10.3389/fpls.2019.00191.s001 Mari Mäki Mari Mäki Juho Aalto Juho Aalto Heidi Hellén Heidi Hellén Mari Pihlatie Mari Pihlatie Jaana Bäck Jaana Bäck Data_Sheet_1_Interannual and Seasonal Dynamics of Volatile Organic Compound Fluxes From the Boreal Forest Floor.CSV Frontiers 2019 biogenic volatile organic compound flux forest floor temperature seasonality vegetation decomposition 2019-02-22 04:14:19 Dataset https://frontiersin.figshare.com/articles/dataset/Data_Sheet_1_Interannual_and_Seasonal_Dynamics_of_Volatile_Organic_Compound_Fluxes_From_the_Boreal_Forest_Floor_CSV/7755344 <p>In the northern hemisphere, boreal forests are a major source of biogenic volatile organic compounds (BVOCs), which drive atmospheric processes and lead to cloud formation and changes in the Earth’s radiation budget. Although forest vegetation is known to be a significant source of BVOCs, the role of soil and the forest floor, and especially interannual variations in fluxes, remains largely unknown due to a lack of long-term measurements. Our aim was to determine the interannual, seasonal and diurnal dynamics of boreal forest floor volatile organic compound (VOC) fluxes and to estimate how much they contribute to ecosystem VOC fluxes. We present here an 8-year data set of forest floor VOC fluxes, measured with three automated chambers connected to the quadrupole proton transfer reaction mass spectrometer (quadrupole PTR-MS). The exceptionally long data set shows that forest floor fluxes were dominated by monoterpenes and methanol, with relatively comparable emission rates between the years. Weekly mean monoterpene fluxes from the forest floor were highest in spring and in autumn (maximum 59 and 86 μg m<sup>-2</sup> h<sup>-1</sup>, respectively), whereas the oxygenated VOC fluxes such as methanol had highest weekly mean fluxes in spring and summer (maximum 24 and 79 μg m<sup>-2</sup> h<sup>-1</sup>, respectively). Although the chamber locations differed from each other in emission rates, the inter-annual dynamics were very similar and systematic. Accounting for this chamber location dependent variability, temperature and relative humidity, a mixed effects linear model was able to explain 79–88% of monoterpene, methanol, acetone, and acetaldehyde fluxes from the boreal forest floor. The boreal forest floor was a significant contributor in the forest stand fluxes, but its importance varies between seasons, being most important in autumn. The forest floor emitted 2–93% of monoterpene fluxes in spring and autumn and 1–72% of methanol fluxes in spring and early summer. The forest floor covered only a few percent of the forest stand fluxes in summer.</p>