Das Gupta Sanatan, Mackenzie M Derek
Natural Resources Canada, Canadian Forest Service, Northern Forestry Centre, Edmonton, AB, Canada.
Department of Renewable Resources, University of Alberta, Edmonton AB, Canada.
PLoS One. 2016 Nov 10;11(11):e0165602. doi: 10.1371/journal.pone.0165602. eCollection 2016.
Fire in boreal ecosystems is known to affect CO2 efflux from forest soils, which is commonly termed soil respiration (Rs). However, there is limited information on how fire and recovery from this disturbance affects spatial variation in Rs. The main objective of this study was to quantify the spatial variability of Rs over the growing season in a boreal aspen (Populus tremuloides Michx.) fire chronosequence. The chronosequence included three stands in northern Alberta; a post fire stand (1 year old, PF), a stand at canopy closure (9 years old, CC), and a mature stand (72 years old, MA). Soil respiration, temperature and moisture were measured monthly from May to August using an intensive spatial sampling protocol (n = 42, minimum lag = 2 m). Key aboveground and belowground properties were measured one time at each sampling point. No spatial structure was detected in Rs of the PF stand during the peak growing season (June and July), whereas Rs was auto-correlated at a scale of < 6 m in the CC and MA stands. The PF stand had the lowest mean Rs (4.60 μmol C m-2 s-1) followed by the CC (5.41 μmol C m-2 s-1), and the MA (7.32 μmol C m-2 s-1) stand. Forest floor depth was the only aboveground factor that influenced the spatial pattern of Rs in all three stands and was strongest in the PF stand. Enzyme activity and fine root biomass, on the other hand, were the significant belowground factors driving the spatial pattern of Rs in the CC and MA stands. Persistent joint aboveground and belowground control on Rs in the CC and MA stands indicates a tight spatial coupling, which was not observed in the PF stand. Overall, the current study suggests that fire in the boreal aspen ecosystem alters the spatial structure of Rs and that fine scale heterogeneity develops quickly as stands reach the canopy closure phase (<10 years).
已知北方生态系统中的火灾会影响森林土壤的二氧化碳排放通量,这通常被称为土壤呼吸(Rs)。然而,关于火灾以及从这种干扰中恢复如何影响土壤呼吸的空间变异的信息有限。本研究的主要目的是量化北方白杨(Populus tremuloides Michx.)火灾时间序列中整个生长季节土壤呼吸的空间变异性。该时间序列包括阿尔伯塔省北部的三个林分;一个火灾后林分(1年生,PF)、一个郁闭林分(9年生,CC)和一个成熟林分(72年生,MA)。从5月到8月,采用密集空间采样方案(n = 42,最小间距 = 2米)每月测量土壤呼吸、温度和湿度。在每个采样点一次性测量关键的地上和地下属性。在生长旺季(6月和7月),PF林分的土壤呼吸未检测到空间结构,而CC和MA林分的土壤呼吸在<6米的尺度上具有自相关性。PF林分的平均土壤呼吸最低(4.60 μmol C m-2 s-1),其次是CC林分(5.41 μmol C m-2 s-1)和MA林分(7.32 μmol C m-2 s-1)。林下层深度是影响所有三个林分土壤呼吸空间格局的唯一地上因素,在PF林分中最为显著。另一方面,酶活性和细根生物量是驱动CC和MA林分土壤呼吸空间格局的重要地下因素。CC和MA林分中地上和地下对土壤呼吸的持续联合控制表明存在紧密的空间耦合,而在PF林分中未观察到这种情况。总体而言,当前研究表明北方白杨生态系统中的火灾会改变土壤呼吸的空间结构,并且随着林分达到郁闭阶段(<10年),小尺度异质性会迅速发展。
