Your search keyword '"terrestrial biodiversity"' showing total 65 results

1. Terrestrial Biodiversity in Arid Environments: One Global Component of Climate Crisis Resilience

Author

Conkey, April Torres, Purchase, Cromwell, Richer, Renee, Yamaguchi, Nobuyuki, Rahman, Md Mizanur, Series Editor, Cochrane, Logan, editor, and Al-Hababi, Reem, editor

Published

2023

2. Terrestrial Biodiversity Hotspots and Their Threats in Guangdong Province

Author

Geng Shoubao, Sun Zhongyu, Zhang Min, Xu Wei, Zhou Xia, Ye Yuyao, Dai Jialing, and Liu Zhengqian

Subjects

terrestrial biodiversity, hotspot, threat, conservation and restoration, guangdong province, Geography (General), G1-922

Abstract

Biodiversity plays an important role in providing ecosystem services and maintaining ecosystem stability, which are closely related to human welfare. The identification of biodiversity hotspots and analysis of their threats provide effective ways for biodiversity conservation and restoration. Current studies generally combine species diversity and its threat situation to determine hotspots for priority protection. However, in-depth analysis of threats to biodiversity hotspots is still lacking. Guangdong Province is one of the key biodiversity areas in the world, but it faces great challenges in biodiversity preservation. To understand biodiversity hotspots and their threats in Guangdong Province more completely, this study developed a heat index for terrestrial biodiversity by considering plant species diversity, animal species diversity, and landscape diversity based on multi-source data of plant and animal species, ecosystem stand types, and land use. Then, the heat index was used to identify biodiversity hotspots, and their threat levels and controlling factors were analyzed according to the major threats to biodiversity. The results showed that areas with high values of terrestrial biodiversity heat index were mainly distributed in mountainous regions with relatively few human disturbances, whereas most areas with low values were concentrated in estuarine plains and intermontane basins with heavy human activities. Based on the zonation of the heat index, four biodiversity hotspots were identified, Yunwu Mountain, Nanling Mountain, Luofu Mountain, and Lianhua Mountain, with area percentages of 15.54%, 44.90%, 17.66%, and 21.90%, respectively. The area of biodiversity hotspots was 59,931.82 km2, accounting for 33.58% of the total land area of Guangdong Province. The 122 nature reserves within hotspots had an area of 6,594.39 km2, covering 61.33% of the whole area of the total 204 terrestrial nature reserves in Guangdong Province. This proportion gradually decreased with reduction of nature reserve grade, indicating that the nature reserves in hotspots were principally at a higher grade (nation and province levels) rather than at a lower grade (city and county levels). However, the area of these nature reserves in hotspots was only 11.00% of the whole area of hotspots, and most of the nature reserves that were not distributed in hotspots were located in the northeastern cities of Heyuan and Meizhou. Therefore, a large number of potential demands for biodiversity conservation still exist. For the four hotspots, the biodiversity in Yunwu Mountain was primarily under moderate to severe stress, with the intensity of economic development as the controlling factor. The biodiversity of the other three hotspots mainly underwent slight to moderate stress. The most important threat was the extensive economic development of the central part of Nanling Mountain and the southern parts of Luofu Mountain and Lianhua Mountain, whereas the periphery of Nanling Mountain and the northern parts of Luofu Mountain and Lianhua Mountain were more threatened by habitat quality or geological hazards. In addition, extreme stress on biodiversity occurred in all four hotspots, although within very small areas. Thus, more targeted management strategies for biodiversity should be proposed according to the stress levels and controlling threats. The results of this study provide a scientific reference for the comprehensive conservation and precise restoration of biodiversity hotspots in Guangdong Province.

Published

2023

3. 广东省陆地生物多样性热点区域及其胁迫因素.

Author

耿守保, 孙中宇, 张敏, 徐卫, 周霞, 叶玉瑶, 戴佳玲, and 刘郑倩

Abstract

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

Published

2023

4. The biodiversity of ice-free Antarctica database.

Author

Terauds A, Lee JR, Wauchope HS, Raymond B, Bergstrom DM, Convey P, Mason C, Patterson CR, Robinson SA, Van de Putte A, Watts D, and Chown SL

Subjects

Antarctic Regions, Animals, Conservation of Natural Resources methods, Biodiversity, Databases, Factual

Abstract

Antarctica is one of Earth's most untouched, inhospitable, and poorly known regions. Although knowledge of its biodiversity has increased over recent decades, a diverse, wide-ranging, and spatially explicit compilation of the biodiversity that inhabits Antarctica's permanently ice-free areas is unavailable. This absence hinders both Antarctic biodiversity research and the integration of Antarctica in global biodiversity-related studies. Fundamental and applied research on biodiversity patterns, ecological structure and function, and options for conservation are reliant on spatially resolved, taxonomically consistent observations. Such information is especially important for modern, data-driven biodiversity science, in both Antarctica and globally, and forms the backbone of biodiversity informatics, reflected, for example, in the Darwin Core Standard used by the Global Biodiversity Information Facility. Biodiversity data are also essential to fulfill the conservation requirements for Antarctica, as set out in the Protocol on Environmental Protection to the Antarctic Treaty and inform the design of systematic surveys to address biodiversity and ecological knowledge gaps, for both specific taxa and ecosystems. Such surveys are key requirements for understanding and mitigating the impacts of environmental change on the region's biodiversity. Here, we address these requirements through the public release of The Biodiversity of Ice-free Antarctica Database. In 2008, we extracted a subset of biodiversity records only from terrestrial ice-free areas from the Scientific Committee on Antarctic Research (SCAR) Antarctic Biodiversity Database. We have subsequently added thousands of records from a range of sources: checking, and where necessary (and possible), correcting the spatial location, clarifying, cross-referencing, and harmonizing taxonomy with globally recognized sources, and documenting the original source of records. The Biodiversity of Ice-free Antarctica Database spans the early 1800s to 2019 (with most records collected after 1950) and represents the most comprehensive consolidation of Antarctic ice-free biodiversity occurrence data yet compiled into a single database. The Biodiversity of Ice-free Antarctica Database contains 35,654 records of 1890 species in over 800 genera across six kingdoms and spans all Antarctic Conservation Biogeographic Regions. These data are released under a CC BY Attribution License (http://creativecommons.org/licenses/by/4.0/)., (© 2025 The Author(s). Ecology published by Wiley Periodicals LLC on behalf of The Ecological Society of America.)

Published

2025

5. Productive versus environmental objectives of agricultural policies dealing with climate change: a French case study

Author

Tiphaine Guillet and Lauriane Mouysset

Subjects

land-use change, ecosystem service, bioeconomic model, public policy scenario, Europe, terrestrial biodiversity, Environmental sciences, GE1-350

Abstract

The study aims at reconciling contrasting productive and environmental goals of agricultural policies at a given budget in the context of climate change. Based on a quantitative bioeconomic model integrating interdependencies between agricultural systems and agroecosystems, we compare the impacts of 4 contrasted public policy scenarios based either on productive (food or energy) or environmental goals (pollution reduction or ecosystem state) on a set of 18 bioeconomic indicators. We run the policy scenarios under two contrasted climate change scenarios to investigate their robustness. We confirm that it is possible to achieve productive and environmental goals with the on-going budget of European agricultural policy. Synergies between productive and environmental performances exist even if they are not trivial nor systematic. More precisely, an agricultural public policy which focuses on energy production might offer a good compromise regarding the different facets of agricultural landscapes. The Pollution scenario constitutes a credible environmentally oriented alternative even if it remains slightly less competitive regarding both ecological and economic sides than an energy-oriented policy. Eventually, our analysis shows that our conclusions are robust to climate change, suggesting that adequate agricultural public policies might attenuate climate change effects when considering intermediary climate change scenarios.

Published

2022

6. Terrestrial biodiversity threatened by increasing global aridity velocity under high-level warming.

Author

Hao Shi, Hanqin Tian, Lange, Stefan, Jia Yang, Shufen Pan, Bojie Fu, and Reyer, Christopher P. O.

Subjects

*VELOCITY, *VEGETATION greenness, *BIODIVERSITY, *NATURE reserves, *CITIES & towns

Abstract

Global aridification is projected to intensify. Yet, our knowledge of its potential impacts on species ranges remains limited. Here, we investigate global aridity velocity and its overlap with three sectors (natural protected areas, agricultural areas, and urban areas) and terrestrial biodiversity in historical (1979 through 2016) and future periods (2050 through 2099), with and without considering vegetation physiological response to rising CO2. Both agricultural and urban areas showed a mean drying velocity in history, although the concurrent global aridity velocity was on average +0.05/+0.20 km/yr-1 (no CO2 effects/with CO2 effects; "+" denoting wetting). Moreover, in drylands, the shifts of vegetation greenness isolines were found to be significantly coupled with the tracks of aridity velocity. In the future, the aridity velocity in natural protected areas is projected to change from wetting to drying across RCP (representative concentration pathway) 2.6, RCP6.0, and RCP8.5 scenarios. When accounting for spatial distribution of terrestrial taxa (including plants, mammals, birds, and amphibians), the global aridity velocity would be -0.15/-0.02 km/yr-1 ("-" denoting drying; historical), -0.12/-0.15 km/yr-1 (RCP2.6), -0.36/-0.10 km/yr-1 (RCP6.0), and -0.75/-0.29 km/yr-1 (RCP8.5), with amphibians particularly negatively impacted. Under all scenarios, aridity velocity shows much higher multidirectionality than temperature velocity, which is mainly poleward. These results suggest that aridification risks may significantly influence the distribution of terrestrial species besides warming impacts and further impact the effectiveness of current protected areas in future, especially under RCP8.5, which best matches historical CO2 emissions [C. R. Schwalm et al., Proc. Natl. Acad. Sci. U.S.A. 117, 19656-19657 (2020)]. [ABSTRACT FROM AUTHOR]

Published

2021

7. 中国陆域生物多样性综合评估指标体系构建.

Author

王琦, 史娜娜, 韩煜, and 肖能文

Abstract

Copyright of Chinese Journal of Applied Ecology / Yingyong Shengtai Xuebao is the property of Chinese Journal of Applied Ecology 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

2021

8. Biodiversity of Mammoth Cave

Author

Culver, David C., Hobbs, Horton H., III, LaMoreaux, James W., Series editor, Hobbs III, Horton H., editor, Olson, Rickard A, editor, Winkler, Elizabeth G, editor, and Culver, David C., editor

Published

2017

9. Genetic diversity of soil invertebrates corroborates timing estimates for past collapses of the West Antarctic Ice Sheet.

Author

Collins, Gemma E., Hogg, Ian D., Convey, Peter, Sancho, Leopoldo G., Cowan, Don A., Lyons, W. Berry, Adams, Byron J., Wall, Diana H., and Green, T. G. Allan

Subjects

*ANTARCTIC ice, *SOIL invertebrates, *ICE sheets, *INVERTEBRATE diversity, *CYTOCHROME oxidase

Abstract

During austral summer field seasons between 1999 and 2018, we sampled at 91 locations throughout southern Victoria Land and along the Transantarctic Mountains for six species of endemic microarthropods (Collembola), covering a latitudinal range from 76.0°S to 87.3°S. We assembled individual mitochondrial cytochrome c oxidase subunit 1 (COI) sequences (n = 866) and found high levels of sequence divergence at both small (<10 km) and large (>600 km) spatial scales for four of the six Collembola species. We applied molecular clock estimates and assessed genetic divergences relative to the timing of past glacial cycles, including collapses of the West Antarctic Ice Sheet (WAIS). We found that genetically distinct lineages within three species have likely been isolated for at least 5.54 My to 3.52 My, while the other three species diverged more recently (<2 My). We suggest that Collembola had greater dispersal opportunities under past warmer climates, via flotation along coastal margins. Similarly increased opportunities for dispersal may occur under contemporary climate warming scenarios, which could influence the genetic structure of extant populations. As Collembola are a living record of past landscape evolution within Antarctica, these findings provide biological evidence to support geological and glaciological estimates of historical WAIS dynamics over the last ca. 5 My. [ABSTRACT FROM AUTHOR]

Published

2020

10. Additions to the lichenized fungi biota of North America and Alaska from collections held in the University of Alaska Museum of the North herbarium (ALA)

Author

Alan M. Fryday

Subjects

arctic, new reports, north slope, brooks range, terrestrial biodiversity, Environmental sciences, GE1-350, Environmental engineering, TA170-171

Abstract

The data presented here are based on examination of collections made in the 1970s mainly by Barbara Murray and held in the University of Alaska Museum of the North herbarium, Fairbanks (ALA). Four species, Micarea inquinans, Placynthium garovaglioi, Protoblastenia lilacina, and Trimmatothele perquisita, are reported for the first time from North America and 10 species, Clauzadea metzleri, Clauzadeana macula, Ionaspis obtecta, Lambiella gyrizans, Lemmopsis arnoldiana, Placynthium tantaleum, Poeltinula cerebrina, Protoblastenia incrustans, Rimularia gibbosa, and Sagiolechia protuberans, are reported for the first time from Alaska. Records of nine other species that are uncommon in Alaska are also reported.

Published

2017

11. Bioregionalization approaches for conservation: methods, biases, and their implications for Australian biodiversity.

Author

Montalvo-Mancheno, Cristian S., Ondei, Stefania, Brook, Barry W., and Buettel, Jessie C.

Subjects

BIODIVERSITY conservation, BIODIVERSITY, SCIENTISTS

Abstract

Biogeographic classification schemes have been developed to prioritize biodiversity conservation efforts at large scales, but their efficacy remains understudied. Here we develop a systematic map of the literature on bioregional planning, based on a case study of the Interim Biogeographic Regionalization for Australia (IBRA), to identify where and how such schemes have been used in scientific research. We identified 67 relevant studies, finding that the majority investigated biodiversity exclusively within a single bioregion (65.7%), with 18 of these studies splitting the targeted bioregion based on administrative boundaries. Most used inferential techniques (74.6%) or pattern-based measures (68.7%), and few studies (9%) both considered biodiversity across multiple bioregions and compared findings between bioregions. Species were investigated ten times more frequently than ecosystems attributes, with mammals and birds monopolizing scientists' attention. These findings show that our knowledge of biodiversity at bioregional scales is patchy, even for well-studied taxa, and that we have a limited understanding of the synthetic relationship between biodiversity and IBRA bioregions (which are demarcated according to other biophysical factors). This creates a barrier for systematic conservation planning, which requires unbiased information on the spatial attributes of biodiversity, and therefore this knowledge deficit warrants more attention. [ABSTRACT FROM AUTHOR]

Published

2020

12. Environmental effects of short‐rotation woody crops for bioenergy: What is and isn't known.

Author

Griffiths, Natalie A., Rau, Benjamin M., Vaché, Kellie B., Starr, Gregory, Bitew, Menberu M., Aubrey, Doug P., Martin, James A., Benton, Elizabeth, and Jackson, C. Rhett

Subjects

*WOODY plants, *BIOMASS energy, *AQUATIC invertebrates, *WATER quality, *BIODIVERSITY

Abstract

Logging and mill residues are currently the largest sources of woody biomass for bioenergy in the United States, but short‐rotation woody crops (SRWCs) are expected to become a larger contributor to biomass production, primarily on lands marginal for food production. However, there are very few studies on the environmental effects of SRWCs, and most have been conducted at stand rather than at watershed scales. In this manuscript, we review the potential environmental effects of SRWCs relative to current forestry or agricultural practices and best management practices (BMPs) in the southeast United States and identify priorities and constraints for monitoring and modeling these effects. Plot‐scale field studies and a watershed‐scale modeling study found improved water quality with SRWCs compared to agricultural crops. Further, a recent watershed‐scale experiment suggests that conventional forestry BMPs are sufficient to protect water quality from SRWC silvicultural activities, but the duration of these studies is short with respect to travel times of groundwater transporting nitrate to streams. While the effects of SRWC production on carbon (C) and water budgets depend on both soil properties and previous land management, woody crops will typically sequester more C when compared with agricultural crops. The overall C offset by SRWCs will depend on a variety of management practices, the number of rotations, and climate. Effects of SRWCs on biodiversity, especially aquatic organisms, are not well studied, but a meta‐analysis found that bird and mammal biodiversity is lower in SRWC stands than unmanaged forests. Long‐term (i.e., over multiple rotations) water quality, water use, C dynamics, and soil quality studies are needed, as are larger‐scale (i.e., landscape scale) biodiversity studies, to evaluate the potential effects of SRWC production. Such research should couple field measurement and modeling approaches due to the temporal (i.e., multiple rotations) and spatial (i.e., heterogeneous landscape) scaling issues involved with SRWC production. Evaluating the environmental effects of short‐rotation woody crop (SRWC) production for bioenergy requires watershed‐scale experiments and long‐term observations coupled with watershed‐ to landscape‐scale models. These integrative approaches can evaluate environmental effects over multiple SRWC rotations. [ABSTRACT FROM AUTHOR]

Published

2019

13. Current logistical capacity is sufficient to deliver the implementation and management of a representative Antarctic protected area system

Author

Kevin A. Hughes and Susie M. Grant

Subjects

Spatial protection, Environmental Protocol, remote sensing, human impacts, terrestrial biodiversity, Environmental sciences, GE1-350, Oceanography, GC1-1581

Abstract

Antarctica’s terrestrial ecosystems are vulnerable to impacts resulting from climate change and local human activities. The Antarctic Treaty System (ATS) provides for the designation of protected areas through the Protocol on Environmental Protection to the Antarctic Treaty. Unsystematic use of agreed management tools, including Antarctic Specially Protected Areas (ASPAs), has resulted in a protected area system lacking representation across the full range of Antarctic terrestrial ecosystems and Antarctic Conservation Biogeographic Regions (ACBRs). Systematic Conservation Planning (SCP) methods provide established mechanisms to fulfil ATS protected area designation goals. However, how would a continent-wide ASPA system be delivered should appropriate sites be identified using SCP or other methods? Although the rate of area protection has slowed recently, we show that newer Consultative Parties to the Antarctic Treaty are increasingly active as ASPA proponents and may have scope for further engagement with protected area management activities. Furthermore, all 16 ACBRs were found to be within the operational footprint of at least two Parties, indicating that this current logistical footprint could support the implementation and management of a continent-wide ASPA system. Effective management of a representative Antarctic protected areas system could be delivered through greater participation by those Parties with currently more limited protected area management responsibilities and greater use of remote-sensing technologies for protected area monitoring, where appropriate. Crucially, political will to implement an ASPA system identified through SCP approaches may be greater once a pragmatic means of delivery and effective management has been identified.

Published

2018

14. The fate of terrestrial biodiversity during an oceanic island volcanic eruption

Author

Ministerio de Ciencia e Innovación (España), Cabildo Insular de La Palma, Gobierno de Canarias, Cabildo de Tenerife, Nogales, Manuel, Guerrero‑Campos, María, Boulesteix, Thomas, Taquet, Noémie, Beierkuhnlein, Carl, Campion, Robin, Fajardo, Silvia, Zurita, Nieves, Arechavaleta, Manuel, García, Rafael, Weiser, Frank, Medina, Félix M., Ministerio de Ciencia e Innovación (España), Cabildo Insular de La Palma, Gobierno de Canarias, Cabildo de Tenerife, Nogales, Manuel, Guerrero‑Campos, María, Boulesteix, Thomas, Taquet, Noémie, Beierkuhnlein, Carl, Campion, Robin, Fajardo, Silvia, Zurita, Nieves, Arechavaleta, Manuel, García, Rafael, Weiser, Frank, and Medina, Félix M.

Abstract

Volcanic activity provides a unique opportunity to study the ecological responses of organisms to catastrophic environmental destruction as an essential driver of biodiversity change on islands. However, despite this great scientific interest, no study of the biodiversity at an erupting volcano has yet been undertaken. On La Palma (Canary archipelago), we quantified the main species affected and their fate during the 85-day eruption (September–December 2021). Our main objective consisted of monitoring the biodiversity subjected to critical stress during this volcanic eruption. We found that all biodiversity within a 2.5 km radius was severely affected after the first two weeks. It is challenging to assess whether volcanism can drive evolutionary traits of insular organisms. Examples are the adaptation of an endemic conifer to high temperatures, selection of functional plant types—secondary woodiness—, effects of the disappearance of invertebrates and their influence in trophic nets and vertebrate trophic plasticity. However, our data suggest that such previous evolutionary changes might continue to favour their resilience during this eruption. Lastly, it is a very good opportunity to assess the extent to which these periodic volcanic catastrophes may constitute temporary windows of repeated opportunities for the evolution and speciation of oceanic island biota.

Published

2022

15. The fate of terrestrial biodiversity during an oceanic island volcanic eruption

Author

Manuel Nogales, María Guerrero-Campos, Thomas Boulesteix, Noémie Taquet, Carl Beierkuhnlein, Robin Campion, Silvia Fajardo, Nieves Zurita, Manuel Arechavaleta, Rafael García, Frank Weiser, Félix M. Medina, Ministerio de Ciencia e Innovación (España), Cabildo Insular de La Palma, Gobierno de Canarias, and Cabildo de Tenerife

Subjects

Islands, Multidisciplinary, Terrestrial biodiversity, oceanic island, Oceans and Seas, Animals, Volcanic Eruptions, Biodiversity, volcanic eruption, Invertebrates

Abstract

Volcanic activity provides a unique opportunity to study the ecological responses of organisms to catastrophic environmental destruction as an essential driver of biodiversity change on islands. However, despite this great scientific interest, no study of the biodiversity at an erupting volcano has yet been undertaken. On La Palma (Canary archipelago), we quantified the main species affected and their fate during the 85-day eruption (September–December 2021). Our main objective consisted of monitoring the biodiversity subjected to critical stress during this volcanic eruption. We found that all biodiversity within a 2.5 km radius was severely affected after the first two weeks. It is challenging to assess whether volcanism can drive evolutionary traits of insular organisms. Examples are the adaptation of an endemic conifer to high temperatures, selection of functional plant types—secondary woodiness—, effects of the disappearance of invertebrates and their influence in trophic nets and vertebrate trophic plasticity. However, our data suggest that such previous evolutionary changes might continue to favour their resilience during this eruption. Lastly, it is a very good opportunity to assess the extent to which these periodic volcanic catastrophes may constitute temporary windows of repeated opportunities for the evolution and speciation of oceanic island biota., Daily interchange of biological information with our team of volcanologists was the key to better understanding many details of the impact of this 85-day eruption on the rich local biodiversity. Pablo González, Sergio Rodríguez, Jesica López provided us with important references, comments, and support in the field. Sergio Pérez helped identify lichens, and Juan Ignacio Padrón and Jesús Marco provided all kinds of logistic support. We thank the financial support from the Spanish Ministry of Science and Innovation (Real Decreto 1078/2021, de 7 de diciembre), to fund the research activities of the CSIC-PIE project with ID numbers CSIC-LAPALMA-02 and CSIC-LAPALMA-05. The administration of the IPNA-CSIC, Cabildo Insular de La Palma, Gobierno de Canarias and Gesplan S.A. facilitated our work. The manuscript was proof edited by Guido Jones, currently funded by the Cabildo de Tenerife, under the TFinnova Programme supported by MEDI and FDCAN funds. This article is dedicated to the memory of Aurelio Acevedo Rodríguez for his defence of Canarian biodiversity, particularly threatened endemic plants.

Published

2022

16. Assessing the utility of a novel terrestrial biodiversity quality indicator with 10 years of monitoring data.

Author

Mckenzie, Theresa, Normand, Lionel, Iwanycki, Natalie, Miller, Gavin, and Prior, Paul

Subjects

*BIODIVERSITY, *CONSERVATION & restoration, *BENCHMARKING (Management), *URBANIZATION, *GREATER honeyguide

Abstract

We introduce a novel terrestrial biodiversity quality index developed to inform conservation management at a regional/local scale. Our index, the indicator species score (ISS), is derived from data for indicator birds, amphibians, mammals, plants and lichens representative of the major landscape-scale habitat types in the region and a range of sensitivities to urbanization. The ISS incorporates the conservation concern scores of the species monitored. We assess the practical utility of the ISS using 10 years of data for 50 indicator species monitored at 54 fixed sites in the Toronto region, Ontario, Canada. We test the sensitivity of the ISS to temporal and spatial differences/trends. We assess its responsiveness to landscape-level habitat size and quality predictors including natural cover area and wetland area within 500 m, 1 km, and 2 km of the monitoring site centroid, as well as habitat patch score, and road density. We investigate the utility of the ISS in modelling landscape-level effects. We find that it responds to the habitat predictors, to road density and to urbanization impacts other than those tested. We conclude that the ISS supports ecologically relevant interpretation and management target setting/benchmarking. It is intuitive in nature, easily communicated to a non-scientific audience and therefore useful for management reporting. ISS results following 10 years of monitoring also lead us to consider the relative importance of the many impacts that urbanization exerts on areas of natural cover that remain within an urban matrix. We recognize the need to develop metrics, where possible, in order to quantify individual impacts, monitor them, and establish priorities for the reduction or mitigation of the specific drivers of biodiversity quality decline. [ABSTRACT FROM AUTHOR]

Published

2018

17. Regionalised life cycle assessment of pasta production in Iran: Damage to terrestrial ecosystems.

Author

Heidari, Mohammad Davoud, Huijbregts, Mark A.J., Mobli, Hossein, Omid, Mahmoud, Rafiee, Shahin, and van Zelm, Rosalie

Subjects

*PRODUCT life cycle, *PASTA industry, *INDUSTRIAL productivity, *ENVIRONMENTAL impact analysis, *CLIMATE change

Abstract

The field of life cycle assessment (LCA) is moving towards the implementation of advanced damage models to assess specific areas of protection. The goal of this study was to quantify the main sources of terrestrial ecosystem damage from pasta production, based on a regionalised life cycle inventory and impact assessment. The impacts on terrestrial biodiversity caused by climate change, ecotoxicity, acidification, land use, photochemical ozone formation and water use were assessed for pasta production from durum wheat on 90 farms in Iran. The results showed that the agricultural stage was the main source of environmental damage in the life cycle of pasta production. Most variability between farms is caused by variation in the wheat yields. Climate change contribution, water use (for irrigation), and photochemical ozone formation were the main contributors to the impacts on terrestrial biodiversity. Climate change contribution was mainly due to carbon dioxide emissions from diesel fuel burning during agricultural operations. Nitrogen oxide emissions from nitrogen fertiliser production were the main contributor to photochemical ozone formation. Farmers can reduce their diesel use in field operations by combining tillage operations so that only one pass across the soil is required. Various innovative practices in irrigation, such as sprinkler irrigation, can result in higher yields which will lead to reduced environmental damage relating to water use. [ABSTRACT FROM AUTHOR]

Published

2017

18. Genetic diversity of soil invertebrates corroborates timing estimates for past collapses of the West Antarctic Ice Sheet

Author

W. Berry Lyons, Gemma E Collins, Leopoldo G. Sancho, Diana H. Wall, Don A. Cowan, Byron J. Adams, T. G. Allan Green, Peter Convey, and Ian D. Hogg

Subjects

0106 biological sciences, Range (biology), Evolution, Climate Change, Climate change, Antarctic ice sheet, Antarctic Regions, phylogeography, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Soil, Earth, Atmospheric, and Planetary Sciences, Animals, Ice Cover, Glacial period, Molecular clock, 030304 developmental biology, 0303 health sciences, Multidisciplinary, Ecology, molecular clock, Genetic Variation, Biological Sciences, Invertebrates, microarthropods, terrestrial biodiversity, Phylogeography, Geography, Genetic structure, Physical Sciences, Biological dispersal, Seasons, human activities

Abstract

Significance Changes in the extent of ice sheets through evolutionary timescales have influenced the connectivity of soil invertebrate populations across the Antarctic landscape. We use genetic divergences to estimate isolation times for soil invertebrates along the Transantarctic Mountains. Four species of Collembola (Arthropoda) each showed genetically distinct populations at locations likely isolated for millions of years. Two further species were less genetically diverse although also range restricted. Our genetic data corroborate climate reconstructions and estimates of past warm periods of reduced ice and absent ice shelf in the Ross Sea region, during which time open seaways would have facilitated dispersal of Collembola, and possibly other taxa., During austral summer field seasons between 1999 and 2018, we sampled at 91 locations throughout southern Victoria Land and along the Transantarctic Mountains for six species of endemic microarthropods (Collembola), covering a latitudinal range from 76.0°S to 87.3°S. We assembled individual mitochondrial cytochrome c oxidase subunit 1 (COI) sequences (n = 866) and found high levels of sequence divergence at both small (600 km) spatial scales for four of the six Collembola species. We applied molecular clock estimates and assessed genetic divergences relative to the timing of past glacial cycles, including collapses of the West Antarctic Ice Sheet (WAIS). We found that genetically distinct lineages within three species have likely been isolated for at least 5.54 My to 3.52 My, while the other three species diverged more recently (

Published

2020

19. Release of data added to the PREDICTS database (November 2022)

Author

Contu, Sara, De Palma, Adriana, Bates, Rachel, Borer, Jessica, Espinoza De Janon, Felipe, Gao, Di, Harvey, Lorna, Huang, Xiao, Jung, Martin, Maney, Calum, Needler, Gabrielle, Suryometaram, Sasha, Yao, Yujun, Zhang, Hanbin, Albercht, Harald, Almazán-Núñez, Roberto Carlos, Alvarez Alvarez, Edson A., Anitha, K., Barnes, Andrew D., Barzan, Flavia Romina, Baudron, Frederic, Becker, Rafael, Bogyó, David, Bone, James, Bos, Merijn M., Bouam, Idriss, Bravo-Monroy, Liliana, Brown, Keiron, Cabral, Hugo, Calcaterra, Luis, Carpenter, Dan, Carrascal, Luis M., Chiawo, David, Coetzee, Bernard, Connelly, Heather, Cusser, Sarah, da Silva, Luis, Dallimer, Martin, Davies, Stephen, De Smedt, Pallieter, Edwards, David, Eggleton, Paul, Farahat, Emad, Farrell, Mark, Flinn, Kathryn, Forrest, Jessica, Gardner, Charlie, Gardner, Toby, Geoffroy, Jean-Jacques, Gove, Aaron, Guillemot, Joannès, Hendrix, Stephen, Horváth, Roland, Hvenegaard, Glen, Irwin, Sandra, Jackson, Michelle, Jalilova, Gulnaz, Jha, Shalene, Jianghong, Ran, Jones, David T, Kajtoch, Lukasz, Kambach, Stephan, Kamp, Johannes, Karp, Daniel, Kazerani, Farzane, Kessler, Michael, Kitazawa, Munehiro, Knoll, Fátima do Rosário Naschenveng, Kone, Mouhamadou, Kosewska, Agnieszka, Kremen, Claire, Kutt, Alex S, Lacasella, Federica, Lange, Markus, Lees, David, Lei, Fumin, Leong, Misha, Leso, Peter, López Ricaurte, Lina, Magura, Tibor, Mandle, Lisa, Marinaro, Sofía, Martin, Dominic, Massawe, Apia, Minor, Maria, Mir, Aabid Hussain, Mohandass, D., Morgado, Rui, Mulder, Christian, Murvanidze, Maka, Nascimento, Marcelo, Nielsen, Martin Reinhardt, Özden, Özge, Pall, José Luis María, Palomino, David, Philippe, Vaast, Piovesan, Gianluca, Ponge, Jean-François, Sreekar, Rachakonda, Raman, T. R. Shankar, Rengaian, Ganesan, Rolim, Samir, Sahoo, Uttam Kumar, Salmon, Sandrin, Sambuichi, Regina Helena Rosa, Schmiedel, Ute, Schmitt, Christine B, Schmitt, Christine, Selwyn, Mark Arthur, Shahabuddin, Saleh, Sharma, Neeraj, Sofia, Silvia Helena, Soga, Masashi, Song, Gang, Suarez, Andrew V., Suarez-Rubio, Marcela, Sunil, Chikkahuchaiah, Taboada, Angela, Tanalgo, Krizler C., Tóthmérész, Béla, Van Bael, Sunshine, Vanbergen, Adam, Van Vu, Lien, Weideman, Eleanor, Williams, Neal, Wuyts, Karen, Xue, Chen, Yan, Xiaoli, Yongjie, Wu, Zhang, Taxing, Brummitt, Neil, Burton, Victoria, Hill, Samantha L.L., Hudson, Lawrence, Humphries, Josh, Newbold, Tim, Phillips, Helen, Sanchez-Ortiz, Katia, Tobias, Joseph, Vincent, Sarah, Walkden, Patrick, Weeks, Tom, Woodburn, Matt, and Purvis, Andy

Subjects

terrestrial biodiversity, land cover, predicts, land use, global biodiversity, global change, biodiversity

Abstract

This dataset comprises 1,040,752 measurements, collated from 9,544 sampling locations in 46 countries and representing 10,635 species. The data was collated from 115 existing spatial comparisons of local-scale biodiversity exposed to different intensities and types of anthropogenic pressures, from terrestrial sites around the world. The database was assembled as part of the PREDICTS project - Projecting Responses of Ecological Diversity In Changing Terrestrial Systems; https://www.nhm.ac.uk/our-science/our-work/biodiversity/predicts.html This release is an addition to the data presented with The 2016 release of the PREDICTS database (available on the NHM Data Portal: https://data.nhm.ac.uk/dataset/the-2016-release-of-the-predicts-database).

Published

2022

20. Bacterial and eukaryotic biodiversity patterns in terrestrial and aquatic habitats in the Sør Rondane Mountains, Dronning Maud Land, East Antarctica.

Author

Obbels, Dagmar, Verleyen, Elie, Mano, Marie-José, Namsaraev, Zorigto, Sweetlove, Maxime, Tytgat, Bjorn, Fernandez-Carazo, Rafael, De Wever, Aaike, D'hondt, Sofie, Ertz, Damien, Elster, Josef, Sabbe, Koen, Willems, Anne, Wilmotte, Annick, and Vyverman, Wim

Subjects

*BIODIVERSITY, *AQUATIC habitats, *PYROSEQUENCING, *RIBOSOMAL RNA, *CRYOCONITE

Abstract

The bacterial and microeukaryotic biodiversity were studied using pyrosequencing analysis on a 454 GS FLX+ platform of partial SSU rRNA genes in terrestrial and aquatic habitats of the Sør Rondane Mountains, including soils, on mosses, endolithic communities, cryoconite holes and supraglacial and subglacial meltwater lenses. This inventory was complemented with Denaturing Gradient Gel Electrophoresis targeting Chlorophyta and Cyanobacteria. OTUs belonging to the Rotifera, Chlorophyta, Tardigrada, Ciliophora, Cercozoa, Fungi, Bryophyta, Bacillariophyta, Collembola and Nematoda were present with a relative abundance of at least 0.1% in the eukaryotic communities. Cyanobacteria, Proteobacteria, Bacteroidetes, Acidobacteria, FBP and Actinobacteria were the most abundant bacterial phyla. Multivariate analyses of the pyrosequencing data revealed a general lack of differentiation of both eukaryotes and prokaryotes according to habitat type. However, the bacterial community structure in the aquatic habitats was dominated by the filamentous cyanobacteria Leptolyngbya and appeared to be significantly different compared with those in dry soils, on mosses, and in endolithic habitats. A striking feature in all datasets was the detection of a relatively large amount of sequences new to science, which underscores the need for additional biodiversity assessments in Antarctic inland locations. [ABSTRACT FROM AUTHOR]

Published

2016

21. Biological diversity and climate change

Author

Leemans, R., Nunez Ramos, S.E., Alkemade, J.R.M., Leemans, R., Nunez Ramos, S.E., and Alkemade, J.R.M.

Abstract

This chapter reviews the climate change impacts on biodiversity, species, and ecosystems. However, other threats, such as land use change and habitat destruction, also contribute to the global decline of biodiversity. This chapter uses an integrated approach by singling out climatic factors where ever possible and combining them with other relevant factors where needed. Such an approach paints an integrated picture of change in biodiversity and allows to inform policies to slow or halt the decline of biodiversity. The first climate change impact studies focused on modeling potentially shifting vegetation and phenology patterns. Later, other ecological aspects were included. During the 1990s, actual climate change impacts were observed, which enriched the model-based impacts assessments. From 2000 and onward, the climate change impacts on biodiversity, species, and ecosystems were used to inform politicians on the urgency to limit climate change and to protect biodiversity. This was probably effective as the UN FCCC's Paris Target is largely motivated by extreme weather events and threats to biodiversity. This chapter concludes by evaluating if current and proposed climate change and conservation policies are adequate to protect biodiversity. The analysis unambiguously shows that they not yet are successful and that the decline in biodiversity continues.

Published

2021

22. Can ecosystem-scale translocations mitigate the impact of climate change on terrestrial biodiversity? Promises, pitfalls, and possibilities

Author

Boyer, Stephane, Case, Bradley S., Lefort, Marie-Caroline, Waterhouse, Benjamin, and Wratten, Stephen D.

Published

2016

23. Conclusions

Author

Worm, Boris, author and Tittensor, Derek P., author

Published

2018

24. Observed Patterns of Global Biodiversity

Author

Worm, Boris, author and Tittensor, Derek P., author

Published

2018

25. Introduction

Author

Worm, Boris, author and Tittensor, Derek P., author

Published

2018

26. Biological diversity and climate change

Author

Rob Alkemade, Sarahi Nunez, and Rik Leemans

Subjects

Policy’s effectiveness, WIMEK, Terrestrial biodiversity, Phenology, Impact assessments and scenarios, Biodiversity, Climate change, Vegetation, Extreme weather, Geography, Habitat destruction, Environmental Systems Analysis, The paris target, Milieusysteemanalyse, Ecosystem, Land use, land-use change and forestry, Species and ecosystem responses, Environmental planning

Abstract

This chapter reviews the climate change impacts on biodiversity, species, and ecosystems. However, other threats, such as land use change and habitat destruction, also contribute to the global decline of biodiversity. This chapter uses an integrated approach by singling out climatic factors where ever possible and combining them with other relevant factors where needed. Such an approach paints an integrated picture of change in biodiversity and allows to inform policies to slow or halt the decline of biodiversity. The first climate change impact studies focused on modeling potentially shifting vegetation and phenology patterns. Later, other ecological aspects were included. During the 1990s, actual climate change impacts were observed, which enriched the model-based impacts assessments. From 2000 and onward, the climate change impacts on biodiversity, species, and ecosystems were used to inform politicians on the urgency to limit climate change and to protect biodiversity. This was probably effective as the UN FCCC's Paris Target is largely motivated by extreme weather events and threats to biodiversity. This chapter concludes by evaluating if current and proposed climate change and conservation policies are adequate to protect biodiversity. The analysis unambiguously shows that they not yet are successful and that the decline in biodiversity continues.

Published

2021

27. Characteristics of climate change refugia for Australian biodiversity.

Author

Reside, April E., Welbergen, Justin A., Phillips, Ben L., Wardell‐Johnson, Grant W., Keppel, Gunnar, Ferrier, Simon, Williams, Stephen E., and VanDerWal, Jeremy

Subjects

*CLIMATE change, *BIODIVERSITY conservation, *BIOTIC communities, *ECOLOGY, *PHYSIOLOGICAL stress

Abstract

Identifying refugia is a critical component of effective conservation of biodiversity under anthropogenic climate change. However, despite a surge in conceptual and practical interest, identifying refugia remains a significant challenge across diverse continental landscapes. We provide an overview of the key properties of refugia that promote species' persistence under climate change, including their capacity to (i) buffer species from climate change; (ii) sustain long-term population viability and evolutionary processes; (iii) minimize the potential for deleterious species interactions, provided that the refugia are (iv) available and accessible to species under threat. Further, we classify refugia in terms of the environmental and biotic stressors that they provide protection from (i.e. thermal, hydric, cyclonic, pyric and biotic refugia), but ideally refugia should provide protection from a multitude of stressors. Our systematic characterization of refugia facilitates the identification of refugia in the Australian landscape. Challenges remain, however, specifically with respect to how to assess the quality of refugia at the level of individual species and whole species assemblages. It is essential that these challenges are overcome before refugia can live up to their acclaim as useful targets for conservation and management in the context of climate change. [ABSTRACT FROM AUTHOR]

Published

2014

28. Effects of natural resource development on the terrestrial biodiversity of Canadian boreal forests1.

Author

Venier, L.A., Thompson, I.D., Fleming, R., Malcolm, J., Aubin, I., Trofymow, J.A., Langor, D., Sturrock, R., Patry, C., Outerbridge, R.O., Holmes, S.B., Haeussler, S., De Grandpré, L., Chen, H.Y.H., Bayne, E., Arsenault, A., and Brandt, J.P.

Subjects

*FOREST management, *TAIGAS, *PLANT growth, *HABITATS, *NATURAL resources

Abstract

Much of Canada's terrestrial biodiversity is supported by boreal forests. Natural resource development in boreal forests poses risks to this biodiversity. This paper reviews the scientific literature to assess the effects of natural resource development on terrestrial biodiversity in Canadian boreal forests. We address four questions: (1) To what extent have Canadian boreal forests changed due to natural resource development? (2) How has biodiversity responded to these changes? (3) Will the biodiversity of second-growth forests converge with that of primary boreal forests? (4) Are we losing species from boreal forests? We focus on trees, understory plants, insects, fungi, selected mammals, and songbirds because these groups have been most studied. We review more than 600 studies and found that changes in community composition are prevalent in response to large-scale conversion of forest types, changes in stand structures and age distributions, and altered landscape structure resulting from forest management and habitat loss associated with other developments such as oil and gas, hydroelectric, and mining. The southern boreal forest has been more highly impacted than the north due to more extensive forest management and the cumulative effects of multiple forms of development. There is abundant evidence that most species are not in danger of being extirpated from the boreal forest due to these anthropogenic changes. A few species, including woodland caribou ( Rangifer tarandus) and grizzly bear ( Ursus arctos), have, however, undergone long-term range contractions. Significant gaps in our ability to assess the effects of natural resource development on biodiversity in the boreal zone are the lack of long-term spatial and population data to monitor the impact of forest changes on ecosystems and species. [ABSTRACT FROM AUTHOR]

Published

2014

29. Effects of natural resource development on the terrestrial biodiversity of Canadian boreal forests1.

Author

Venier, L.A., Thompson, I.D., Fleming, R., Malcolm, J., Aubin, I., Trofymow, J.A., Langor, D., Sturrock, R., Patry, C., Outerbridge, R.O., Holmes, S.B., Haeussler, S., De Grandpré, L., Chen, H.Y.H., Bayne, E., Arsenault, A., and Brandt, J.P.

Subjects

FOREST management, TAIGAS, PLANT growth, HABITATS, NATURAL resources

Abstract

Copyright of Environmental Reviews is the property of Canadian Science Publishing 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

2014

30. Fauna in decline: The community way

Author

Boyer, S

Published

2014

31. Modelling individual and collective species responses to climate change within Small Island States.

Author

Maharaj, Shobha S. and New, Mark

Subjects

*CLIMATE change, *SPECIES, *BIOLOGICAL adaptation, *ISLANDS, *MATHEMATICAL models

Abstract

Highlights: [•] Impact of SRES A2 conditions upon tree species within a small island were modelled. [•] New method to determine collective response of any number of species to climate change. [•] Collective response is very useful for planning within limited spaces of small islands. [•] Individual and collective species projected to lose over 50% of present climate space. [•] Many important species may disappear within small islands as climate changes. [Copyright &y& Elsevier]

Published

2013

32. A review of scientific research trends within ASPA No. 126 Byers Peninsula, South Shetland Islands, Antarctica.

Author

Benayas, J., Pertierra, L., Tejedo, P., Lara, F., Bermudez, O., Hughes, K.A., and Quesada, A.

Subjects

CLIMATE research, GEOLOGY, LIMNOLOGY, PALEONTOLOGY, PROTECTED areas, BIODIVERSITY

Abstract

Byers Peninsula, Livingston Island, was one of the first sites in Antarctica designated for environmental conservation and scientific protection. Research on Byers Peninsula has been predominantly international, with 88 indexed publications (93% of them published during last 20 years) from 209 authors affiliated to 110 institutions from 22 nations, all of which are signatories to the Antarctic Treaty. Palaeontological research represented 20% of the published articles. The variety of freshwater bodies within the area has made Byers Peninsula a reference site for limnological studies (24% of papers). The site also contains numerous outcrops and periglacial features relevant to geology, stratigraphy and geomorphology (29%). Terrestrial biodiversity is extraordinarily high for lichens, bryophytes and invertebrates (15% of articles). Only 5% of the publications concern research on human activities, including both archaeology and impact monitoring. Glaciology, meteorology and climatology studies represent only 7% of papers. This work highlights the international and multidisciplinary nature of science conducted on Byers Peninsula in order to promote international cooperation and to provide information relevant for environmental management and conservation. [ABSTRACT FROM PUBLISHER]

Published

2013

33. Continental governance and environmental management mechanisms under the Antarctic Treaty System: sufficient for the biodiversity challenges of this century?

Author

Convey, Peter, Hughes, Kevin A., and Tin, Tina

Subjects

ENVIRONMENTAL management, ANTARCTIC Treaty system, BIODIVERSITY, ENVIRONMENTAL degradation

Abstract

Antarctic terrestrial biodiversity is challenged by rapid climatic changes and expansion of the human footprint. As well as the potential for environmental damage at the local level, these challenges are likely to act synergistically to increase the risk of introduction and establishment of non-native species and diseases and reduce the resilience of native ecosystems. The Protocol on Environmental Protection to the Antarctic Treaty (‘the Protocol’) entered into force in 1998 and is the main governance mechanism that regulates environmental management in Antarctica. We examine how well the Protocol and associated management tools are currently equipped to protect Antarctic terrestrial biodiversity in a warmer and busier Antarctic, considering likely future challenges, current levels of compliance with the Protocol and implementation of its requirements, and participation in environmental matters by Antarctic Treaty Parties. We argue that a strategic-level response will be needed to boost the ability of the Antarctic Treaty System to deal with the large-scale, pervasive challenges of climate change and increased human activity. A strategic planning approach that can (1) account for trends over long periods, (2) take into consideration cumulative effects, (3) be guided by a set of consciously chosen priorities, and (4) take an integrated approach towards management of human activities and the conservation of the Antarctic environment, will permit the anticipation of upcoming challenges and risks and adoption of proactive and holistic management strategies. [ABSTRACT FROM AUTHOR]

Published

2012

34. Considering habitat conversion and fragmentation in characterisation factors for land-use impacts on vertebrate species richness.

Author

Kuipers, Koen J.J., May, Roel, and Verones, Francesca

Published

2021

35. Impact of increased wood pellet demand on biodiversity in the south-eastern United States

Author

Duden, Anna S., Rubino, Matthew J., Tarr, Nathan M., Verweij, Pita A., Faaij, Andre P.C., van der Hilst, Floor, Biobased Economy, Energy System Analysis, Energy and Resources, Biobased Economy, Energy System Analysis, and Energy and Resources

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, spatial analysis, CONSERVATION, Biodiversity, DIVERSITY, Context (language use), 010603 evolutionary biology, 01 natural sciences, land-use change, MONITORING BIODIVERSITY, potential species richness, Bioenergy, Urbanization, TERRESTRIAL BIODIVERSITY, Land use, land-use change and forestry, Renewable Energy, Waste Management and Disposal, 0105 earth and related environmental sciences, US, Land use, Sustainability and the Environment, Agroforestry, Renewable Energy, Sustainability and the Environment, SPECIES RICHNESS, solid biomass, Forestry, LAND-USE CHANGE, ENDEMISM, HOTSPOTS, SCENARIOS, pine plantation, Geography, Threatened species, Species richness, Agronomy and Crop Science

Abstract

Increasing wood pellet exports from the United States are projected to lead to changes in land use and timberland management, including a shift from natural timberland to pine plantations. These projected changes may impact biodiversity. This study aims to quantify potential biodiversity impacts of increased wood pellet demand in the south-eastern United States in a spatially explicit manner. We determined differences according to an index of potential species richness (for total, threatened and endemic species and four taxonomic groups) between scenarios of high and low demand for wood pellets, while taking into account potential developments in other wood markets and other land uses. Increased demand for wood pellets was projected to cause both positive and negative biodiversity impacts. Negative shifts in total potential species richness were projected for areas in Florida, coastal Virginia and North Carolina, and parts of the Gulf Coast. Positive shifts in total potential species richness were projected in parts of Oklahoma and Arkansas. In some locations, the direction of change differed per taxonomic group, highlighting the importance of analysing different taxonomic groups. Shifts in potential species richness due to increased wood pellet demand were considerably smaller compared to the changes due to other drivers, such as urbanization and increased timber demand. Biodiversity impacts due to wood pellet demand should therefore be considered in the context of other drivers of land-use change and biodiversity loss. Our results provide information that allows policymakers, industry and NGOs to focus on areas of concern and take appropriate mitigation measures to limit negative biodiversity impacts and promote positive impacts. The spatially explicit approach presented in this study can be applied to different regions and drivers of land-use change, to show how projected demand for an internationally traded commodity may lead to impacts on land use and biodiversity in the procurement region.

Published

2018

36. Current logistical capacity is sufficient to deliver the implementation and management of a representative Antarctic protected area system

Author

Susie M. Grant and Kevin A. Hughes

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Climate change, Antarctic treaty, Oceanography, 010603 evolutionary biology, 01 natural sciences, remote sensing, lcsh:Oceanography, Earth and Planetary Sciences (miscellaneous), Environmental Chemistry, lcsh:GC1-1581, lcsh:Environmental sciences, 0105 earth and related environmental sciences, General Environmental Science, Spatial protection, Environmental protocol, human impacts, lcsh:GE1-350, business.industry, Environmental resource management, Environmental Protocol, Current (stream), terrestrial biodiversity, Remote sensing (archaeology), Environmental science, Terrestrial ecosystem, business, Protected area

Abstract

Antarctica’s terrestrial ecosystems are vulnerable to impacts resulting from climate change and local human activities. The Antarctic Treaty System (ATS) provides for the designation of protected areas through the Protocol on Environmental Protection to the Antarctic Treaty. Unsystematic use of agreed management tools, including Antarctic Specially Protected Areas (ASPAs), has resulted in a protected area system lacking representation across the full range of Antarctic terrestrial ecosystems and Antarctic Conservation Biogeographic Regions (ACBRs). Systematic Conservation Planning (SCP) methods provide established mechanisms to fulfil ATS protected area designation goals. However, how would a continent-wide ASPA system be delivered should appropriate sites be identified using SCP or other methods? Although the rate of area protection has slowed recently, we show that newer Consultative Parties to the Antarctic Treaty are increasingly active as ASPA proponents and may have scope for further engagement with protected area management activities. Furthermore, all 16 ACBRs were found to be within the operational footprint of at least two Parties, indicating that this current logistical footprint could support the implementation and management of a continent-wide ASPA system. Effective management of a representative Antarctic protected areas system could be delivered through greater participation by those Parties with currently more limited protected area management responsibilities and greater use of remote-sensing technologies for protected area monitoring, where appropriate. Crucially, political will to implement an ASPA system identified through SCP approaches may be greater once a pragmatic means of delivery and effective management has been identified.

Published

2018

37. A protocol for an intercomparison of biodiversity and ecosystem services models using harmonized land-use and climate scenarios

Author

H. Kim, I. M. D. Rosa, R. Alkemade, P. Leadley, G. Hurtt, A. Popp, D. P. van Vuuren, P. Anthoni, A. Arneth, D. Baisero, E. Caton, R. Chaplin-Kramer, L. Chini, A. De Palma, F. Di Fulvio, M. Di Marco, F. Espinoza, S. Ferrier, S. Fujimori, R. E. Gonzalez, M. Gueguen, C. Guerra, M. Harfoot, T. D. Harwood, T. Hasegawa, V. Haverd, P. Havlík, S. Hellweg, S. L. L. Hill, A. Hirata, A. J. Hoskins, J. H. Janse, W. Jetz, J. A. Johnson, A. Krause, D. Leclère, I. S. Martins, T. Matsui, C. Merow, M. Obersteiner, H. Ohashi, B. Poulter, A. Purvis, B. Quesada, C. Rondinini, A. M. Schipper, R. Sharp, K. Takahashi, W. Thuiller, N. Titeux, P. Visconti, C. Ware, F. Wolf, H. M. Pereira, Aquatic Ecology (AqE), Ecologie Systématique et Evolution (ESE), Ecole Nationale du Génie Rural, des Eaux et des Forêts (ENGREF)-Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS), Department of Geographical Sciences, University of Maryland [College Park], University of Maryland System-University of Maryland System, Potsdam-Institut für Klimafolgenforschung (PIK), PBL Netherlands Environmental Assessment Agency, Institut für Meteorologie und Klimaforschung - Atmosphärische Umweltforschung (IMK-IFU), Karlsruher Institut für Technologie (KIT), Natural Capital Project, Woods Institute for the Environment, Stanford University, National Institute for Environmental Studies (NIES), Laboratoire d'Ecologie Alpine (LECA ), Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019]), Oceans and Atmosphere Flagship [Brisbane], Commonwealth Scientific and Industrial Research Organisation [Canberra] (CSIRO), International Institute for Applied Systems Analysis [Laxenburg] (IIASA), Land and Water Flagship [Canberra], Martin-Luther-Universität Halle Wittenberg (MLU), Yale University [New Haven], International Institute for Applied Systems Analysis (IIASA), Montana State University (MSU), Division of Biology [London], Imperial College London, Laboratoire des Sciences du Climat et de l'Environnement [Gif-sur-Yvette] (LSCE), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Helmholtz Zentrum für Umweltforschung = Helmholtz Centre for Environmental Research (UFZ), Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ), and Environmental Sciences

Subjects

0106 biological sciences, CARBON-CYCLE MODELS, 010504 meteorology & atmospheric sciences, RANGE SHIFTS, Ecosystem modeling, Biodiversity, 01 natural sciences, Ecosystem services, Carbon-cycle models, terrestrial biodiversity, species distribution, global biodiversity, atmoshere-ocean, simpler model, range switch, impacts, vegetation, future, TERRESTRIAL BIODIVERSITY, 11. Sustainability, SPECIES DISTRIBUTION, ddc:550, Climate change, Geosciences, Multidisciplinary, Land use change, Environmental planning, Strategic planning, 0303 health sciences, Convention on Biological Diversity, ATMOSPHERE-OCEAN, Environmental resource management, lcsh:QE1-996.5, Geology, Representative Concentration Pathways, General Medicine, international, Milieusysteemanalyse, Physical Sciences, IMPACTS, Conservation status, Ecosystem service, [SDE.MCG]Environmental Sciences/Global Changes, 04 Earth Sciences, Earth and Planetary Sciences(all), Harmonization, 010603 evolutionary biology, LPJ-GUESS, Intergovernmental panel on climate change, 03 medical and health sciences, FUTURE, Modelling and Simulation, Life Science, IPBES, 030304 developmental biology, 0105 earth and related environmental sciences, Science & Technology, Land use, business.industry, 15. Life on land, [SDE.ES]Environmental Sciences/Environmental and Society, lcsh:Geology, Earth sciences, Environmental Systems Analysis, GLOBAL BIODIVERSITY, 13. Climate action, Strategic approach, Environmental science, VEGETATION, [SDE.BE]Environmental Sciences/Biodiversity and Ecology, business, SIMPLER MODEL, Global biodiversity

Abstract

To support the assessments of the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services (IPBES), the IPBES Expert Group on Scenarios and Models is carrying out an intercomparison of biodiversity and ecosystem services models using harmonized scenarios (BES-SIM). The goals of BES-SIM are (1) to project the global impacts of land-use and climate change on biodiversity and ecosystem services (i.e., nature's contributions to people) over the coming decades, compared to the 20th century, using a set of common metrics at multiple scales, and (2) to identify model uncertainties and research gaps through the comparisons of projected biodiversity and ecosystem services across models. BES-SIM uses three scenarios combining specific Shared Socio-economic Pathways (SSPs) and Representative Concentration Pathways (RCPs) – SSP1xRCP2.6, SSP3xRCP6.0, SSP5xRCP8.6 – to explore a wide range of land-use change and climate change futures. This paper describes the rationale for scenario selection, the process of harmonizing input data for land use, based on the second phase of the Land Use Harmonization Project (LUH2), and climate, the biodiversity and ecosystem services models used, the core simulations carried out, the harmonization of the model output metrics, and the treatment of uncertainty. The results of this collaborative modeling project will support the ongoing global assessment of IPBES, strengthen ties between IPBES and the Intergovernmental Panel on Climate Change (IPCC) scenarios and modeling processes, advise the Convention on Biological Diversity (CBD) on its development of a post-2020 strategic plans and conservation goals, and inform the development of a new generation of nature-centred scenarios. ISSN:1991-9603 ISSN:1991-959X

Published

2018

38. Connecting Earth observation to high-throughput biodiversity data

Author

James D.A. Millington, Heiko Balzter, Alfried P. Vogler, Kristine Bohmann, Douglas W. Yu, Richard Reeve, Piran C. L. White, Beth Cole, Fabian H. Leendertz, Ingrid J. Visseren-Hamakers, John R. Olson, Dave Raffaelli, Christopher Martius, Otso Ovaskainen, Alex Bush, M. Thomas P. Gilbert, Louise Matthews, Stewart Snape, Rahel Sollmann, Sébastien Calvignac-Spencer, Christina A. Cobbold, Andreas Wilting, Torrey W. Rodgers, Simon Ferrier, Brent C. Emerson, Martin J. Wooster, Mark-Oliver Rödel, Martin Herold, András Zlinszky, Laurence Jones, Terence P. Dawson, and Natural Environment Research Council (UK)

Subjects

0106 biological sciences, Earth observation, LAND, Conservation Biology, 010504 meteorology & atmospheric sciences, Computer science, CONSERVATION, MODELS, Biodiversity, Environmental Sciences & Ecology, ECOSYSTEM SERVICES, 010603 evolutionary biology, 01 natural sciences, Ecology and Environment, Ecosystem services, ENVIRONMENTAL-CHANGE, Environmental impact, Laboratory of Geo-information Science and Remote Sensing, TERRESTRIAL BIODIVERSITY, SUPPORT, Life Science, Measurement of biodiversity, Ecosystem, Environmental impact assessment, Laboratorium voor Geo-informatiekunde en Remote Sensing, BETA-DIVERSITY, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, Pace, Evolutionary Biology, Science & Technology, Ecology, business.industry, Environmental resource management, SCIENCE, 15. Life on land, PE&RC, FOREST, 13. Climate action, Conservation biology, business, Decision making, Life Sciences & Biomedicine

Abstract

Understandably, given the fast pace of biodiversity loss, there is much interest in using Earth observation technology to track biodiversity, ecosystem functions and ecosystem services. However, because most biodiversity is invisible to Earth observation, indicators based on Earth observation could be misleading and reduce the effectiveness of nature conservation and even unintentionally decrease conservation effort. We describe an approach that combines automated recording devices, high-throughput DNA sequencing and modern ecological modelling to extract much more of the information available in Earth observation data. This approach is achievable now, offering efficient and near-real-time monitoring of management impacts on biodiversity and its functions and services., This Perspective is a product of the EO-BESS Working Group, organized by H.B., D.R. and B.C. and funded by the UK Natural Environment Research Council.

Published

2017

39. Global characterization factors for terrestrial biodiversity impacts of future land inundation in Life Cycle Assessment.

Author

Dorber, Martin, Kuipers, Koen, and Verones, Francesca

Abstract

• Land inundation results in loss of terrestrial habitat. • Life Cycle Assessment has neglected inundation impacts on terrestrial biodiversity. • We develop global and regional characterization factors for land inundation. • These are designed for sea level rise, land aquaculture and reservoir construction. Life Cycle Assessment (LCA) is a tool for analyzing and comparing environmental impacts of products throughout their life cycles, facilitating shifts towards more environmentally friendly products. However, LCA does currently not address terrestrial biodiversity impacts related to the conversion of terrestrial habitat into aquatic habitat. This conversion can occur because of sea level rise, establishment of new land-based aquaculture, as well as reservoir expansion or creation. Here, we focus on land occupation and terrestrial biodiversity impacts, while transformation impacts, and habitat gain for aquatic species were beyond the scope of the study. To be able to estimate the regional and global terrestrial biodiversity impacts of future land occupation from terrestrial to aquatic habitat in LCA, we developed new characterization factors (CFs) for 781 terrestrial ecoregions, 5 land cover/use types, and 4 taxonomic groups. The basis for the development of the proposed CFs is the model concept of the currently recommended method for quantifying land use impacts on biodiversity in LCA by the Life Cycle Initiative hosted by United Nations Environmental Program. The global CFs vary between 7.44 E−20 PDF/m2 and 6.25 E−09 PDF/m2, showing that a highly variable terrestrial biodiversity impact of land inundation between land cover/use types, taxonomic groups and ecoregions exists. [ABSTRACT FROM AUTHOR]

Published

2020

40. [Establishment of an indicator system for comprehensive assessment on terrestrial biodiversity in China].

Author

Wang Q, Shi NN, Han Y, and Xiao NW

Subjects

China, Sustainable Development, Biodiversity, Conservation of Natural Resources

Abstract

The comprehensive evaluation of terrestrial biodiversity is a key basic work for biodiversity protection. Clarifying the status, trend, and driving factors of biodiversity is premise and necessary for formulating policies and measures of biodiversity protection. At present, there is no unified indicator system for the comprehensive assessment of terrestrial biodiversity in China. We constructed a comprehensive assessment indicator system of terrestrial biodiversity in China, by combining the Aichi biodiversity targets of the Convention on Biological Diversity and the sustainable development goals of the United Nations, learning from the development trend of biodiversity assessment in the world, and following the Pressure-State-Response framework. A total of 22 indicators were obtained, including eight status indicators, seven pressure indicators, and seven response indicators. The correlation and accessibility of the indicators were analyzed. These indicators could be applied to not only an independent assessment for biodiversity status, threatened and protection effectiveness, but also for the comprehensive assessment of terrestrial biodiversity to optimize and adjust priority protection areas and protection measures. Our results would provide a technical support for calculating green GDP and formulating regional ecological compensation policies.

Published

2021

41. Local factors mediate the response of biodiversity to land use on two African mountains

Author

Anne Fournier, Samantha L. L. Hill, Philip J. Platts, Stefan J. Siebert, Tim Newbold, Martin Jung, Neil D. Burgess, F. B. Munyekenye, Andy Purvis, Rob Marchant, Patrimoines locaux, Environnement et Globalisation (PALOC), Muséum national d'Histoire naturelle (MNHN)-Institut de Recherche pour le Développement (IRD)-Sorbonne Université (SU), and Natural Environment Research Council (NERC)

Subjects

0106 biological sciences, Biodiversity & Conservation, 05 Environmental Sciences, HABITAT LOSS, Biodiversity, 01 natural sciences, Abundance (ecology), biodiversity model, TERRESTRIAL BIODIVERSITY, ComputingMilieux_MISCELLANEOUS, 2. Zero hunger, GE, QH0075, Ecology, SPECIES RICHNESS, EASTERN ARC MOUNTAINS, Vegetation, EXTINCTION RISK, PREDICTS, COVER CHANGE, Biodiversity Conservation, QH0540, Life Sciences & Biomedicine, TROPICAL FOREST, CONSERVATION, Land management, Environmental Sciences & Ecology, Biology, KILIMANJARO, 010603 evolutionary biology, tropics, QH301, QL0671, Kilimanjaro, Nature and Landscape Conservation, Science & Technology, Land use, 010604 marine biology & hydrobiology, land use, 06 Biological Sciences, 15. Life on land, Habitat destruction, GLOBAL BIODIVERSITY, birds, Species richness, [SDE.BE]Environmental Sciences/Biodiversity and Ecology, QH0001, biodiversity responses, Global biodiversity

Abstract

Land-use change is the single biggest driver of biodiversity loss in the tropics. Biodiversity models can be useful tools to inform policymakers and conservationists of the likely response of species to anthropogenic pressures, including land-use change. However, such models generalize biodiversity responses across wide areas and many taxa, potentially missing important characteristics of particular sites or clades. Comparisons of biodiversity models with independently collected field data can help us understand the local factors that mediate broad-scale responses. We collected independent bird occurrence and abundance data along two elevational transects in Mount Kilimanjaro, Tanzania and the Taita Hills, Kenya. We estimated the local response to land use and compared our estimates with modelled local responses based on a large database of many different taxa across Africa. To identify the local factors mediating responses to land use, we compared environmental and species assemblage information between sites in the independent and African-wide datasets. Bird species richness and abundance responses to land use in the independent data followed similar trends as suggested by the African-wide biodiversity model, however the land-use classification was too coarse to capture fully the variability introduced by local agricultural management practices. A comparison of assemblage characteristics showed that the sites on Kilimanjaro and the Taita Hills had higher proportions of forest specialists in croplands compared to the Africa-wide average. Local human population density, forest cover and vegetation greenness also differed significantly between the independent and Africa-wide datasets. Biodiversity models including those variables performed better, particularly in croplands, but still could not accurately predict the magnitude of local species responses to most land uses, probably because local features of the land management are still missed. Overall, our study demonstrates that local factors mediate biodiversity responses to land use and cautions against applying biodiversity models to local contexts without prior knowledge of which factors are locally relevant.

Published

2017

42. Quantifying species contributions to ecosystem processes

Author

Rampal S. Etienne, Alex L. Pigot, Joe Tobias, Tom P. Bregman, Catherine Sheard, Benjamin Daly, and Etienne group

Subjects

0106 biological sciences, 0301 basic medicine, Life Sciences & Biomedicine - Other Topics, MUTUALISTIC NETWORKS, Biodiversity, DIVERSITY, COMPLEMENTARITY, 01 natural sciences, TERRESTRIAL BIODIVERSITY, SPECIALIZATION, Phylogeny, General Environmental Science, Phylogenetic tree, Ecology, Special Feature, General Medicine, 11 Medical And Health Sciences, Plants, functional diversity, seed dispersal, Trait, phylogenetic diversity, General Agricultural and Biological Sciences, Life Sciences & Biomedicine, Seed dispersal, CONSERVATION, PLANETARY BOUNDARY, Environmental Sciences & Ecology, Biology, 010603 evolutionary biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, ecosystem function, Animals, Ecosystem diversity, ecological network, Evolutionary Biology, Science & Technology, General Immunology and Microbiology, LAND-USE, BIRDS, 06 Biological Sciences, Ecological network, Phylogenetic diversity, 030104 developmental biology, DRIVES, Complementarity (molecular biology), 07 Agricultural And Veterinary Sciences, mutualistic interaction

Abstract

Quantifying the role of biodiversity in ecosystems not only requires understanding the links between species and the ecological functions and services they provide, but also how these factors relate to measurable indices, such as functional traits and phylogenetic diversity. However, these relationships remain poorly understood, especially for heterotrophic organisms within complex ecological networks. Here, we assemble data on avian traits across a global sample of mutualistic plant–frugivore networks to critically assess how the functional roles of frugivores are associated with their intrinsic traits, as well as their evolutionary and functional distinctiveness. We find strong evidence for niche complementarity, with phenotypically and phylogenetically distinct birds interacting with more unique sets of plants. However, interaction strengths—the number of plant species dependent on a frugivore—were unrelated to evolutionary or functional distinctiveness, largely because distinct frugivores tend to be locally rare, and thus have fewer connections across the network. Instead, interaction strengths were better predicted by intrinsic traits, including body size, gape width and dietary specialization. Our analysis provides general support for the use of traits in quantifying species ecological functions, but also highlights the need to go beyond simple metrics of functional or phylogenetic diversity to consider the multiple pathways through which traits may determine ecological processes.

Published

2016

43. The 2016 release of the PREDICTS database

Author

Hudson, Lawrence N., Newbold, Tim, Contu, Sara, Hill, Samantha L.L., Lysenko, Igor, De Palma, Adriana, Phillips, Helen R.P., Alhusseini, Tamera I., Bedford, Felicity E., Bennett, Dominic J., Bugter, R.J.F., Hudson, Lawrence N., Newbold, Tim, Contu, Sara, Hill, Samantha L.L., Lysenko, Igor, De Palma, Adriana, Phillips, Helen R.P., Alhusseini, Tamera I., Bedford, Felicity E., Bennett, Dominic J., and Bugter, R.J.F.

Published

2016

44. PREDICTS: site-level summary biodiversity and pressure data

Author

Hudson, Lawrence, Newbold, Tim, Contu, Sara, Hill, Samantha L L, Lysenko, Igor, De Palma, Adriana, Phillips, Helen, Senior, Rebecca A, Bennett, Dominic J, Booth, Hollie, Choimes, Argyrios, Correia, David L P, Day, Julie, Echeverría-Londoño, Susy, Garon, Morgan, Harrison, Michelle L K, Ingram, Daniel J, Jung, Martin, Kemp, Victoria, Kirkpatrick, Lucinda, Martin, Callum, Pan, Yuan, White, Hannah J, Aben, Job, Abrahamczyk, Stefan, Adum, Gilbert B, Aguilar-Barquero, Virginia, Aizen, Marcelo A, Ancrenaz, Marc, Arbeláez-Cortés, Enrique, Armbrecht, Inge, Azhar, Badrul, Azpiroz, Adrián B, Baeten, Lander, Báldi, András, Banks, John E, Barlow, Jos, Batáry, Péter, Bates, Adam J, Bayne, Erin M, Beja, Pedro, Berg, Åke, Berry, Nicholas J, Bicknell, Jake E, Bihn, Jochen H, Böhning-Gaese, Katrin, Boekhout, Teun, Boutin, Céline, Bouyer, Jérémy, Brearley, Francis Q, Brito, Isabel, Brunet, Jörg, Buczkowski, Grzegorz, Buscardo, Erika, Cabra-García, Jimmy, Calviño-Cancela, María, Cameron, Sydney A, Cancello, Eliana M, Carrijo, Tiago F, Carvalho, Anelena L, Castro, Helena, Castro-Luna, Alejandro A, B, Rolando Cerda, Cerezo, Alexis, Chauvat, Matthieu, Clarke, Francis M, Cleary, Daniel F R, Connop, Stuart P, D'Aniello, Biagio, da Silva, Pedro Giovâni, Darvill, Ben, Dauber, Jens, Dejean, Alain, Diekötter, Tim, Dominguez-Haydar, Yamileth, Dormann, Carsten F, Dumont, Bertrand, Dures, Simon G, Dynesius, Mats, Edenius, Lars, Elek, Zoltán, Entling, Martin H, Farwig, Nina, Fayle, Tom M, Felicioli, Antonio, Felton, Annika M, Ficetola, Gentile F, Filgueiras, Bruno K C, Fonte, Steven J, Fraser, Lauchlan H, Fukuda, Daisuke, Furlani, Dario, Ganzhorn, Jörg U, Garden, Jenni G, Gheler-Costa, Carla, Giordani, Paolo, Giordano, Simonetta, Gottschalk, Marco S, Goulson, Dave, Gove, Aaron D, Grogan, James, Hanley, Mick E, Hanson, Thor, Hashim, Nor R, Hawes, Joseph E, Hébert, Christian, Helden, Alvin J, Henden, John-André, Hernández, Lionel, Herzog, Felix, Higuera-Diaz, Diego, Hilje, Branko, Horgan, Finbarr G, Horváth, Roland, Hylander, Kristoffer, Isaacs-Cubides, Paola, Ishitani, Masahiro, Jacobs, Carmen T, Jaramillo, Víctor J, Jauker, Birgit, Jonsell, Mats, Jung, Thomas S., Kapoor, Vena, Kati, Vassiliki, Katovai, Eric, Kessler, Michael, Knop, Eva, Kolb, Annette, Kőrösi, Ádám, Lachat, Thibault, Lantschner, Victoria, Le Féon, Violette, LeBuhn, Gretchen, Légaré, Jean-Philippe, Letcher, Susan G, Littlewood, Nick, López-Quintero, Carlos A, Louhaichi, Mounir, Lövei, Gabor L, Lucas-Borja, Manuel Esteban, Luja, Victor H, Maeto, Kaoru, Magura, Tibor, Mallari, Neil Aldrin, Marin-Spiotta, Erika, Marshall, E J P, Martínez, Eliana, Mayfield, Margaret M, Mikusinski, Grzegorz, Milder, Jeffrey C, Miller, James R, Morales, Carolina L, Muchane, Mary N, Muchane, Muchai, Naidoo, Robin, Nakamura, Akihiro, Naoe, Shoji, Nates-Parra, Guiomar, Gutierrez, Dario A Navarrete, Neuschulz, Eike L, Holstein, Norbert, Norfolk, Olivia, Noriega, Jorge Ari, Nöske, Nicole M, O'Dea, Niall, Oduro, William, Ofori-Boateng, Caleb, Oke, Christopher Omamoke, Osgathorpe, Lynne M, Paritsis, Juan, Parra-H, Alejandro, Pelegrin, Nicolás, Peres, Carlos A, Persson, Anna S, Hayes, Peta Angela, Phalan, Ben, Philips, T Keith, Poveda, Katja, Power, Eileen F, Presley, Steven J, Proença, Vânia, Quaranta, Marino, Quintero, Carolina, Redpath-Downing, Nicola A, Reid, J Leighton, Reis, Yana T, Ribeiro, Danilo Bandini, Richardson, Barbara A, Richardson, Michael J, Robles, Carolina A, Römbke, Jörg, Romero-Duque, Luz Piedad, Rosselli, Loreta, Rossiter, Stephen J, Roulston, T'ai H, Rousseau, Laurent, Sadler, Jonathan, Sáfián, Szabolcs, Saldaña-Vázquez, Romeo A, Samnegård, Ulrika, Schüepp, Christof, Schweiger, Oliver, Sedlock, Jodi L, Shahabuddin, Ghazala, Sheil, Douglas, Silva, Fernando A B, Slade, Eleanor M, Smith-Pardo, Allan H, Sodhi, Navjot S, Somarriba, Eduardo J, Sosa, Ramón A, Stout, Jane C, Struebig, Matthew J, Sung, Yik-Hei, Threlfall, Caragh G, Tonietto, Rebecca K, Tóthmérész, Béla, Tscharntke, Teja, Turner, Edgar C, Tylianakis, Jason, Vanbergen, Adam, Vassilev, Kiril, Verboven, Hans A F, Vergara, Carlos H, Vergara, Pablo M, Verhulst, Jort, Walker, Tony R, Wang, Yanping, Watling, James I, Wells, Konstans, Williams, Christopher, Willig, Michael R, Woinarski, John C Z, Wolf, Jan H D, Woodcock, Ben A, Yu, Douglas W, Zaitsev, Andrey S, Collen, Ben, Ewers, Rob M, Mace, Georgina M, Purves, Drew W, Scharlemann, Jorn, and Purvis, Andy

Subjects

terrestrial biodiversity, land cover, land use, alpha diversity, global change, habitat destruction

Abstract

This dataset contains site-level summaries of more than 1.6 million samples from 78 countries representing over 28,000 species, collated from existing spatial comparisons of local-scale biodiversity exposed to different intensities and types of anthropogenic pressures, from terrestrial sites around the world. The underlying database is being assembled as part of the [PREDICTS project](https://www.nhm.ac.uk/our-science/our-work/biodiversity/predicts.html) - Projecting Responses of Ecological Diversity In Changing Terrestrial Systems. A complete description of the data is given in [https://doi.org/10.1002/ece3.1303](https://doi.org/10.1002/ece3.1303).

Published

2015

45. Nitrogen deposition and reduction of terrestrial biodiversity: Evidence from temperate grasslands

Author

Dise, Nancy B. and Stevens, J.

Published

2005

46. Characteristics of climate change refugia for Australian biodiversity

Author

Reside, April E, Welbergen, Justin A, Phillips, Ben L, Wardell-Johnson, Grant W, Keppel, Gunnar, Ferrier, S, Williams, Stephen E, and VanDerWal, Jeremy

Subjects

terrestrial biodiversity, synergies, climate change, refugia, conservation

Abstract

Identifying refugia is a critical component of effective conservation of biodiversity under anthropogenic climate change. However, despite a surge in conceptual and practical interest, identifying refugia remains a significant challenge across diverse continental landscapes. We provide an overview of the key properties of refugia that promote species' persistence under climate change, including their capacity to (i) buffer species from climate change; (ii) sustain long-term population viability and evolutionary processes; (iii) minimize the potential for deleterious species interactions, provided that the refugia are (iv) available and accessible to species under threat. Further, we classify refugia in terms of the environmental and biotic stressors that they provide protection from (i.e. thermal, hydric, cyclonic, pyric and biotic refugia), but ideally refugia should provide protection from a multitude of stressors. Our systematic characterization of refugia facilitates the identification of refugia in the Australian landscape. Challenges remain, however, specifically with respect to how to assess the quality of refugia at the level of individual species and whole species assemblages. It is essential that these challenges are overcome before refugia can live up to their acclaim as useful targets for conservation and management in the context of climate change. Refereed/Peer-reviewed

Published

2014

47. Characteristics of climate change refugia for Australian biodiversity

Author

Reside, A., Welbergen, J., Phillips, B., Wardell-Johnson, Grant, Keppel, Gunnar, Ferrier, S., Williams, S., Vanderwal, J., Reside, A., Welbergen, J., Phillips, B., Wardell-Johnson, Grant, Keppel, Gunnar, Ferrier, S., Williams, S., and Vanderwal, J.

Abstract

Identifying refugia is a critical component of effective conservation of biodiversity under anthropogenic climate change. However, despite a surge in conceptual and practical interest, identifying refugia remains a significant challenge across diverse continental landscapes. We provide an overview of the key properties of refugia that promote species' persistence under climate change, including their capacity to (i) buffer species from climate change; (ii) sustain long-term population viability and evolutionary processes; (iii) minimize the potential for deleterious species interactions, provided that the refugia are (iv) available and accessible to species under threat. Further, we classify refugia in terms of the environmental and biotic stressors that they provide protection from (i.e. thermal, hydric, cyclonic, pyric and biotic refugia), but ideally refugia should provide protection from a multitude of stressors. Our systematic characterization of refugia facilitates the identification of refugia in the Australian landscape. Challenges remain, however, specifically with respect to how to assess the quality of refugia at the level of individual species and whole species assemblages. It is essential that these challenges are overcome before refugia can live up to their acclaim as useful targets for conservation and management in the context of climate change.

Published

2014

48. Current logistical capacity is sufficient to deliver the implementation and management of a representative Antarctic protected area system.

Author

Hughes, Kevin A. and Grant, Susie M.

Subjects

REMOTE-sensing images, ECOSYSTEMS, ANTARCTIC Treaty system, ENVIRONMENTAL protection, REMOTE sensing

Abstract

Antarctica's terrestrial ecosystems are vulnerable to impacts resulting from climate change and local human activities. The Antarctic Treaty System (ATS) provides for the designation of protected areas through the Protocol on Environmental Protection to the Antarctic Treaty. Unsystematic use of agreed management tools, including Antarctic Specially Protected Areas (ASPAs), has resulted in a protected area system lacking representation across the full range of Antarctic terrestrial ecosystems and Antarctic Conservation Biogeographic Regions (ACBRs). Systematic Conservation Planning (SCP) methods provide established mechanisms to fulfil ATS protected area designation goals. However, how would a continent-wide ASPA system be delivered should appropriate sites be identified using SCP or other methods? Although the rate of area protection has slowed recently, we show that newer Consultative Parties to the Antarctic Treaty are increasingly active as ASPA proponents and may have scope for further engagement with protected area management activities. Furthermore, all 16 ACBRs were found to be within the operational footprint of at least two Parties, indicating that this current logistical footprint could support the implementation and management of a continent-wide ASPA system. Effective management of a representative Antarctic protected areas system could be delivered through greater participation by those Parties with currently more limited protected area management responsibilities and greater use of remote-sensing technologies for protected area monitoring, where appropriate. Crucially, political will to implement an ASPA system identified through SCP approaches may be greater once a pragmatic means of delivery and effective management has been identified. [ABSTRACT FROM AUTHOR]

Published

2018

49. Introduction

Author

Borges, Paulo A. V.

Subjects

Açores, Biodiversidade Terrestre, Azores, Terrestrial Biodiversity

Abstract

Neste capítulo apresentamos uma descrição sumária dos vários capítulos desta obra. A informação presente reflecte por um lado o objectivo de listar toda a biodiversidade terrestre dos Açores (Capítulo 4), mas igualmente apresentar uma síntese da diversidade específica nos diferentes grupos taxonómicos (Capítulo 2). Desenvolvem-se igualmente alguns aspectos importantes sobre a utilização de modelos para predizer a distribuição espacial das espécies (Capítulo 3). Todos os dados obtidos são carregados no Programa ATLANTIS Tierra 2.0, que se espera constitua uma ferramenta muito útil na gestão da conservação da natureza nas ilhas da Macaronésia. Este livro apresenta a primeira lista exaustiva dos organismos vivos dos habitats terrestres dos Açores, o que constitui uma fonte de informação muito importante para as diferentes áreas do conhecimento, tais como a taxonomia, ecologia, agricultura, silvicultura e gestão da conservação da natureza. ABSTRACT: In this chapter we present an overview of the several chapters of the book. The information presented in this work reflects the dual goal of listing most of the Azorean terrestrial biodiversity (Chapter 4) and also of presenting a synthesis of the patterns of the diversity in the different taxonomic groups (Chapter 2). The importance of using GIS environmental information to predict the spatial distribution and the habitat suitability of species (Chapter 3) is also developed. The software ATLANTIS Tierra 2.0 is described as a promising tool to be used in the conservation management of the Macaronesian islands. This book presents the first exhaustive compilation of the terrestrial organisms of the Azores which will help many people working in the areas of taxonomy, ecology, agriculture, forestry and nature conservation management.

Published

2005

50. Descrição da biodiversidade terrestre dos Açores

Author

Borges, Paulo A. V., Cunha, Regina Tristão da, Gabriel, Rosalina, Martins, António M. de Frias, Silva, Luís, Vieira, Virgílio, Dinis, Francisco, Lourenço, Paula C., and Pinto, Nuno

Subjects

Açores, Biodiversidade Terrestre, Azores, Terrestrial Biodiversity

Abstract

Os Açores constituem um arquipélago de nove ilhas oceânicas isoladas, onde os organismos terrestres chegaram através do vento, do mar, noutros animais e, nos tempos históricos, com a ajuda humana. Este capítulo analisa de forma detalhada aquilo que se conhece sobre a biodiversidade terrestre dos Açores. Para tal analisámos os quatro grandes grupos de organismos listados no capítulo 4: Bryophyta (musgos, antocerotas e hepáticas), Pteridophyta e Spermatophyta (fetos e fanerogâmicas), Mollusca (lesmas e caracóis) e Arthropoda (centopeias, diplópodes, crustáceos, aranhas, ácaros, insectos, etc.). O número total de espécies e/ou subespécies dos Açores pertencentes aos quatro grupos de organismos acima referidos é de cerca de 3705 (3666 espécies e 224 subespécies). No entanto, adicionando outros grupos como os vertebrados (Chordata, Vertebrata), anelídeos (Annelida), nemátodos (Nematoda) e líquenes, aquele número sobe para 4487 espécies e/ou subspecies (4443 espécies e 232 subespécies). O número total de espécies e/ou subespécies endémicas dos Açores pertencentes aos Bryophyta, Pteridophyta, Spermatophyta, Mollusca e Arthropoda totaliza as 393 (384 espécies e 44 subespécies). Os filos animais são os mais diversos em taxa endémicos (Mollusca = 49; Arthropoda = 267), com cerca de 80 % dos endemismos dos Açores. Deve ser ainda de assinalar a elevada percentagem de endemismo nos caracóis e lesmas (Mollusca) terrestres dos Açores, com cerca de 44% de endemismo. As plantas vasculares possuem 68 endemismos e os briófitos 9. Usando um estimador não paramétrico, a estimativa conservadora da riqueza de taxa endémicos terrestres de briófitos, plantas vasculares, moluscos e artrópodes rondará 530 taxa, pelo que apenas 77% dos endemismos dos Açores serão conhecidos. Em apenas alguns géneros se verificou uma taxa de especiação elevada, na sua maior parte pertencentes aos filos Mollusca e Arthropoda. A maior parte das espécies de artrópodes e moluscos endémicos são conhecidas apenas de uma ilha, enquanto que, nas plantas, uma grande fracção das espécies ocorre na maioria das ilhas. A análise das proporções das várias categorias de colonização mostra que uma grande proporção da phanerofauna de artrópodes e da flora de plantas vasculares do arquipélago é constituída por espécies introduzidas. Deste modo, as invasões por espécies exóticas constituem um problema actual e terão impactos futuros na biodiversidade dos Açores, criando um padrão de uniformização da fauna e flora. Os Açores constituem o arquipélago da Macaronésia geologicamente mais recente, estando situado mais a norte. As suas nove ilhas isoladas no meio do oceano Atlântico possuem uma grande diversidade de histórias geológicas e constituem laboratórios ecológicos e evolutivos extraordinários. Torna-se cada vez mais importante um esforço adicional nos estudos de taxonomia e ecologia de comunidades que envolvam o estudo de grupos taxonómicos mal conhecidos (fungos, líquenes, muitos grupos de artrópodes) mas também a revisão taxonómica de muitas espécies de briófitos e plantas vasculares. ABSTRACT: The Azores is a remote oceanic archipelago of nine islands where the terrestrial organisms arrived by wind, on the sea, on other animals and on historical times by human assistance. This chapter highlights what we know about Azorean terrestrial biodiversity. Four important terrestrial taxonomic groups listed in Chapter 4 are analysed in detail: Bryophyta (mosses, liverworts), Pteridophyta and Spermatophyta (ferns and phanerogamics), Mollusca (slugs and snails) and Arthropoda (millipedes, centipedes, mites, spiders, insects, etc.). Currently the total number of terrestrial species and/or subspecies of the above mentioned organisms in the Azores is estimated of about 3705 (3666 species and 224 subspecies). However, if we add other groups like vertebrates (Chordata, Vertebrata), annelids (Annelida), nematodes (Nematoda) and lichens, this number reaches 4487 species and/or subspecies (4443 species and 232 subspecies). The total number of endemic species and/or subspecies from the Azores belonging to Bryophyta, Pteridophyta, Spermatophyta, Mollusca and Arthropod is about 393 (384 species and 44 subspecies). The animals Phyla are the most diverse in endemic taxa (Mollusca = 49; Arthropoda = 267), comprising about 80% of the Azorean endemics. The percentage of endemismo within Mollusca (44%) is remarkable. Vascular plants have 68 endemic species while bryophytes have 9 endemics. Using a non-parametric estimator we obtained a conservative estimate for endemic Azorean terrestrial vascular plants, bryophytes, molluscs and arthropods around 530 taxa, which mean that only about 77% have already been described. In only some genera there was a substantial inter and intra-island speciation, most cases occurring in Mollusca and Arthropoda. Most of the endemic arthropods and molluscs are known in only one island, whereas in plants a large proportion of species occur in most islands. Na analysis of the proportions of the colonization categories in arthropods and vascular plants shows that a major proportion of the species are introduced. Therefore, invasions of alien organisms are an actual and future environmental threat in the Azores, creating a pattern of biotic homogenization that is of great contemporary concern. The Azores is the northernmost and the most recent Macaronesian archipelago. The nine islands, isolated in the middle of the Atlantic, with different geological histories, are wonderful ecological and evolutionary laboratories. An additional effort on taxonomic and community-level research implies the detailed examination of poorly studied groups (fungi, lichens, many arthropod groups), but a revision of the taxonomic status of many bryophyte and vascular plants is also deeply needed.

Published

2005