Search

Your search keyword '"Hahs AK"' showing total 39 results
Start Over Author "Hahs AK"
39 results on '"Hahs AK"'

2. Large positive ecological changes of small urban greening actions

Author

Mata, L, Hahs, AK, Palma, E, Backstrom, A, Johnston, N, King, T, Olson, AR, Renowden, C, Smith, TR, Vogel, B, Ward, S, Mata, L, Hahs, AK, Palma, E, Backstrom, A, Johnston, N, King, T, Olson, AR, Renowden, C, Smith, TR, Vogel, B, and Ward, S

Abstract

The detrimental effects of environmental change on human and non-human diversity are acutely manifested in urban environments. While urban greenspaces are known to mitigate these effects and support functionally diverse ecological communities, evidence of the ecological outcomes of urban greening remains scarce. We use a longitudinal observational design to provide empirical evidence of positive ecological changes brought about by greening actions. We collected a plant–insect interactions data set 1 year before, and for 3 years after, a greenspace received a small greening action within a densely urbanised municipality. We then assessed how (i) insect species richness; (ii) the probabilities of occurrence, survival and colonisation of the insect community; and (iii) the plant–insect network structure varied across the 4 years of the study. As we understand, this is the first study to apply statistical and network analytical frameworks to quantitatively track how positive ecological changes accrue over time at a site after the implementation of a specific urban greening action. We show how a small greening action quickly led to large positive changes in the richness, demographic dynamics and network structure of a depauperate insect community. An increase in the diversity and complexity of the plant community led to, after only 3 years, a large increase in insect species richness, a greater probability of occurrence of insects within the greenspace and a higher number and diversity of interactions between insects and plant species. We demonstrate how large positive ecological changes may be derived from investing in small greening actions and how these contribute to bring indigenous species back to greenspaces where they have become rare or been extirpated by urbanisation. Our findings provide crucial evidence that supports best practice in greenspace design and contributes to re-invigorate policies aimed at mitigating the negative impacts of urbanisation on people a

Published
2023

3. Urban forest invertebrates: how they shape and respond to the urban environment

Author

Kotze, DJ, Lowe, EC, MacIvor, JS, Ossola, A, Norton, BA, Hochuli, DF, Mata, L, Moretti, M, Gagne, SA, Handa, IT, Jones, TM, Threlfall, CG, Hahs, AK, Kotze, DJ, Lowe, EC, MacIvor, JS, Ossola, A, Norton, BA, Hochuli, DF, Mata, L, Moretti, M, Gagne, SA, Handa, IT, Jones, TM, Threlfall, CG, and Hahs, AK

Abstract

Invertebrates comprise the most diversified animal group on Earth. Due to their long evolutionary history and small size, invertebrates occupy a remarkable range of ecological niches, and play an important role as “ecosystem engineers” by structuring networks of mutualistic and antagonistic ecological interactions in almost all terrestrial ecosystems. Urban forests provide critical ecosystem services to humans, and, as in other systems, invertebrates are central to structuring and maintaining the functioning of urban forests. Identifying the role of invertebrates in urban forests can help elucidate their importance to practitioners and the public, not only to preserve biodiversity in urban environments, but also to make the public aware of their functional importance in maintaining healthy greenspaces. In this review, we examine the multiple functional roles that invertebrates play in urban forests that contribute to ecosystem service provisioning, including pollination, predation, herbivory, seed and microorganism dispersal and organic matter decomposition, but also those that lead to disservices, primarily from a public health perspective, e.g., transmission of invertebrate-borne diseases. We then identify a number of ecological filters that structure urban forest invertebrate communities, such as changes in habitat structure, increased landscape imperviousness, microclimatic changes and pollution. We also discuss the complexity of ways that forest invertebrates respond to urbanisation, including acclimation, local extinction and evolution. Finally, we present management recommendations to support and conserve viable and diverse urban forest invertebrate populations into the future.

Published
2022

4. Connecting Biodiversity With Mental Health and Wellbeing - A Review of Methods and Disciplinary Perspectives

Author

Hedin, M, Hahs, AK, Mata, L, Lee, K, Hedin, M, Hahs, AK, Mata, L, and Lee, K

Abstract

Biodiversity conservation and mental health and wellbeing are of increasing global concern, with growing relevance to planning and policy. A growing body of literature exploring the relationships between biodiversity and mental health and wellbeing—based on early research conducted largely from social science perspectives—suggests that particular qualities within natural environments confer particular benefits. Results so far have been inconclusive and inconsistent, contributing to an incohesive body of evidence. While past reviews have focused on reporting variations in results, the present study builds on early reviews by exploring variations from the perspective of author disciplines and the use of different guiding theories, and variables used to measure biodiversity, mental health and wellbeing. This aims to address a research gap in understanding whether research in this topic has become more interdisciplinary or has employed more consistent study designs, which were highlighted as priorities in past reviews, but the progress of which has not yet been explored in depth. We found that research connecting biodiversity and mental health and wellbeing has become only marginally more interdisciplinary in recent years, and there is still a large inconsistency in the use of guiding theories, variables and overall study designs. The variation in disciplinary perspectives and methods reflects a growing interest in this field and the variety of ways researchers are trying to understand and test the complex relationships between biodiversity and mental health and wellbeing. Our study shows that there are unique perspectives that different disciplines can contribute to this body of research and continuing to increase collaboration between disciplines with the use of consistent mixed methods approaches in future may contribute to a more cohesive body of evidence. We provide a framework to conceptualize recommendations for future research, highlighting the importance of int

Published
2022

5. AusTraits, a curated plant trait database for the Australian flora

Author

Falster, D, Gallagher, R, Wenk, EH, Wright, IJ, Indiarto, D, Andrew, SC, Baxter, C, Lawson, J, Allen, S, Fuchs, A, Monro, A, Kar, F, Adams, MA, Ahrens, CW, Alfonzetti, M, Angevin, T, Apgaua, DMG, Arndt, S, Atkin, OK, Atkinson, J, Auld, T, Baker, A, von Balthazar, M, Bean, A, Blackman, CJ, Bloomfield, K, Bowman, DMJS, Bragg, J, Brodribb, TJ, Buckton, G, Burrows, G, Caldwell, E, Camac, J, Carpenter, R, Catford, JA, Cawthray, GR, Cernusak, LA, Chandler, G, Chapman, AR, Cheal, D, Cheesman, AW, Chen, SC, Choat, B, Clinton, B, Clode, PL, Coleman, H, Cornwell, WK, Cosgrove, M, Crisp, M, Cross, E, Crous, KY, Cunningham, S, Curran, T, Curtis, E, Daws, MI, DeGabriel, JL, Denton, MD, Dong, N, Du, P, Duan, H, Duncan, DH, Duncan, RP, Duretto, M, Dwyer, JM, Edwards, C, Esperon-Rodriguez, M, Evans, JR, Everingham, SE, Farrell, C, Firn, J, Fonseca, CR, French, BJ, Frood, D, Funk, JL, Geange, SR, Ghannoum, O, Gleason, SM, Gosper, CR, Gray, E, Groom, PK, Grootemaat, S, Gross, C, Guerin, G, Guja, L, Hahs, AK, Harrison, MT, Hayes, PE, Henery, M, Hochuli, D, Howell, J, Huang, G, Hughes, L, Huisman, J, Ilic, J, Jagdish, A, Jin, D, Jordan, G, Jurado, E, Kanowski, J, Kasel, S, Falster, D, Gallagher, R, Wenk, EH, Wright, IJ, Indiarto, D, Andrew, SC, Baxter, C, Lawson, J, Allen, S, Fuchs, A, Monro, A, Kar, F, Adams, MA, Ahrens, CW, Alfonzetti, M, Angevin, T, Apgaua, DMG, Arndt, S, Atkin, OK, Atkinson, J, Auld, T, Baker, A, von Balthazar, M, Bean, A, Blackman, CJ, Bloomfield, K, Bowman, DMJS, Bragg, J, Brodribb, TJ, Buckton, G, Burrows, G, Caldwell, E, Camac, J, Carpenter, R, Catford, JA, Cawthray, GR, Cernusak, LA, Chandler, G, Chapman, AR, Cheal, D, Cheesman, AW, Chen, SC, Choat, B, Clinton, B, Clode, PL, Coleman, H, Cornwell, WK, Cosgrove, M, Crisp, M, Cross, E, Crous, KY, Cunningham, S, Curran, T, Curtis, E, Daws, MI, DeGabriel, JL, Denton, MD, Dong, N, Du, P, Duan, H, Duncan, DH, Duncan, RP, Duretto, M, Dwyer, JM, Edwards, C, Esperon-Rodriguez, M, Evans, JR, Everingham, SE, Farrell, C, Firn, J, Fonseca, CR, French, BJ, Frood, D, Funk, JL, Geange, SR, Ghannoum, O, Gleason, SM, Gosper, CR, Gray, E, Groom, PK, Grootemaat, S, Gross, C, Guerin, G, Guja, L, Hahs, AK, Harrison, MT, Hayes, PE, Henery, M, Hochuli, D, Howell, J, Huang, G, Hughes, L, Huisman, J, Ilic, J, Jagdish, A, Jin, D, Jordan, G, Jurado, E, Kanowski, J, and Kasel, S

Abstract

We introduce the AusTraits database - a compilation of values of plant traits for taxa in the Australian flora (hereafter AusTraits). AusTraits synthesises data on 448 traits across 28,640 taxa from field campaigns, published literature, taxonomic monographs, and individual taxon descriptions. Traits vary in scope from physiological measures of performance (e.g. photosynthetic gas exchange, water-use efficiency) to morphological attributes (e.g. leaf area, seed mass, plant height) which link to aspects of ecological variation. AusTraits contains curated and harmonised individual- and species-level measurements coupled to, where available, contextual information on site properties and experimental conditions. This article provides information on version 3.0.2 of AusTraits which contains data for 997,808 trait-by-taxon combinations. We envision AusTraits as an ongoing collaborative initiative for easily archiving and sharing trait data, which also provides a template for other national or regional initiatives globally to fill persistent gaps in trait knowledge.

Published
2021

6. Indigenous plants promote insect biodiversity in urban greenspaces

Author

Mata, L, Andersen, AN, Morán-Ordóñez, A, Hahs, AK, Backstrom, A, Ives, CD, Bickel, D, Duncan, D, Palma, E, Thomas, F, Cranney, K, Walker, K, Shears, I, Semeraro, L, Malipatil, M, Moir, ML, Plein, M, Porch, Nicholas, Vesk, PA, Smith, TR, Lynch, Y, Mata, L, Andersen, AN, Morán-Ordóñez, A, Hahs, AK, Backstrom, A, Ives, CD, Bickel, D, Duncan, D, Palma, E, Thomas, F, Cranney, K, Walker, K, Shears, I, Semeraro, L, Malipatil, M, Moir, ML, Plein, M, Porch, Nicholas, Vesk, PA, Smith, TR, and Lynch, Y

Published
2021

8. A global horizon scan of the future impacts of robotics and autonomous systems on urban ecosystems

Author

Goddard, MA, Davies, ZG, Guenat, S, Ferguson, MJ, Fisher, JC, Akanni, A, Ahjokoski, T, Anderson, PML, Angeoletto, F, Antoniou, C, Bates, AJ, Barkwith, A, Berland, A, Bouch, CJ, Rega-Brodsky, CC, Byrne, LB, Cameron, D, Canavan, R, Chapman, T, Connop, S, Crossland, S, Dade, MC, Dawson, DA, Dobbs, C, Downs, CT, Ellis, EC, Escobedo, FJ, Gobster, P, Gulsrud, NM, Guneralp, B, Hahs, AK, Hale, JD, Hassall, C, Hedblom, M, Hochuli, DF, Inkinen, T, Ioja, I-C, Kendal, D, Knowland, T, Kowarik, I, Langdale, SJ, Lerman, SB, MacGregor-Fors, I, Manning, P, Massini, P, McLean, S, Mkwambisi, DD, Ossola, A, Luque, GP, Perez-Urrestarazu, L, Perini, K, Perry, G, Pett, TJ, Plummer, KE, Radji, RA, Roll, U, Potts, SG, Rumble, H, Sadler, JP, de Saille, S, Sautter, S, Scott, CE, Shwartz, A, Smith, T, Snep, RPH, Soulsbury, CD, Stanley, MC, Van de Voorde, T, Venn, SJ, Warren, PH, Washbourne, C-L, Whitling, M, Williams, NSG, Yang, J, Yeshitela, K, Yocom, KP, Dallimer, M, Goddard, MA, Davies, ZG, Guenat, S, Ferguson, MJ, Fisher, JC, Akanni, A, Ahjokoski, T, Anderson, PML, Angeoletto, F, Antoniou, C, Bates, AJ, Barkwith, A, Berland, A, Bouch, CJ, Rega-Brodsky, CC, Byrne, LB, Cameron, D, Canavan, R, Chapman, T, Connop, S, Crossland, S, Dade, MC, Dawson, DA, Dobbs, C, Downs, CT, Ellis, EC, Escobedo, FJ, Gobster, P, Gulsrud, NM, Guneralp, B, Hahs, AK, Hale, JD, Hassall, C, Hedblom, M, Hochuli, DF, Inkinen, T, Ioja, I-C, Kendal, D, Knowland, T, Kowarik, I, Langdale, SJ, Lerman, SB, MacGregor-Fors, I, Manning, P, Massini, P, McLean, S, Mkwambisi, DD, Ossola, A, Luque, GP, Perez-Urrestarazu, L, Perini, K, Perry, G, Pett, TJ, Plummer, KE, Radji, RA, Roll, U, Potts, SG, Rumble, H, Sadler, JP, de Saille, S, Sautter, S, Scott, CE, Shwartz, A, Smith, T, Snep, RPH, Soulsbury, CD, Stanley, MC, Van de Voorde, T, Venn, SJ, Warren, PH, Washbourne, C-L, Whitling, M, Williams, NSG, Yang, J, Yeshitela, K, Yocom, KP, and Dallimer, M

Abstract

Technology is transforming societies worldwide. A major innovation is the emergence of robotics and autonomous systems (RAS), which have the potential to revolutionize cities for both people and nature. Nonetheless, the opportunities and challenges associated with RAS for urban ecosystems have yet to be considered systematically. Here, we report the findings of an online horizon scan involving 170 expert participants from 35 countries. We conclude that RAS are likely to transform land use, transport systems and human-nature interactions. The prioritized opportunities were primarily centred on the deployment of RAS for the monitoring and management of biodiversity and ecosystems. Fewer challenges were prioritized. Those that were emphasized concerns surrounding waste from unrecovered RAS, and the quality and interpretation of RAS-collected data. Although the future impacts of RAS for urban ecosystems are difficult to predict, examining potentially important developments early is essential if we are to avoid detrimental consequences but fully realize the benefits.

Published
2021

9. Dynamic Changes in Melbourne's Urban Vegetation Cover-2001 to 2016

Author

Timalsina, B, Mavoa, S, Hahs, AK, Timalsina, B, Mavoa, S, and Hahs, AK

Abstract

Understanding changes in urban vegetation is essential for ensuring sustainable and healthy cities, mitigating disturbances due to climate change, sustaining urban biodiversity, and supporting human health and wellbeing. This study investigates and describes the distribution and dynamic changes in urban vegetation over a 15-year period in Greater Melbourne, Australia. The study investigates how vegetation cover across Melbourne has changed at five-yearly intervals from 2001 to 2016 using the newly proposed dynamic change approach that extends the net change approach to quantify the amount of vegetation gain as well as loss. We examine this question at two spatial resolutions: (1) at the municipal landscape scale to capture broadscale change regardless of land tenure; and (2) at the scale of designated public open spaces within the municipalities to investigate the extent to which the loss of vegetation has occurred on lands that are intended to provide public access to vegetated areas in the city. Vegetation was quantified at four different times (2001, 2006, 2011, 2016), using the normalized difference vegetation index (NDVI). Dynamic changes of gain and loss in urban vegetation between the three periods were quantified for six local government areas (LGAs) and their associated public open spaces using a change matrix. The results showed an overall net loss of 64.5 square kilometres of urban vegetation from 2001 to 2016 in six LGAs. When extrapolated to the Greater Melbourne Area, this is approximately equivalent to 109 times the size of Central Park in New York City.

Published
2021

10. Balancing fire risk and human thermal comfort in fire-prone urban landscapes

Author

Mourshed, M, MacLeod, TA, Hahs, AK, Penman, TD, Mourshed, M, MacLeod, TA, Hahs, AK, and Penman, TD

Abstract

Vegetation in urban areas provides many essential ecosystem services. These services may be indirect, such as carbon sequestration and biological diversity, or direct, including microclimate regulation and cultural values. As the global population is becoming ever more urbanized these services will be increasingly vital to the quality of life in urban areas. Due to the combined effects of shading and evapotranspiration, trees have the potential to cool urban microclimates and mitigate urban heat, reduce thermal discomfort and help to create comfortable outdoor spaces for people. Understory vegetation in the form of shrubs and grass layers are also increasingly recognized for the positive role they play in human aesthetics and supporting biodiversity. However, in fire-prone urban landscapes there are risks associated with having denser and more complex vegetation in public open spaces. We investigated the effects of plant selection and planting arrangement on fire risk and human thermal comfort using the Forest Flammability Model and Physiological Equivalent Temperature (PET), to identify how planting arrangement can help balance the trade-offs between these risks and benefits. Our research demonstrated the importance of vertical separation of height strata and suggests that Clumped and Continuous planting arrangements are the most effective way of keeping complex vegetation in public open space to deliver the greatest human thermal comfort benefit while minimizing potential fire behaviour. This study provides an example of how existing research tools in multiple ecological fields can be combined to inform positive outcomes for people and nature in urban landscapes.

Published
2019

13. Increasing biodiversity in urban green spaces through simple vegetation interventions

Author

Beggs, J, Threlfall, CG, Mata, L, Mackie, JA, Hahs, AK, Stork, NE, Williams, NSG, Livesley, SJ, Beggs, J, Threlfall, CG, Mata, L, Mackie, JA, Hahs, AK, Stork, NE, Williams, NSG, and Livesley, SJ

Abstract

Summary Cities are rapidly expanding world‐wide and there is an increasing urgency to protect urban biodiversity, principally through the provision of suitable habitat, most of which is in urban green spaces. Despite this, clear guidelines of how to reverse biodiversity loss or increase it within a given urban green space is lacking. We examined the taxa‐ and species‐specific responses of five taxonomically and functionally diverse animal groups to three key attributes of urban green space vegetation that drive habitat quality and can be manipulated over time: the density of large native trees, volume of understorey vegetation and percentage of native vegetation. Using multi‐species occupancy‐detection models, we found marked differences in the effect of these vegetation attributes on bats, birds, bees, beetles and bugs. At the taxa‐level, increasing the volume of understorey vegetation and percentage of native vegetation had uniformly positive effects. We found 30–120% higher occupancy for bats, native birds, beetles and bugs with an increase in understorey volume from 10% to 30%, and 10–140% higher occupancy across all native taxa with an increase in the proportion of native vegetation from 10% to 30%. However, increasing the density of large native trees had a mostly neutral effect. At the species‐specific level, the majority of native species responded strongly and positively to increasing understorey volume and native vegetation, whereas exotic bird species had a neutral response. Synthesis and applications. We found the probability of occupancy of most species examined was substantially reduced in urban green spaces with sparse understorey vegetation and few native plants. Our findings provide evidence that increasing understorey cover and native plantings in urban green spaces can improve biodiversity outcomes. Redressing the dominance of simplified and exotic vegetation present in urban landscapes with an increase in understorey vegetation volume and percent

Published
2017

15. Conserving herbivorous and predatory insects in urban green spaces

Author

Mata, L, Threlfall, CG, Williams, NSG, Hahs, AK, Malipatil, M, Stork, NE, Livesley, SJ, Mata, L, Threlfall, CG, Williams, NSG, Hahs, AK, Malipatil, M, Stork, NE, and Livesley, SJ

Abstract

Insects are key components of urban ecological networks and are greatly impacted by anthropogenic activities. Yet, few studies have examined how insect functional groups respond to changes to urban vegetation associated with different management actions. We investigated the response of herbivorous and predatory heteropteran bugs to differences in vegetation structure and diversity in golf courses, gardens and parks. We assessed how the species richness of these groups varied amongst green space types, and the effect of vegetation volume and plant diversity on trophic- and species-specific occupancy. We found that golf courses sustain higher species richness of herbivores and predators than parks and gardens. At the trophic- and species-specific levels, herbivores and predators show strong positive responses to vegetation volume. The effect of plant diversity, however, is distinctly species-specific, with species showing both positive and negative responses. Our findings further suggest that high occupancy of bugs is obtained in green spaces with specific combinations of vegetation structure and diversity. The challenge for managers is to boost green space conservation value through actions promoting synergistic combinations of vegetation structure and diversity. Tackling this conservation challenge could provide enormous benefits for other elements of urban ecological networks and people that live in cities.

Published
2017

16. Hierarchical filters determine community assembly of urban species pools

Author

Aronson, MFJ, Nilon, CH, Lepczyk, CA, Parker, TS, Warren, PS, Cilliers, SS, Goddard, MA, Hahs, AK, Herzog, C, Katti, M, La Sorte, FA, Williams, NSG, Zipperer, W, Aronson, MFJ, Nilon, CH, Lepczyk, CA, Parker, TS, Warren, PS, Cilliers, SS, Goddard, MA, Hahs, AK, Herzog, C, Katti, M, La Sorte, FA, Williams, NSG, and Zipperer, W

Abstract

The majority of humanity now lives in cities or towns, with this proportion expected to continue increasing for the foreseeable future. As novel ecosystems, urban areas offer an ideal opportunity to examine multi-scalar processes involved in community assembly as well as the role of human activities in modulating environmental drivers of biodiversity. Although ecologists have made great strides in recent decades at documenting ecological relationships in urban areas, much remains unknown, and we still need to identify the major ecological factors, aside from habitat loss, behind the persistence or extinction of species and guilds of species in cities. Given this paucity of knowledge, there is an immediate need to facilitate collaborative, interdisciplinary research on the patterns and drivers of biodiversity in cities at multiple spatial scales. In this review, we introduce a new conceptual framework for understanding the filtering processes that mold diversity of urban floras and faunas. We hypothesize that the following hierarchical series of filters influence species distributions in cities: (1) regional climatic and biogeographical factors; (2) human facilitation; (3) urban form and development history; (4) socioeconomic and cultural factors; and (5) species interactions. In addition to these filters, life history and functional traits of species are important in determining community assembly and act at multiple spatial scales. Using these filters as a conceptual framework can help frame future research needed to elucidate processes of community assembly in urban areas. Understanding how humans influence community structure and processes will aid in the management, design, and planning of our cities to best support biodiversity.

Published
2016

17. Moving beyond biotic homogenization: searching for new insights into vegetation dynamics

Author

Hahs, AK, McDonnell, MJ, Hahs, AK, and McDonnell, MJ

Abstract

Biotic homogenization has been predicted to occur in cities across the world. However, the empirical evidence has been less than convincing. Lososová et al. explore the middle ground between these two points of view in this issue of Journal of Vegetation Science. They take a more sophisticated approach, linking homogenization to bigger questions of vegetation assembly in urban environments.

Published
2016

18. The conservation value of urban green space habitats for Australian native bee communities

Author

Threlfall, CG, Walker, K, Williams, NSG, Hahs, AK, Mata, L, Stork, N, Livesley, SJ, Threlfall, CG, Walker, K, Williams, NSG, Hahs, AK, Mata, L, Stork, N, and Livesley, SJ

Abstract

Networks of urban green space can provide critical resources for wild bees, however it is unclear which attributes of green spaces provide these resources, or how their management can be improved to benefit a diversity of bee species. We examined bee communities in three dominant urban green space habitats: (1) golf courses (2) public parks and (3) front gardens and streetscapes in residential neighbourhoods in Melbourne, Australia and assessed which local and landscape attributes influenced bee communities. There was a greater abundance and richness of bee species in public parks compared to golf courses and residential neighbourhoods, where the latter habitat was dominated by European Honeybees (Apis mellifera). The occurrence of A. mellifera was positively associated with increases in flowering and native plants. Ground-nesting Homalictus species occurred more frequently in older golf courses and public parks surrounded by low impervious surface cover, and with a low diversity of flowering plants. Cavity nesting, floral specialists within the Colletidae family occurred more often in green space habitats with greater native vegetation, and occurred infrequently in residential neighbourhoods. The lack of appropriate nesting habitat and dominance of exotic flowering plants in residential neighbourhoods appeared to positively impact upon the generalist A. mellifera, but negatively affected cavity and ground nesting floral specialist bee species (e.g. Halictidae and Colletidae). Our results highlight the need to include urban areas in pollinator conservation initiatives, as providing resources critical to diverse bee communities can assist in maintaining these key pollinators in urban landscapes.

Published
2015

19. Urban habitat complexity affects species richness but not environmental filtering of morphologically-diverse ants

Author

Ossola, A, Nash, MA, Christie, FJ, Hahs, AK, Livesley, SJ, Ossola, A, Nash, MA, Christie, FJ, Hahs, AK, and Livesley, SJ

Abstract

Habitat complexity is a major determinant of structure and diversity of ant assemblages. Following the size-grain hypothesis, smaller ant species are likely to be advantaged in more complex habitats compared to larger species. Habitat complexity can act as an environmental filter based on species size and morphological traits, therefore affecting the overall structure and diversity of ant assemblages. In natural and semi-natural ecosystems, habitat complexity is principally regulated by ecological successions or disturbance such as fire and grazing. Urban ecosystems provide an opportunity to test relationships between habitat, ant assemblage structure and ant traits using novel combinations of habitat complexity generated and sustained by human management. We sampled ant assemblages in low-complexity and high-complexity parks, and high-complexity woodland remnants, hypothesizing that (i) ant abundance and species richness would be higher in high-complexity urban habitats, (ii) ant assemblages would differ between low- and high-complexity habitats and (iii) ants living in high-complexity habitats would be smaller than those living in low-complexity habitats. Contrary to our hypothesis, ant species richness was higher in low-complexity habitats compared to high-complexity habitats. Overall, ant assemblages were significantly different among the habitat complexity types investigated, although ant size and morphology remained the same. Habitat complexity appears to affect the structure of ant assemblages in urban ecosystems as previously observed in natural and semi-natural ecosystems. However, the habitat complexity filter does not seem to be linked to ant morphological traits related to body size.

Published
2015

24. AusTraits, a curated plant trait database for the Australian flora

Author

Falster, D, Gallagher, R, Wenk, EH, Wright, IJ, Indiarto, D, Andrew, SC, Baxter, C, Lawson, J, Allen, S, Fuchs, A, Monro, A, Kar, F, Adams, MA, Ahrens, CW, Alfonzetti, M, Angevin, T, Apgaua, DMG, Arndt, S, Atkin, OK, Atkinson, J, Auld, T, Baker, A, von Balthazar, M, Bean, A, Blackman, CJ, Bloomfield, K, Bowman, DMJS, Bragg, J, Brodribb, TJ, Buckton, G, Burrows, G, Caldwell, E, Camac, J, Carpenter, R, Catford, JA, Cawthray, GR, Cernusak, LA, Chandler, G, Chapman, AR, Cheal, D, Cheesman, AW, Chen, S-C, Choat, B, Clinton, B, Clode, PL, Coleman, H, Cornwell, WK, Cosgrove, M, Crisp, M, Cross, E, Crous, KY, Cunningham, S, Curran, Timothy, Curtis, E, Daws, MI, DeGabriel, JL, Denton, MD, Dong, N, Du, P, Duan, H, Duncan, DH, Duncan, RP, Duretto, M, Dwyer, JM, Edwards, C, Esperon-Rodriguez, M, Evans, JR, Everingham, SE, Farrell, C, Firn, J, Fonseca, CR, French, BJ, Frood, D, Funk, JL, Geange, SR, Ghannoum, O, Gleason, SM, Gosper, CR, Gray, E, Groom, PK, Grootemaat, S, Gross, C, Guerin, G, Guja, L, Hahs, AK, Harrison, MT, Hayes, PE, Henery, M, Hochuli, D, Howell, J, Huang, G, Hughes, L, Huisman, J, Ilic, J, Jagdish, A, Jin, D, Jordan, G, Jurado, E, Kanowski, J, Kasel, S, Kellermann, J, Kenny, B, Kohout, M, Kooyman, RM, Kotowska, MM, Lai, HR, Laliberté, E, Lambers, H, Lamont, BB, Lanfear, R, van Langevelde, F, Laughlin, DC, Laugier-Kitchener, B-A, Laurance, S, Lehmann, CER, Leigh, A, Leishman, MR, Lenz, T, Lepschi, B, Lewis, JD, Lim, F, Liu, U, Lord, J, Lusk, CH, Macinnis-Ng, C, McPherson, H, Magallón, S, Manea, A, López-Martinez, A, Mayfield, M, McCarthy, JK, Meers, T, van der Merwe, M, Metcalfe, DJ, Milberg, P, Mokany, K, Moles, AT, Moore, BD, Moore, N, Morgan, JW, Morris, W, Muir, A, Munroe, S, Nicholson, Á, Nicolle, D, Nicotra, AB, Niinemets, Ü, North, T, O’Reilly-Nugent, A, O’Sullivan, OS, Oberle, B, Onoda, Y, Ooi, MKJ, Osborne, CP, Paczkowska, G, Pekin, B, Guilherme Pereira, C, Pickering, C, Pickup, M, Pollock, LJ, Poot, P, Powell, JR, Power, SA, Prentice, IC, Prior, L, Prober, SM, Read, J, Reynolds, V, Richards, AE, Richardson, B, Roderick, ML, Rosell, JA, Rossetto, M, Rye, B, Rymer, PD, Sams, MA, Sanson, G, Sauquet, H, Schmidt, S, Schönenberger, J, Schulze, E-D, Sendall, K, Sinclair, S, Smith, B, Smith, R, Soper, F, Sparrow, B, Standish, RJ, Staples, TL, Stephens, R, Szota, C, Taseski, G, Tasker, E, Thomas, F, Tissue, DT, Tjoelker, MG, Tng, DYP, de Tombeur, F, Tomlinson, K, Turner, NC, Veneklaas, EJ, Venn, S, Vesk, P, Vlasveld, C, Vorontsova, MS, Warren, CA, Warwick, N, Weerasinghe, LK, Wells, J, Westoby, M, White, M, Williams, NSG, Wills, J, Wilson, PG, Yates, C, Zanne, AE, Zemunik, G, and Ziemińska, K

Full Text
View/download PDF

25. The city nature challenge: A global citizen science phenomenon contributing to biodiversity knowledge and informing local government practices.

Author

Palma E, Mata L, Cohen K, Evans D, Gandy B, Gaskell N, Hatchman H, Mezzetti A, Neumann D, O'Keefe J, Shaw A, Wells M, Williams L, and Hahs AK

Abstract

The bioblitz phenomenon has recently branched into cities, presenting exciting opportunities for local governments to channel participants' efforts toward local issues. The City Nature Challenge (CNC) is one such initiative that has been quickly taken up by hundreds of municipalities worldwide. Despite high levels of participation, we still lack a framework for evaluating how the CNC contributes to local biodiversity knowledge and to inform local government practices. In the present article, we develop such a tool and present a case study that illustrates its applicability. We demonstrate that the collected records contributed to a better understanding of contemporary, local biodiversity patterns and provide a more realistic representation of understudied groups such as insects and fungi. Importantly, we show that the CNC presented local governments with a cost-effective tool to make informed, evidence-based management and policy decisions, improve education and engagement programs, foster cross-council collaborations, and support a stronger sense of environmental stewardship within the local community., (© The Author(s) 2024. Published by Oxford University Press on behalf of the American Institute of Biological Sciences.)

Published
2024
Full Text
View/download PDF

26. Urbanisation generates multiple trait syndromes for terrestrial animal taxa worldwide.

Author

Hahs AK, Fournier B, Aronson MFJ, Nilon CH, Herrera-Montes A, Salisbury AB, Threlfall CG, Rega-Brodsky CC, Lepczyk CA, La Sorte FA, MacGregor-Fors I, Scott MacIvor J, Jung K, Piana MR, Williams NSG, Knapp S, Vergnes A, Acevedo AA, Gainsbury AM, Rainho A, Hamer AJ, Shwartz A, Voigt CC, Lewanzik D, Lowenstein DM, O'Brien D, Tommasi D, Pineda E, Carpenter ES, Belskaya E, Lövei GL, Makinson JC, Coleman JL, Sadler JP, Shroyer J, Shapiro JT, Baldock KCR, Ksiazek-Mikenas K, Matteson KC, Barrett K, Siles L, Aguirre LF, Armesto LO, Zalewski M, Herrera-Montes MI, Obrist MK, Tonietto RK, Gagné SA, Hinners SJ, Latty T, Surasinghe TD, Sattler T, Magura T, Ulrich W, Elek Z, Castañeda-Oviedo J, Torrado R, Kotze DJ, and Moretti M

Subjects
Animals, Bees, Syndrome, Ecosystem, Biodiversity, Birds, Urbanization, Chiroptera
Abstract

Cities can host significant biological diversity. Yet, urbanisation leads to the loss of habitats, species, and functional groups. Understanding how multiple taxa respond to urbanisation globally is essential to promote and conserve biodiversity in cities. Using a dataset encompassing six terrestrial faunal taxa (amphibians, bats, bees, birds, carabid beetles and reptiles) across 379 cities on 6 continents, we show that urbanisation produces taxon-specific changes in trait composition, with traits related to reproductive strategy showing the strongest response. Our findings suggest that urbanisation results in four trait syndromes (mobile generalists, site specialists, central place foragers, and mobile specialists), with resources associated with reproduction and diet likely driving patterns in traits associated with mobility and body size. Functional diversity measures showed varied responses, leading to shifts in trait space likely driven by critical resource distribution and abundance, and taxon-specific trait syndromes. Maximising opportunities to support taxa with different urban trait syndromes should be pivotal in conservation and management programmes within and among cities. This will reduce the likelihood of biotic homogenisation and helps ensure that urban environments have the capacity to respond to future challenges. These actions are critical to reframe the role of cities in global biodiversity loss., (© 2023. Springer Nature Limited.)

Published
2023
Full Text
View/download PDF

27. AusTraits, a curated plant trait database for the Australian flora.

Author

Falster D, Gallagher R, Wenk EH, Wright IJ, Indiarto D, Andrew SC, Baxter C, Lawson J, Allen S, Fuchs A, Monro A, Kar F, Adams MA, Ahrens CW, Alfonzetti M, Angevin T, Apgaua DMG, Arndt S, Atkin OK, Atkinson J, Auld T, Baker A, von Balthazar M, Bean A, Blackman CJ, Bloomfield K, Bowman DMJS, Bragg J, Brodribb TJ, Buckton G, Burrows G, Caldwell E, Camac J, Carpenter R, Catford JA, Cawthray GR, Cernusak LA, Chandler G, Chapman AR, Cheal D, Cheesman AW, Chen SC, Choat B, Clinton B, Clode PL, Coleman H, Cornwell WK, Cosgrove M, Crisp M, Cross E, Crous KY, Cunningham S, Curran T, Curtis E, Daws MI, DeGabriel JL, Denton MD, Dong N, Du P, Duan H, Duncan DH, Duncan RP, Duretto M, Dwyer JM, Edwards C, Esperon-Rodriguez M, Evans JR, Everingham SE, Farrell C, Firn J, Fonseca CR, French BJ, Frood D, Funk JL, Geange SR, Ghannoum O, Gleason SM, Gosper CR, Gray E, Groom PK, Grootemaat S, Gross C, Guerin G, Guja L, Hahs AK, Harrison MT, Hayes PE, Henery M, Hochuli D, Howell J, Huang G, Hughes L, Huisman J, Ilic J, Jagdish A, Jin D, Jordan G, Jurado E, Kanowski J, Kasel S, Kellermann J, Kenny B, Kohout M, Kooyman RM, Kotowska MM, Lai HR, Laliberté E, Lambers H, Lamont BB, Lanfear R, van Langevelde F, Laughlin DC, Laugier-Kitchener BA, Laurance S, Lehmann CER, Leigh A, Leishman MR, Lenz T, Lepschi B, Lewis JD, Lim F, Liu U, Lord J, Lusk CH, Macinnis-Ng C, McPherson H, Magallón S, Manea A, López-Martinez A, Mayfield M, McCarthy JK, Meers T, van der Merwe M, Metcalfe DJ, Milberg P, Mokany K, Moles AT, Moore BD, Moore N, Morgan JW, Morris W, Muir A, Munroe S, Nicholson Á, Nicolle D, Nicotra AB, Niinemets Ü, North T, O'Reilly-Nugent A, O'Sullivan OS, Oberle B, Onoda Y, Ooi MKJ, Osborne CP, Paczkowska G, Pekin B, Guilherme Pereira C, Pickering C, Pickup M, Pollock LJ, Poot P, Powell JR, Power SA, Prentice IC, Prior L, Prober SM, Read J, Reynolds V, Richards AE, Richardson B, Roderick ML, Rosell JA, Rossetto M, Rye B, Rymer PD, Sams MA, Sanson G, Sauquet H, Schmidt S, Schönenberger J, Schulze ED, Sendall K, Sinclair S, Smith B, Smith R, Soper F, Sparrow B, Standish RJ, Staples TL, Stephens R, Szota C, Taseski G, Tasker E, Thomas F, Tissue DT, Tjoelker MG, Tng DYP, de Tombeur F, Tomlinson K, Turner NC, Veneklaas EJ, Venn S, Vesk P, Vlasveld C, Vorontsova MS, Warren CA, Warwick N, Weerasinghe LK, Wells J, Westoby M, White M, Williams NSG, Wills J, Wilson PG, Yates C, Zanne AE, Zemunik G, and Ziemińska K

Subjects
Australia, Plant Physiological Phenomena, Databases, Factual, Phenotype, Plants
Abstract

We introduce the AusTraits database - a compilation of values of plant traits for taxa in the Australian flora (hereafter AusTraits). AusTraits synthesises data on 448 traits across 28,640 taxa from field campaigns, published literature, taxonomic monographs, and individual taxon descriptions. Traits vary in scope from physiological measures of performance (e.g. photosynthetic gas exchange, water-use efficiency) to morphological attributes (e.g. leaf area, seed mass, plant height) which link to aspects of ecological variation. AusTraits contains curated and harmonised individual- and species-level measurements coupled to, where available, contextual information on site properties and experimental conditions. This article provides information on version 3.0.2 of AusTraits which contains data for 997,808 trait-by-taxon combinations. We envision AusTraits as an ongoing collaborative initiative for easily archiving and sharing trait data, which also provides a template for other national or regional initiatives globally to fill persistent gaps in trait knowledge., (© 2021. The Author(s).)

Published
2021
Full Text
View/download PDF

28. Indigenous plants promote insect biodiversity in urban greenspaces.

Author

Mata L, Andersen AN, Morán-Ordóñez A, Hahs AK, Backstrom A, Ives CD, Bickel D, Duncan D, Palma E, Thomas F, Cranney K, Walker K, Shears I, Semeraro L, Malipatil M, Moir ML, Plein M, Porch N, Vesk PA, Smith TR, and Lynch Y

Subjects
Animals, Cities, Ecosystem, Humans, Insecta, Plants, Biodiversity, Parks, Recreational
Abstract

The contribution of urban greenspaces to support biodiversity and provide benefits for people is increasingly recognized. However, ongoing management practices favor vegetation oversimplification, often limiting greenspaces to lawns and tree canopy rather than multi-layered vegetation that includes under- and midstorey, and the use of nonnative species. These practices hinder the potential of greenspaces to sustain indigenous biodiversity, particularly for taxa like insects that rely on plants for food and habitat. Yet, little is known about which plant species may maximize positive outcomes for taxonomically and functionally diverse insect communities in greenspaces. Additionally, while cities are expected to experience high rates of introductions, quantitative assessments of the relative occupancy of indigenous vs. introduced insect species in greenspace are rare, hindering understanding of how management may promote indigenous biodiversity while limiting the establishment of introduced insects. Using a hierarchically replicated study design across 15 public parks, we recorded occurrence data from 552 insect species on 133 plant species, differing in planting design element (lawn, midstorey, and tree canopy), midstorey growth form (forbs, lilioids, graminoids, and shrubs) and origin (nonnative, native, and indigenous), to assess (1) the relative contributions of indigenous and introduced insect species and (2) which plant species sustained the highest number of indigenous insects. We found that the insect community was overwhelmingly composed of indigenous rather than introduced species. Our findings further highlight the core role of multi-layered vegetation in sustaining high insect biodiversity in urban areas, with indigenous midstorey and canopy representing key elements to maintain rich and functionally diverse indigenous insect communities. Intriguingly, graminoids supported the highest indigenous insect richness across all studied growth forms by plant origin groups. Our work highlights the opportunity presented by indigenous understory and midstorey plants, particularly indigenous graminoids, in our study area to promote indigenous insect biodiversity in urban greenspaces. Our study provides a blueprint and stimulus for architects, engineers, developers, designers, and planners to incorporate into their practice plant species palettes that foster a larger presence of indigenous over regionally native or nonnative plant species, while incorporating a broader mixture of midstorey growth forms., (© 2021 by the Ecological Society of America.)

Published
2021
Full Text
View/download PDF

29. A global horizon scan of the future impacts of robotics and autonomous systems on urban ecosystems.

Author

Goddard MA, Davies ZG, Guenat S, Ferguson MJ, Fisher JC, Akanni A, Ahjokoski T, Anderson PML, Angeoletto F, Antoniou C, Bates AJ, Barkwith A, Berland A, Bouch CJ, Rega-Brodsky CC, Byrne LB, Cameron D, Canavan R, Chapman T, Connop S, Crossland S, Dade MC, Dawson DA, Dobbs C, Downs CT, Ellis EC, Escobedo FJ, Gobster P, Gulsrud NM, Guneralp B, Hahs AK, Hale JD, Hassall C, Hedblom M, Hochuli DF, Inkinen T, Ioja IC, Kendal D, Knowland T, Kowarik I, Langdale SJ, Lerman SB, MacGregor-Fors I, Manning P, Massini P, McLean S, Mkwambisi DD, Ossola A, Luque GP, Pérez-Urrestarazu L, Perini K, Perry G, Pett TJ, Plummer KE, Radji RA, Roll U, Potts SG, Rumble H, Sadler JP, de Saille S, Sautter S, Scott CE, Shwartz A, Smith T, Snep RPH, Soulsbury CD, Stanley MC, Van de Voorde T, Venn SJ, Warren PH, Washbourne CL, Whitling M, Williams NSG, Yang J, Yeshitela K, Yocom KP, and Dallimer M

Subjects
Cities, Forecasting, Humans, Biodiversity, Ecosystem
Abstract

Technology is transforming societies worldwide. A major innovation is the emergence of robotics and autonomous systems (RAS), which have the potential to revolutionize cities for both people and nature. Nonetheless, the opportunities and challenges associated with RAS for urban ecosystems have yet to be considered systematically. Here, we report the findings of an online horizon scan involving 170 expert participants from 35 countries. We conclude that RAS are likely to transform land use, transport systems and human-nature interactions. The prioritized opportunities were primarily centred on the deployment of RAS for the monitoring and management of biodiversity and ecosystems. Fewer challenges were prioritized. Those that were emphasized concerns surrounding waste from unrecovered RAS, and the quality and interpretation of RAS-collected data. Although the future impacts of RAS for urban ecosystems are difficult to predict, examining potentially important developments early is essential if we are to avoid detrimental consequences but fully realize the benefits.

Published
2021
Full Text
View/download PDF

30. Balancing fire risk and human thermal comfort in fire-prone urban landscapes.

Author

MacLeod TA, Hahs AK, and Penman TD

Subjects
Forests, Humans, Plants, Risk, Trees, Urbanization, Ecosystem, Fires, Temperature, Thermosensing
Abstract

Vegetation in urban areas provides many essential ecosystem services. These services may be indirect, such as carbon sequestration and biological diversity, or direct, including microclimate regulation and cultural values. As the global population is becoming ever more urbanized these services will be increasingly vital to the quality of life in urban areas. Due to the combined effects of shading and evapotranspiration, trees have the potential to cool urban microclimates and mitigate urban heat, reduce thermal discomfort and help to create comfortable outdoor spaces for people. Understory vegetation in the form of shrubs and grass layers are also increasingly recognized for the positive role they play in human aesthetics and supporting biodiversity. However, in fire-prone urban landscapes there are risks associated with having denser and more complex vegetation in public open spaces. We investigated the effects of plant selection and planting arrangement on fire risk and human thermal comfort using the Forest Flammability Model and Physiological Equivalent Temperature (PET), to identify how planting arrangement can help balance the trade-offs between these risks and benefits. Our research demonstrated the importance of vertical separation of height strata and suggests that Clumped and Continuous planting arrangements are the most effective way of keeping complex vegetation in public open space to deliver the greatest human thermal comfort benefit while minimizing potential fire behaviour. This study provides an example of how existing research tools in multiple ecological fields can be combined to inform positive outcomes for people and nature in urban landscapes., Competing Interests: The authors have declared that no competing interests exist.

Published
2019
Full Text
View/download PDF

31. Urban impacts across realms: Making the case for inter-realm monitoring and management.

Author

Bugnot AB, Hose GC, Walsh CJ, Floerl O, French K, Dafforn KA, Hanford J, Lowe EC, and Hahs AK

Subjects
Conservation of Natural Resources methods, Ecosystem, Urbanization
Abstract

Burgeoning populations and the increasing concentration of humans in urban areas have resulted in extensive and increasing degradation and destruction of natural ecosystems. The multitude of impacts and their drivers in urban areas across realms are often studied at local scales, but there is regularly a mismatch between the spatial extent of the impacts and that of the pressures driving those impacts. For example, most human activities occur on land and therefore disturb terrestrial habitats (intrinsic impacts), but their impacts can also extend to the atmosphere and aquatic realms (extrinsic impacts). Management of urban impacts is often designed at local scales and aims to control local pressures, mostly overlooking pressures originating outside the 'managed' area. This is often due to jurisdictional barriers but can also result from the lack of knowledge and recognition among scientists and managers of larger scale pressures. With the aim to highlight the importance of ameliorating extrinsic impacts for holistic management of urban areas, this paper discusses the range and extent of extrinsic impacts produced by the most common pressures in urban environments. We discuss that the terrestrial realm is a 'net-donor' of impacts, as most human activities occur on land and the resulting impacts are transferred to aquatic and atmospheric realms. However, activities in aquatic realms can result in impacts on land. We conclude that, to achieve effective management strategies, greater collaboration is needed between scientists and managers focussing on different realms and regions and we present suggestions for approaches to achieve this., (Copyright © 2018. Published by Elsevier B.V.)

Published
2019
Full Text
View/download PDF

32. Conserving herbivorous and predatory insects in urban green spaces.

Author

Mata L, Threlfall CG, Williams NS, Hahs AK, Malipatil M, Stork NE, and Livesley SJ

Subjects
Animals, Gardens, Parks, Recreational, Biodiversity, Cities, Ecosystem, Insecta classification, Insecta growth & development
Abstract

Insects are key components of urban ecological networks and are greatly impacted by anthropogenic activities. Yet, few studies have examined how insect functional groups respond to changes to urban vegetation associated with different management actions. We investigated the response of herbivorous and predatory heteropteran bugs to differences in vegetation structure and diversity in golf courses, gardens and parks. We assessed how the species richness of these groups varied amongst green space types, and the effect of vegetation volume and plant diversity on trophic- and species-specific occupancy. We found that golf courses sustain higher species richness of herbivores and predators than parks and gardens. At the trophic- and species-specific levels, herbivores and predators show strong positive responses to vegetation volume. The effect of plant diversity, however, is distinctly species-specific, with species showing both positive and negative responses. Our findings further suggest that high occupancy of bugs is obtained in green spaces with specific combinations of vegetation structure and diversity. The challenge for managers is to boost green space conservation value through actions promoting synergistic combinations of vegetation structure and diversity. Tackling this conservation challenge could provide enormous benefits for other elements of urban ecological networks and people that live in cities.

Published
2017
Full Text
View/download PDF

33. Hierarchical filters determine community assembly of urban species pools.

Author

Aronson MF, Nilon CH, Lepczyk CA, Parker TS, Warren PS, Cilliers SS, Goddard MA, Hahs AK, Herzog C, Katti M, La Sorte FA, Williams NS, and Zipperer W

Subjects
Animals, Plants classification, Biodiversity, Cities
Abstract

The majority of humanity now lives in cities or towns, with this proportion expected to continue increasing for the foreseeable future. As novel ecosystems, urban areas offer an ideal opportunity to examine multi-scalar processes involved in community assembly as well as the role of human activities in modulating environmental drivers of biodiversity. Although ecologists have made great strides in recent decades at documenting ecological relationships in urban areas, much remains unknown, and we still need to identify the major ecological factors, aside from habitat loss, behind the persistence or extinction of species and guilds of species in cities. Given this paucity of knowledge, there is an immediate need to facilitate collaborative, interdisciplinary research on the patterns and drivers of biodiversity in cities at multiple spatial scales. In this review, we introduce a new conceptual framework for understanding the filtering processes that mold diversity of urban floras and faunas. We hypothesize that the following hierarchical series of filters influence species distributions in cities: (1) regional climatic and biogeographical factors; (2) human facilitation; (3) urban form and development history; (4) socioeconomic and cultural factors; and (5) species interactions. In addition to these filters, life history and functional traits of species are important in determining community assembly and act at multiple spatial scales. Using these filters as a conceptual framework can help frame future research needed to elucidate processes of community assembly in urban areas. Understanding how humans influence community structure and processes will aid in the management, design, and planning of our cities to best support biodiversity., (© 2016 by the Ecological Society of America.)

Published
2016
Full Text
View/download PDF

34. Soil Carbon and Carbon/Nitrogen Ratio Change under Tree Canopy, Tall Grass, and Turf Grass Areas of Urban Green Space.

Author

Livesley SJ, Ossola A, Threlfall CG, Hahs AK, and Williams NS

Subjects
Poaceae, Trees, Carbon analysis, Nitrogen analysis, Soil chemistry
Abstract

Soils in urban green spaces are an important carbon (C) store, but urban soils with a high carbon to nitrogen (C/N) ratio can also buffer N eutrophication from fertilizer use or atmospheric deposition. The influence of vegetation management practices on soil C cycling and C/N ratios in urban green spaces is largely unknown. In 2013, we collected replicate ( = 3) soil samples from tree canopy, tall grass, and short turf grass areas ( = 3) at four random plot locations ( = 4) established in 13 golf courses ( = 13). At each sample point, soil was separated into 0- to 0.1-, 0.1- to 0.2-, and 0.2- to 0.3-m depths (total = 1404). Linear mixed models investigated the relationships between soil properties, vegetation attributes, and green space age. Tree canopy soil was less compacted (1.07 g cm) than grassy areas (1.32 g cm). Similarly, tree canopy soil had mean C/N ratios of 17.2, as compared with between 14.2 and 15.3 in grassy areas. Soil properties in tree canopy areas were best explained by tree basal area and understory vegetation volume. Soil C/N increased with increasing understory vegetation, and the difference in soil C/N between tree canopy and short turf grass areas increased over time. The soil properties in tree canopy areas of urban green space mean they can increasingly buffer the localized use of N fertilizers and atmospheric N deposition. Managers of urban green spaces concerned about N pollution of groundwater and waterways could consider planting trees in suitable topographic locations and promoting understory vegetation and surface litter accumulation., (Copyright © by the American Society of Agronomy, Crop Science Society of America, and Soil Science Society of America, Inc.)

Published
2016
Full Text
View/download PDF

35. Urban habitat complexity affects species richness but not environmental filtering of morphologically-diverse ants.

Author

Ossola A, Nash MA, Christie FJ, Hahs AK, and Livesley SJ

Abstract

Habitat complexity is a major determinant of structure and diversity of ant assemblages. Following the size-grain hypothesis, smaller ant species are likely to be advantaged in more complex habitats compared to larger species. Habitat complexity can act as an environmental filter based on species size and morphological traits, therefore affecting the overall structure and diversity of ant assemblages. In natural and semi-natural ecosystems, habitat complexity is principally regulated by ecological successions or disturbance such as fire and grazing. Urban ecosystems provide an opportunity to test relationships between habitat, ant assemblage structure and ant traits using novel combinations of habitat complexity generated and sustained by human management. We sampled ant assemblages in low-complexity and high-complexity parks, and high-complexity woodland remnants, hypothesizing that (i) ant abundance and species richness would be higher in high-complexity urban habitats, (ii) ant assemblages would differ between low- and high-complexity habitats and (iii) ants living in high-complexity habitats would be smaller than those living in low-complexity habitats. Contrary to our hypothesis, ant species richness was higher in low-complexity habitats compared to high-complexity habitats. Overall, ant assemblages were significantly different among the habitat complexity types investigated, although ant size and morphology remained the same. Habitat complexity appears to affect the structure of ant assemblages in urban ecosystems as previously observed in natural and semi-natural ecosystems. However, the habitat complexity filter does not seem to be linked to ant morphological traits related to body size.

Published
2015
Full Text
View/download PDF

36. Habitat complexity influences fine scale hydrological processes and the incidence of stormwater runoff in managed urban ecosystems.

Author

Ossola A, Hahs AK, and Livesley SJ

Subjects
Australia, Hydrology, Soil chemistry, Cities, Ecosystem, Rain
Abstract

Urban ecosystems have traditionally been considered to be pervious features of our cities. Their hydrological properties have largely been investigated at the landscape scale and in comparison with other urban land use types. However, hydrological properties can vary at smaller scales depending upon changes in soil, surface litter and vegetation components. Management practices can directly and indirectly affect each of these components and the overall habitat complexity, ultimately affecting hydrological processes. This study aims to investigate the influence that habitat components and habitat complexity have upon key hydrological processes and the implications for urban habitat management. Using a network of urban parks and remnant nature reserves in Melbourne, Australia, replicate plots representing three types of habitat complexity were established: low-complexity parks, high-complexity parks, and high-complexity remnants. Saturated soil hydraulic conductivity in low-complexity parks was an order of magnitude lower than that measured in the more complex habitat types, due to fewer soil macropores. Conversely, soil water holding capacity in low-complexity parks was significantly higher compared to the two more complex habitat types. Low-complexity parks would generate runoff during modest precipitation events, whereas high-complexity parks and remnants would be able to absorb the vast majority of rainfall events without generating runoff. Litter layers on the soil surface would absorb most of precipitation events in high-complexity parks and high-complexity remnants. To minimize the incidence of stormwater runoff from urban ecosystems, land managers could incrementally increase the complexity of habitat patches, by increasing canopy density and volume, preserving surface litter and maintaining soil macropore structure., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published
2015
Full Text
View/download PDF

38. A global synthesis of plant extinction rates in urban areas.

Author

Hahs AK, McDonnell MJ, McCarthy MA, Vesk PA, Corlett RT, Norton BA, Clemants SE, Duncan RP, Thompson K, Schwartz MW, and Williams NS

Subjects
Conservation of Natural Resources, Population Dynamics, Biodiversity, Cities, Extinction, Biological, Plants
Abstract

Plant extinctions from urban areas are a growing threat to biodiversity worldwide. To minimize this threat, it is critical to understand what factors are influencing plant extinction rates. We compiled plant extinction rate data for 22 cities around the world. Two-thirds of the variation in plant extinction rates was explained by a combination of the city's historical development and the current proportion of native vegetation, with the former explaining the greatest variability. As a single variable, the amount of native vegetation remaining also influenced extinction rates, particularly in cities > 200 years old. Our study demonstrates that the legacies of landscape transformations by agrarian and urban development last for hundreds of years, and modern cities potentially carry a large extinction debt. This finding highlights the importance of preserving native vegetation in urban areas and the need for mitigation to minimize potential plant extinctions in the future.

Published
2009
Full Text
View/download PDF

39. A dispersal-constrained habitat suitability model for predicting invasion of alpine vegetation.

Author

Williams NS, Hahs AK, and Morgan JW

Subjects
Australia, Population Dynamics, Time Factors, Asteraceae physiology, Conservation of Natural Resources, Ecosystem, Models, Biological
Abstract

Developing tools to predict the location of new biological invasions is essential if exotic species are to be controlled before they become widespread. Currently, alpine areas in Australia are largely free of exotic plant species but face increasing pressure from invasive species due to global warming and intensified human use. To predict the potential spread of highly invasive orange hawkweed (Hieracium aurantiacum) from existing founder populations on the Bogong High Plains in southern Australia, we developed an expert-based, spatially explicit, dispersal-constrained, habitat suitability model. The model combines a habitat suitability index, developed from disturbance, site wetness, and vegetation community parameters, with a phenomenological dispersal kernel that uses wind direction and observed dispersal distances. After generating risk maps that defined the relative suitability of H. aurantiacum establishment across the study area, we intensively searched several locations to evaluate the model. The highest relative suitability for H. aurantiacum establishment was southeast from the initial infestations. Native tussock grasslands and disturbed areas had high suitability for H. aurantiacum establishment. Extensive field searches failed to detect new populations. Time-step evaluation using the location of populations known in 1998-2000, accurately assigned high relative suitability for locations where H. aurantiacum had established post-2003 (AUC [area under curve] = 0.855 +/- 0.035). This suggests our model has good predictive power and will improve the ability to detect populations and prioritize areas for ongoing monitoring.

Published
2008
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results