Tar characterisation in new generation agro-residue gasifiers - Cyclone and downdraft open top twin air entry systems

This paper deals with the characterisation of tar from two configurations of bioresidue thermochemical conversion reactors designed for producer gas based power generation systems. The pulverised fuel reactor is a cyclone system (R1) and the solid bioresidue reactor (denoted R2) is an open top twin air entry system both at 75-90 kg/h capacity (to generate electricity similar to 100 kVA). The reactor, R2, has undergone rigorous test in a major Indo-Swiss programme for the tar quantity at various conditions. The former is a recent technology development. Tars collected from these systems by a standard tar collection apparatus at the laboratory at Indian Institute of Science have been analysed at the Royal Institute of Technology (KTH), Sweden. The results of these analyses show that these thermochemical conversion reactors behave differently from the earlier reactors reported in literature in so far as tar generation is concerned. The extent of tar in hot gas is about 700-800 ppm for R1 and 70-100 ppm for R2. The amounts of the major compounds - naphthalene and phenol-are much lower that what is generally understood to happen in the gasifiers in Europe. It is suggested that the longer residence times at high temperatures allowed for in these reactors is responsible for this behavior. It is concluded the new generation reactor concepts extensively tried out at lower power levels hold promise for high power atmospheric gasification systems for woody as well as pulverisable bioresidues.

EXPERIENCE OF OPERATING OPEN TOP BIOMASS GASIFIER USING A LOW DENSITY FUEL-COCONUT FRONDS

Use of fuel other than woody generally has been limited to rice husk and other residues are rarely tried as a fuel in a gasification system. With the availability of woody biomass in most countries like India, alternates fuels are being explored for sustainable supply of fuel. Use of agro residues has been explored after briquetting. There are few feedstock's like coconut fronts, maize cobs, etc, that might require lesser preprocessing steps compared to briquetting. The paper presents a detailed investigation into using coconut fronds as a fuel in an open top down draft gasification system. The fuel has ash content of 7% and was dried to moisture levels of 12 %. The average bulk density was found to be 230 kg/m3 with a fuel size particle of an average size 40 mm as compared to 350 kg/m3 for a standard wood pieces. A typical dry coconut fronds weighs about 2.5kgs and on an average 6 m long and 90 % of the frond is the petiole which is generally used as a fuel. The focus was also to compare the overall process with respect to operating with a typical woody biomass like subabul whose ash content is 1 %. The open top gasification system consists of a reactor, cooling and cleaning system along with water treatment. The performance parameters studied were the gas composition, tar and particulates in the clean gas, water quality and reactor pressure drop apart from other standard data collection of fuel flow rate, etc. The average gas composition was found to be CO 15 1.0 % H-2 16 +/- 1% CH4 0.5 +/- 0.1 % CO2 12.0 +/- 1.0 % and rest N2 compared to CO 19 +/- 1.0 % H-2 17 +/- 1.0 %, CH4 1 +/- 0.2 %, CO2 12 +/- 1.0 % and rest N2. The tar and particulate content in the clean gas has been found to be about 10 and 12 mg/m3 in both cases. The presence of high ash content material increased the pressure drop with coconut frond compared to woody biomass.

Open top chambers and infrared lamps : a comparison of heating efficacy and CO₂/CH₄ dynamics in a Lake Superior coastal peatland

Experimental warming provides a method to determine how an ecosystem will respond to increased temperatures. Northern peatland ecosystems, sensitive to changing climates, provide an excellent setting for experimental warming. Storing great quantities of carbon, northern peatlands play a critical role in regulating global temperatures. Two of the most common methods of experimental warming include open top chambers (OTCs) and infrared (IR) lamps. These warming systems have been used in many ecosystems throughout the world, yet their efficacy to create a warmer environment is variable and has not been widely studied. To date, there has not been a direct, experimentally controlled comparison of OTCs and IR lamps. As a result, a factorial study was implemented to compare the warming efficacy of OTCs and IR lamps and to examine the resulting carbon dioxide (CO2) and methane (CH4) flux rates in a Lake Superior peatland. IR lamps warmed the ecosystem on average by 1-2 #°C, with the majority of warming occurring during nighttime hours. OTC's did not provide any long-term warming above control plots, which is contrary to similar OTC studies at high latitudes. By investigating diurnal heating patterns and micrometeorological variables, we were able to conclude that OTCs were not achieving strong daytime heating peaks and were often cooler than control plots during nighttime hours. Temperate day-length, cloudy and humid conditions, and latent heat loss were factors that inhibited OTC warming. There were no changes in CO2 flux between warming treatments in lawn plots. Gross ecosystem production was significantly greater in IR lamp-hummock plots, while ecosystem respiration was not affected. CH4 flux was not significantly affected by warming treatment. Minimal daytime heating differences, high ambient temperatures, decay resistant substrate, as well as other factors suppressed significant gas flux responses from warming treatments.

Effect of elevated atmospheric carbon dioxide concentration on rice blast in open-top chambers in Brazil.

2008

Meadow plant growth and competition under elevated ozone and carbon dioxide

The main aim of my thesis project was to assess the impact of elevated ozone (O3) and carbon dioxide (CO2) on the growth, competition and community of meadow plants in northern Europe. The thesis project consisted of three separate O3 and CO2 exposure experiments that were conducted as open-top-chamber (OTC) studies at Jokioinen, SW Finland, and a smaller-scale experiment with different availabilities of resources in greenhouses in Helsinki. The OTC experiments included a competition experiment with two- and three-wise interactions, a mesocosm-scale meadow community with a large number of species, and a pot experiment that assessed intraspecific differences of Centaurea jacea ecotypes. The studied lowland hay meadow proved to be an O3-sensitive biotope, as the O3 concentrations used (40-50 ppb) were moderate, and yet, six out of nine species (Campanula rotundifolia, Centaurea jacea, Fragaria vesca, Ranunculus acris, Trifolium medium, Vicia cracca) showed either significant reductions in biomass or reproductive development, visible O3 injury or any two as a response to elevated O3. The plant species and ecotypes exhibited large intra- and interspecific variation in their response to O3, but O3 and CO2 concentrations did not cause changes in their interspecific competition or in community composition. However, the largest O3-induced growth reductions were seen in the least abundant species (C. rotundifolia and F. vesca), which may indicate O3-induced suppression of weak competitors. The overall effects of CO2 were relatively small and mainly restricted to individual species and several measured variables. Based on the present studies, most of the deleterious effects of tropospheric O3 are not diminished by a moderate increase in CO2 under low N availability, and variation exists between different species and variables. The present study indicates that the growth of several herb species decreases with increasing atmospheric O3 concentrations, and that these changes may pose a threat to the biodiversity of meadows. Ozone-induced reductions in the total community biomass production and N pool are likely to have important consequences for the nutrient cycling of the ecosystem.

CO2浓度升高对羊草草原生产力和碳平衡的影响

自工业革命以来，大气的C02浓度以前所未有的速度增加，已经由280μmol mol-1升高到了360μmol mol-l。据预测，到下个世纪中／末期，C02浓度将为目前的二倍。C02浓度升高及其引起的全球气候变化必将影响到植物的生长发育，进而对整个生态系统产生巨大影响。因此，有关C02浓度升高对各类生态系统的影响的研究引起了广泛关注，成为近年来的研究热点。早期的研究多数集中于考察C02浓度升高对植物个体水平生长发育的影响。然而，高C02对植物的效应严重依赖于具体物种和具体环境条件，使得基于由短期盆栽实验获得的研究结果不能够有效地预测自然生态系统的行为。因此，长期、原位处理实验越来越受到重视。由于原位研究的难度较大，目前这方面的研究还不是很多。有限研究结果显示，由于生境条件和种间关系方面的巨大差异，自然生态系统对C02浓度升高的反应迥异。 草原生态系统由于C02浓度控制上比较容易实现，而且其物质循环相对较快，因而一直是C02富集实验研究最多的一类植被，生态系统水平的研究更是如此。然而涉及的区域和草原类型并不多，不足以进行可靠预测。目前，关于C02升高效应，研究比较系统的草原生态系统主要集中在：美国Kansas的高草草原、美国California的一年生草原、瑞士西北部的石灰质草原、美国Colorado的矮草草原和一些牧场。我国总土地面积的40%为草地，类型丰富，然而相关研究不多，尤其是对自然生态系统的原位研究几乎为空白。 为揭示C02浓度升高对羊草草原生产力和碳平衡的效应，我们在中国科学院内蒙古草原生态系统定位研究站的永久羊草样地开展了两年的C02倍增实验(2001，2002)。在羊草样地选择相对均匀地段设置12个开顶式气室（直径1.8m），每个气室内分成4个小样方(0.5m×0.5m)，其中6个气室在生长季给予加倍C02处理（约600μmol mol-l），另6个气室不补充C02（约300μmol moI-l）。地上部分用收割法取样，分种记录数量、高度和重量等指标，地下部分取样用环刀法。用Li-cor6400光合系统测定群落光合和呼吸速率。野外实验结束后，统一分析植物和土壤样品中的C、N等元素含量。另外，在内蒙古草原站院内设置了两组桶培实验，一组是取自羊草样地的带苗原状土，一组是取自羊草样地的混匀土，种上冰草(Agropyron cristatum)、紫花苜蓿(Medicago sativa)和无芒雀麦(Bromus inermis)的种子。2组桶培实验分别用两个水分梯度和两个C02梯度处理。水分处理分别为：浇水处理——每4天浇lOOOml水，相当于平均降雨量的160%;干旱处理——持续干旱，适时补水以保持植物不萎蔫，共浇水4000ml水。C02处理和取样方法与样地原位实验相同。主要研究结果和结论如下： 1)两年的C02加倍处理没有使羊草草原的生物量、植物种和功能型组成发生显著改变，桶培实验中，浇水处理显著促进了植物生长，原状土植物、种子苗实验的冰草和无芒雀麦对C02加倍处理同样不敏感，而种子苗实验的豆科植物紫花苜蓿在C02加倍处理下生物量显著提高。以上结果显示，由于水分和养分（特别是N）的限制，以及优势植物对C02的相对不敏感，C02浓度升高对羊草草原地上生物量和结构的效应相对不大。 2)羊草草原的根垂直分布在加倍C02条件下发生显著改变，但根生物量对C02加倍处 理相对不敏感。在4次取样中只有一次对C02加倍处理表现出显著变化，根长的变化与根生物量的变化不完全一致，根的比根长在加倍C02条件下增加。根垂直分布的变化趋势与降雨的时间分布相适应，干旱少雨时期C02使下层根量增加，多雨时期C02则使上层根量增加。以上结果显示，根的空间分布比根生物量对C02加倍处理更敏感。水分是根空间分布变化的驱动因子，加倍C02条件下，根空间分布的变化趋势倾向于优化对水分的充分利用。 3)加倍C02处理使羊草草原的群落光合速率显著提高，群落呼吸速率显著降低，因而使群落碳净输入量增加。土壤碳贮量占羊草草原碳总贮量的70%以上，碳总贮量及其组分（包括地上碳贮量、根碳贮量、土壤碳贮量）在两个C02浓度处理之问均没有显著差异。另外，加倍C02处理使羊草草原群落及其优势植物羊草的c：N比增加。以上结果显示，在加倍C02条件下羊草草原的碳净输入量增加，这意味着在未来高 C02条件F，羊草草原将作为碳汇对大气C02起反馈调节作用。其碳贮量对加倍C02 处理的不敏感与许多以前的研究结果相似，一般认为是由于土壤碳贮量本底太大， 掩盖了C02效应，这还有待于更长期原位实验的证实。羊草草原群落c：N比在高C02 浓度下的变化将影响凋落物降解、N素循环和动植物营养关系等，进而对生态系统 功能产生深远影响。

中国冬小麦品种对臭氧、二氧化碳和干旱的响应

臭氧属于二次污染物，它是由机动车、工厂等人为源以及天然源排放的氮氧化物(NOx)和挥发性有机物(VOCs)等一次污染物在大气中经过光化学反应形成的。O3 是光化学烟雾的主要成分，可对植物生长产生抑制。近几十年来，全球O3 污染的格局正在发生着巨大改变。由于北美及西欧等经济发达地区采取了有效控制臭氧形成前体物的措施，其空气中的O3 浓度在减少，而亚洲等经济发展中地区的O3 形成前体物的排放却在急剧攀升，导致大气中O3 浓度显著增加。中国经济的快速发展以及汽车保有量的迅猛增加导致O3 前体物的大量排放，许多经济较发达的地区空气中的O3 浓度超过了75ppb。由于O3 污染将导致农作物产量显著降低，因此，亚洲尤其是中国O3 污染对本地区农业生产的影响引起了国内外科学家的广泛关注。然而，在中国开展的关于O3 对植物生长及生产影响的研究相对较少，但已有的几篇研究报道确实指出目前中国部分地区的O3 浓度可导致冬小麦产量大幅下降，并预测到2020 年由O3 污染将引起小麦产量进一步降低。 植物对臭氧的反应或敏感性取决于诸如叶片导度、叶片结构及生化解毒等很多方面。首先，由于高叶片导度将吸收较多的臭氧量，因此，叶片导度通常被认为是决定抗性最为重要的因子。处于湿润条件下的植物，通常具有较高叶片导度，受到臭氧危害的程度一般也较大。其次，植物抗氧化胁迫能力的大小也决定着其对臭氧的敏感性。同一植株的老叶首先表现出伤害症状，这是由于老叶的抗氧化能力差于新叶，体现在抗坏血酸和谷胱甘肽含量及抗坏血酸氧化物酶和谷胱甘肽还原酶活性低于新叶。另外，叶片对臭氧的敏感程度与其叶片结构关系密切，拥有较大的细胞间隙对抗污染特性至关重要，由于叶片上表面的栅栏组织较海绵组织致密，因此通常较早表现出伤害症状。 影响植物对臭氧反应的环境因子很多，诸如光照、水气压亏、温度等。由于臭氧主要通过气孔进入植物体内，因此目前的研究主要集中在能显著调节气孔导度的环境因子，如土壤水分状况和在未来可能会与大气中臭氧浓度同步增加的CO2 浓度。CO2 浓度升高可降低植物的气孔导度，因此，CO2 浓度升高可减少叶片对O3 的吸收量。同时，大气CO2 浓度升高可提高净同化速率，可导致气孔的部分关闭而减少蒸腾，从而显著提高植株的水分利用效率，最终促进作物生长并提高产量。然而，二者对作物产量的交互影响尚不明确。水分胁迫被认为是影响O3 对植株伤害的一个重要环境因子。与正常供水相比，水分胁迫常常伴随着气孔导度的降低，导致进入到植株体内的O3 量相对较少而减轻植株受到的伤害程度。然而水分供应不足本身将导致小麦生长降低及产量下降。因此，水分亏缺可能会保护植株免受O3 伤害，同时也可能会加剧对植株的胁迫。 高浓度臭氧环境下，植物表现出较低的气孔导度。但研究表明，对臭氧敏感性不同的植物其气孔导度对臭氧的反应程度不同。臭氧对气孔的作用将影响植物生产力，同时也将影响植物对其它环境胁迫如干旱等的反应。短时间臭氧熏蒸小麦导致叶片细胞膜系统受损、光合产物输出受阻;而长期受臭氧污染后，小麦叶片的光合速率、光化学效率、叶绿素含量和蔗糖含量均显著降低，并与臭氧剂量的大小和峰值出现的早晚有关。O3 浓度升高将抑制光合作用，减少气孔导度，加强呼吸作用，改变C 同化物分配，加快叶片的衰老。众多研究表明，O3 导致的光合能力下降主要是由Rubisco 最大羧化效率降低导致;而O3 对光合器官捕获光的能力及光合电子传递速率的影响是光合作用下降的另一个原因。 尽管已有不少关于不同物种间对O3 敏感性的种间差异研究，然而育种方法或育种地点对中国不同冬小麦品种的O3 敏感性的影响尚不清楚。因此，我们假设育种年代、育种方法及地点将交互影响冬小麦品种对O3 的生长及生理响应。为进一步明确基因对冬小麦O3 敏感性的控制，研究了普通六倍体冬小麦的近缘体对O3 敏感性的差异。CO2 浓度升高及干旱胁迫对小麦臭氧敏感性的影响也进行了研究。论文主要从生理生化、生长及产量水平上来阐释O3 浓度升高、CO3加倍、干旱对冬小麦生长及生产影响的机理。 本研究主要是在温室中的上部开口的生长箱（open-top chamber, OTC）中进行。先后开展了四个盆栽实验研究，主要目的是确定中国不同基因型冬小麦种或品种对臭氧的敏感性及其反应机理;确定CO2 浓度升高及干旱在减轻O3 伤害方面的作用及其机理。实验材料为中国不同年代选育出的小麦品种，即1745年至2004 年间选育出的20 个品种和7 个小麦材料。主要评价指标包括相对生长速率、异速生长系数、叶绿素荧光、抗氧化活性、可溶性蛋白质含量、膜酯过氧化、气体交换、光合能力、叶绿素含量、暗呼吸、生物量及籽粒产量。实验研究得到的主要结果如下： 1) O3 升高显著降低整株及地上和地下部分的相对生长速率，显著降低异速生长系数、可变荧光、最大光化学效率、量子产额、光化学淬灭系数以及电子传递速率，但提高了非光化学淬灭系数。冬小麦不同品种对O3 的敏感性随育种年代的增加而增大，并与对照植株相对生长速率呈正相关。尽管近年来环境中的O3 浓度比过去显著增加，但新近育出的品种对臭氧的抗性却没有表现出协同进化效应。通过杂交选育的品种对臭氧的敏感性大于通过引进的和重选的品种。从生长和光合生理上来看，不同小麦品种对臭氧的敏感性与育种地点没有相关性，表明冬小麦品种对臭氧的适应能力与其生长环境下的臭氧浓度无关。因此，对臭氧相对敏感的冬小麦品种主要是由培育中较高相对生长速率或较高光合能力的杂交育种方式决定的，而与选育地点环境中的臭氧浓度无关。 2) 臭氧显著降低叶片中抗坏血酸（AsA）和可溶性蛋白的含量，但提高了过氧化物酶（POD）的活性和膜酯过氧化物（MDA）的含量。臭氧浓度升高抑制饱和光强下的净光合速率（Asat），降低气孔导度（gs）和总叶绿素含量，而显著提高暗呼吸速率（Rd）和胞间CO2 浓度（Ci）。臭氧导致总生物量降低，但地下部生物量受到的影响大于地上部。不同基因型小麦对臭氧的潜在敏感性与实际观察到的抗臭氧能力存在很大差异。冬小麦品种对臭氧的敏感性与臭氧环境下植株气孔导度和暗呼吸速率相关。臭氧导致Ci 浓度升高以及膜酯过氧化，由此得出臭氧导致的净光合速率主要是由于臭氧降低了叶肉细胞活性及细胞膜的完整性。新品种对臭氧相对敏感，主要是由于其具有较高的气孔导度抗氧化能力下降幅度较大以及较低的暗呼吸速率，从而对蛋白和细胞膜完整性造成较高的氧化伤害。 3) 臭氧对冬小麦光合和生长的影响存在着显著的种间差异。原初栽培种表现出最大的抗性，当代品种次之，而野生种对臭氧最为敏感。在普通冬小麦不同基因组供体中，钩刺山羊草（Aegilops tauschii，DD）对臭氧最敏感，其次为栽培一粒小麦（T. monococcum，AA），而圆锥小麦（Triticum turgidum ssp.Durum，AABB）对臭氧的抗性最大。因此，当代冬小麦品种对臭氧的敏感性可能是与其D 染色体供体-钩刺山羊草对臭氧敏感有关，而与其A、B 染色体供体-圆锥小麦的关系相对较小。 4) CO2 浓度升高提高了老品种和新品种的Asat，最大羧化速率（Vcmax），最大电子传递速率（Jmax）、光和CO2 饱和光合速率（Amax）。与之相反，臭氧显著降低了这些生理参数。虽然两品种对CO2 的响应没有显著性差异，但CO2浓度升高均有效保护了臭氧对它们的伤害。这种效应与CO2 浓度升高引起的气孔导度降低无关，而与代谢活性的提高有关。 5) 水分胁迫和臭氧分别都显著降低了 Asat 和gs。干旱显著降低Vcmax 和羧化效率（CE），而对Jmax 和暗呼吸（R）的影响不显著。臭氧显著降低冬小麦不同基因型的Vcmax，Jmax，R 和CE。二者均降低了生物量的积累及最终籽粒产量。与六倍体小麦相比，四倍体小麦对干旱相对敏感，但对臭氧却表现出较高抗性。干旱降低了气孔导度从而显著减少了植株对臭氧的吸收量，但两基因型的反应截然不同。干旱使臭氧对六倍体小麦产量和收获指数的伤害分别减少了约16%和50%，而干旱对该四倍体小麦的保护效应不大。

环境变化对内蒙古草原小叶锦鸡儿和羊草土壤氮素转化的影响

氮素是影响内蒙古温带典型草原植物生长和初级生产力的主要因素之一，土壤氮素的可利用性及其对全球环境变化的响应对于预测生态系统碳氮平衡显得尤为重要。空气中的游离氮和土壤中的有机氮必须通过固氮作用和矿化作用，转化为无机氮才能被绝大多数高等植物直接利用，氮素转化决定土壤氮素有效性。因此，研究环境变化对草原灌丛豆科固氮植物小叶锦鸡儿和草原优势植物种羊草土壤氮素转化重要生物过程的影响，对于进一步了解草原氮库变化及其对环境变化的可能响应有重要意义。 在中国科学院内蒙古草原生态系统定位站，利用开顶式生长室（Open-top chamber，OTC）控制实验模拟环境变化，经过三年的实验处理，研究氮素、水分和CO2浓度变化对小叶锦鸡儿根瘤生长和共生固氮、小叶锦鸡儿和羊草土壤净氮矿化速率的影响。观察小叶锦鸡儿根瘤形态和数量、测定根瘤长度和生物量以及固氮酶活性、测定土壤净氮矿化速率和土壤酶活性，探讨小叶锦鸡儿和羊草土壤氮素转化对环境变化响应机理。 结果表明，三年生桶培小叶锦鸡儿根瘤多着生于侧根，以浅黄色的小型球状根瘤为主，其次是棕褐色的棒状和纺锤状根瘤，较大型的褐色Y状根瘤相对较少。添加氮素极显著地抑制根瘤生长发育及其固氮酶活性，这种抑制效应随着水分增加和CO2浓度升高有所减缓。随着水分的增加，根瘤形态多样，根瘤着生部位由主根渐向侧根再向须根发展，根瘤数量和重量也显著增加。水分和CO2浓度升高，固氮酶活性增加但是未达到显著水平。小叶锦鸡儿根瘤生长及其固氮酶活性在加水条件下最好，水分可能是限制内蒙古半干旱草原小叶锦鸡儿固氮能力的关键因素。 环境变化影响小叶锦鸡儿土壤无机氮库。添加氮素处理，土壤无机氮库显著增加。添加氮素后，土壤脲酶活性显著降低，铵态氮和无机氮都出现明显的氮固持，但硝化速率增加，可能是由于添加氮素后土壤化学性质改变更利于硝化细菌进行硝化活动。随着水分和CO2浓度的升高，由于植物生长需求更多氮素的供应，土壤无机氮库显著降低。水分和CO2浓度处理对小叶锦鸡儿土壤脲酶活性和净氮矿化速率没有显著影响，但是能一定程度上减缓了氮素的负效应，促使无机氮的转化，使土壤微生物对铵态氮和无机氮的固持减少。但是蛋白酶活性和硝酸还原酶活性对三种环境因子响应均不敏感，脲酶对环境因子的变化最为敏感。小叶锦鸡儿土壤氮素转化与土壤理化性质密切相关，环境因子通过影响土壤脲酶活性以及土壤酸碱度等影响土壤矿化速率，进而影响土壤无机氮浓度和植物可利用氮。 羊草土壤无机氮库与小叶锦鸡儿土壤无机氮库对环境变化的响应较为一致，添加氮素羊草土壤无机氮含量显著增加，水分增加土壤无机氮含量显著降低。添加氮素使硝化速率显著增大，氨化速率和净氮矿化速率降低，但是未达到显著水平，铵态氮和无机氮出现固持现象。水分的增加降低土壤无机氮库，刺激脲酶活性，微生物对铵态氮的矿化作用增加，但是硝态氮的矿化作用受抑制，对净氮矿化没有影响。CO2浓度升高对羊草土壤无机氮库和土壤氮素矿化都没有显著地影响，但是CO2浓度升高在适宜水分下通过刺激土壤微生物活性，促进脲酶活性和无机氮的转化。羊草土壤酶活性对氮素和CO2浓度的响应与小叶锦鸡儿土壤酶活性的响应一致。 综上，不同环境因子对氮素转化过程影响不同，氮素添加抑制小叶锦鸡儿根瘤及其固氮酶活性，降低小叶锦鸡儿和羊草土壤净氮矿化速率。水分和CO2浓度升高一定程度上缓解了氮素对固氮酶活性以及土壤净氮素矿化速率的抑制作用，有利于土壤氮素转化。

大气NH_3升高对不同供氮水平下小麦叶片光合生理特征的影响

以小麦品种‘小偃6号’(氮高效品种)和‘长旱58’(氮低效品种)为材料,采用开顶式气室和土培实验研究了大气NH3浓度升高对生长于高、低两种供氮介质下小麦植株不同生育期叶片净光合速率(Pn)、气孔导度(Gs)、叶绿素含量、叶绿素荧光参数(Fv/Fm、Fv/F0)和可溶性糖含量的影响。结果显示:两小麦品种高氨低氮处理植株的Pn、Fv/F0和可溶性糖含量均高于高氨高氮和低氨低氮处理,并在生育后期差异达显著水平(P<0.05),氮低效品种的Gs也符合上述规律且不同处理间差异显著(P<0.05);小麦各生育期高氨高氮处理下植株的Pn均显著低于低氨高氮处理,且两处理间灌浆期的叶绿素含量和灌浆期以前的可溶性糖含量的差异显著(P<0.05),而两处理灌浆期以前的叶绿素荧光参数Fv/Fm在各处理条件下均无显著差异;不同处理间及品种间各项光合特征指标差异缺乏规律性。可见,大气中NH3浓度升高有利于改善低供氮介质条件下小麦植株的氮营养状况,但不同氮效率品种间的响应存在差异。

CO2浓度升高对三个树种资源分配模式的影响

　　由大气CO2浓度升高导致的气候变化是全球变化的重要研究内容之一。大气 CO2浓度升高会对植物的生理活动产生深刻的影响。本论文以开顶箱（Open top chamber）法控制 CO2浓度，在长期野外实地模拟基础上，研究三个树种资源分配模式的变化，揭示了长白山地区三个主要树种—红松（Pinus koraiensis）、长白松（Pinus sylvestriformis）和蒙古栎（Quercus mongolica）叶含碳结构物质和次生代谢物（CBSSCs）含量的变化动态及植物各器官内碳-防卫物质分配模式对CO2浓度升高的响应，这对预测未来CO2浓度升高条件下树木的适应性提供了科学依据。研究结果如下： 1）红松和长白松针叶总非结构性碳水化合物含量在生长季呈现先升高后降低的变化趋势，生长季末期稍有升高，休眠季含量较稳定。脂肪和结构性物质如半纤维素、纤维素和木质素含量在生长季和休眠季中含量比较稳定。 2）CBSSCs在植物叶中的含量存在显著的种间差异性，CBSSCs含量在生长季变化较大，休眠季变化很小。 3）从三个树种叶CBSSCs浓度的年平均值来看，植物对高浓度CO2没有持续和明显的反应，叶内不会出现较高浓度的酚类物质和其它CBSSCs物质。 4）高浓度CO2对植株氮总量没有影响，但由于生长导致的稀释效应使得红松叶、茎全氮浓度显著降低。 5）长期高浓度CO2处理使得红松生长和光合能力都有提高，碳向酚类物质和结构物质的分配提高。由高浓度CO2诱导的植物的这种碳向防卫物质的分配格局符合生长分化平衡模型（GDBe）的预测结果。

CO2浓度升高对三种树木叶片化学和舞毒蛾幼虫取食及生长的影响

探讨全球气候变化的生物学和生态学效应是当今生态学中的热点，研究大气CO2浓度升高对植物-昆虫相互作用关系的影响具有重要的理论和实践意义。本文使用开顶式气室（Open-top chamber，OTC）在野外条件下研究了CO2浓度升高对三种树木（小青杨、白桦和蒙古栎）叶片化学成分含量的影响，以及树木叶片品质变化对一种广食性森林昆虫（舞毒蛾）幼虫取食、生长发育和取食偏嗜性的影响。得出如下结果：（1）CO2浓度升高对3个受试树种叶片中的营养成分及次生代谢物含量均有显著影响，总体表现为氮含量降低，而碳氮比、非结构性碳水化合物、总酚和缩合丹宁含量增加。叶片中的化学成分含量可随时间发生显著变化，不同树种、甚至同一树种不同冠层高度的叶片对CO2浓度升高的响应强度也是不同的。叶片的干物质含量和比叶重对CO2浓度升高的响应不显著。（2）室内非选择性取食实验、室内选择性取食实验以及上树取食饲养方式下的多龄期取食实验，均发现高浓度CO2处理组内舞毒蛾幼虫的生长发育受到显著抑制。但对四龄舞毒蛾幼虫所进行的短期生物测定并未发现不同CO2浓度处理下幼虫的生长发育速率、对食物的取食率和转化率等昆虫营养指标存在显著差异。（3）叶片品质的降低是导致舞毒蛾幼虫生长发育受抑制的主要原因。但是总体上，CO2浓度升高导致的叶片品质变化并未显著影响幼虫的取食率和取食量。（4）舞毒蛾幼虫对不同叶片种类表现出清晰的取食选择性，这种选择性在其幼龄期就可表现出来。幼虫对小青杨上层叶片有最显著的偏嗜性，对蒙古栎下层叶片有最明显的拒食性。但是CO2浓度升高导致的叶片品质变化对舞毒蛾幼虫的取食选择性和寄主偏嗜行为并未产生显著影响。（5）检测出高浓度CO2处理组内舞毒蛾幼虫虫粪中含有浓度更高的植物次生代谢物质（总酚和缩合单宁），这很可能是昆虫整体生长发育受抑制的重要原因之一。

CO2浓度升高对红松和长白松幼苗界面过程影响的研究

界面是不同物相之间物质交换和能量流动最活跃的区域，植物通过植物体与环境之间的界面进行生命活动，其中以植物基本代谢物质COZ为媒介的界面过程研究是界面生态学研究的核心部分。本论文以开顶箱（Open toP chamber）法控制CO2浓度，在长期野外实地模拟基础上，研究针叶／大气界面和土壤／大气界面过程，揭示了红松（Pinus koraiensis）和长白松（Pinussylveslriformis）在高浓度CO2下生理生态功能的动态变化，这对预测未来COZ浓度倍增条件下树木的适应性提供了科学依据。研究结果表明：①长期700和500μmolmol-1 CO2处理，红松和长白松发生光合适应现象，但净光合速率仍比空气条件下对照组植株的净光合速率高；②高浓度CO2没有改变两树种的气孔敏感性，Ci／Ca比值增加，气孔响应与光合适应不同步；③红松和长白松的净光合速率与RuBPcase活性、光响应参数、针叶淀粉和全氮含量、相对生长速率具有明显相关性；④红松和长白松的暗呼吸对高浓度CO2的响应是瞬间反应与长期适应性的结合；⑤高浓度CO2提高了两树种的光合水分利用效率；⑥红松和长白松地上、地下部分的生物量分配模式在高浓度CO2下改变；⑦高浓度CO2改变了两树种单位叶面积重量、根体积、主根长、分枝等形态结构方面的特征，叶重比和根重比随CO2处理时间而变化；⑧施放高浓度CO2开顶箱内的土壤温度、土壤有机碳和全氮含量升高，土壤／大气间的CO2交换受到抑制；⑨红松和长白松对高浓度CO2的响应有很多不同之处，开顶箱本身的环境对长白松的生长有一定影响，对红松的影响相对较小；⑩红松和长白松对700和500μmolmol-1 CO2的生理生态响应随植物体的生长和CO2处理时间是动态变化的。

增温对川西北高寒草甸植物群落结构及几种主要植物生长和生理的影响

由于人类活动所引起的地球大气层中温室气体的富集已导致全球地表平均温度在20世纪升高了0.6 ℃，并预测在本世纪将上升1.4-5.8 ℃。气候变暖对陆地植物和生态系统影响深远，并已成为全球变化研究的重要议题。高海拔、高纬度地带的生态系统对气候变化最敏感。而在高原和高山极端环境影响下所形成的高寒草甸生态系统极其脆弱，对由于温室效应引起的全球气候变化极其敏感，对这些变化的响应更具有超前性。 本研究以川西北高寒草甸植物群落及几种主要物种为研究对象，采用国际山地综合研究中心（ITEX）普遍所采用的增温方法-----开顶式生长室（OTC）模拟气候变暖来研究增温对高寒草甸植物群落结构、物质分配及其主要物种生长和生理的影响，以探讨高寒草甸植物响应与适应气候变暖的生物学和生态学机制。主要研究结论如下： 1、OTC的增温效果 由于地温、地表温度和气温的平均值在OTC内分别高出对照样地0.28℃、0.46℃和1.4℃，这说明本研究所采用的开顶式生长室（OTC）起到了增温的作用；同时，由于温室内与温室外接受的降水量相同，温室内由于热量条件的改善，土壤蒸发和植被的蒸腾作用增强，直接导致了OTC内土壤表层相对湿度的减少。 2、群落结构对增温的响应 由于增温时间较短，增温内外样地的物种组成并未发生改变；但增温后一定程度上改变了植物群落的小气候环境，从而导致物种间的竞争关系被破坏，种间竞争关系的破坏引起群落优势种组成发生相应的改变，在对照样地，鹅绒委陵菜、甘青老鹳草、遏蓝菜和蚤缀是占绝对优势的物种，而在OTC内，小米草、尼泊尔酸模、垂穗披碱草、发草和羊茅的重要性显著增加。 禾草和杂草由于对增温的生物学特性及其资源利用响应的不同，加之增温造成土壤含水量下降等环境因子的改变。与对照样地相比较，OTC内禾草的盖度及生物量都显著增加，而杂草的盖度和生物量则显著下降。 3、植物生长期对增温的响应 OTC内立枯和调落物的生物量在生长季末（10月份）都要小于对照样地的立枯和调落物生物量，而OTC内的地上鲜体生物量在10月份却略高于对照样地。这说明OTC内植物的衰老或死亡得以延缓，而植物的生长期得以延长。 4、群落生物量及分配对增温的响应 OTC内的地上鲜体生物量(10月份除外)和地下0-30cm的根系生物量与对照样地相比较，都出现了不同程度的减少；土壤根系的分配格局也发生了明显的改变，其中，OTC内0-10cm土层的生物量分配比例增加，而20-30cm土层生物量分配比例的减少。 5、群落碳、氮对增温的响应 增温后，OTC内植物群落地上活体和地下活根的碳浓度不同程度的高于对照样地，植物群落的碳库在OTC内也略高于对照样地；而OTC内植物群落地上活体和地下活根的氮浓度不同程度的低于对照样地，其植物群落的氮库与对照样地相比也略有下降。 6、几种主要植物的生长及物质分配对增温的响应 垂穗披碱草在增温后株高、比叶面积和地上生物量均显著地增加；尼泊尔酸模在增温后比叶面积和单株平均生物量积累显著地增加，而各组分中，增温处理使叶的生物量显著增加，而根的生物量却显著下降；鹅绒委陵菜在增温后株高、比叶面积和单株平均生物量积累显著地减少，而各组分中，增温处理使叶和茎的生物量显著减少，根的生物量却显著地增加。 尼泊尔酸模的LMR、RMR、R/S、根部碳含量、碳和氮在叶片与根部的分配比例在增温后显著地增加，而SMR、根部氮含量、碳和氮在茎部的分配比例在增温后却显著地降低；鹅绒委陵菜的RMR、R/S、碳和氮在根部的分配比例在增温后显著地增加，而SMR、LMR、碳在叶片的分配比例在增温后却显著地降低 7、几种主要植物的光合生理过程对增温的响应 增温使垂穗披碱草和尼泊尔酸模叶片中的叶绿素a、叶绿素b、总叶绿素含量显著增加；而鹅绒委陵菜叶片的叶绿素a、叶绿素b、总叶绿素含量在增温后显著减少，类胡萝卜素含量在增温后却显著增加。 增温对3种植物的气体交换产生了显著影响。其中，垂穗披碱草和尼泊尔酸模叶片的光响应曲线在增温后明显高于对照处理，A、E、gs、Pmax、、Rday、AQY和LSP显著增加，而LCP则显著降低；鹅绒委陵菜的光响应曲线在增温后则明显的低于对照处理，A、E、gs、Pmax、、Rday、AQY和LSP显著减少，而LCP则显著增加。 增温后垂穗披碱草和尼泊尔酸模叶片的Fv/Fm、Yield和qP显著增加；而鹅绒委陵菜叶片的Fv/Fm、Yield和qP则显著减少，qN却显著地增加。 8、几种主要植物的抗氧化酶系统对增温的响应 增温使垂穗披碱草和尼泊尔酸模体内抗氧化酶活性和非酶促作用有所提高，植物膜脂过氧化作用降低；鹅绒委陵菜叶片中酶促反应和非酶促反应在增温后也显著提高，但可能由于增温后的土壤干旱超过了鹅绒委陵菜叶的抗氧化保护能力，抗氧化酶活性及非酶促反应（脯氨酸、类胡萝卜素）的提高不足以完全清除干旱诱导形成的过量活性氧，因此叶片的膜脂过氧化程度仍然显著提高。 Enrichment of atmospheric greenhouse gases resulted from human activities such as fossil fuel burning and deforestation has increased global mean temperature by 0.6 ℃ in the 20th century and is predicted to increase in this century by 1.4-5.8 ℃. The global warming will have profound, long-term impacts on terrestrial plants and ecosystems. The ecoologcial consequences arising from global warming have also become the very important issuses of global change research. The terrestrial habitats of high-elevation and high-latitude ecosystems are regarded as the most sensitive to changing climate. The alpine meadow ecosystme, which resulted from the composite effects of mountain extreme climatic factors in Tibetan Plateau, is thus thought to be especially vulnerable and sensitive to global warming. In this paper, the response of plant community and several main species in the alpine meadow of Northewst Sichuan to experimemtal warming was studied by using open-top chambers (OTC). The aim of the this study was to research the warming effects on plant community structure, substance allocation, growth and physiological processes of several mian species, and to explore the biological and ecological mechanism of how the alpine meadow plants acclimate and adapt to future global warming. The results were as follows: 1. Warming effects of OTC The mean soil temperature, soil surface temperature and air temperature in OTC manipulation increased by 0.28℃、0.46℃ and 1.4℃ compared to the control during the growing season. This suggested that the OTC used in our study had increased temperature there. Meanwhile, the OTC manipulation slightly altered thermal conditions, but the same amount of precipitation was supplied to both the OTC manipulation and the control, so higher soil evaporation and plant transpiration in OTC manipulation directly lead to the decrease of soil surface water content. 2. The reponse of community structure to experimental warming The species richness was not changed by the short-term effect of OTC manipulation. However, experimental warming changed the microenvironment of plant community, therefore competitive balances among species were shift, leading to changes in species dominance. In the present study, the dominant plant species in the control plots were some forbs including Potentilla anserine, Geranium pylzowianum, Thlaspi arvense and Arenaria serpyllifolia, however, the importance value of some gramineous grasses including Elymus nutans, Deschampsia caespitosa, Festuca ovina, and some forbs including Euphrasia tatarica and Rumex acetosa significantly increased in OTC. The different biology characteristics and resource utilizations between gramineous grasses and forbs, and enhanced temperature caused change in some environment factors such as soil water content. As a result, the coverage and biomass of gramineous grasses significantly increased in OTC compared to the control, however, the coverage and biomass of forbs singnifciantly decreased in OTC compared to the control. 3. The reponse of plant growing season to experimental warming Both the standing dead and fallen litter biomass in OTC were lower than those in the control in October, and the biomass of aboveground live-vegetation in OTC was higher than that of the control. The results indicated that the senescence of plants was postponed, and the growing season was prolonged in our research. 4. The reponse of community biomass accumulation and its allocation to experimental warming Experimental warming caused the decrease of aboveground live biomass and belowground root biomass except for the aboveground live biomass in October. Experimental warming also had pronounced effects on the pattern of root biomass allocation. In the present study, the root biomass in 0-10cm soil layer increased in OTC manipulation compared to the control, however, the root biomass in the 20-30cm soil layer decreased in OTC manipulation compared to the control. 5. The reponse of community C and N content to experimental warming The C concentration and stock in aboveground live and belowground root both increased in OTC manipulation compared to the control. However, the N concentration and stock in aboveground live and belowground root both decreased in OTC manipulation compared to the control. 6. The reponse of gowth and biomass, C and N alloction of several species to experimental warming Experimental warming significantly increased the height, SLA (specific leaf area) and aboveground biomass of Elymus nutans in OTC manipulation compared to the control. The SLA and total biomass of Rumex acetosa also significantly increased in OTC manipulation compared to control, among the different components of Rumex acetosa, leaf biomass significantly increased, but root biomass significantly decreased in OTC manipulation compared to the control. However, the height, SLA and total biomass of Potentilla anserina significantly decreased in OTC manipulation compared to the control, among the different component of Potentilla anserina, leaf and stem biomass significantly decreased, but root biomass significantly increased in OTC manipulation compared to the control. The LMR (leaf mass ratio), RMR (root mass ratio), R/S (shoot/root biomass ration) and root C concentration of Rumex acetosa significantly increased in OTC manipulation compared to outside control, also, Rumex acetosa allocated relatively more C and N content to leaf and root in response to experimental warming, however, the SMR (stem mass ration) and root N concentration of Rumex acetosa significantly decreased in OTC manipulation compared to outside control, also, Rumex acetosa allocated relatively less C and N content to stem in response to experimental warming. The RMR and R/S of Potentilla anserina significantly increased in OTC manipulation compared to outside control, also, Potentilla anserina allocated relatively more C and N content to root in response to experimental warming, however, the SMR and LMR of Potentilla anserina significantly decreased in OTC manipulation compared to outside control, also, Potentilla anserina allocated relatively less C and N content to leaf in response to experimental warming. 7. The reponse of physiological processes of several species to experimental warming Experimental warming significantly increased chlorophyll a, chlorophyll b and total chlorophyll of Elymus nutans and Rumex acetosa in OTC manipulation compared to outside control. However, chlorophyll a, chlorophyll b, total chlorophyll and carotenoid of Potentilla anserina in OTC manipulation significantly decreased compared to outside control. Experimental warming had pronounced effects on gas exchange of Elymus nutans, Rumex acetosa and Potentilla anserine. In the present study, warming markedly increased the light response curves of Elymus nutans and Rumex acetosa in OTC manipulation compared to outside control, and also singnificantly increased A (net photosynthesis rate), E (transpiration rate), gs (stomatal conductance), Pmax (maximum net photosynthetic rate), Rday (dark respiration rate), AQY (apparent quantum yield) and LSP (light saturation point), but LCP (photosynthetic light compensation) of Elymus nutans and Rumex acetosa in OTC manipulation singnificantly decreased compared to outside control. However, warming markedly decreased the light response curves of Potentilla anserina in OTC manipulation compared to outside control, and also singnificantly decreased A, E, gs, Pmax, Rday, AQY and LSP, but LCP of Potentilla anserina in OTC manipulation singnificantly increased compared to outside control. Experimental warming singnificantly increased the chlorophyll fluorescence kinetics parameters such as Fv/Fm, Yield and qP of Elymus nutans and Rumex acetosa and qN of Potentilla anserina in OTC manipulation, but Fv/Fm, Yield and qP of Potentilla anserina in OTC manipulation singnificantly decreased. 8. The reponse of antioxidative systems of several species to experimental warming Experimental warming tended to increase the activities of antioxidative enzymes and stimulate the role of non-enzymes of Elymus nutans and Rumex acetosa. As a result, MDA content of Elymus nutans and Rumex acetosa decreased. The activities of antioxidative enzymes and non-enzymes of Potentilla anserina also significantly increased in OTC manipulation, but more O2- was produced because of lower soil water content, and the O2- accumulation exceeded the defense ability of antioxidative systems and non-enzymes fuctions. As a result, MDA content of Potentilla anserine still increased in OTC manipulation compared to outside control.