Your search keyword '"Halbritter, Aud H' showing total 7 results

1. Plant trait and vegetation data along a 1314 m elevation gradient with fire history in Puna grasslands, Perú.

Author

Halbritter, Aud H., Vandvik, Vigdis, Cotner, Sehoya H., Farfan-Rios, William, Maitner, Brian S., Michaletz, Sean T., Oliveras Menor, Imma, Telford, Richard J., Ccahuana, Adam, Cruz, Rudi, Sallo-Bravo, Jhonatan, Santos-Andrade, Paul Efren, Vilca-Bustamante, Lucely L., Castorena, Matiss, Chacón-Labella, Julia, Christiansen, Casper Tai, Duran, Sandra M., Egelkraut, Dagmar D., Gya, Ragnhild, and Haugum, Siri Vatsø

Subjects

LIFE history theory, GLOBAL warming, GRASSLANDS, LEAF area, ALTITUDES

Abstract

Alpine grassland vegetation supports globally important biodiversity and ecosystems that are increasingly threatened by climate warming and other environmental changes. Trait-based approaches can support understanding of vegetation responses to global change drivers and consequences for ecosystem functioning. In six sites along a 1314 m elevational gradient in Puna grasslands in the Peruvian Andes, we collected datasets on vascular plant composition, plant functional traits, biomass, ecosystem fluxes, and climate data over three years. The data were collected in the wet and dry season and from plots with different fire histories. We selected traits associated with plant resource use, growth, and life history strategies (leaf area, leaf dry/wet mass, leaf thickness, specific leaf area, leaf dry matter content, leaf C, N, P content, C and N isotopes). The trait dataset contains 3,665 plant records from 145 taxa, 54,036 trait measurements (increasing the trait data coverage of the regional flora by 420%) covering 14 traits and 121 plant taxa (ca. 40% of which have no previous publicly available trait data) across 33 families. [ABSTRACT FROM AUTHOR]

Published

2024

2. Plant traits and associated data from a warming experiment, a seabird colony, and along elevation in Svalbard.

Author

Vandvik, Vigdis, Halbritter, Aud H., Althuizen, Inge H. J., Christiansen, Casper T., Henn, Jonathan J., Jónsdóttir, Ingibjörg Svala, Klanderud, Kari, Macias-Fauria, Marc, Malhi, Yadvinder, Maitner, Brian Salvin, Michaletz, Sean, Roos, Ruben E., Telford, Richard J., Bass, Polly, Björnsdóttir, Katrín, Bustamante, Lucely Lucero Vilca, Chmurzynski, Adam, Chen, Shuli, Haugum, Siri Vatsø, and Kemppinen, Julia

Subjects

COLONIAL birds, GLOBAL environmental change, TUNDRAS, VEGETATION dynamics, REMOTE sensing, VASCULAR plants

Abstract

The Arctic is warming at a rate four times the global average, while also being exposed to other global environmental changes, resulting in widespread vegetation and ecosystem change. Integrating functional trait-based approaches with multi-level vegetation, ecosystem, and landscape data enables a holistic understanding of the drivers and consequences of these changes. In two High Arctic study systems near Longyearbyen, Svalbard, a 20-year ITEX warming experiment and elevational gradients with and without nutrient input from nesting seabirds, we collected data on vegetation composition and structure, plant functional traits, ecosystem fluxes, multispectral remote sensing, and microclimate. The dataset contains 1,962 plant records and 16,160 trait measurements from 34 vascular plant taxa, for 9 of which these are the first published trait data. By integrating these comprehensive data, we bridge knowledge gaps and expand trait data coverage, including on intraspecific trait variation. These data can offer insights into ecosystem functioning and provide baselines to assess climate and environmental change impacts. Such knowledge is crucial for effective conservation and management in these vulnerable regions. [ABSTRACT FROM AUTHOR]

Published

2023

3. The role of plant functional groups mediating climate impacts on carbon and biodiversity of alpine grasslands.

Author

Vandvik, Vigdis, Althuizen, Inge H. J., Jaroszynska, Francesca, Krüger, Linn C., Lee, Hanna, Goldberg, Deborah E., Klanderud, Kari, Olsen, Siri L., Telford, Richard J., Östman, Silje A. H., Busca, Sara, Dahle, Ingrid J., Egelkraut, Dagmar D., Geange, Sonya R., Gya, Ragnhild, Lynn, Josh S., Meineri, Eric, Young, Sherry, and Halbritter, Aud H.

Subjects

TUNDRAS, FUNCTIONAL groups, ECOSYSTEMS, NORMALIZED difference vegetation index, PLANT diversity, SOIL temperature, ALPINE regions, GRASSLANDS

Abstract

Plant removal experiments allow assessment of the role of biotic interactions among species or functional groups in community assembly and ecosystem functioning. When replicated along climate gradients, they can assess changes in interactions among species or functional groups with climate. Across twelve sites in the Vestland Climate Grid (VCG) spanning 4 °C in growing season temperature and 2000 mm in mean annual precipitation across boreal and alpine regions of Western Norway, we conducted a fully factorial plant functional group removal experiment (graminoids, forbs, bryophytes). Over six years, we recorded biomass removed, soil microclimate, plant community composition and structure, seedling recruitment, ecosystem carbon fluxes, and reflectance in 384 experimental and control plots. The dataset consists of 5,412 biomass records, 360 species-level biomass records, 1,084,970 soil temperature records, 4,771 soil moisture records, 17,181 plant records covering 206 taxa, 16,656 seedling records, 3,696 ecosystem carbon flux measurements, and 1,244 reflectance measurements. The data can be combined with longer-term climate data and plant population, community, ecosystem, and functional trait data collected within the VCG. Measurement(s) vegetation layer • ecosystem-wide respiration • ecosystem-wide photosynthesis • seedling development stage • temperature of soil • plant functional group biomass • volumetric soil moisture • reflectance spectrum Technology Type(s) Visual species identification and cover estimation • Licor gas analyzer • Visual species identification and estimation • ibutton temperature logger • Analytical Balance • SM300 soil mositure probe, Delta-T • GreenSeeker/Normalized Difference Vegetation Index measurements Factor Type(s) temperature • precipitation • Plant functional type composition Sample Characteristic - Organism Embryophyta Sample Characteristic - Environment alpine tundra biome Sample Characteristic - Location Vestlandet Region [ABSTRACT FROM AUTHOR]

Published

2022

4. Consistent trait–environment relationships within and across tundra plant communities.

Author

Kemppinen, Julia, Niittynen, Pekka, le Roux, Peter C., Momberg, Mia, Happonen, Konsta, Aalto, Juha, Rautakoski, Helena, Enquist, Brian J., Vandvik, Vigdis, Halbritter, Aud H., Maitner, Brian, and Luoto, Miska

Published

2021

5. Plant traits and vegetation data from climate warming experiments along an 1100 m elevation gradient in Gongga Mountains, China.

Author

Vandvik, Vigdis, Halbritter, Aud H., Yang, Yan, He, Hai, Zhang, Li, Brummer, Alexander B., Klanderud, Kari, Maitner, Brian S., Michaletz, Sean T., Sun, Xiangyang, Telford, Richard J., Wang, Genxu, Althuizen, Inge H. J., Henn, Jonathan J., Garcia, William Fernando Erazo, Gya, Ragnhild, Jaroszynska, Francesca, Joyce, Blake L., Lehman, Rebecca, and Moerland, Michelangelo Sergio

Subjects

BIODIVERSITY, CLIMATE change, GROWING season, VASCULAR plants, HERBACEOUS plant growing

Abstract

Functional trait data enhance climate change research by linking climate change, biodiversity response, and ecosystem functioning, and by enabling comparison between systems sharing few taxa. Across four sites along a 3000–4130 m a.s.l. gradient spanning 5.3 °C in growing season temperature in Mt. Gongga, Sichuan, China, we collected plant functional trait and vegetation data from control plots, open top chambers (OTCs), and reciprocally transplanted vegetation turfs. Over five years, we recorded vascular plant composition in 140 experimental treatment and control plots. We collected trait data associated with plant resource use, growth, and life history strategies (leaf area, leaf thickness, specific leaf area, leaf dry matter content, leaf C, N and P content and C and N isotopes) from local populations and from experimental treatments. The database consists of 6,671 plant records and 36,743 trait measurements (increasing the trait data coverage of the regional flora by 500%) covering 11 traits and 193 plant taxa (ca. 50% of which have no previous published trait data) across 37 families. Measurement(s) leaf growth and development trait • Abundance • leaf area trait • leaf composition trait • leaf morphology trait • Vascular Plant • total biomass yield • climate Technology Type(s) balance • visual observation method • Scanner Device • leaf stoichiometry and isotope assays • weather station Factor Type(s) plants • temperature • plant functional traits (specific leaf area, leaf dry matter content, leaf carbon content, leaf nitrogen content, leaf size, leaf thickness) • type of treatment (e.g in situ warming experiments using an Open Top Chamber) Sample Characteristic - Organism Tracheophyta Sample Characteristic - Environment area of sedge- and forb-dominated herbaceous vegetation Sample Characteristic - Location Ganzi Tibetan Autonomous Prefecture Machine-accessible metadata file describing the reported data: 10.6084/m9.figshare.12033786 [ABSTRACT FROM AUTHOR]

Published

2020

6. Publisher Correction: Open Science principles for accelerating trait-based science across the Tree of Life.

Author

Gallagher RV, Falster DS, Maitner BS, Salguero-Gómez R, Vandvik V, Pearse WD, Schneider FD, Kattge J, Poelen JH, Madin JS, Ankenbrand MJ, Penone C, Feng X, Adams VM, Alroy J, Andrew SC, Balk MA, Bland LM, Boyle BL, Bravo-Avila CH, Brennan I, Carthey AJR, Catullo R, Cavazos BR, Conde DA, Chown SL, Fadrique B, Gibb H, Halbritter AH, Hammock J, Hogan JA, Holewa H, Hope M, Iversen CM, Jochum M, Kearney M, Keller A, Mabee P, Manning P, McCormack L, Michaletz ST, Park DS, Perez TM, Pineda-Munoz S, Ray CA, Rossetto M, Sauquet H, Sparrow B, Spasojevic MJ, Telford RJ, Tobias JA, Violle C, Walls R, Weiss KCB, Westoby M, Wright IJ, and Enquist BJ

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2020

7. Open Science principles for accelerating trait-based science across the Tree of Life.

Author

Gallagher RV, Falster DS, Maitner BS, Salguero-Gómez R, Vandvik V, Pearse WD, Schneider FD, Kattge J, Poelen JH, Madin JS, Ankenbrand MJ, Penone C, Feng X, Adams VM, Alroy J, Andrew SC, Balk MA, Bland LM, Boyle BL, Bravo-Avila CH, Brennan I, Carthey AJR, Catullo R, Cavazos BR, Conde DA, Chown SL, Fadrique B, Gibb H, Halbritter AH, Hammock J, Hogan JA, Holewa H, Hope M, Iversen CM, Jochum M, Kearney M, Keller A, Mabee P, Manning P, McCormack L, Michaletz ST, Park DS, Perez TM, Pineda-Munoz S, Ray CA, Rossetto M, Sauquet H, Sparrow B, Spasojevic MJ, Telford RJ, Tobias JA, Violle C, Walls R, Weiss KCB, Westoby M, Wright IJ, and Enquist BJ

Subjects

Biological Evolution, Phenotype, Research, Biodiversity, Ecology

Abstract

Synthesizing trait observations and knowledge across the Tree of Life remains a grand challenge for biodiversity science. Species traits are widely used in ecological and evolutionary science, and new data and methods have proliferated rapidly. Yet accessing and integrating disparate data sources remains a considerable challenge, slowing progress toward a global synthesis to integrate trait data across organisms. Trait science needs a vision for achieving global integration across all organisms. Here, we outline how the adoption of key Open Science principles-open data, open source and open methods-is transforming trait science, increasing transparency, democratizing access and accelerating global synthesis. To enhance widespread adoption of these principles, we introduce the Open Traits Network (OTN), a global, decentralized community welcoming all researchers and institutions pursuing the collaborative goal of standardizing and integrating trait data across organisms. We demonstrate how adherence to Open Science principles is key to the OTN community and outline five activities that can accelerate the synthesis of trait data across the Tree of Life, thereby facilitating rapid advances to address scientific inquiries and environmental issues. Lessons learned along the path to a global synthesis of trait data will provide a framework for addressing similarly complex data science and informatics challenges.

Published

2020