降雨量改变对黄河三角洲滨海湿地土壤呼吸的影响

全球变化背景下,降雨模式变化造成土壤水分波动是引起土壤呼吸动态变化的重要驱动力。但滨海湿地如何响应降雨模式变化,进而引起生态系统蓝碳功能改变的机制尚不清楚。依托黄河三角洲滨海湿地增减雨野外控制试验平台,采用土壤碳通量观测系统(LI—8100)对湿地土壤呼吸速率进行监测,探究了2017年黄河三角洲滨海湿地土壤呼吸及环境、生物因子对减雨60%、减雨40%、对照60%、对照40%、增雨40%、增雨60%等变化的响应及机制。结果表明:1)随着降雨量增加,湿地土壤温度逐渐降低;同时增雨和减雨处理均显著提高了湿地土壤湿度(P0.05)。(2)降雨量变化显著影响湿地植被物种组成、地上和地下生物量分配以及植被根冠比(P0.05)。增雨40%和增雨60%均显著提高了湿地植物种类和植被根冠比,但同时显著降低了湿地植被地上生物量。此外,增雨40%和减雨60%处理均显著提高了湿地植被地下生物量。(3)降雨量变化对2017年湿地季节土壤呼吸无显著影响,但在湿地非淹水期,增雨60%和增雨40%均显著提高了湿地土壤呼吸速率(P0.05)。(4)2017年湿地不同降雨处理的土壤呼吸与土壤湿度均呈二次曲线关系(P0.05),相关系数随降雨量增加而降低;同时在非淹水期不同降雨处理的土壤呼吸与土壤温度均指数相关(P0.05),土壤呼吸温度敏感性(Q_(10))随降雨量增加而增大。在淹水期不同降雨处理土壤呼吸与土壤温度无显著相关关系。(5)淹水期土壤呼吸速率与地表水位呈指数负相关(P0.001)。     

短期模拟增温对黄河三角洲滨海湿地芦苇光响应特征的影响

黄河三角洲滨海湿地地下水位浅,淡咸水交互作用明显,其土壤水盐状况成为影响该地区生态系统关键过程的主要因子。另外,随着气候变暖,黄河三角洲在过去50年(1961—2010年)进入显著升温阶段,温度升高直接或间接影响着植物的光合作用和光响应特征,从而影响黄河三角洲滨海湿地的演变。采用红外辐射加热器模拟增温,分析了增温对黄河三角洲滨海湿地生长季(2015年5月初—2015年10月底)芦苇光响应特征的影响。根据土壤含水量波动情况生长季可分为3个时期,即干旱期、淹水期和湿润期。结果表明,干旱期,10 cm土壤温度升高3.3℃,土壤水分含量升高了9.4%,土壤盐分含量升高了16.7%;盐分增加使芦苇叶片在强光下发生光抑制,并且显著降低最大光合速率(Pnmax)、暗呼吸速率(Rd)、光补偿点(LCP)和光饱和点(LSP)。淹水期,增温对10 cm土壤温度、湿度和盐分均无显著影响,过饱和的水分状况限制叶片光合速率,使得Pnmax达到最低。湿润期,10 cm土壤温度显著升高3.0℃,土壤含水量升高了2.9%,土壤盐分无显著差异;这一阶段,温度升高促进中强光下芦苇叶片的光合速率;同时叶片Pnmax、Rd和LSP分别增加27.7%、14.9%和23.3%。从整个生长季来看,增温使土壤温度显著升高2.9℃,土壤盐分含量升高7.0%,而对光合参数无显著影响。由此可见,在滨海湿地生态系统中,增温对光合作用的影响受土壤水盐状况的控制。     

降雨量改变对常绿阔叶林干旱和湿润季节土壤呼吸的影响

通过野外原位试验,研究降雨量改变对华西雨屏区常绿阔叶林干旱和湿润季节土壤呼吸速率的影响。采用LI-8100土壤碳通量分析系统(LI-COR Inc.,USA)测定干旱和湿润季节对照(CK)、增雨10%(LA)、增雨5%(TA)、减雨10%(LR)、减雨20%(MR)、减雨50%(HR)6个处理水平的土壤呼吸速率,并通过回归方程分析温度和湿度与土壤呼吸速率间的关系。结果表明:湿润季节土壤呼吸速率高于干旱季节,HR处理对干旱季节土壤呼吸速率影响较大,而LA处理对湿润季节土壤呼吸速率的影响较大。TA和LR处理使土壤呼吸的温度敏感性增加,而HR、LA和MR处理使土壤呼吸的温度敏感性降低,干旱季节Q10值高于湿润季节。各处理湿润季节土壤微生物量碳氮含量显著高于干旱季节,HR、MR和LA处理减少土壤微生物生物量碳、氮的含量,而TA和LR处理增加土壤微生物生物量碳、氮的含量。与湿润季节相比,干旱季节土壤水分对土壤呼吸速率的影响较大;而与土壤温度相比,土壤水分对土壤呼吸速率的影响较小。在降雨量改变的背景下,华西雨屏区常绿阔叶林无论是干旱还是湿润季节,适当增雨和减雨都会促进土壤呼吸速率,而较高量的增雨和减雨会抑制土壤呼吸速率。     

模拟降雨量变化对黄河三角洲湿地植物群落特征的影响

气候变化背景下,降雨变化能够深刻影响河口湿地土壤水盐条件,而土壤水盐条件是影响植物群落特征的关键环境因子。本研究以黄河三角洲湿地植物群落为对象,依托野外降雨控制试验平台(减雨60%、减雨40%、自然对照、增雨40%、增雨60%),探讨了经过6年降雨处理后湿地植物群落特征对降雨量变化的响应及机制。结果表明: 随降雨量增加,土壤电导率显著降低,土壤湿度显著增大。降雨量变化影响了植物群落物种组成,增雨处理降低了碱蓬和盐地碱蓬的优势地位,提高了荻和白茅的优势地位。随降雨量增加,植物群落Shannon指数和Margalef丰富度指数显著提高。与对照相比,增减雨处理均降低了群落频度、多度和盖度,增雨60%处理群落频度显著降低54.9%,减雨60%、减雨40%、增雨40%、增雨60%处理群落多度分别显著降低38.9%、33.8%、35.8%和45.7%。随降雨量增加,植物群落地上生物量显著增加,但可能受淹水胁迫的影响,增雨60%处理地上生物量显著低于增雨40%。Margalef丰富度指数与地上生物量呈显著正相关;地上生物量、Shannon指数、Margalef丰富度指数、Simpson多样性指数均与土壤电导率呈显著负相关;地上生物量与土壤湿度呈显著正相关。降雨量变化通过改变黄河三角洲湿地土壤水盐条件显著影响了植物群落生长特征、物种组成和多样性。     

黄土高原藓结皮土壤呼吸速率对降雨量变化的响应

全球气候变化加剧背景下，干旱和半干旱地区的降雨模式将进一步改变，其造成的土壤水分波动是引起土壤呼吸动态变化的重要因素，但生物结皮土壤呼吸响应降雨模式变化继而影响陆地生态系统碳源/汇功能的机制尚不明确。针对黄土高原风沙土发育的藓结皮，以自然降雨量为对照，分别进行幅度为10%、30%、50%的模拟增雨和减雨处理，并利用便携式土壤碳通量分析仪(LI-8100A)测定了模拟增减雨后的藓结皮土壤呼吸速率，对比分析了其对降雨量变化的响应及机制。结果表明：(1)整个实验周期(2018和2019)增雨和减雨分别显著提高(增幅分别为17.9%—48.2%和27.1%—54.2%)和降低了(降幅分别为1.8%—26.8%和5.2%—20.8%)土壤含水量，但对土壤温度的影响不显著；(2)增雨抑制了藓结皮土壤呼吸速率(降幅分别为7.8%—31.7%和14.7%—39.4%),且随梯度增大抑制作用越明显；减雨则取决于减雨梯度，减雨10%和30%会促进土壤呼吸速率(增幅分别为27.5%、9.6%和23.6%、9.7%)而减雨50%具有抑制作用(降幅分别为15.6%和18.5%)。不同实验周期和不同降雨处理间藓结...     

模拟氮沉降和降雨对华西雨屏区常绿阔叶林土壤呼吸的影响

从2013年12月至2014年11月,通过野外原位试验,对华西雨屏区常绿阔叶林进行了模拟氮沉降和降雨试验,采用LI-8100土壤碳通量分析系统(LI-COR Inc.,USA)测定了对照(CK)、氮沉降(N)、减雨(R)、增雨(W)、氮沉降+减雨(NR)、氮沉降+增雨(NW)6个处理水平的土壤呼吸速率,并通过回归方程分析了温度和湿度与土壤呼吸速率间的关系。结果表明:(1)氮沉降和增雨抑制了常绿阔叶林土壤呼吸速率,减雨促进了常绿阔叶林土壤呼吸速率。(2)减雨使华西雨屏区常绿阔叶林土壤呼吸年通量增加了258 g/m~2,而模拟氮沉降和增雨使华西雨屏区常绿阔叶林土壤呼吸年通量分别减少了321g/m~2和406g/m~2。(3)减雨增加了土壤呼吸的温度敏感性,模拟氮沉降和增雨降低了土壤呼吸的温度敏感性。(4)模拟温度和湿度与土壤呼吸速率间回归方程分析表明,土壤水分对土壤呼吸速率的影响较小。(5)模拟氮沉降和增雨处理减少土壤微生物生物量碳、氮的含量,减雨处理增加了土壤微生物生物量碳、氮的含量。(6)模拟氮沉降和降雨对华西雨屏区土壤CO_2释放的影响未表现出明显的交互作用。     

降雨量和降雨时间共同调控黄河三角洲典型盐沼湿地土壤碳矿化

研究降雨格局(如降雨量和降雨时间)对滨海盐沼湿地土壤碳矿化的影响,对于深入理解土壤碳的稳定性和积累机制具有重要意义。本研究选取远离海岸且不受潮汐影响的黄河三角洲原生盐地碱蓬盐沼湿地为对象,通过野外原状土柱的控制试验,分析土壤碳矿化(CO₂和CH₄通量)在不同时期(干旱期和湿润期)对降雨事件的响应。结果表明: 降雨时间和降雨量对土壤CO₂通量的影响存在交互作用。在干旱期,大降雨事件显著降低了土壤CO₂通量;而湿润期的降雨事件对土壤CO₂通量没有显著影响,这可能与盐沼湿地的水盐运移有关。降雨量、降雨时间及其交互作用均对土壤CH₄通量没有显著影响。降雨时间和降雨量对CH₄/CO₂比率均没有显著影响,但是相关分析表明随着土壤含水量和盐分的升高,CH₄/CO₂比率呈升高趋势。随着降雨量的增加,土壤含水量和土壤盐分都显著增加,且两因素呈现显著的正相关关系。因此,未来该地区降雨体系改变将可能通过调控土壤水盐运移等条件对该滨海湿地土壤碳矿化和碳汇功能产生深远影响。     

黄渤海湿地芦苇光合特征对增温的响应

滨海湿地是高效的蓝碳碳汇系统,但气候变暖正在直接或间接地影响着滨海湿地植物的光合作用特征,从而影响湿地的碳汇功能。本研究在少雨的黄河三角洲(东营)和多雨的江苏盐城两地芦苇湿地建设增温观测站,采用Li-6800光合测量系统研究在东营和盐城两地芦苇的光合特征对模拟增温的响应机制,并对比了东营6月与8月两个生长季的差异。结果表明：与8月相比,6月芦苇光合作用能力更强,增温在2个生长季均提高了芦苇的净光合速率(P_n)、蒸腾速率(T_r)、气孔导度(g_s)和胞间CO₂浓度(C_i),但在8月P_n的正响应波动较小;与东营相比,盐城湿地的芦苇具有更高的P_n和水分利用率(WUE),且盐城湿地芦苇的最大净光合速率(P_{n max})、光饱和点(LSP)、表观量子效率(AQY)和暗呼吸速率(R_d)对增温的正响应更为显著,其AQY、LSP和P_{n max}在增温样地分别提高了16.7%、53.6%和30...     

模拟增温对黄河三角洲滨海湿地非生长季土壤呼吸的影响

冬季土壤呼吸能释放生长季所固存的碳, 因而在陆地碳循环中占有重要地位。随着全球气候变暖, 平均地表温度将升高0.3-4.8 ℃, 且冬季增温更加明显, 而温度的升高会促进更多CO₂的释放。另外, 滨海湿地地下水位浅, 淡咸水交互作用明显, 增温能引起土壤表层盐分升高, 从而影响土壤呼吸。该研究以黄河三角洲滨海湿地为研究对象, 采用红外辐射加热器模拟增温, 研究了该地区非生长季土壤呼吸的日动态及季节动态, 同时探讨了土壤呼吸对环境因子的响应机制。结果显示: 日动态中, 增温与对照的土壤呼吸速率变化趋势一致, 为单峰曲线; 在平均日变化中, 整个非生长季不同处理的土壤呼吸速率无显著差异, 而土壤温度和土壤盐分均为增温大于对照, 并且土壤呼吸峰值时间均比土壤温度提前。季节动态中, 整个研究期分为非盐分限制阶段(2014年11月-2015年2月中旬)和盐分限制阶段(2015年2月中旬-2015年4月)。在整个非生长季, 土壤呼吸速率无显著差异; 在非盐分限制阶段, 当10 cm土壤温度升高4.0 ℃时, 土壤呼吸速率显著提高22.9%, 而土壤呼吸温度敏感性系数(Q₁₀)与对照相比有所降低; 在盐分限制阶段, 尽管土壤温度升高3.3 ℃, 土壤呼吸速率却降低了20.7%, 这可能是由于增温引起了土壤盐分的升高, 同时由增温引起的土壤含水量的升高在一定程度上也限制了土壤呼吸, 而此阶段增温对Q₁₀无显著影响。因此, 在滨海湿地中, 增温除了直接影响土壤温度, 还可通过影响土壤水盐状况来影响土壤呼吸, 进而影响滨海湿地土壤碳库。     

干旱荒漠区不同生活型植物生长对降雨量变化的响应

降水是荒漠生态系统过程和功能的最重要限制因子,荒漠生态系统中的植物物种对生长季降雨的变化极端敏感。根据生长季内每次降雨量,进行不同梯度的人工模拟降雨试验(减雨50%、减雨25%、增雨25%、增雨50%、增雨100%),以自然降雨为对照,研究植物生长对降雨量变化的响应。结果表明:生长季降雨量影响植物的生长和初级生产力,不同生活型植物对降雨量变化的响应显著不同;减雨处理减缓了柠条、油蒿新枝生长,但影响不显著;增雨25%未能显著促进柠条、油蒿新枝生长;50%增雨未能促进柠条新枝生长而能促进油蒿的新枝生长;5—7月,增雨100%能显著增加油蒿新枝生长量,仅能增加柠条6—7月生长量;1年生草本植物地上部分生物量随降雨量增加呈线性增加趋势,减雨50%显著降低了草本植物株高,而其他降雨处理对株高影响不显著。     

Effects of elevated temperature on soil respiration in a coastal wetland during the non- growing season in the Yellow River Delta,China

Aims Winter soil respiration plays a crucial role in terrestrial carbon cycle, which could lose carbon gained in the growing season. With global warming, the average near-surface air temperatures will rise by 0.3 to 4.8 °C. Winter is expected to be warmer obviously than other seasons. Thus, the elevated temperature can significantly affect soil respiration. The coastal wetland has shallow underground water level and is affected by the fresh water and salt water. Elevated temperature can cause the increase of soil salinity, and as a result high salinity can limit soil respiration. Our objectives were to determine the diurnal and seasonal dynamics of soil respiration in a coastal wetland during the non-growing season, and to explore the responses of soil respiration to environmental factors, especially soil temperature and salinity.
Methods A manipulative warming experiment was conducted in a costal wetland in the Yellow River Delta using the infrared heaters. A complete random block design with two treatments, including control and warming, and each treatment was replicated each treatment four times. Soil respiration was measured twice a month during the non-growing season by a LI-8100 soil CO₂ efflux system. The measurements were taken every 2 h for 24 h at clear days. During each soil respiration measurement, soil environmental parameters were determined simultaneously, including soil temperature, moisture and salinity.
Important findings The diurnal variation of soil respiration in the warming plots was closely coupled with that in the control plots, and both exhibited single-peak curves. The daily soil respiration in the warming was higher than that in the control from November 2014 to January 2015. Contrarily, from March to April 2015. During the non-growing seasons, there were no significant differences in the daily mean soil respiration between the two treatments. However, soil temperature and soil salt content in the warming plots were significantly higher than those in the control plots. The non-growing season was divided into the no salt restriction period (November 2014 to middle February 2015) and salt restriction period (middle February 2015 to April 2015). During non-growing season, soil respiration in the warming had no significant difference compared with that in control. During the no salt restriction period, soil respiration in the warming was 22.9% (p < 0.01) greater than the control when soil temperature at 10 cm depth in warming was elevated by 4.0 °C compared with that in control. However, experimental warming decreased temperature sensitivity of soil respiration (Q₁₀). During salt restriction period, soil warming decreased soil respiration by 20.7% compared with the control although with higher temperature (3.3 °C), which may be attributed to the increased soil salt content (Soil electric conductivity increased from 4.4 ds·m^-1 to 5.3 ds·m^-1). The high water content can limit soil respiration in some extent. In addition, the Q₁₀ value in the warming had no significant difference compared with that in control during this period. Therefore, soil warming can not only increase soil respiration by elevating soil temperature, but also decrease soil respiration by increasing soil salt content due to evaporation, which consequently regulating the soil carbon balance of coastal wetlands.     

水位调控对崇明东滩围垦区滩涂湿地芦苇和白茅光合、形态及生长的影响

于2011年植物生长季,研究了长江口崇明东滩围垦区滩涂湿地3个地下水位梯度(低水位、中水位和高水位)下芦苇和白茅的光合、形态和生长特征,以及土壤温度、湿度、盐度和无机氮含量等土壤因子.结果表明： 在生长旺期,芦苇叶片光合能力在高水位显著低于低水位和中水位,白茅叶片光合能力在3个水位梯度间无显著差异.整个生长季内,在单株水平,芦苇形态和生长指标总体上在中水位最优,白茅大多数形态和生长指标在3个水位梯度间差异不显著;在种群水平,芦苇植株密度、叶面积指数和单位面积地上生物量在高水位最大,白茅植株密度、叶面积指数和单位面积地上生物量在低水位最大.生长季初期,3个水位梯度间0～20 cm土层芦苇根状茎生物量差异不显著,而0～20 cm土层白茅根状茎生物量在高水位显著低于低水位和中水位.作为围垦前的原生湿生植物,芦苇在3个水位梯度下表现的差异性可能是由于不同水位梯度下土壤因子和白茅竞争强度不同.合理调控围垦区滩涂湿地水位可以抑制中生草本植物白茅的生长和繁殖,有助于以芦苇为单优势种的原有湿地植物群落的恢复.     

水分胁迫对黄河三角洲河口湿地芦苇光合参数的影响

通过盆栽试验,分析了多梯度土壤水分条件对黄河三角洲河口湿地淡水沼泽芦苇快速生长期叶片净光合速率(P_n)、蒸腾速率(T_r)、气孔导度(G_s)、胞间CO₂浓度(C_i)、水分利用效率(WUE)和光能利用效率(LUE)等光合参数的影响,探讨淡水沼泽芦苇正常生长发育适宜的土壤水分条件.结果表明：淡水沼泽芦苇的P_n、T_r、WUE及LUE对土壤水分的变化有明显的响应阈值.渍水状态不是淡水沼泽芦苇生理状态最好的水分条件.维持淡水沼泽芦苇快速生长期正常生长,适宜的土壤体积含水率(W_v)应大于25.7%(即相对含水率W_r>66.6%),最佳W_v为36.9%(W_r为95.6%),正常生长所允许的最低土壤含水率W_v为21.5%(W_r为55.7%).气孔限制是淡水沼泽芦苇对水分胁迫的主要响应机制.干旱胁迫下,淡水沼泽芦苇的最大净光合速率(P_{n max})和表观量子效率(AQY)均显著下降,其暗呼吸速率(R_d)降低,减少呼吸作用对光合产物的消耗,提高WUE,以维持较高的光合速率.     

环境因子和生物因子对黄河三角洲滨海湿地土壤呼吸的影响

采用Li-8150多通道土壤呼吸自动测量系统对黄河三角洲滨海湿地土壤呼吸进行全年连续测定,同步测量了温度、土壤含水量、地上生物量以及叶面积指数等环境因子和生物因子.结果表明: 土壤呼吸日动态在全年尺度上多呈单峰型,但在受到土壤封冻和地表积水干扰时,土壤呼吸日动态呈多峰型.土壤呼吸具有明显的季节动态特征,总体呈单峰型,年平均土壤呼吸速率为0.85 μmol CO₂·m^-2·s^-1,生长季平均土壤呼吸速率为1.22 μmol CO₂·m^-2·s^-1.在全年尺度上,土壤温度是滨海湿地土壤呼吸的主要控制因子,可解释全年土壤呼吸87.5%的变化.在生长季尺度上,土壤含水量和叶面积指数对土壤呼吸的协同影响达到85%.     

Effects of soil moisture regimes on photosynthesis and growth in cattail (Typha latifolia)

Both waterlogging and water deficiency are major environmental factors affecting plant growth and functioning in many wetland and floodplain ecosystems across North America. Wetland plants possess various characteristics that enable them to survive and function in the intermittently flooded wetland environments, while their sensitivity to drought has received less attention. The present study quantified the photosynthetic and growth responses of cattail (Typha latifolia), an important species of freshwater wetlands, to a wide range of soil moisture regimes. In addition, changes in the efficiency of photosynthetic apparatus following initiation of the treatments were investigated. Under greenhouse conditions, seedlings were subjected to four soil moisture regimes: (1) drained (control), (2) continuous flooding, (3) periodic flooding, and (4) periodic drought. Results indicated that dark fluorescence yield was increased in response to periodic drought, while it showed decreases under continuous flooding. Net photosynthesis and stomatal conductance were enhanced by continuous flooding and periodic flooding. In contrast, these parameters exhibited reduction under periodic drought. In addition, leaf chlorophyll content was adversely affected by periodic drought. Recovery of net photosynthesis was noted, along with enhanced height growth, in both continuously and periodically flooded plants. Meanwhile, continuous flooding enhanced biomass production while periodic drought led to biomass reduction. Periodic drought also contributed to substantial reduction in root growth compared with shoot growth. Therefore, the combined photosynthetic performance and growth responses of cattail are likely to contribute to the ability of this species to thrive in flooded condition but be susceptive to periodic drought.     

Effects of alternate flooding–drought conditions on degenerated Phragmites australis salt marsh in Northeast China

The hydrological regime is the dominant factor associated with the degradation and restoration of inland salt marshes in Northeast China. This study investigates whether alternate flooding–drought conditions could be used to actively restore degraded inland salt marshes with the native plant Phragmites australis. Pot experiments were designed to examine changes in the growth and physiology of P. australis, as well as the saline–alkaline soil characteristics, in response to different hydrological regimes, alternate flooding–drought treatments, and single treatments of moisture, flooding, and drought. After 4 months of treatments, the P. australis population that grew in alternate flooding–drought conditions exhibited substantially more biomass accumulation and less Na⁺ absorption compared with the single treatments of moisture, flooding, and drought. Photosynthesis physiology served as regulating and adaptive responses to different water regimes, with increased values after the short‐term flooding, long‐term drought, and flooding–drought cycles. In addition, the saline–alkaline soil properties changed in response to the flooding–drought cycles. The flooding–drought cycles increased organic matter and total nitrogen contents, but decreased pH, electrical conductivity, and saline ion levels. Plant growth and saline–alkaline soil were improved by flooding–drought cycles (not drought–flooding cycles), which suggests that this may be an effective approach for restoration inland salt marshes.