Atmospheric cu and pb deposition and transport in lake sediments in a remote mountain area；northern China

IEECAS SKLLQG

Characteristics of soils from the Quartermain Mountain area, Antarctica

Soil-forming processes and soil development rates are compared and contrasted on glacial deposits in two adjacent and coeval valleys of the Quartermain Mountains, which are important because they display Miocene glacial stratigraphy and some of the oldest landforms in the McMurdo Dry Valleys. More than 100 soil profiles were examined on seven drift sheets ranging from 115 000 to greater than 11.3 million years in age in Beacon Valley and Arena Valley. Although the two valleys contain drifts of similar age, they differ markedly in ice content of the substrate. Whereas Arena Valley generally has 'dry-frozen' permafrost in the upper 1 m and minimal patterned ground, Beacon Valley contains massive ice buried by glacial drift and ice-cored rock glaciers and has ice-cemented permafrost in the upper 1 m and considerable associated patterned ground. Arena Valley soils have twice the rate of profile salt accumulation than Beacon Valley soils, because of lower available soil water and minimal cryoturbation. The following soil properties increase with age in both valleys: weathering stage, morphogenetic salt stage, thickness of the salt pan, the quantity of profile salts, electrical conductivity of the horizon of maximum salt enrichment, and depth of staining. Whereas soils less than 200 000 years and older soils derived from sandstone-rich ground moraine are Typic Anhyorthels and Anhyturbels, soils of early Quaternary and older age, particularly on dolerite-rich drifts, are Petronitric Anhyorthels. Arena Valley has the highest pedodiversity recorded in the McMurdo Dry Valleys. The soils of the Quartermain Mountains are the only soils in the McMurdo Dry Valleys known to contain abundant nitrates.

Analyses of manganese deposits in the Riding Mountain area

Several bog manganese deposits were discovered in the Riding Mountain area in Manitoba during the spring and summer of 1940. A study was made of the known deposits to determine the grade of the occurrences, a possible source of the manganese oxides in the bog deposits and the possibilities of locating other manganese occurrences. Samples of the bog manganese, of spring waters from which the manganese oxides have apparently been precipitated, of the Odanah shale in which the deposits occur, and of "ironstone" nodules found in the Odanah and Riding Mountain shales were gathered in the field and later analyzed. In addition to chemical analyses of the above-mentioned samples, several polished sections of the manganese oxides were prepared and studied under the microscope, thin-sections of nodules were examined, and spectrographic analyses of both nodules and bog manganese were made. ...

Deadwood Conglomerate monazite deposit Bald Mountain area, Sheridan and Big Horn Counties, Wyoming /

"March 1953."

Ecology of the pea aphid in the Blue Mountain area of eastern Washington and Oregon /

Caption title.

北京山区落叶阔叶林优势种水分生理生态研究

本文研究了北京山区落叶阀叶林优势种一辽东栎、大叶白蜡、北京丁香、核桃楸、山杏和荆条等乔灌木的稳定碳同位素比率，长期水分利用效率、植物蒸腾特性和土壤植物体的水分运动特点，并从植物解剖学的角度研究了这些植物叶片特点和其水分生理生态特性的关系。 对北京山区落叶阔叶林生态系统这几种乔、灌木植物叶片中的碳稳定性同位素比率(δ¹³C值)测定结果显示，这些植物叶片的δ¹³C值受多种因子的影响，具有较大的种间差异及时空异质性。主要表现在不同植物种叶片δ¹³C值不同，其排列顺序为山杏(- 24.75±0.85%。>大叶白蜡(- 25,94±1.52%。)=荆条(- 26.01±1.63%。)=辽东栎(一26.07±1.17%。)=北京丁香(-26.46±0.80c70。)>核桃楸(-28.11±1.52%。);生长初期叶片δ¹³C值较生长末期高，尤以核桃楸和辽东栎表现明显其生长初期和末期的叶片δ¹³C值皆相差达3‰;生境条件，特别是土壤水分含量和土层厚度，对植物叶片的813C值的高低有较大的影响，生长在于旱生境中的植物具有较高的δ¹³C值。另外，即使是同一株植物，叶片δ¹³C值也因其在冠层中所处的位置不同而异，冠层项部叶片的δ¹³C值高于林冠内部的叶片。北京山区落叶阔叶林优势种的长期水分利用效率与种的特点有关，山杏最高(4.950±0．l71mmolC0_2•mol-1H_2O)，核桃楸最低(3.760±0.203mmolC0_2•mol-1H_2O)，大叶白蜡、荆条、辽东栎和北京丁香居中(4.346- 4.530 mmolCO_2•mol-1H_2O)，大部分植物长期水分利用效率在春季（5月）较高，秋季较低，荆条由于物候期的特殊性在其生长季初期较低，而后逐渐增高。核桃楸在不存在水分亏缺情况下，树干液流速率受微气候因子的影响，液流速率的最大值达1600g•hour 左右。树干液流速率的日进程和大气相对湿度、温度的日进程具有相当好的生态学同步性。通过对核桃楸夜晚树干液流的分析可以得出其有根压存在的结论。 植物叶片和枝条中自由水和束缚水含量主要决定于植物种的特性，枝条的年龄、生境特点，特别是土壤水分特点。在落叶阔叶林I(样地2)中植物叶片自由水含量的排列顺序是：北京丁香>核桃楸>大叶白蜡>辽东栎;而杂灌丛（样地1）中植物叶片自由水含量的排列顺序是：核桃楸>大叶白蜡>山杏>荆条>北京丁香>辽东栎，可见群落类型对植物自由水含量影响是很大的，植物束缚水含量与其自由水含量的格局完全相反，荆条、山杏等植物含量高，核桃揪含量低。枝条水分含量有与叶片水分含量相类似的特点。 北京山区落叶阔叶林优势种的水分生理生态学特性和其叶片的特点有很大的关系，首先是植物叶片的特点总是和其种的特性相联系，主要表现在叶的类型、叶片上毛、气孔密度、着生方式等，如荆条叶片上下表面都密被披针形毛，气孔小，核桃楸气孔较大且凸出，大叶白蜡叶片上的气孔凹陷，辽东栎的气孔呈椭圆状，保卫细胞上有许多白色蜡质结晶。有一些种有环状的气孔外缘。生境的变化对叶片的形态特征有影响，在全光照条件下叶片小而犀，而在庇荫条件下叶片大而薄，在扫描电镜下可见全光照条件下北京丁香叶片基本无毛，庇荫条件下则有短微毛，全光条件下荆条叶片上毛有小乳头状凸起，庇荫条件下没有。本文所研究的植物种气孔都着生在叶片的下表面，气孔密度的大小排列顺序是：辽东栎>山杏>北京丁香>核桃楸>大叶白蜡。经方差分析显示种闷气孔密度存在极显著性差异。对所研究植物的气孔导度和环境因子、叶片解剖特点进行线性回归分析，得到了总体的和各个种的回归模型，结果表明光照强度、气孔密度等对气孔导度影响显著，但因种的不同相互之间存在差别。 植物的蒸腾速率受多因子的影响，主要有种的特点、微气候因子（光照强度、大气相对湿度、叶面温度、叶室温度等）和土壤水分特点。植物的蒸腾速率日进程和微气候因子日进程有相当好的生态学同步性。对辽东栎的蒸腾速率和光照强度的研究发现二者有很好的线性关系。这些植物蒸腾速率都表现出一定规律的日进程和季节进程，大多数植物蒸腾速率在一天中有数次波动，最高峰一般出现在中午12时之前;在整个生长季中，6月底至8月初的蒸腾速率高于其他月份。

暖温带典型森林生态系统未来碳平衡的LPJ-GUESS模型模拟与分析

森林作为陆地生态系统的主体，在全球陆地碳循环中起着决定性作用。实测和模型研究均表明北半球的森林是重要的大气CO2汇，在缓解全球碳收支失衡中发挥着关键作用。过去几十年北半球所经历的显著气候变化，已经很大地改变了陆地生态系统的碳平衡状况。随着未来100年气候变化继续增大，对未来气候变化下森林生态系统碳平衡的预测研究就尤为重要。 北京山区森林属于典型的暖温带森林生态系统，前人对本区森林的植被特征、生态系统结构和功能、养分循环以及长期动态变化等都进行了深入的研究。然而长期的人类活动已使本区原生的地带性植被破坏殆尽。因此，对该区域森林生态系统碳平衡的模拟研究可以帮助我们认识其生态系统碳平衡变化特点及未来气候变化对其潜在的影响。 本研究采用LPJ-GUESS植被动态机理模型，利用IPCC于2000年发布的《排放情景特别报告》(SRES)的A2和B2两种情景下不同气候模式对华北地区未来100年温度和降水预测的平均值以及相应大气CO2浓度变化情景进行驱动，模拟北京山区未来100年暖温带森林生态系统的净初级生产力和碳平衡，尽可能真实地反映未来百年的变化趋势。通过比较当前和未来气候情景下北京山区以辽东栎（Quercus liaotungensis）为优势种的落叶阔叶林、以白桦（Betula platyphylla）为主的落叶阔叶林和油松（Pinus tabulaeformis）为主的针阔混交林三种典型暖温带森林生态系统的碳平衡差异，了解未来北京山区这三种暖温带森林生态系统的碳源汇功能，认识气候变化和大气CO2浓度升高对净初级生产力（Net primary productivity, NPP）、净生态系统碳交换（Net ecosystem exchange, NEE）、土壤异养呼吸（Heterotrophic respiration, Rh）和碳储量（Carbon biomass, C biomass）的影响，以及不同生态系统碳平衡对气候变化响应的异质性。 结果表明，未来100年两种气候情景下三种森林生态系统的NPP和Rh均增加，并且A2情景下增加的程度更大。由于三种生态系统树种组成的不同，未来气候情景下各自NPP和Rh增加的比例不同，导致三者NEE的变化也相异：100年后辽东栎林由碳汇转变为弱碳源，白桦林仍保持为碳汇但功能减弱，油松林成为一个更大的碳汇。三种森林生态系统的碳生物量在未来气候情景下均增大，21世纪末与20世纪末相比：辽东栎林在A2情景下碳生物量增加的比例为27.6%，大于B2情景下的19.3%；白桦林和油松林在B2情景下碳生物量增加的比例分别为34.2%和52.2%，大于A2情景下的30.8%和28.4%。各森林类型碳平衡状况不同，原因除气候因素外，主要是由于树种组成的差异所导致。SRES A2和B2两种气候情景相比，相对较低的排放情景（B2）下，生态系统有更高的碳储量。

Community engagement and groundwater investigation in a rural/peri urban basaltic aquifier system, Tamborine Mountain, South East Queensland

The Tamborine Mt area is a popular residential and tourist area in the Gold Coast hinterland, SE Qld. The 15km2 area occurs on elevated remnant Tertiary Basalts of the Beechmont Group, which comprise a number of mappable flow units originally derived from the Tweed volcanic centre to the south. The older Albert Basalt (Tertiary), which underlies the Beechmont Basalt at the southern end of the investigation area, is thought to be derived from the Focal Peak volcanic centre to the south west. The Basalts contain a locally significant ‘un-declared’ groundwater resource, which is utilised by the Tamborine Mt community for: • domestic purposes to supplement rainwater tank supplies, • commercial scale horticulture and • commercial export off-Mountain for bottled water. There is no reticulated water supply, and all waste water is treated on-site through domestic scale WTPs. Rainforest and other riparian ecosystems that attract residents and tourist dollars to the area, are also reliant on the groundwater that discharges to springs and surface streams on and around the plateau. Issues regarding a lack of compiled groundwater information, groundwater contamination, and groundwater sustainability are being investigated by QUT, utilising funding provided by the Federal Government’s ‘Caring for our Country’ programme through SEQ Catchments Ltd. The objectives of the two year project, which started in April 2009, are to: • Characterise the nature and condition of groundwater / surface water systems in the Tamborine Mountain area in terms of the issues being raised; • Engage and build capacity within the community to source local knowledge, encourage participation, raise awareness and improve understanding of the impacts of land and water use; • Develop a stand-alone 3D Visualisation model for dissemination into the community and use as a communication tool.