长白山阔叶红松林CO2廓线和CO2贮存的动态

从1999年8至10月,2000年的4至6月,2002年8月至2003年9月,在平均树高为26米的长白山阔叶红松林内,用红外气体分析仪(2250D,LI-CORInc.和LI-COR,820)测定了不同高度的二氧化碳浓度。根据测定的数据,分析了阔叶红松林二氧化碳廓线的日变化和季节变化动态。结果表明:CO2浓度的垂直分布在白天和夜间是不同的,在接近地面处CO2浓度始终最大。从季节CO2廓线看出,在植物生长季节林冠处CO2浓度有明显的成层现象,不同高度(60~2.5m)的CO2浓度3月份变化较小差值为10mmol穖ol-1,而在7月份变化较大,差值为60mmol穖ol-1。7月份林冠处(22,26,32m)CO2浓度梯度较大,浓度差为8mmol穖ol-1。计算位于涡度相关仪器之下的40米高空气柱中CO2贮存状况表明,年际贮存是负值,但对NEE的贡献很小。图4参11。     

亚热带三种林型甲烷通量及其影响因子

利用静态箱-气相色谱法,观测中亚热带三种森林类型(杉木人工林(CL)、青冈-石栎常绿阔叶林(CG)和马尾松-石栎针阔叶混交林(PM))土壤CH4通量,及土壤温度、含水率、土壤有机质(SOC)和全氮含量等相关因子。结果表明:亚热带三种森林类型土壤CH4通量总体变化趋势相似,均表现出一定的月变化规律,冬季高、春夏季逐渐降低。其通量平均值为-1.71μg/(m2·h)(CL),-4.14μg/(m2·h)(CG)和-9.48μg/(m2·h)(PM),均表现为大气CH4的汇。土壤CH4通量与土壤温度(地表、地下5 cm和地下10cm)之间相关性显著(p0.01)。杉木林和马尾松-石栎林土壤CH4通量与土壤5 cm含水率显著相关(p0.05)。土壤CH4通量与青冈-石栎林SOC含量,杉木林、马尾松-石栎林的全氮含量的相关性显著(p0.05)。     

非生长季长白山红松针阔叶混交林CO2通量特征

采用开路式涡度相关系统对长白山红松针阔叶混交林非生长季的CO2通量特征进行连续监测.结果显示:非生长季CO2通量变动范围为-0.3～0.5 mg·m-2s-1;秋末与初春均为显著的释放过程,虽然气温低于生物学最低温度,但在晴朗的午间,森林仍有数小时表现为碳汇的特征;在冬季覆雪状态下,森林存在微弱的相对恒定的CO2释放,在融雪阶段有一释放高峰;土壤温度高于0℃时,净生态系统碳交换量与5 cm深土壤温度呈指数相关变化.观测期间(190 d),长白山红松针阔叶混交林净碳交换量为127 g C·m-2,整体表现为一定强度的碳释放.     

长白山森林生态系统土壤氮矿化时空动态特征

通过对土壤温度的定位观测(土壤深度5cm处)及分析,长白山北坡3种不同林型土壤氮矿化速率表现为季节动态变化,与土壤温度季节动态变化比较相似。在不同月份氮矿化速率存在较大差异。在7、8月份时,氮矿化速率最大且红松云冷杉林土壤氮矿化速率明显高于阔叶红松林和岳桦云冷杉林。而在11、12、1～3月份之间氮矿化速率比较低且变化比较平稳。主要是因为温度对氮矿化速率起限制作用。就不同林型而言,阔叶红松林土壤年氮矿化量是44.13kg/hm2.a为最高,其次是红松云冷杉林31.3kg/hm2.a和岳桦云冷杉林25.73kg/hm2.a。因此阔叶红松林土壤供氮潜力更大。     

湖南莽山4种林型甲烷通量及其影响因子

以湖南省莽山地区4种典型森林类型(阔叶混交林、针阔混交林、常绿阔叶林及山地矮林)为研究对象,采用静态箱-气相色谱法观测4种森林类型土壤CH_4通量,比较其CH_4通量的动态及影响因子。结果表明:在生长季,4种森林类型甲烷通量总体上表现为汇,其大小顺序为常绿阔叶林(-10.290 9±9.900 5μg·m~(-2)h~(-1))山地矮林(-14.175 8±11.559 0μg·m~(-2)h~(-1))阔叶混交林(-17.115 5±11.074 8μg·m~(-2)h~(-1))针阔混交林(-23.700 2±10.484 7μg·m~(-2)h~(-1));除针阔混交林外,甲烷通量与土壤含水量无显著的相关性,4种森林类型甲烷通量均与土壤温度呈显著的负相关;甲烷通量对土壤养分的响应出现差异:山地矮林甲烷通量与土壤全氮、全磷呈显著正相关;常绿阔叶林甲烷通量与土壤有机碳呈显著负相关,与土壤全氮显著正相关,其他两种森林类型甲烷通量均与全氮呈显著正相关,说明土壤温度和土壤全氮是影响莽山地区甲烷通量的主要因素。     

武夷山不同海拔土壤和大气温度的时空变化特征

选取武夷山国家级自然保护区内5个海拔(1 200、1 400、1 600、1 800和2 000 m)的黄山松样地，对近地面大气(0～12 cm)和土壤(-6～0 cm)温度进行17个月的连续监测，以期揭示近地面大气和土壤温度的时空变化规律和温度梯度变化特征。结果表明：土壤温度显著高于大气温度(P<0.05),土壤和大气温度存在月份和季节变化规律。土壤和大气温度在不同海拔中存在显著差异(P<0.05),在海拔1 200 m最高，分别为12.85±5.15和12.45±7.25℃;海拔2 000 m最低，分别为10.26±4.99和9.58±6.56℃。土壤和大气年平均温度梯度变化分别为3.24和3.59℃。不同季节存在不同的温度变化特征，并且黑夜的土壤和大气温度梯度变化高于白天。土壤和大气温度存在时空变化规律，并且不同季节和昼夜变化对温度梯度变化存在影响。     

土壤温度和水分对长白山3种温带森林土壤呼吸的影响

为了研究土壤温度和土壤含水量对阔叶红松林(山地暗棕壤)、云冷杉暗针叶林(山地棕针叶林土壤)和岳桦林(生草森林土)的土壤呼吸的影响,于2001年9月在长白山进行了土壤实验。利用增加土壤样柱的含水量,将土壤含水量分为9%,、21%、30%、37%和43%5个等级,土壤样品分别在0、5、15、25和35的温度下保持24小时。阔叶红松林土壤在0~35范围内,土壤呼吸速率与温度呈正相关。在一定的含水量范围内(21%~37%),土壤呼吸随含水量的增加而升高,当含水量超出该范围,土壤呼吸速率则随含水量的变化而降低。土壤温度和水分对土壤呼吸作用存在明显的交互作用。不同森林类型土壤呼吸作用强弱存在显著差异,大小顺序为阔叶红松林>岳桦林>云冷杉暗针叶林.红松阔叶林土壤呼吸作用的最佳条件是土壤温度35,含水量37%;云冷杉暗针叶林下的山地棕色针叶土壤呼吸作用的最佳条件是25,21%;岳桦林土壤呼吸作用的最佳条件是35,含水量37%。但是,由于长白山阔叶红松林,云冷杉林和岳桦林处在不同的海拔带上,同期不同森林类型土壤温度各不相同,相差4~5,所以野外所测的同期的山地棕色针叶林土呼吸速率应低于暗棕色森林土呼吸速率,山地生草森林土呼吸速率应高于山地棕色针叶林土的呼吸速率。图2表1参25。     

长白山阔叶-红松林主要树种对高浓度CO2的响应

以长白山阔叶-红松林主要树种为材料,盆栽于模拟自然光照和人工调节CO2浓度400μmol/mol、700μmol/mol下两个生长季节,高浓度CO2下生长的8种供试树种光合速度比对照组的幼树提高29.40%～58.39%.通过对高浓度CO2下幼树光合作用动态变化的研究,发现经长期在高浓度CO2下生长的供试8个树种均表现出随时间的延长树木叶片光合速度失去原有在高浓度CO2下出现的光合优势.     

华北落叶松人工林土壤CO2和CH4通量的时间动态变化

采用静态箱—气相色谱(GC)法,对大青山地区华北落叶松人工林夏季(6～8月)土壤CO2和CH4通量进行原位测定,研究了夏季土壤温室气体通量和昼夜变化规律及其与温度的关系.结果表明:大青山华北落叶松人工林6、7、8月土壤CO2排放通量平均值分别为296.7、727.7、461.2 mg/m2·h;不同月份的CO2通量昼夜变化均呈现昼高夜低的现象.大青山华北落叶松人工林土壤为大气CH4的汇,6～8月土壤月均CH4吸收通量均值大小顺序为8月＞7月＞6月;各月CH4吸收通量昼夜变化表现为单峰型,最大吸收通量出现在白天.9:00和19:00这2个时间区域内进行土壤呼吸观测,经矫正后可以代表6～8月大青山华北落叶松人工林土壤CO2和CH4气体通量值.温度是影响CO2和CH4通量的重要因子.     

不同光照条件下红松幼苗光合作用诱导反应的研究

无论光通量密度(PPFD)为200靘ol穖-2穝-1还是500靘ol穖-2穝-1,生长在林冠下的红松幼苗光合速率达稳定净光合速率的50%和90%的诱导时间均长于全光条件下生长苗木。全光下生长的红松幼苗在PPFD为500靘ol穖-2穝-1时的诱导反应较PPFD为200靘ol穖-2穝-1时缓慢,而林冠下生长苗木则恰好相反。表明林冠下生长红松幼苗的光合作用诱导期与光斑强度有关。图3参6。     

造纸废渣和养分的改良对北部硬阔叶林土壤表面CO2通量的影响

Safe and economical disposal of paper mill sludge is a key consideration for forest products industry. A study was conducted to examine the effects of amendments of sludge and nutrients on soil surface CO₂ flux (R_s) in northern hardwood forests and to quantify the relat among R₅, soil temperature, and moisture in these stands. The experiment was a randomized complete block design that included sludge-amended, fertilized, and control treatments in sugar maple (Acer saccharum Marsh) dominated hardwood forests in the Upper Peninsula of Michigan, USA. Results showed that R_s was positively correlated to soil temperature (R²=0.80, p<0.001), but was poorly correlated to soil moisture. Soil moisture positively affected the R_s only in the sludge-amended treatment. The R_s was significantly greater in the sludge-amended treatment than in the fertilized (p=0.033) and the control (p=0.048) treatments. The maximum R_s in the sludge-amended treatment was 8.8 μmol CO₂·m⁻²·s⁻¹, 91% and 126% greater than those in the fertilized (4.6 μmol CO₂·m⁻²·s⁻¹) and control (3.9 μmol CO₂·m⁻²·s⁻¹) treatments, respectively. The R_s did not differ significantly between the fertilized and control treatments. The difference in R_s between sludge-amended and the other treatments decreased with time following treatment. Foundation item: The research was funded by a NCASI grant to S.T. Gower. Wang CK was supported by Innovated Talent Program of Northeast Forestry University (2004–07) Biography: WANG Chuan-kuan (1963-), male, Professor in the Ecology Program, College of Forestry, Northeast Forestry University, Harbin 150040, China. Responsible editor: Chai Ruihai     

The contribution of root respiration of<Emphasis Type="Italic">Pinus koraiensis</Emphasis> seedlings to total soil respiration under elevated CO<Subscript>2</Subscript> concentrations

The impacts of elevated atmospheric CO₂ concentrations (500 μmol·mol⁻¹ and 700 μmol·mol⁻¹) on total soil respiration and the contribution of root respiration ofPinus koraiensis seedlings were investigated from May to October in 2003 at the Research Station of Changbai Mountain Forest Ecosystems, Chinese Academy of Sciences, Jilin Province, China. After four growing seasons in top-open chambers exposed to elevated CO₂, the total soil respiration and roots respiration ofPinus koraiensis seedlings were measured by a Li-6400-09 soil CO₂ flux chamber. Three PVC cylinders in each chamber were inserted about 30 cm into the soil instantaneously to terminate the supply of current photosynthates from the tree canopy to roots for separating the root respiration from total soil respiration. Soil respirations both inside and outside of the cylinders were measured on June 16, August 20 and October 8, respectively. The results indicated that: there was a marked diurnal change in air temperature and soil temperature at depth of 5 cm on June 16, the maximum of soil temperature at depth of 5 cm lagged behind that of air temperature, no differences in temperature between treatments were found (P>0.05). The total soil respiration and soil respiration with roots severed showed strong diurnal and seasonal patterns. There was marked difference in total soil respiration and soil respiration with roots severed between treatments (P<0.01); Mean total soil respiration and contribution of root under different treatments were 3.26, 4.78 and 1.47 μmol·m⁻²·s⁻¹, 11.5%, 43.1% and 27.9% on June 16, August 20 and October 8, respectively. Foundation item: This study was supported by the Knowledge Innovation Project of the Chinese Academy of Sciences (KZCX1-SW-01) and the National Natural Science Foundation of China (30070158). Biography: LIU Ying (1976-), female, Ph. D. Institute of Applied Ecology, Chinese Academy of Sciences, Shenyang 110016, P. R. China. Responsible editor: Song Funan     

Carbon fluxes and their response to environmental variables in a Dahurian larch forest ecosystem in northeast China

The Dahurian larch forest in northeast China is important due to its vastness and location within a transitional zone from boreal to temperate and at the southern distribution edge of the vast Siberian larch forest. The continuous carbon fluxes were measured from May 2004 to April 2005 in the Dahurian larch forest in Northeast China using an eddy covariance method. The results showed that the ecosystem released carbon in the dormant season from mid-October 2004 to April 2005, while it assimilated CO₂ from the atmosphere in the growing season from May to September 2004. The net carbon sequestration reached its peak of 112 g·m⁻²·month⁻¹ in June 2004 (simplified expression of g (carbon)·m⁻²·month⁻¹) and then gradually decreased. Annually, the larch forest was a carbon sink that sequestered carbon of 146 g·m⁻²·a⁻¹ (simplified expression of g (carbon)·m⁻²·a⁻¹) during the measurements. The photosynthetic process of the larch forest ecosystem was largely affected by the vapor pressure deficit (VPD) and temperature. Under humid conditions (VPD < 1.0 kPa), the gross ecosystem production (GEP) increased with increasing temperature. But the net ecosystem production (NEP) showed almost no change with increasing temperature because the increment of GEP was counterbalanced by that of the ecosystem respiration. Under a dry environment (VPD > 1.0 kPa), the GEP decreased with the increasing VPD at a rate of 3.0 μmol·m⁻²·s⁻¹·kPa^-1 and the ecosystem respiration was also enhanced simultaneously due to the increase of air temperature, which was linearly correlated with the VPD. As a result, the net ecosystem carbon sequestration rapidly decreased with the increasing VPD at a rate of 5.2 μmol·m⁻²·s⁻¹·kPa⁻¹. Under humid conditions (VPD < 1.0 kPa), both the GEP and NEP were obviously restricted by the low air temperature but were insensitive to the high temperature because the observed high temperature value comes within the category of the optimum range.     

Photosynthetic induction responses of Pinus koraiensis seedlings grown in different light environments

The time processes of photosynthetic induction responses to various irradiances in Korean pine (Pinus koraiensis) seedlings grown in open-light environments and in understory of forest were studied in an area near the Research Station of Changbai Mountain Forest Ecosystems, Jilin Province, China from July 15 to August 5, 1997. The results showed that at 200 μmol·m⁻²·s⁻¹ photosynthetic photon flux density (PPFD) and 500 μmol·m⁻²·s⁻¹ PPFD, the induction time for the photosynthetic rates of understory-grown seedlings to reach 50% and 90% steady-state net photosynthetic rates was longer than that of the open-grown seedlings. The induction responses of open-growth seedlings at 500 μmol·m⁻²·s⁻¹ PPFD were slower than those at 200 μmol·m⁻²·s⁻¹ PPFD, but it was the very reverse for understory-growth seedlings, which indicates that the photosynthetic induction times of Korean pine seedlings grown in the understory depended on the sunfleck intensity. Biograph: ZHOU Yong-bin (1970-), female, associate professor of Shenyang Agricultural University, Shenyang 110161, P.R. China. Responsible editor: Song Funan     

白桦光合特性的研究

测定了3年生白桦的光合与呼吸作用对温度,湿度以及CO2浓度的响应;还测定了光补偿点,光饱和点和CO2补偿点。结果表明:在目前的空气CO2浓度下,光合和呼吸作用的最适温度分别是24℃和30℃;当相对湿度是80%时,白桦能维持较强的光合作用;呼吸作用与相对湿度无明显的相关性;光补偿点和光饱和点分别是25 molm-2s-1和1375 祄olm-2s-1;CO2补偿点是180 礚L-1;白桦在CO2浓度为2400 礚L-1时仍有吸收潜力。图4参19。     

温度对大叶桃花心木(Swietenia macrophylla King)幼苗叶片的光合影响

本文研究了大叶桃花心木（Swietenia macrophylla King）一年生幼苗在经过夜温处理后的光响应曲线和在饱和光强下的CO2反应曲线.结果表明:在大气CO2浓度下,叶片的最佳光合作用温度在25-31℃之间,而在饱和CO2浓度下为31-35℃.在25℃以下光合速率开始降低,主要是由于羧化效率的降低,而当温度超过31℃时,光合速率下降,是因为羧化效率的降低和呼吸速率的增加.CO2浓度对光合的促进作用在低温下受到抑制,这意味着未来在CO2浓度增高的情况下,高浓度的CO2对热带常绿植物光合的促进在冬天低温情况下表现不十分明显.图4参23.     

A study on the shade tolerance ofMuehlewbeckia complera

Muehlewbeckia complera was introduced to China in 2002 as indoor-hanging ornamental foliage plant. The experiment of the shade tolerance for this species was carried out in different light intensities (0.14–946.00 μmol·m⁻²·s⁻¹). After 40 days in experimental areas, leaf photosynthentic characteristics indexes ofM. complera in different photosynthesis active radiation (PAR) were measured with LI-COR6400 apparatus, such as the light compensation point, light saturation point, and maximum net photosynthesis rate, at the same time, the increments of total leaf area and leaf amount were measured. The results showed that the optimum light intensity range forM. complera was from 9.26 μmol·m⁻²·s⁻¹ to 569.00 μmol·m⁻²·s⁻¹ (463–28150 lx, relative humidity (RH) for 46–60%, temperature at 16–22°C). Under this condition, leaf photosynthetic efficiency was tiptop. AlthoughM. complera belonged to the moderate sun-adaptation plant species, the plant growth was inhibited when PAR increased to the level of 569.000 μmol·m⁻²·s⁻¹ or above.M. complera could sprout new leaves in photosynthesis active radiation of 0.16–19.22 μmol·m⁻²·s⁻¹ (8–961 lx), or 10 μmol·m⁻²·s⁻¹ for above 6 h. Foundation item: This study was supported by the Research Foundation of Northeast Forestry University. Biography: YUE Hua (1962-), female, Associate professor in Northeast Forestry University, Harbin 150040, P. R. China. Responsible editor: Zhu Hong     

长白山白桦林地土壤呼吸的季节变化

2004年5月至9月,研究了长白山白桦林土壤呼吸以及根系呼吸对土壤呼吸的贡献随土壤温度和土壤湿度的季节变化,研究结果表明：土壤总呼吸、断根土壤呼吸和根系呼吸在生长季内有相似的季节变化趋势,夏季潮湿而且温度较高,呼吸速率也较高,春季和秋季温度较低,呼吸速率也较低。2004年5月至9月,土壤总呼吸、断根土壤呼吸和根系呼吸的平均值分别为4.44,2.30和2.14μmol&#183;m^-2s^-1,三者与土壤温度均呈指数相关,与土壤湿度呈线性相关,三者的Q10值分别为2.82,2.59和3.16,这与其他学者的结果相似。根系呼吸是土壤呼吸的一个重要组成部分,2004年5月至9月,根系呼吸对土壤总呼吸的贡献在29.3～58.7%之间。根据Q10模型估算的土壤总呼吸、断根土壤呼吸和根系呼吸的全年平均值分别为1.96、1.08和0.87μmol&#183;m^-2s^-1,即741.73、408.71和329.24gC&#183;m^-2&#183;a^-1,全年根系对土壤总呼吸的贡献为44.4%。土壤呼吸和土壤温度之间的关系模型是了解和预测长白山白桦林生态系统潜在的随森林管理和气候变化而变化的有用工具。     

非生长季刺槐林土壤CH4通量的变化特征及其影响因子

[目的]探讨在非生长季不同天气条件下45年生刺槐林土壤CH₄通量的日变化和季节变化特征,并确定其主要影响因子.[方法]2014年10月-2015年4月(非生长季),在华北低山丘陵区黄河小浪底森林生态系统定位研究站,利用基于离轴积分腔输出光谱技术的土壤CH₄通量自动观测系统,对土壤CH₄通量进行连续观测,同步观测林内大气温度和相对湿度、5 cm深处土壤温度和土壤湿度、林内总辐射以及降雨量,分析各因子间的相互关系并确定影响土壤CH₄通量的主要因子.[结果]表明:(1)在非生长季,刺槐人工林土壤为大气CH₄重要的汇,变化范围为-0.15~-2.34 nmol·m^-2·s^-1 .晴天的林地土壤吸收CH₄能力 (-0.78 nmol·m^-2·s^-1) 明显高于阴天(-0.61 nmol·m^-2·s^-1)、降雨或降雪天气 (-0.58 nmol·m^-2·s^-1),而且呈"V"型日际变化特征;在2014年11月-2015年1月,土壤吸收CH₄能力逐渐下降,并维持相对较低的水平,直至2015年3月达到最大值 (-2.34 nmol·m^-2·s^-1);(2)土壤CH₄通量与大气温度、5 cm深处土壤温度呈显著负相关,与相对湿度呈正相关;在2015年1月,土壤CH₄通量与总辐射呈正相关;(3)在生长末期土壤上冻阶段和冬季土壤冻结阶段,大气温度和相对湿度为影响土壤CH₄通量的主要因子;而在生长季初期,主要的影响因子为大气温度和5 cm深处土壤温度.[结论]非生长季刺槐林土壤表现为大气CH₄的汇,在非生长季初期土壤吸收CH₄的能力最弱,主要受大气温度和相对湿度的影响,而在非生长季末期土壤吸收CH₄的能力逐渐增加,主要受大气温度和土壤温度的影响.