@article {bnh-5094, title = {Can a growth model be used to describe forest carbon and water balance after fuel reduction burning in temperate forests?}, journal = {Science of the Total Environment}, volume = {615}, year = {2018}, month = {02/2018}, pages = {1000-1009}, chapter = {1000}, abstract = {

Empirical evidence from Australia shows that fuel reduction\ burningsignificantly reduces the incidence and extent of unplanned fires. However, the integration of environmental values into\ fire management\ operations is not yet well-defined and requires further research and development.

WAVES, a plant growth model that incorporates Soil-Vegetation-Atmosphere Transfer, was used to simulate the hydrological and\ ecological effects\ of three fuel management scenarios on a\ forest ecosystem. WAVES was applied using inputs from a set of forest plots for one year after three potential scenarios: (1) all litter removed, (2) all litter and 50\% of the\ understorey\ removed, (3) all litter and understorey removed. Modelled outputs were compared with sites modelled with no-fuel reduction treatment (Unburnt).

The key change between unburnt and fuel reduced forests was a significant increase in soil moisture after fire. Predictions of the recovery of aboveground carbon as plant biomass were driven by model structure and thus variability in available light and soil moisture at a local scale. Similarly, effects of fuel reduction burning on\ water processes\ were mainly due to changes in vegetation interception capacity (i.e. regrowth) and soil evaporation. Predicted effects of fuel reduction burning on total\ evapotranspiration\ (ET) {\textendash} the major component of\ water balance\ {\textendash} were marginal and not significant, even though a considerable proportion of ET had effectively been transferred from understorey to overstorey. In common with many plant growth models, outputs from WAVES are dictated by the assumption that overstorey trees continue to grow irrespective of their age or stage of maturity. Large areas of eucalypt forests and woodlands in SE Australia are well beyond their aggrading phase and are instead over-mature. The ability of these forests to rapidly respond to greater availability of water remains uncertain.

}, doi = {https://doi.org/10.1016/j.scitotenv.2017.09.315}, url = {https://www.sciencedirect.com/science/article/pii/S0048969717326669?via\%3Dihub}, author = {Gharun, Mana and Malcolm Possell and R. Willem Vervoort and Adams, Mark A. and Bell, Tina} }