN meadows, *NATURE conservation

Abstract

The UN Decade on Ecosystem Restoration 2021–2030 has launched nature conservation, environmental protection, and ecosystem services' restoration on the global environmental policy agenda. However, particularly high mountain habitats being subject to erosion are up to now hardly restorable. Erosion with associated loss of vegetation, soil, and its fertility, is one of the most urgent environmental problems throughout the world. Consequently, we analyzed the soil seed bank of calcareous high‐mountain grassland in the European Alps to reveal the natural regeneration potential after shallow erosion events. We applied a chronosequence approach taking recently eroded grassland areas (<5 years) as well as areas with earlier erosion events (>5 up to 10 and >27 years) into account. Our results revealed that the vegetation of old eroded areas was not closely similar to the surrounding intact grasslands. However, it was well differentiated from the initial stages of young and intermediate eroded areas' vegetation and had higher plant cover and species richness. The old eroded areas' seed bank had higher seed density and species richness compared to younger areas. While typical mountain meadow species were present in the seedbank of eroded areas, the assessed indicator species of both, younger and older eroded areas did not resemble the ones of the aboveground vegetation. We conclude that the seed bank has important but limited potential for the restoration of the complete species range of calcareous eroded alpine grasslands. This implies that additional restoration measures are needed to reintroduce species absent from the seed bank. [ABSTRACT FROM AUTHOR]

Published

2024

33. Low predictability in aboveground biomass accumulation in Brazilian semi‐deciduous seasonal Atlantic Forest restoration sites.

Author

Arcanjo, Fátima A., Lemos, Giovanna G., Tartari, Letícia G., and Torezan, José M. D.

Subjects

*FOREST restoration, *BIOMASS, *TREE planting, *FOREST density, *CARBON sequestration, *BIOMASS conversion, WOOD density

Abstract

There are high expectations about the role of active reforestation in mitigating climate change, by means of carbon sequestration and storage, fueling the carbon credit market. Carbon credits are calculated in advance based on the number of planted trees or, at best, the expected size and wood density of planted trees. However, the contribution of tropical reforestations with native species for carbon sequestration in the long term is still unclear, since most sites being monitored are less than 20 years old, thus limiting the ability to make forecasts of what is a dynamic, multifactor restoration outcome. We used a chronosequence to analyze aboveground biomass (AGB) accumulation in 30 Brazilian semi‐deciduous seasonal Atlantic Forest restoration sites sharing the same climate, soil type, and restoration technique. We evaluated the entire age range of 1–19 years, and three age intervals, 1–3 years, 4–8 years, and over 9 years. AGB, basal area, and tree density increased considering all ages (1–19 years). Our results showed, however, that the AGB, tree density, and basal area can increase linearly from 1 to 3 years but present no significant trend after 4 years. Adjusted model r2 values decreased with time, suggesting that the controlled effects of active restoration are quickly replaced by other natural, uncontrolled, and, to some extent, unknown factors. Although continued efforts are needed to make more realistic predictions of long‐term carbon stocks based on tree planting, high levels of biomass estimates for time intervals as short as 20 years may never be achieved. [ABSTRACT FROM AUTHOR]

Published

2024

34. Long-term soil organic carbon changes after cropland conversion to grazed grassland in Southern Sweden.

Author

Johansson, Anna, Livsey, John, Guasconi, Daniela, Hugelius, Gustaf, Lindborg, Regina, and Manzoni, Stefano

Subjects

GRASSLANDS, CLIMATE change mitigation, FARMS, SOIL mineralogy, CARBON in soils, PLATEAUS, LAND cover

Abstract

There is growing awareness of the potential value of agricultural land for climate change mitigation. In Sweden, cropland areas have decreased by approximately 30% over recent decades, creating opportunities for these former croplands to be managed for climate change mitigation by increasing soil organic carbon (SOC) stocks. One potential land-use change is conversion of cropland to grazed grasslands, but the long-term effect of such change in management is not well understood and likely varies with soil type and site-specific conditions. Through sampling of mineral and peatland soils within a 75-year chronosequence of land converted from crop production to grazed grassland, we assessed how time since conversion, catenary position, and soil depth affected SOC storage. The SOC stocks calculated at an equivalent soil or ash mass increased through time since conversion in mineral soils at all topographic positions, at a rate of ~0.65% year-1. Soils at low topographic positions gained the most carbon. Peat SOC stock gains after conversion were large, but only marginally significant and only when calculated at an equivalent ash mass. We conclude that the conversion of mineral soil to grazed grassland promotes SOC accumulation at our sites, but climate change mitigation potential would need to be evaluated through a full greenhouse gas balance. [ABSTRACT FROM AUTHOR]

Published

2024

35. Incomplete recovery of tree community composition and rare species after 120 years of tropical forest succession in Panama.

Author

Elsy, Alexander D., Pfeifer, Marion, Jones, Isabel L., DeWalt, Saara J., Lopez, Omar R., and Dent, Daisy H.

Subjects

FOREST succession, ENDANGERED species, TROPICAL forests, FOREST biodiversity, SECONDARY forests, OLD growth forests

Abstract

Copyright of Biotropica 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

2024

36. Bacterial community network complexity and role of stochasticity decrease during primary succession

Author

He, Yucheng, Tripathi, Binu M., Fang, Jie, Liu, Zihao, Guo, Yaping, Xue, Yue, and Adams, Jonathan M.

Published

2024

37. Changes in Diversity and Abundance of Ammonia-Oxidizing Archaea and Bacteria along a Glacier Retreating Chronosequence in the Tianshan Mountains, China.

Author

Wu, Xiukun, Zhang, Wei, Liu, Guangxiu, Chen, Tuo, and Li, Zhongqin

Subjects

AMMONIA-oxidizing archaebacteria, AMMONIA-oxidizing bacteria, SOIL chronosequences, NITROGEN cycle, GLOBAL warming, MICROBIAL communities

Abstract

Glaciers retreating due to global warming create important new habitats, particularly suitable for studying ecosystem development where nitrogen is a limiting factor. Nitrogen availability mainly results from microbial decomposition and transformation processes, including nitrification. AOA and AOB perform the first and rate-limiting step of nitrification. Investigating the abundance and diversity of AOA and AOB is essential for understanding early ecosystem development. The dynamics of AOA and AOB community structure along a soil chronosequence in Tianshan No. 1 Glacier foreland were analyzed using qPCR and clone library methods. The results consistently showed low quantities of both AOA and AOB throughout the chronosequence. Initially, the copy numbers of AOB were higher than those of AOA, but they decreased in later stages. The AOB community was dominated by "Nitrosospira cluster ME", while the AOA community was dominated by "the soil and sediment 1". Both communities were potentially connected to supra- and subglacial microbial communities during early stages. Correlation analysis revealed a significant positive correlation between the ratios of AOA and AOB with soil ammonium and total nitrogen levels. These results suggest that variations in abundance and diversity of AOA and AOB along the chronosequences were influenced by ammonium availability during glacier retreat. [ABSTRACT FROM AUTHOR]

Published

2023

38. Development of sandy soil properties within subtropical residential landscapes

Author

Ronald A. Fox, Allan R. Bacon, Heather A. Enloe, and Eban Z. Bean

Subjects

Urban soil, Residential landscapes, Chronosequence, Turfgrass, Carbon accumulation, Soil quality, Science, Technology

Abstract

Abstract Urbanization is homogenizing residential developments and soils across a wide climate gradient of the United States. Land development practices commonly install landscapes on low-quality compacted fill material. While previous research shows that soil quality beneath urban lawns improves over time, studies used golf courses to represent lawns or sampled across variable development and management styles. Limited data on sandy soil quality within residential landscapes in subtropical climate warranted investigation. To evaluate the effect of age on residential soil characteristics, two residential developments from Central and Southwest Florida were selected based on known lot ages up to 31 years. Soil samples (0 to 30 cm) were collected from landscape beds and lawns, along with lawn of common areas, to evaluate bulk density and organic matter over time. Though landscape beds typically require less management, soil characteristics were similar between lawns and landscape beds, suggesting similar processes. Bulk densities decreased by 22–34% and 9–20% within the upper (0–15 cm) and lower (15–30 cm) soil depths, respectively. Upper layer soil carbon accumulation rates ranged from 0.060 to 0.156 kg C m−2 yr−1, comparable to previous studies but did not exceed 0.021 kg C m−2 yr−1 or were not significant for greater depths. The results of this study are representative of past chronosequence studies conducted in cooler climates with fine soil texture. Sandy soil texture and warm climate do not govern carbon sequestration rates, but instead vegetation type and landscape management practices overcome these conditions.

Published

2023

39. Diversity and Distribution of Monocot Understory Herbs during Tropical Forest Succession in Northeastern Costa Rica

Author

Jennifer W. C. Sun, Robin L. Chazdon, and Philip W. Rundel

Subjects

understory herb, chronosequence, secondary tropical forests, forest succession, Araceae, Biology (General), QH301-705.5

Abstract

Broad-leaved monocot herbs form one of the most common and diverse growth forms of Neotropical plants. Their significance and frequency of occurrence is particularly notable in the understories of tropical rainforests, where they form a dominant element. We assessed and quantified changes in the cover and diversity of understory herb communities in a chronosequence of 1 ha permanent plots established as part of a multidisciplinary study on tropical forest regeneration in the Atlantic lowlands of northeastern Costa Rica. Sampled were two young stands cleared 12 years ago, two secondary forests with 21 and 39 of years of recovery since clearance, and two stands in old-growth primary forest. Changes in species composition during succession were assessed using Chao’s Jaccard similarity index. Observed species richness ranged from 15 to 26 species in individual plots, with the greatest number of species in the 21-year intermediate-age and fewest in the young 12-year plots. Herb species sampled represented 6 families, 15 genera, and 39 species, with the Araceae contributing the largest number of species. Ten species were sampled in all six stands, while fourteen species were found exclusively in one plot. Herb density (ramets m−2) showed a hump-shade trend, with peak density in the intermediate stands and a lower level in mature and young secondary forests. Mean herb cover in 25 m2 quadrats ranged from 2.0% (young stand) to 22.7% (intermediate-age stand) and differed significantly both among stand types and among sites. Both observed and estimated species richness increased along the chronosequence as a whole, with the highest number of species in primary forest, although only slightly higher than in intermediate-age stands. Over half of the species exhibited some degree of clonal growth, with the extent of clonal spread varying among species and forest stands. Although we did not find a clear pattern between clonality and forest age, we observed a greater number of clonal patches in secondary over primary forest stands.

Published

2024

40. The Temporal and Spatial Dynamics of Succession in a Glacial Foreland in Southern Iceland: The Effects of Landscape Heterogeneity

Author

Lawrence Tanner, Genevieve Kikukawa, and Kaylyn Weits

Subjects

primary succession, glacial foreland, chronosequence, moraine, outwash plain, functional group, Agriculture

Abstract

One of the more visible consequences of anthropogenic climate change is the ongoing retreat of glaciers worldwide. Rates of primary succession in the resulting glacial forelands are commonly calculated from a single measurement set using a single set of measurements across a landscape of varying age, but repeated measurements over decadal scales may be a more effective means of examining the rates and trends of colonization and community development. Repeated measurements of vegetation groups in a glacial foreland in southern Iceland demonstrate that successional changes are measurable, as shown by the calculation of the dissimilarity index at sites over a 15 year interval. Inter-site dissimilarity validates the essential paradigm of primary succession, where vegetative coverage increases in the glacial foreland as a function of time and supports earlier interpretations saying that species richness decreases on older surfaces, even as the total vegetation cover increases. However, successional processes are subject to major abiotic factors, such as aspect, which is controlled by landscape topography, and the substrate composition. The glacial moraines and outwash plain are underlain by different substrates which produce separate successional trajectories. Succession on the moraines ultimately produces a birch-shrub-heath community, while the outwash deposits promote development of a moss-heath community.

Published

2024

41. Succession as a Natural Tool for Restoration of Oak—Lime Forests on Aspen-Covered Clearcuts

Author

Alina Nasibullina, Katharina Tiebel, and Sven Wagner

Subjects

chronosequence, generalized additive model, rejuvenation, Quercus robur L., Tilia cordata Mill., Populus tremula L., Biology (General), QH301-705.5

Abstract

The genus Quercus, including species like pedunculate oak (Quercus robur L.), can play a key role in maintaining climate-resistant mixed forests due to its broad ecological spectrum and drought tolerance. Unfortunately, in some parts of Europe, clearcutting has drastically reduced the oak population. An example of this event is our survey of heritage Oak—Lime forests in European Russia, which were transformed into pure aspen stands. The aim of our study was to provide forecasts and silvicultural recommendations for the passive restoration of these forests. We took a chronosequence approach to assess changes associated with natural succession over 60 years. In our survey of the development of oaks, limes and accompanying tree species (aspen, birches, maples, elms), we used 190 plots ranging across a wide spectrum of forest disturbance due to clearcutting. We demonstrate that aspen reproduce rapidly by root suckers after cutting and occupy more than 60% of the space. But the dominance of aspen decreases continuously from the age of 30, and then the lime trees begin to dominate. Oak does not show successful natural regeneration. Therefore, we recommend planting oak seedlings or sowing acorns, i.e., active restoration, in combination with the natural restoration of lime.

Published

2024

42. Development of Nutrient Stocks and Soil Properties of Restored Solid Waste Dump After 5 Years of Afforestation with Guava Fruit Orchard

Author

Bandyopadhyay, Sneha, Maiti, Subodh Kumar, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Kumar, Sunil, editor, Ghangrekar, Makarand M., editor, and Kundu, Abhijit, editor

Published

2023

43. Nematode community diversity and function across an alpine landscape undergoing plant colonization of previously unvegetated soils

Author

Porazinska, Dorota L, de Mesquita, Clifton P Bueno, Farrer, Emily C, Spasojevic, Marko J, Suding, Katharine N, and Schmidt, Steven K

Subjects

Climate Action, Life Below Water, Chronosequence, Plant gradient, Primary succession, Soil C and N, Soil microbiota, Environmental Sciences, Biological Sciences, Agricultural and Veterinary Sciences, Agronomy & Agriculture

Published

2021

44. Pioneer Arabidopsis thaliana spans the succession gradient revealing a diverse root-associated microbiome

Author

Vera Hesen, Yvet Boele, Tanja Bakx-Schotman, Femke van Beersum, Ciska Raaijmakers, Ben Scheres, Viola Willemsen, and Wim H. van der Putten

Subjects

Secondary succession, Soil, Bacteria, Fungi, Chronosequence, Environmental sciences, GE1-350, Microbiology, QR1-502

Abstract

Abstract Background Soil microbiomes are increasingly acknowledged to affect plant functioning. Research in molecular model species Arabidopsis thaliana has given detailed insights of such plant-microbiome interactions. However, the circumstances under which natural A. thaliana plants have been studied so far might represent only a subset of A. thaliana’s full ecological context and potential biotic diversity of its root-associated microbiome. Results We collected A. thaliana root-associated soils from a secondary succession gradient covering 40 years of land abandonment. All field sites were situated on the same parent soil material and in the same climatic region. By sequencing the bacterial and fungal communities and soil abiotic analysis we discovered differences in both the biotic and abiotic composition of the root-associated soil of A. thaliana and these differences are in accordance with the successional class of the field sites. As the studied sites all have been under (former) agricultural use, and a climatic cline is absent, we were able to reveal a more complete variety of ecological contexts A. thaliana can appear and sustain in. Conclusions Our findings lead to the conclusion that although A. thaliana is considered a pioneer plant species and previously almost exclusively studied in early succession and disturbed sites, plants can successfully establish in soils which have experienced years of ecological development. Thereby, A. thaliana can be exposed to a much wider variation in soil ecological context than is currently presumed. This knowledge opens up new opportunities to enhance our understanding of causal plant-microbiome interactions as A. thaliana cannot only grow in contrasting soil biotic and abiotic conditions along a latitudinal gradient, but also when those conditions vary along a secondary succession gradient. Future research could give insights in important plant factors to grow in more ecologically complex later-secondary succession soils, which is an impending direction of our current agricultural systems.

Published

2023

45. Understanding the influence of soil development on contaminant reactivity along a fluvial chronosequence in the Oregon Coast Range

Author

Chelsea S. Obeidy and Matthew L. Polizzotto

Subjects

Contaminant sorption, Chronosequence, Oregon Coast Range, Amorphous minerals, Science

Abstract

Weathering processes are recognized as drivers of soil and water resource sustainability, but how pedogenesis stage impacts contaminant reactivity and mobility in soils has been minimally investigated. The primary goal of this study was to quantify how soil development influences contaminant reactivity. To achieve this goal, soils from two depths (30 and 100 cm) across a chronosequence (ages 3.5, 20, 69, 140, 200, and 908 ky) in the Oregon Coast Range were subjected to arsenic (As) adsorption isotherms, with As removal from solution serving as a proxy for soil-contaminant reactivity. Langmuir models were applied to isotherm data to quantify relationships between contaminant retention capacity, soil age and soil physicochemical properties, and data revealed that 20 ky soils from a 30-cm-depth had the greatest affinity for As sorption (8,474.5 mg kg−1). Chemical extractions revealed that amorphous (oxy)hydroxides were the dominant mineral phases governing As sorption, even in the presence of abundant crystalline oxides. Micro-X-ray fluorescence spectroscopy revealed a strong spatial correlation between As and Fe in reacted soils. The abundance of amorphous minerals within soils is controlled by the balance between their production from weathering of primary minerals and their loss from ripening to crystalline minerals, and because the mode, extent and minerals governing contaminant sorption determine solid-aqueous phase partitioning, this knowledge will assist in improving models for predicting Critical Zone processes that govern the sustainability of soil and water quality.

Published

2024

46. Successional development of the phototrophic community in biological soil crusts, along with soil formation on Holocene deposits at the Baltic Sea coast

Author

Sandra Kammann, Peter Leinweber, Karin Glaser, Ulf Schiefelbein, Christian Dolnik, Tatiana Mikhailyuk, Eduard Demchenko, Elena Heilmann, and Ulf Karsten

Subjects

biocrusts, chronosequence, dunes, phosphorus, phototrophic diversity, soil development, Evolution, QH359-425, Ecology, QH540-549.5

Abstract

Harsh environmental conditions form habitats colonized by specialized primary microbial colonizers, e.g., biological soil crusts (biocrusts). These cryptogamic communities are well studied in drylands but much less in temperate coastal dunes, where they play a crucial role in ecological functions. Following two dune chronosequences, this study highlights the successional development of the biocrust’s community composition on the Baltic Sea coast. A vegetation survey, followed by morphological species determination, was conducted. Sediment/soil cores of the different dune types were analyzed to uncover the potential impacts of the biocrust community on initial soil formation processes, with special emphasis on biogeochemical phosphorous (P) transformations. Biocrust succession was characterized by a dune type-specific community composition, shifting from thinner algae-dominated biocrusts in dynamic dunes to more stable moss-dominated biocrusts in mature dunes. The change in the biocrust community structure was accompanied by an increase in Chl a, water, and organic matter content. In total, 25 algal and cyanobacterial species, 16 mosses, and 26 lichens across all sampling sites were determined. The pedological characterization of these cores elucidated initial processes of soil genesis, such as decalcification, acidification, and the accumulation of organic matter with dune and biocrust development. Furthermore, the chemistry of iron (Fe)-containing compounds such as the Fedithionite/Fetotal ratios confirmed mineral weathering and the beginning of soil profile development. The biocrusts accumulated P over time, while the P content in the underlying sediment did not change. That implies that biocrusts take up P from the geological parent material in the dunes, thereby accumulating available P in the ecosystem, which gets transferred into subsoil horizons through leaching or redeposition. The relative proportion of the bioavailable P pool (56% to 74% of Pt) increased with dune succession. That happened at the expense of more stable bound P, which was transformed into labile P. Thus, the level of plant available P along the dune chronosequences increased due to the microbial activity of the biocrust organisms. It can be concluded that biocrusts of temperate coastal dunes play a crucial role in maintaining their habitat by accumulating nutrients and organic matter, supporting soil development and subsequent vegetation.

Published

2024

47. Comammox bacteria and ammonia oxidizing archaea are major drivers of nitrification in glacier forelands

Author

Hanxia Yu, Jupei Shen, Jun Zeng, Hang-Wei Hu, Elise Pendall, Haoyan Xiao, Zikai Liu, Hui Zhang, Hong J. Di, Zhongqin Li, and Ji-Zheng He

Subjects

Chronosequence, Comammox bacteria, Glacier retreating, Nitrification, Gene abundance, Science

Abstract

This study investigated the abundance of comammox bacteria and canonical ammonia-oxidizing bacteria (AOB) and archaea (AOA), and their relative contribution to nitrification along a chronosequence of deglaciated forelands. The results showed that nitrification related gene abundance tended to increase with glacier retreat, with comammox bacteria and AOA appearing to be the most critical drivers for soil nitrification rates. These findings provide new evidence for the presence of comammox bacteria in glacier forelands and enhance our understanding of the niche differentiation of canonical nitrifier and comammox bacteria.

Published

2023

48. Rapid functional but slow species diversity recovery of steppe vegetation on former arable fields in southern Ukraine.

Author

Dembicz, Iwona, Zachwatowicz, Maria, Moysiyenko, Ivan, Shapoval, Viktor, Smreczak, Bożena, Zagorodniuk, Natalia, Davydova, Anastasia, Vynokurov, Denys, Seiler, Hallie, and Sudnik‐Wójcikowska, Barbara

Subjects

*SPECIES diversity, *STEPPES, *ONE-way analysis of variance, *ENDANGERED ecosystems, *CHEMICAL composition of plants

Abstract

Questions: European steppes are among the most threatened ecosystems in the Palaearctic region, mainly because of conversion to arable land. Abandonment may allow for the passive recovery of steppes. We made use of an exceptional old‐field succession chronosequence of nearly 100 years to answer the following questions: (a) Are the plant species composition, species richness and functional characteristics typical of virgin grass steppes able to self‐restore during ca. 100 years after abandonment? (b) Do the rates of recovery of the above vegetation characteristics differ over the studied chronosequence? (c) Do topsoil carbon and nitrogen content change over the succession chronosequence, leading to concentrations similar to that of virgin steppes? Location: Southern Ukraine. Methods: We sampled vegetation and soil in a virgin grass steppe and in old fields abandoned for 6, 15, 31, 50 and ca. 97 years. We subjected the composition data to multivariate analysis. To test whether species richness, functional and soil characteristics of the old fields diverge from those of the virgin steppe, we used one‐way analysis of variance with Tukey's honestly significant difference (HSD) statistic to create 90% confidence intervals. Results: The vegetation composition of the three most recently abandoned old fields differed significantly from that of the virgin steppe. The species richness of vascular plants was lower in old fields than in the virgin steppe. The share of steppe habitat specialists was similar to the virgin steppe only in the field abandoned for ca. 97 years. Functional characteristics were significantly different from the virgin steppe only in the most recently abandoned old field. Contents of Corg and Ntot in fields abandoned for ≤50 years were lower compared with the virgin steppe. Conclusions: The functional characteristics of steppe vegetation seem to recover much faster than its biodiversity. However, based on our results, 100 years can be enough time for the spontaneous re‐establishment of typical steppe vegetation. [ABSTRACT FROM AUTHOR]

Published

2023

49. Studying Tropical Dry Forests Secondary Succession (2005–2021) Using Two Different LiDAR Systems.

Author

Liu, Chenzherui, Sanchez-Azofeifa, Arturo, and Bax, Connor

Subjects

*TROPICAL dry forests, *SECONDARY forests, *FOREST succession, *LIDAR, *DECIDUOUS plants, *NATIONAL parks & reserves

Abstract

Chronosequence changes among Tropical Dry Forests (TDFs) are essential for understanding this unique ecosystem, which is characterized by its seasonality (wet and dry) and a high diversity of deciduous trees and shrubs. From 2005 to 2021, we used two different airborne LiDAR systems to quantify structural changes in the forest at Santa Rosa National Park. Line- and shape-based waveform metrics were used to record the overall changes in the TDF structure. Based on a 16-year growth analysis, notable variations in height-related profiles were observed, particularly for RH50, RH100, and waveform-produced canopy heights. The results showed that Cy and RG have increased since the forests have been growing, whereas Cx has decreased. The decrease in Cx is because ground returns are lower when the canopy density i and canopy height increase. A positive relationship was observed between Cy and CH, RG, and RH100, particularly for the wet season data collected in 2021. These findings provide important insights into the growth dynamics of TDFs in Santa Rosa National Park and could inform future conservation efforts. [ABSTRACT FROM AUTHOR]

Published

2023

50. Local-scale changes in plant community composition following succession of oak-hornbeam forest after grassland abandonment.

Author

Jelinčić, Antun, Perčin, Aleksandra, Zgorelec, Željka, and Papković, Dora

Subjects

*FOREST succession, *CHEMICAL composition of plants, *PLANT communities, *COMMUNITY change, *GRASSLANDS, *OAK, *EUROPEAN aspen

Abstract

-- In this local-scale synecological study, we investigated the changes in plant community composition throughout secondary succession occurring after cessation of agricultural land use (i.e. grassland abandonment). The successional sequence studied had the following pathway: Avenula pubescens (Huds.) Dumort. hay-pastures ® Brachypodium pinnatum (L.) P.Beauv. successional grassland ® Cornus sanguinea L. scrubs ® late-successional Populus tremula L. forest ® late-successional oak-hornbeam (Quercus-Carpinus) forest. The last forest stage was represented by the association Epimedio-Carpinetum betuli (Horvat 1938) Borhidi 1963. Occurrence of plant species throughout secondary succession was mostly stage-specific; only Fragaria vesca L., Ajuga reptans L., Cornus s anguinea, Prunus spinosa L., and Viola hirta L. showed survival ability throughout almost all stages. [ABSTRACT FROM AUTHOR]

Published

2023