Plant traits and associated ecological data from global change experiments and climate gradients in Norway.
Vandvik V., Halbritter AH., Macias-Fauria M., Maitner BS., Michaletz ST., Telford RJ., Bison N., Chacon-Labella J., Cotner S., Egelkraut D., Garen J., Gaudard J., Geange SR., Rosati MA., Andersen EAS., Ahler SJ., Atkinson J., Baumane M., Bradler PM., Dawson HR., Eckberg J., Elsy AD., Erkelenz J., Eshelman SE., Guclu C., Gullvåg R., Gya R., Hartford S., Hayden MT., Holle MJM., Kullberg AT., Lepley K., Correia M., Löwenstein CE., Maré C., Mauki D., Navarro J., Oberholzer B., Olivier B., Olson AN., Ray CA., von Oppen J., Vorstenbosch T., Wang JA., Enquist BJ.
Plant functional trait-based approaches are powerful tools to assess the consequences of global environmental changes for plant ecophysiology, population and community ecology, ecosystem functioning, and landscape ecology. Here, we present data capturing these ecological dimensions from grazing, nitrogen addition, and warming experiments conducted along a 821 m a.s.l. elevation gradient and from a climate warming experiment conducted across a 3,200 mm precipitation gradient in boreal and alpine grasslands in Vestland County, western Norway. From these systems we collected 28,762 plant and leaf functional trait measurements from 76 vascular plant species, 88 leaf assimilation-temperature responses, 577 leaf handheld hyperspectral readings, 2.26 billion leaf temperature measurements, 3,696 ecosystem CO2 flux measurements, and 10.69 ha of multispectral (10-band) and RGB cm-resolution imagery from 4,648 individual images obtained from airborne sensors. These data augment existing longer-term data on local climate, soils, plant populations, plant community composition, and ecosystem functioning from within the same experiments and study systems and from similar systems in other mountain regions globally.