Roadside diversity in relation to age and surrounding source habitat: evidence for long time lags in valuable green infrastructure

Auffret, Alistair G.; Lindgren, E.

doi:10.1002/2688-8319.12005

Cited by 21 publications

(27 citation statements)

References 64 publications

(102 reference statements)

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“…This is an important data gap because evidence from non-urban systems demonstrates ecological time lags can determine the success of ecological management and conservation efforts (Watts et al, 2020). For instance, in road verges, multi-decadal time lags have been identified when investigating community assembly, thus posing new challenges when designing appropriate urban restoration and conservation efforts (Auffret and Lindgren, 2020). More detailed knowledge is needed on the effects of time lags and delays on urban biodiversity and ecological functioning, and how they could underpin effective urban planning and management interventions.…”

Section: Synchrony/asynchrony Time Lags and Delaysmentioning

confidence: 99%

Valuing the Role of Time in Urban Ecology

2021

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Cities and towns are complex ecosystems with features that can vary dramatically in space and time. Our knowledge of the spatial structure of urban land and ecological systems is expanding. These systems have been investigated across spatial scales, urban to rural gradients, networks of urban macrosystems, and global megalopolises. However, the temporal dimensions of urban ecosystems – such as those related to ecological cycles and historical legacies – are far less understood and investigated. Here, we outline the main dimensions of time that can shape how events in urban ecosystems unfold, which we categorize as: (i) time flows and duration, (ii) synchrony, lags, and delays, (iii) trends and transitions, (iv) cycles and hysteresis, (v) legacies and priming, (vi) temporal hotspots and hot moments, and (vii) stochastic vs. deterministic processes affecting our ability to forecast the future of cities and the species that live in them. First, we demonstrate the roles of these understudied dimensions by discussing exemplary studies. We then propose key future research directions for investigating how processes over time may regulate the structure and functioning of urban land and biodiversity, as well as its effects on and implications for urban ecology. Our analysis and conceptual framework highlights that several temporal dimensions of urban ecosystems – like those related to temporal hotspots/moments and stochastic vs. deterministic processes – are understudied. This offers important research opportunities to further urban ecology and a comprehensive research agenda valuing the “Urban Chronos” – the change of urban ecosystems through time.

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Section: Synchrony/asynchrony Time Lags and Delaysmentioning

confidence: 99%

Valuing the Role of Time in Urban Ecology

2021

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“…However, their mere presence does not guarantee that plant species migrations are effectively happening along these remnant grasslands, supporting so-called functional connectivity (Auffret et al, 2017b). Numerous environmental factors such as matrix quality, management or habitat age indeed constrain the efficiency of the green infrastructure (Baum et al, 2004;Aavik & Liira, 2010;Thiele et al, 2018;Auffret & Lindgren, 2020), and our results add habitat quality of the remnants prominently to this list. Local habitat quality has repeatedly been pinpointed as a crucial factor explaining the richness and abundance of numerous taxa when compared to other patch-and landscape-scale variation in large, intact semi-natural grasslands (Gonthier et al, 2014;Zulka et al, 2014), but it is clear from our results that this also holds for the grassland remnants.…”

Section: Importance Of Remnant Grasslands For Conservationmentioning

confidence: 60%

“…In order to attain nature retention goals, conservationists are increasingly turning their attention to small, remnant or even artificial habitats that are scattered in the landscape to assess their potential in conserving biodiversity in human‐dominated landscapes (Wintle et al, 2019). These include, for example, urban lawns (Thompson et al, 2004), small forests (Valdés et al, 2019), burial mounds (Deak et al, 2018), hedgerows (Staley et al, 2013), ditches (Meier et al, 2017), forest edges (Lindgren et al, 2018), road verges (Auffret & Lindgren, 2020) or other linear landscape features (Gardiner et al, 2018). Such small, individual habitat patches tend to support only a limited number of species, yet their combined surface area can substantially contribute to the landscape‐scale habitat amount (Lindgren & Cousins, 2017; Gardiner et al, 2018), potentially increasing the species density in local communities (Watling et al, 2020) and harbouring important portions of landscape‐scale species pools, including habitat specialists (Deak et al, 2018; Gardiner et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Soil phosphorus availability determines the contribution of small, individual grassland remnants to the conservation of landscape‐scale biodiversity

Plue

Baeten

2021

Applied Vegetation Science

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Questions Small, remnant habitats embedded in degraded, human‐dominated landscapes are generally not a priority in conservation, despite their potential role in supporting landscape‐scale biodiversity. To warrant their inclusion in conservation management and policy, we question under which conditions they may exhibit the largest conservation value. Location Nine landscapes spread across the counties of Stockholm and Södermanland, Sweden. Methods Per landscape, plant communities were surveyed in 6 and 12 1 × 1 m2 plots across large, intact semi‐natural grasslands and small remnant grasslands, respectively. These two contrasting grassland types served as a model system. A topsoil sample was taken in each plot to determine habitat quality in terms of soil pH, plant‐available P, and C:N ratio. We used a joint species distribution model to analyse the extent to which grassland type and habitat quality define and predict resident community diversity and composition, including whether they support grassland specialists. Results At the landscape scale, the combined remnant grasslands sustained diverse plant communities which did include a significant subset of habitat specialists. Yet, the contribution of individual remnants clearly varied with local‐scale habitat quality; soil phosphorus availability lowered plot‐level species richness, mostly by constraining the occurrence of grassland specialists. Semi‐natural grassland communities were comparatively insensitive to variation in soil phosphorus availability. Conclusions The combined habitat amount and the significant number of habitat specialists sustained by remnant grasslands with high habitat quality, shows they can represent a valuable resource to support landscape‐scale biodiversity conservation. This offers no wildcard to neglect the continued biotic and abiotic threats on semi‐natural grassland plant diversity such as chronic and accumulating P eutrophication, discontinuation of management or poor matrix permeability, as semi‐natural grasslands harbour the majority of habitat specialists, while sourcing surrounding remnant grassland communities.

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“…All plant species within 1 m of a purple loosestrife infestation were recorded, and increased species richness was a predictor of higher purple loosestrife density. Species richness and diversity along roadside right of way (ROW) has been studied as it connects to the spread from the ROW to neighboring forests or hedgerows 44 or grasslands 45 , and agriculture landscapes 46 as well as the conservation value of ROWs for avian and small mammal conservation 46 . These studies most often focus on the conservation value or use as habitat for wildlife.…”

Section: Discussionmentioning

confidence: 99%

Mapping the purple menace: spatiotemporal distribution of purple loosestrife (Lythrum salicaria) along roadsides in northern New York State

Rogers

Humagain

Pearson

2022

Sci Rep

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Purple loosestrife (Lythrum salicaria L.) is an invasive, herbaceous plant, frequently found in wetlands, creating monoculture stands, resulting in intensive management strategies in central New York, Ontario, and Quebec. The goal of this study was to identify the extent of infestations and to investigate factors that promote the spread of purple loosestrife. We attempted to answer several questions regarding level of infestation, connection to mowing, and influence of culverts. During flowering season in July and August, 2017–2019, we mapped infestations along 150 km (93 miles) of state highway between the Adirondack Park and the St. Lawrence River using the ESRI Collector app. The results of our preliminary analysis revealed significant increase in the number of plants (P < 0.001). In addition, a linear correlation analysis demonstrated a higher loosestrife density with an increase in plant species richness and a decrease in the distance to the closest infestation and wetland (P < 0.001 each). We found no statistical evidence that mowing promotes the spread of loosestrife. As expected, there were more individual infestations in highway ditches, but larger and denser infestations in wetlands (P = 0.003 in 2019). Culverts enable purple loosestrife to spread underneath highways and should be managed to prevent spread.

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Roadside diversity in relation to age and surrounding source habitat: evidence for long time lags in valuable green infrastructure

Cited by 21 publications

References 64 publications

Valuing the Role of Time in Urban Ecology

Valuing the Role of Time in Urban Ecology

Soil phosphorus availability determines the contribution of small, individual grassland remnants to the conservation of landscape‐scale biodiversity

Mapping the purple menace: spatiotemporal distribution of purple loosestrife (Lythrum salicaria) along roadsides in northern New York State

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