Atkinson Robert B, Weaver Abigail, Kincaid Joshua A, Wurster Frederic C, Doyle James M B
Department of Organismal and Environmental Biology, Christopher Newport University, Newport News, VA 23606 USA.
Middle East District, US Army Corps of Engineers, 201 Prince Frederick Drive, Winchester, VA 22602 USA.
Trees (Berl West). 2025;39(4):55. doi: 10.1007/s00468-025-02633-x. Epub 2025 Jun 6.
Tree rings of exhibit growth responses that are influenced by local hydrologic conditions through decadal timescales. That perspective can assist peatland natural resource managers in selection of hydrologic restoration targets that minimize chronic microbial oxidation and acute peat loss associated with fire.
Temperate forested peatlands are valued for myriad ecosystem services including carbon storage and biodiversity which may be lost through anthropogenic disturbance of hydrologic regimes. Hydrologic alterations may be recorded in tree stem growth patterns and provide insights for management and restoration. In (Atlantic White Cedar, Juniper) swamps, stand drainage causes a shift from net soil carbon sink to source as microbial oxidation and catastrophic fire oxidize stored organic matter. Here, we analyze historic radial growth patterns in in order to characterize drainage history to guide hydrologic management for peat conservation and restoration. Basal area increment (BAI) estimates across a ~ 60-year chronology (1939-2003) were analyzed by flexible beta cluster analysis of 185 trees from 13 stands in the Great Dismal Swamp National Wildlife Refuge in Virginia and North Carolina, USA. Stands formed 3 groups, and growth rates among all groups were indicative of a drained hydrologic regime throughout the chronology compared to an undrained control stand. Regime shift analyses identified positive shifts for 2 stand groups in 1954 and for all 3 stand groups in 1963. Multiple response permutation procedures and partial mantel tests both identified two predictive growth variables including (1) visual observations of fluctuation in the water table and (2) proximity to a primary ditch. Growth rate was suppressed when weirs were installed in the mid-1980s; however, growth rebounded within ~ 2 years. The chronology ends when stands were struck by a major hurricane in 2003 and fires in 2008 and 2011 liberated 1.38 Tg of peat carbon. We conclude that dendroecology can detect hydrologic changes through time and can reduce risks of microbial oxidation and catastrophic fire in forested peatlands.
树木年轮显示出的生长响应受到当地水文条件的影响,这种影响跨越数十年的时间尺度。这一观点有助于泥炭地自然资源管理者选择水文恢复目标,以尽量减少与火灾相关的长期微生物氧化和急性泥炭损失。
温带森林泥炭地因其众多生态系统服务而受到重视,包括碳储存和生物多样性,但这些服务可能会因人为改变水文状况而丧失。水文变化可能记录在树木茎干生长模式中,并为管理和恢复提供见解。在大西洋白柏(大西洋雪松、杜松)沼泽地,林分排水导致土壤从净碳汇转变为碳源,因为微生物氧化和灾难性火灾会氧化储存的有机物质。在这里,我们分析大西洋白柏的历史径向生长模式,以确定排水历史,为泥炭保护和恢复的水文管理提供指导。通过对美国弗吉尼亚州和北卡罗来纳州大迪斯默尔沼泽国家野生动物保护区13个林分中185棵树进行灵活的β聚类分析,分析了约60年时间序列(1939 - 2003年)中的基部面积增量(BAI)估计值。林分形成了3组,与未排水的对照林分相比,所有组的生长速率都表明在整个时间序列中处于排水的水文状况。 regime shift分析确定了1954年2个林分组和1963年所有3个林分组的正向转变。多重响应排列程序和部分曼特尔检验都确定了两个预测生长变量,包括(1)地下水位波动的目视观测和(2)与主要沟渠的距离。20世纪80年代中期安装堰时,生长速率受到抑制;然而,生长在约2年内反弹。当林分在2003年遭受重大飓风袭击,2008年和2011年发生火灾释放了1.38太克泥炭碳时,时间序列结束。我们得出结论,树木年轮生态学可以检测随时间的水文变化,并可以降低森林泥炭地中微生物氧化和灾难性火灾的风险。
