Asynchrony and Time-Lag between Primary and Secondary Growth of Norway Spruce Growing in Different Elevations

0543381 - ÚVGZ 2022 RIV CH eng J - Journal Article
Nezval, Ondřej - Krejza, Jan - Bellan, M. - Světlík, Jan
Asynchrony and Time-Lag between Primary and Secondary Growth of Norway Spruce Growing in Different Elevations.
Forests. Roč. 12, č. 5 (2021), č. článku 627. E-ISSN 1999-4907
Research Infrastructure: CzeCOS III - 90123
Institutional support: RVO:86652079
Keywords : intraannual radial growth * climate-change * wood formation * picea-abies * phenology * dynamics * drought * xylem * trees * vulnerability * Picea abies [L * ] Karts * elongation * growth rate * growing season * dendrometer * shoots * phenocamera
OECD category: Forestry
Impact factor: 3.282, year: 2021
Method of publishing: Open access
https://www.mdpi.com/1999-4907/12/5/627

Norway spruce is one of the most economically important coniferous species in Europe, but it has faced high mortality rates in the last few decades due to the increasing frequency of extreme weather events. Primary and secondary growth development may be affected by these non-optimal conditions. In this study, we aimed to analyze the timing, possible asynchrony and time-lag between the growth processes of Norway spruce. We used a novel methodological approach of primary (based on phenocamera picture evaluation) and secondary (dendrometers) growth detection. The combination of these novel approaches allowed us to compare these growth process in high temporal resolution. Measurements were performed in two experimental plots with contrasting climatic conditions (middle and higher elevations) in the years 2016-2019, during the presence of extreme climatic conditions. We demonstrated a significant elongation of the growing season, with a more pronounced effect at higher elevation. Compared to the long-term mean, we observed an additional 50 days with a temperature above 15 degrees C at the higher elevation plot. There were no found patterns in the time-shift of both growth processes between plots. On the other hand we observed asynchrony of radial growth and meristems growth. Radial growth began earlier than the phenology of apical meristems growth. The onset, end and duration of meristem growth differed between studied plots and years as well. The onset of radial growth did not follow the gradient of microclimatic parameters, however, the differences in climatic conditions between plots did cause a shift in the onset of meristem growth. The process of the radial growth was twice as long as for apical meristem development. On average, radial growth requires 71 days more than meristem phenology to reach full process completion. Our data confirmed that these growth processes are strongly affected by external weather conditions and the duration of the growing season. More advanced and detailed monitoring of these processes can provide more accurate data of the health status of trees in the forest.
Permanent Link: http://hdl.handle.net/11104/0320595