Originally set up as a joint project between the former Macaulay Institute and CEH Banchory as part of the MOORCO [1] project this experiment aims to identify mechanisms and rates of change as well as the role of herbivores in driving changes during succession from moorland to woodland. In addition this experiment includes Pinus sylvestris as well as Betula pubescens trees. The experiment was established in 2005 and our data collection so far has focused on changes in CO2, DOC and soil carbon dynamics during the early stages of tree colonisation.
The experiment is called the BIG experiment because it is established at 3 sites: Ballogie, Invercauld and Glensaugh.
The results from this experiment will help detect how trees affect soil organic matter dynamics. The influences of physical parameters on these dynamics have to be understood and mechanistically quantified first. This requires the parameterisation of temperature and moisture models describing gaseous and dissolved exports. As climate change will alter these parameters, scenario calculations would greatly benefit from these parameterisations stemming from a specific Scottish moorland soil context.
Results will help understand the impact of changing land cover. The appearance of native trees on Scotland's heather-moorland is an unbroken trend, both in planted schemes as well as through natural regeneration following reduced grazing pressure. In the future, climate change will increasingly determine which areas are suitable for regeneration of native tree species. Our work will give important insights into how soil organic matter dynamics of these areas will be influenced.
Results will inform on the preservation of soil carbon stocks (through losses from land-use): Scotland’s soils contain a carbon stock of national and international importance, predominantly in the form of upland and blanket peat. Preservation of that carbon stock is mandatory to reduce contributions through land-use induced losses to national emissions and feeding back to atmospheric CO2 levels.
The initial five years of tree planting with birch and pine at the Invercauld field site has shown little impact on CO2 and DOC but that the variation in response of CO2 and DOC is related to time of season and soil type.
See Publications [2] for further details of results.
Site Name | Grid reference |
---|---|
Glensaugh | NO675801 |
Invercauld | NO170950 |
Ballogie | NO550930 |
Within each block were the following treatments:
Within each fence or unfence plot were the treatments below:
Data type | Date | Details |
---|---|---|
Vegetation | 2005- baseline | Species composition (% cover) |
Soil chemistry1 | 2005 - baseline | Al, C, C:N, Ca, Ca, Fe, K, LOI, Mg, Mn, moisture, N, Na, N-mineralization, P, pH. Data for organic and mineral horizons |
Soil seedbank | 2005 - baseline | |
Soil physical properties | 2005 - baseline | LFH depth, O depth, bulk density |
Soil respiration | 2008-2011 | Continuous at Invercauld from 2008-2001, but not all plots measured. Once a quarter at the other sites in 2010& 2011 |
Soil water chemistry (DOC) plus other chemical content | 2006-2010 | Only collected at Invercauld, once every 6 weeks |
Root growth | 2007-2009 | Only collected at Invercauld, root growth, new roots and roots lost |
Root chemical content | 2005 | Only collected at Invercauld |
Soil temperature | 2007- onwards | Only collected at Invercauld, continuous monitoring |
Soil moisture | 2007- onwards | Only collected at Invercauld continuous monitoring |
Weather data | 2007- onwards | Only collected at Invercauld. Rainfall, temperature, sunshine hours on daily basis |
During 2005 we established long-term monitoring of gaseous carbon exports from the soils by means of continuous-flow soil respiration chambers attached to infrared gas analysers in ungrazed tree and control plots at Invercauld. We also established zero-tension lysimeters to collect dissolved carbon and nitrogen exports from all plots and mini-rhizotron tubes were installed on all main plot treatments, adjacent to the respiration chambers, to monitor root production and root disappearance. Soil cores are also taken from the plots to determine standing root biomass and C and N inputs.
We continuously monitor gaseous and dissolved losses of carbon from these experimental plots. We also quantify soil carbon inputs by measuring both aboveground and belowground plant litter production. Detailed measures of the soil environment, such as temperature and moisture, as well as climatic parameters obtained from a dedicated weather station will create the necessary framework to interpret our findings. Soil climate data are continuously taken and recorded in order to differentiate between environment and treatment drivers of exports. An automatic weather station was established in 2008 and provides a live feed [3] available for the general public.
MOORCO [1] is a collaborative project across several groups and themes within the James Hutton Institute and with many different staff involved. In the first instance please contact Dr Ruth Mitchell [4] for further details.
Links:
[1] http://www.hutton.ac.uk/research/groups/ecological-sciences/community-ecology/moorco
[2] http://www.hutton.ac.uk/research/groups/ecological-sciences/community-ecology/moorco/publications
[3] http://www.macaulay.ac.uk/ECN/invercauld_livedata/index.php
[4] mailto:ruth.mitchell@hutton.ac.uk?subject=Enquiry%20about%20MOORCO
[5] http://abwww03.hutton.ac.uk/staff/ruth-mitchell