Influence of climate change and postdelisting management on long‐term population viability of the conservation‐reliant Kirtland's Warbler

Rapid global climate change is resulting in novel abiotic and biotic conditions and interactions. Identifying management strategies that maximize probability of long‐term persistence requires an understanding of the vulnerability of species to environmental changes. We sought to quantify the vulnerability of Kirtland's Warbler (Setophaga kirtlandii), a rare Neotropical migratory songbird that breeds almost exclusively in the Lower Peninsula of Michigan and winters in the Bahamian Archipelago, to projected environmental changes on the breeding and wintering grounds. We developed a population‐level simulation model that incorporates the influence of annual environmental conditions on the breeding and wintering grounds, and parameterized the model using empirical relationships. We simulated independent and additive effects of reduced breeding grounds habitat quantity and quality, and wintering grounds habitat quality, on population viability. Our results indicated the Kirtland's Warbler population is stable under current environmental and management conditions. Reduced breeding grounds habitat quantity resulted in reductions of the stable population size, but did not cause extinction under the scenarios we examined. In contrast, projected large reductions in wintering grounds precipitation caused the population to decline, with risk of extinction magnified when breeding habitat quantity or quality also decreased. Our study indicates that probability of long‐term persistence for Kirtland's Warbler will depend on climate change impacts to wintering grounds habitat quality and contributes to the growing literature documenting the importance of considering the full annual cycle for understanding population dynamics of migratory species.     

Allelopathic effects of volatile organic compounds released from Pinus halepensis needles and roots

The Mediterranean region is recognized as a global biodiversity hotspot. However, over the last decades, the cessation of traditional farming in the north part of the Mediterranean basin has given way to strong afforestation leading to occurrence of abandoned agricultural lands colonized by pioneer expansionist species like Pinus halepensis. This pine species is known to synthesize a wide range of secondary metabolites, and previous studies have demonstrated strong allelopathic potentialities of its needle and root leachates. Pinus halepensis is also recognized to release significant amounts of volatile organic compounds (VOC) with potential allelopathic effects that have never been investigated. In this context, the objectives of the present study were to improve our knowledge about the VOC released from P. halepensis needles and roots, determine if these VOC affect the seed germination and root growth of two herbaceous target species (Lactuca sativa and Linum strictum), and evaluate if soil microorganisms modulate the potential allelopathic effects of these VOC. Thirty terpenes were detected from both, needle and root emissions with β‐caryophyllene as the major volatile. Numerous terpenes, such as β‐caryophyllene, δ‐terpinene, or α‐pinene, showed higher headspace concentrations according to the gradient green needles < senescent needles < needle litter. Seed germination and root growth of the two target species were mainly reduced in presence of P. halepensis VOC. In strong contrast with the trend reported with needle leachates in literature, we observed an increasing inhibitory effect of P. halepensis VOC with the progress of needle physiological stages (i.e., green needle < senescent needle < needle litter). Surprisingly, several inhibitory effects observed on filter paper were also found or even amplified when natural soil was used as a substrate, highlighting that soil microorganisms do not necessarily limit the negative effects of VOC released by P. halepensis on herbaceous target species.     

Acid-catalyzed steam pretreatment of lodgepole pine and subsequent enzymatic hydrolysis and fermentation to ethanol

Utilization of ethanol produced from biomass has the potential to offset the use of gasoline and reduce CO(2) emissions. This could reduce the effects of global warming, one of which is the current outbreak of epidemic proportions of the mountain pine beetle (MPB) in British Columbia (BC), Canada. The result of this is increasing volumes of dead lodgepole pine with increasingly limited commercial uses. Bioconversion of lodgepole pine to ethanol using SO(2)-catalyzed steam explosion was investigated. The optimum pretreatment condition for this feedstock was determined to be 200 degrees C, 5 min, and 4% SO(2) (w/w). Simultaneous saccharification and fermentation (SSF) of this material provided an overall ethanol yield of 77% of the theoretical yield from raw material based on starting glucan, mannan, and galactan, which corresponds to 244 g ethanol/kg raw material within 30 h. Three conditions representing low (L), medium (M), and high (H) severity were also applied to healthy lodgepole pine. Although the M severity conditions of 200 degrees C, 5 min, and 4% SO(2) were sufficiently robust to pretreat healthy wood, the substrate produced from beetle-killed (BK) wood provided consistently higher ethanol yields after SSF than the other substrates tested. BK lodgepole pine appears to be an excellent candidate for efficient and productive bioconversion to ethanol.     

林窗尺度对马尾松人工林林下灌草层优势种生态位的早期影响北大核心CSCD

马尾松作为中国广泛栽植的乡土树种,其人工林群落结构简单和生物多样性低下是普遍存在的生态学问题。探究不同林窗尺度对马尾松人工林林下植被群落的影响,可为马尾松人工林近自然经营提供理论依据。该研究在45 a生马尾松人工林中分别设置A(50 m^(2))、B(100 m^(2))、C(200 m^(2))和D(667 m^(2))4种不同尺度的林窗,以不做任何处理的马尾松人工林作为对照(CK),探究采伐开窗后林窗内自然更新1 a后的灌草层植物组成、优势种生态位宽度和生态位重叠度分布特征。结果显示:(1)除100 m^(2)林窗下灌木层物种数与对照无显著差异外,其余林窗灌草层物种数均显著高于对照(P<0.05),且200 m^(2)林窗下灌草层物种数均最多,分别为35种和20种;4种林窗下灌草层物种丰富度指数较对照均显著增加(P<0.05),最大值均出现在200 m^(2)林窗下,其值分别为对照的1.5倍和2.6倍。(2)林窗增加了灌草层喜光植物种类,且在200 m^(2)林窗下种类最多,灌木层喜光植物有13种,草本层喜光植物有5种。(3)4种林窗下灌草层优势种中,喜光植物生态位宽度均较大,200 m^(2)林窗下灌草层生态位宽度平均值最小,其对资源利用程度低,重要值与生态位宽度之间无显著相关性(P>0.05)。(4)4种林窗下灌草层优势种间生态位重叠度指数均较小。667 m^(2)林窗下,灌草层优势种平均生态位重叠度指数最小,分别为0.029和0.024,200 m^(2)林窗下灌草层优势种高生态位重叠度占总数比例最大,分别为20%和23.8%。研究表明,采伐开窗促进了马尾松人工林林下植被发育,丰富了林下植物多样性,有利于马尾松林稳定持续发展,对精准提升马尾松人工林质量具有重要意义。     

辽西樟子松人工林净生态系统碳交换

樟子松是三北地区造林的主要树种之一,研究樟子松人工林净生态系统碳交换(NEE)及其影响要素对理解我国人工林碳平衡有重要意义。本研究以辽西樟子松人工林为对象,采用涡度相关系统及其配套设备于2020年对樟子松人工林NEE和环境要素进行了原位连续观测。结果表明: 在0.5 h尺度上,1—12月夜间为碳源,白天为碳汇,且受干旱影响5—8月下午碳吸收受到明显抑制。在日尺度上,受干旱影响,控制夜间NEE季节动态的主要要素为土壤温度和土壤湿度,控制白天NEE季节动态的主要要素为土壤湿度和饱和水汽压差;土壤干旱时降水可促进夜间和白天NEE,并导致光合呼吸参数升高。在月尺度上,白天NEE与表观量子利用效率和最大光合速率均呈显著负相关,当空气温度小于5 ℃时,10 ℃生态系统呼吸和生态系统呼吸温度敏感性随空气温度降低而呈线性增加。2020年辽西樟子松人工林NEE积累量为-145.17 g C·m^-2,表现为弱碳汇。     

树种及多样性组配对南亚热带人工林早期树木生长的影响

为科学筛选提升南亚热带人工林生产力的树种配置模式,选择南亚热带8个乡土树种,采用随机区组的试验设计,建立了树种多样性梯度(1、2、4、6个树种)人工新造林试验平台,研究树种多样性及不同功能特性树种混交对人工林早期树木生长的影响。结果表明: 在树木生长第5年,树木生长并没有随树种多样性增加而增加;速生树种马尾松和米老排纯林生长量是珍贵树种红椎和格木纯林的2.5～4.5倍;2个树种混交和4个树种混交情况下,针阔树种混交、速生树种与固氮树种混交显著提高树木生长量51.5%～132.8%,而当6个树种混交时,不同树种组配对生长量没有显著影响。不同树种配置模式下土壤氮、磷养分是影响树木早期生长的主要因素。针阔树种混交、速生和固氮树种混交能显著提高南亚热带人工林树木的早期生长。     

不同林龄杉木人工林土壤团聚体磷素分布特征

探究不同林龄杉木人工林土壤团聚体各形态磷素的分布特征有利于提升杉木人工林土壤磷素有效性。本研究选取位于广西融水县的幼龄(9 a)、中龄(17 a)、成熟(26 a)杉木人工林和邻近撂荒地(CK),利用干筛法将采集到的表层(0～20 cm)原状土壤分为4个粒级团聚体(>2、1～2、0.25～1和<0.25 mm),测定各粒级团聚体中不同形态磷组分。结果表明: 1)不同林龄杉木人工林土壤团聚体组成差异显著,CK和各林龄杉木人工林中>2 mm粒级团聚体含量显著较高,随林龄的增长先增后减,在17 a时最高;土壤平均重量直径(MWD)和几何平均直径(GMD)的变化趋势与>2 mm粒级团聚体一致。2)CK和各林龄杉木人工林中各粒级土壤团聚体全磷、无机磷和有机磷含量差异均不显著,而土壤有效磷含量在>2 mm粒级团聚体中显著较高,达1.23～7.33 mg·kg^-1;不同林龄杉木人工林土壤团聚体及全土全磷、有效磷和无机磷含量均显著高于CK,并随杉木林龄的增长先增后减,全土总磷和有效磷含量在9 a时最高,分别为322.40和7.33 mg·kg^-1,全土无机磷含量在17 a时最高,为114.05 mg·kg^-1;全土有机磷含量随杉木林龄的增长先增再减再增,在9 a时最高,为210.00 mg·kg^-1。3)不同粒级土壤团聚体磷储量与土壤团聚体组成比例显著相关。CK和各林龄杉木人工林中>2 mm粒级团聚体各形态磷储量较高。除有机磷外,各形态土壤磷储量均随杉木林龄的增长先增后减。综上,林龄17 a之前,杉木人工林的种植有利于提升土壤团聚体稳定性,促进土壤磷素水平的提升;林龄17 a后,>2 mm粒级团聚体的破碎导致土壤团聚体稳定性和土壤磷素供应水平逐渐下降。因此,在杉木人工林培育栽种17 a以后应重视土壤中>2 mm粒级团聚体的保护,以保障土壤质量,维持土壤供磷水平。     

北京通州平原生态林空间结构特征

林分空间结构直接反映林木间资源竞争情况和生长空间分配状况,对掌握生态林生长状况、制定林分结构调控措施,提升森林质量和生态服务具有重要作用。本文以北京市通州区油松林、白蜡林、旱柳林、毛白杨林、国槐林、刺槐林和垂柳林7种平原生态林为对象,采用聚集度、角尺度、大小比数、开敞度、树冠指数、竞争指数、边缘效益和空间结构综合指数评价了平原生态林的空间结构特征。结果表明: 研究区林分水平分布格局良好,聚集度处于0.32～1.41,角尺度都分布在0.4左右,大小比数主要分布在0.5附近。林分垂直分布格局有待改善,开敞度介于0.19～0.52,大部分树冠指数在0.7左右,竞争指数均大于50,整体居于高位状态。除刺槐林空间结构综合评价指数为Ⅲ级外,其他6种林分均为Ⅱ级,林分开阔程度较低,生活力一般,各林分空间结构综合评价指数从大到小为刺槐林>垂柳林>油松林>旱柳林>白蜡林>国槐林>毛白杨林。     

南亚热带10种造林树种的水力结构和水力安全

南亚热带地区人工纯林面积大, 但是结构简单, 对气候变化响应敏感。在区域气候干旱化的背景下, 造林树种的生理生态策略及其对季节性干旱的响应亟待研究。该研究选择南亚热带地区10种造林树种(包括6种乡土种和4种外来种), 测定这些树种的平均生长速率、水力学性状以及经济学性状, 分析性状与生长速率之间的相关关系, 并比较水力安全边际和气孔安全边际的种间差异。结果发现: (1)造林树种的生长速率与木质部导水率显著正相关, 但与木材密度、比叶面积以及水力安全性指标无显著相关性。(2)造林树种的水分传导效率性和安全性之间没有权衡关系, 外来树种Acacia crassicarpa和Eucalyptus grandis × urophylla同时具有较高的木质部导水率和较强的抗栓塞能力。(3)造林树种的水力安全边际和气孔安全边际的种间差异显著, 大叶相思(Acacia auriculiformis)、红锥(Castanopsis hystrix)、壳菜果(Mytilaria laosensis)和阴香(Cinnamomum burmannii)在干季发生水力失败的风险较高。建议南亚热带人工林的生态监测指标体系中应包括树木水力学性状, 进而为人工林的可持续经营管理提供重要参考。     

阔叶红松林不同林层和生长阶段树木生长对采伐强度的响应

采伐是调整林分结构的重要手段。不同林层的树木对采伐强度有着不同的响应方式。但以往考察采伐对树木生长的影响时多采用定性或简单定量的方法(如按树高等距)划分森林的垂直层次, 这就忽略了同一林层内不同树种间和不同发育阶段树木生长的差异。该研究在吉林蛟河天然阔叶红松(Pinus koraiensis)林内建立轻度(胸高断面积采伐强度17.3%)、中度(34.7%)、重度(51.9%)采伐以及对照(不采伐)样地, 跟踪调查采伐后自然恢复2、4、7年保留木的生长动态。根据不同树种每一个体所处的林层位置和生长发育阶段, 将保留木划分为3个组别: 林冠层树种的成熟个体(I)、林冠层树种的未成熟个体(II)以及林下层树种的全部个体(III), 比较不同恢复时期各组别树木的生长对于采伐强度的响应差异。结果表明, 第II组树木的平均胸径相对生长速率(0.033 cm·cm^-1·a^-1)显著高于第I (0.016 cm·cm^-1·a^-1)和III组(0.018 cm·cm^-1·a^-1)。总体来看, 采伐促进了大多数林冠层优势树种(第I、II组)的生长, 尤其是第II组树木的相对生长速率随采伐强度的增加而增加, 但第I组树木的相对生长速率只在重度采伐样地显著高于对照样地。然而林冠层少见种的生长速率并未受到采伐活动的显著影响。值得注意的是, 第I和II组树木生长对于采伐的响应都存在一定的时间滞后, 伐后短期内(2年)采伐样地与对照样地的生长速率没有显著差异, 而采伐对树木生长的促进效果在伐后2-4年才开始出现, 并在随后的监测期内持续存在。各组别树木的相对生长速率均随初始胸径的增大而降低, 且这种负相关关系的斜率随采伐强度增加逐渐增大, 表明随着采伐强度增加, 较小的树木个体从减弱的竞争中获益更多, 呈现出更加明显的生长释放现象。