An Electro-osmotic Fuel Pump for Dircet Methanol Fuel Cells

This work reports on the design and performance evaluation of a miniature direct methanol fuel cell(DMFC)integrated with an electro_osmotic(EO)pump for methanol delivery.Electro-osmotic pumps require minimal parasitic power while boasting no moving parts and simple fuel cell integration.Here ,aneletro-osmotic pump is realized from a commercially available porous glass frit.We characterize a custom-fabricated DMFC with a free convection cathode and coupled to an extennal electro-osmotic pump operated at applied potentials of 4.0,7.0,and 10V.Maximum gross power density of our free convection DMFC(operated at 50°)is 55 mW/cm2 using 4.0 mol/L concentration methanol solution supplied by the EO pump.Experimental results show that electro-osmotic pumps can deliver 2.0,4.0 and 8.0mol/L methanol/water mixtures to DMFCs while utilizing ~5.0% of the fuel cell power.Furthermore ,we discuss pertinent design considerations when using electro-osmotic pumps with DMFCs and areas of further study.

Rare Earth Pyrophosphates: Effective Catalysts for the Production of Acrolein from Vapor-phase Dehydration of Glycerol

Vapor-phase dehydration of glycerol to produce acrolein was investigated at 320 A degrees C over rare earth (including La, Ce, Nd, Sm, Eu, Gd, Tb, Ho, Er, Tm, Yb, Lu) pyrophosphates, which were prepared by precipitation method. The most promising catalysts were characterized by means of XRD, FT-IR, TG-DTA, BET and NH3-TPD measurements. The excellent catalytic performance of rare earth pyrophosphate depends on the appropriate surface acidity which can be obtained by the control of pH value in the precipitation and the calcination temperature, e.g. Nd-4(P2O7)(3) precipitated at pH = 6 and calcined at 500 A degrees C in the catalyst preparation.

THE DEHYDRATION BEHAVIOR OF RARE-EARTH COMPLEXES OF M-NITROBENZOIC ACID

Rare earth complexes of m-nitrobenzoic acid (LnL3.2H2O, Ln = La-Lu and Y, except Pm, HL = m-nitrobenzoic acid) were synthesized and characterized by elemental analysis, chemical analysis, IR spectroscopy and X-ray diffraction analysis. The dehydration beh

Photosynthetic parameters of sexually different parts of Porphyra katadai var. hemiphylla (Bangiales, Rhodophyta) during dehydration and re-hydration

Physiological data from extreme habitat organisms during stresses are vital information for comprehending their survival. The intertidal seaweeds are exposed to a combination of environmental stresses, the most influential one being regular dehydration and re-hydration. Porphyra katadai var. hemiphylla is a unique intertidal macroalga species with two longitudinally separated, color distinct, sexually different parts. In this study, the photosynthetic performance of both PSI and PSII of the two sexually different parts of P. katadai thalli during dehydration and re-hydration was investigated. Under low-grade dehydration the variation of photosystems of male and female parts of P. katadai were similar. However, after the absolute water content reached 42%, the PSI of the female parts was nearly shut down while that of the male parts still coordinated well and worked properly with PSII. Furthermore, after re-hydration with a better conditioned PSI, the dehydrated male parts were able to restore photosynthesis within 1 h, while the female parts did not. It is concluded that in P. katadai the susceptibility of photosynthesis to dehydration depends on the accommodative ability of PSI. The relatively lower content of phycobiliprotein in male parts may be the cause for a stronger PSI after severe dehydration.

Three-stage transformation of chlorophyll transient fluorescence pattern under sustained dehydration and the discovery of critical water content in seaweeds

The chlorophyll fluorescence kinetics of marine red alga Grateloupia turutunt Yamada, green alga Ulva pertusa Kjellm and brown alga Laminaria japonica Aresch during natural sustained dehydration were monitored and investigated. The pulse amplified modulation (PAM) system was used to analyze the distinct fluorescence parameters during thallus dehydration. Results proved that the fluorescence kinetics of different seaweed all showed three patterns of transformation with sustained water loss. These were: 1) peak kinetic pattern (at the early stage of dehydration fluorescence enhanced and quenched subsequently, representing a normal physiological state). 2) plateau kinetic pattern (with sustained water loss fluorescence enhanced continuously but quenching became slower, finally reaching its maximum). 3) Platform kinetic pattern (fluorescence fell and the shape of kinetic curve was similar to plateau kinetic pattern). A critical water content (CWC) could be found and defined as the percentage of water content just prior to the fluorescence drop and to be a significant physiological index for evaluation of plant drought tolerance. Once thallus water content became lower than this value the normal peak pattern can not be recovered even through rehydration, indicating an irreversible damage to the thylakoid membrane. The CWC value corresponding to different marine species were varied and negatively correlated with their desiccation tolerance, for example. Laminaria japonica had the highest CWC value (around 90%) and the lowest dehydration tolerance of the three. In addition, a fluorescence "burst" was found only in red algae during rehydration. The different fluorescence parameters F-o, F-v and F-v, F-m were measured and compared during water loss. Both F-o and F-v increased in the first stage of dehydration but F-v/F-m. kept almost constant. So the immediate response of in vivo chlorophyll fluorescence to dehydration was an enhancement. Later with sustained dehydration F-o increased continuously while F-v decreased and tended to become smaller and smaller. The major changes in fluorescence (including fluorescence drop during dehydration and the burst during rehydration) were all attributed to the change in F-o instead of F-v This significance of F-o indicates that it is necessary to do more research on F-o as well as on its relationship with the state of thylakoid membrane.

An industrial scale dehydration process for natural gas involving membranes

An industrial scale dehydration process based on hollow fiber membranes for lowering the dew point of natural gas is described in this paper. A pilot test with the feed flux scale of 12x10(4) Nm(3)/d was carried out. Dew points of -8 degreesC-13 degreesC at a gas transport pressure in the pipeline of 4.6M Pa and methane recovery of more than 98% were attained. The water vapor content of the product gas could be maintained around 0.01 vol% during a continuous run of about 700 hours. The effects of feed flux and operation pressure on methane recovery and water vapor content were also investigated. Additionally, some auxiliary technologies, such as a full-time engine using natural gas as fuel and the utilization of vent gas in the process, are also discussed. A small amount of the vent gas from the system was used as a fuel for an engine to drive vacuum pumps, and the heat expelled from the engine was used to warm up the natural gas feed. The whole system can be operated in a self-sustainable manner from an energy point of view, and has a relatively high efficiency in the utilization of natural gas.

Quantifying Cell Binding Kinetics Mediated By Surface-Bound Blood Type B Antigen To Immobilized Antibodies

Cell adhesion is crucial to many biological processes, such as inflammatory responses, tumor metastasis and thrombosis formation. Recently a commercial surface plasmon resonance (SPR)-based BIAcore biosensor has been extended to determine cell binding mediated by surface-bound biomolecular interactions. How such cell binding is quantitatively governed by kinetic rates and regulating factors, however, has been poorly understood. Here we developed a novel assay to determine the binding kinetics of surface-bound biomolecular interactions using a commercial BIAcore 3000 biosensor. Human red blood cells (RBCs) presenting blood group B antigen and CM5 chip bearing immobilized anti-B monoclonal antibody (mAb) were used to obtain the time courses of response unit, or sensorgrams, when flowing RBCs over the chip surface. A cellular kinetic model was proposed to correlate the sensorgrams with kinetic rates. Impacts of regulating factors, such as cell concentration, flow duration and rate, antibody-presenting level, as well as pH value and osmotic pressure of suspending medium were tested systematically, which imparted the confidence that the approach can be applied to kinetic measurements of cell adhesion mediated by surface-bound biomolecular interactions. These results provided a new insight into quantifying cell binding using a commercial SPR-based BIAcore biosensor.

Membrane Deformability and Membrane Tension of Single Isolated Mitochondria

Mitochondria dynamics is crucial to many biological processes such as mitochondria fusion and fission, which is highly correlated to the mechanics of single mitochondria. However, the mechanobiological coupling of mitochondria has been poorly understood. Here membrane deformability and membrane tension of individual mitochondria isolated from MtDsRed labeled human embryonic T-Rex-293 kidney cells were measured using a micropipette aspiration assay. The results demonstrated that membrane deformation of isolated mitochondria exhibited an elastic transition phase followed by an equilibrium phase, and mitochondrial membrane tension was proportional to the area compressibility. It was also indicated that mitochondrial membrane deformability was significantly affected by physical chemical factors such as osmotic pressure or pH value, and was further correlated to mitochondrial functionality in different respiratory states and Ca2+ regulation. These findings provide a new insight into understanding the mechanical regulation of mitochondrial physiology.

掺铒磷酸盐玻璃反应气氛法除水的研究

制备了不同含水量的掺铒磷酸盐玻璃，研究了各种工艺参数对反应气氛法除水效果的影响。结果表明由鼓泡气体带入的除水剂是玻璃除水的主要动力；在通气最初阶段的除水速率最快，并且提高除水温度、增大通气流量均有助于提高除水效率；结合实验从反应热力学角度讨论了除水机理，并指出在玻璃熔体中除水反应受熔体“笼效应”影响，反应速率大小取决于OH与CCl4形成偶遇对概率的大小。

复苏植物牛耳草Boea hygrometrica耐旱复苏过程中LEA基因表达调控及功能研究

本实验室以复苏被子植物旋蒴苣苔（Boea hygrometrica (Bunge) R Br，牛耳草）为实验材料，利用cDNA微阵列技术，筛选到2个LEA蛋白的cDNA片段。它们在干旱条件下表达水平增加一倍以上。在上述基础上，通过5’-RACE的方法扩增得到这两个LEA基因的全长cDNA，BhLEA1和BhLEA2，发现二者编码蛋白均与玄参科复苏植物Craterostigma plantagineum中的第4组LEA蛋白pcCC2具有最高的同源性。PCR扩增得到的基因组序列中发现BhLEA1和BhLEA2在靠近5’端处各有一内含子，分别为97和171bp。利用tail-PCR和inverse-PCR扩增得到BhLEA2的1215bp的启动子序列，其中含ABRE、W-box、HDEs、MYB、MYC、和生长素响应元件等。两个基因在不同胁迫、激素等处理下都有诱导表达。构建过量表达载体, 转化烟草。筛选T2代的纯合体植株进行抗旱试验，测定了干旱过程中的土壤和叶片含水量，PSⅡ最大光化学效率Fv/Fm、SOD和POD酶的活性及蛋白质降解程度，发现BhLEA1和BhLEA2过量表达的烟草抗旱性有明显提高，与野生型相比，叶片含水量和光系统Ⅱ活性下降慢、SOD和POD活性增高、蛋白质降解减少。Western blot检测发现在干旱时，野生型烟草的RbcL、LHCⅡ和PsBO蛋白明显降解，而转基因植物的几乎没有降解，或者降解较少，说明BhLEA的过量表达可以在一定程度上抑制干旱诱导的蛋白质降解。这些结果表明，BhLEA基因可能直接或间接地在牛耳草干旱过程中参与了保护蛋白质的作用，为牛耳草叶片的复苏提供了基础。

甘蓝型油菜中脯氨酸积累的分子调控机制

　　渗透胁迫下植物中游离脯氨酸的积累被普遍认为对植物有保护作用。本文对甘蓝型油菜（Brassica napus）中的脯氨酸积累及其调控机理进行了研究。正常生长条件下幼苗叶中脯氨酸含量最高，根中脯氨酸含量最低，盐胁迫后不同部位脯氨酸积累程度相近。盐浓度200 mM起，幼苗开始有明显脯氨酸积累,并随着浓度的增加而增加。PEG处理后脯氨酸积累要明显高于ABA和盐胁迫处理后脯氨酸积累。在成株中，生殖器官中脯氨酸含量明显高于营养器官中脯氨酸含量。 　　我们克隆了编码Δ1-二氢吡咯啉-5-羧酸合成酶（P5CS）,鸟氨酸转氨酶(OAT)和脯氨酸脱氢酶(PDH)的四个基因的cDNA。通过Southern杂交检测P5CS基因在甘蓝型油菜及其亲本白菜型油菜和甘蓝中的拷贝数，发现杂交条带在4倍体油菜中并没有显著的多于其两个2倍体亲本，推测有可能是在物种进化的过程中发生了基因丢失。 　　利用实时定量PCR的方法检测了渗透胁迫下甘蓝型油菜中BnP5CS，BnOAT和BnPDH等基因的表达水平。在ABA处理，盐处理和干旱处理时，BnP5CS1和BnP5CS2的表达在脯氨酸积累开始前就开始有明显上调，但是BnP5CS1的上调水平要比BnP5CS2高许多。BnOAT在ABA处理后表达水平没有太大的变化，在盐胁迫后甚至有一点下调，在干旱处理后却表现为一定程度的上调。另一方面，BnPDH的表达在ABA处理，盐胁迫和干旱胁迫后都受到了抑制。在成株不同器官相关基因表达的研究中发现，BnOAT在叶中表达量最高，BnP5CS和BnPDH在花蕾和花中的表达水平都比其他器官中要高。 　　我们的结果说明，渗透胁迫下甘蓝型油菜中的脯氨酸积累是脯氨酸合成途径的诱导和脯氨酸降解途径的抑制共同作用的结果。在轻度的渗透胁迫下，谷氨酸合成途径占主导地位，而在较为严重的渗透胁迫后期，谷氨酸合成途径和鸟氨酸合成途径共同起作用。甘蓝型油菜生殖器官花和花蕾中脯氨酸的代谢非常旺盛，说明脯氨酸可能在花发育中起着一定的作用。

暖温带山地森林生态系统水分问题研究

本文的研究是中国科学院院重大项目“暖温带森林生态系统结构、功能及生产力持续发展”的主要内容之一。作者以详实的第一手资料，从森林小气候及环境特征、森林降水的水文学效应及降水化学、森林的热量平衡及蒸发散、树木个体的水分生理生态学几个方面阐述、分析了暖温带山地森林生态系统主要林分的水分及其相关生态学问题。 在森林小气候及环境特征一章，作者从不同季节的日变化和生长季的月际变化两个视角，以落叶阔叶混交林和油松林为研究对象，考察了林冠上和林下四个不同梯度的风速、气温、湿度、地温的时空动态。 在森林降水的水文学效应和降水化学一章，笔者以1993、1994年试验年度的83次降雨观测资料为基础，分析了暖温带落叶阔叶混交林、辽东栎林、油松林、落叶松林、次生灌丛降水总量与各降水分量的关系，建立了单次降雨与各降雨分量的经验模型，并给出了生长季林冠作用层和林地作用层的水量分配的月际动态。在探讨上述水量关系的同时，作者还分析了前四类林分大气降水及各降水分量中N、K、Ca、S、Mg、P、Al七种元素的浓度及含量变化，就不同树种对上述元素的选择性交换作了探讨，比较了不同林分的降水化学效应差异。 在第四章，作者以落叶阔叶混交林和油松林为研究对象，分析了两类林分在94试验年度生长季辐射平衡、显热通量、潜热通量、蒸发散以及土壤热通量的季节变化和日变化特征。 在树木个体的水分生理生态部分，作者应用压力室一容积技术测定了暖温带落叶阔叶林、油松林和次生灌丛10种主要树种的水分生理指标：日最低水势值、最大膨压时的渗透势、膨压为零时的渗透势、初始质壁分离时渗透水的相对含量、初始质壁分离时的相对含水量、质外体水的相对含量、细胞最大弹性模量，并比较了不同树种间上述指标与抗旱性的关系。此外，作者还应用Li-1600稳态气孔计测定了上述林分中主要树种的日均蒸腾强度的季节动态，并比较了上下两面叶片蒸腾特性的差异。最后，作者采用九种水分生理指标对10种主要树种的抗旱性作了主分量分析，给出了综合性抗旱指标。 在第六章，作者应用热脉冲技术系统地研究了暖温带山地森林主要乔木树种的树干液流的时空变化特征，并应用时序分析方法对上述树种的树液流量变化建立了自回归模型，在此基础上提出了生理惯性指标，给予了生理学解释。

锡林郭勒典型草原 四种禾本科技牧草对水分胁迫的生理生态防御机制的比较研究

本文以不同水分胁迫下的四种禾本科牧草（羊草、冰草、洽草、糙隐子草）为对象，比较研究了水分胁迫对植物的生理生态损伤，以及植物的渗透调节、内源保护酶系统与水分胁迫的关系。 结果表明：水分胁迫对植物造成一定的影响／伤害，表现在相对含水量、高度、生物量、总叶绿素、总糖及蛋白质含量均降低。在同一水分胁迫梯度时，植物的保水能力以羊草最高，糙隐子草、冰草次之，洽草最低。参与渗透调节的物质以K+、游离非必须氨基酸为主;以Na+，游离必须氨基酸、糖为辅，不同植物渗透调节物质不同。供试植物的渗透调节能力以羊草最强。 在水分胁迫下，植物细胞膜的脂质过氧化程度降低，说明这几种植物具有较强的内源保护酶系统，表现在SOD、POD活性明显增高;ASA和还原性糖的缓慢变化。说明在水分胁迫下植物通过维持较高的保护酶活性，以减轻膜脂过氧化作用和膜的损伤。保护酶系统中的各组分所起的作用与物种有关。在供试植物中冰草、隐子草的这种保护能力强于羊草、洽草。渗透调节和内源保护酶系统或其一可能是这四种牧草具较强抗旱性的原因之一。

浑善达克退化生态系统恢复研究

　　浑善达克沙地是我国四大沙地之一，地处北方干旱半干旱区，为草原区向荒漠区过渡的地带。长期以来，由于人类不合理的生产活动，加上这里脆弱的生态环境，已引起了严重的土地退化问题：流动沙丘面积由1950s年占沙地总面积的2%增加到1990s的近50%。因此浑善达克沙地成为我国研究土地退化、防治沙尘暴的重点地区，本文从自然科学和人文科学相结合的角度出发，对浑善达克沙地草地退化原因、自然恢复潜力、恢复过程、适宜物种选择，以及社区生存、生产等方面进行了综合研究，得出以下主要结论： 　　 1) 浑善达克沙地土壤种子库中含有大量的种子，在退化草地自然恢复中表现出极大的潜力。这些种子在摆脱人和牲畜干扰的前提下，可以萌发、定居并形成植物群落，使退化草地恢复;当地表达到一定程度的植被覆盖，可有效减少沙尘暴的危害。土壤种子库中的植物种类与地上植被有极显著的相似性(P<0.05)，这是地上植被形成稳定群落的基础。种子库中的物种组成影响植被恢复演替的进程;反之，恢复演替也制约着种子库组成和幼苗建立。 　　2)退化沙地草地围封后，对不同恢复阶段草地的群落学调查表明，该地区自然恢复过程大致分为3个阶段：围封2年的恢复早期，流动沙丘向半固定沙丘转变;围封3-5年的恢复中期，半固定沙丘向固定沙丘转变;围封6年后的恢复后期，为固定沙丘稳定发展阶段。根据生活型及植物种类随恢复演替的变化规律，浑善达克沙地植被演替的总体趋势可归纳为：沙米 (Agriophyllum squarrosum)+ 雾冰藜(Bassia dasyphylla)群落→黄柳(Salix gordejevii)+ 冰草(Agropyron cristatum)群落→褐沙蒿(Artemisia intramongolica) + 冰草群落→沙地榆(Ulmus pumila var. sabulosa)疏林+冰草群落。在围封禁牧下，浑善达克退化沙地草地在较短时间内实现自然恢复，因此制约退化草地恢复演替的关键因素主要是人为和牲畜的干扰，只要排除了这种干扰因素，浑善达克大面积的退化沙地草地完全能够借助自然力实现生态恢复。 　　3) 浑善达克沙地3种生境下84种植物叶片渗透势值和含水量，表现出不同功能型上的差异。总体变化趋势为： 深根系 > 浅根系;灌木 > 乔木 > 草本;分布在湿地和丘间低地的植物叶片渗透势和含水量较高，而生长在沙丘上的植物叶片渗透势较低，需要有发达的根系吸收土壤深层的水。不同植物具有独特的水分利用特性，使它们能共存于同一生态系统中。这些不同植物功能型表现出的植物水分生理生态特性，表明浑善达克天然分布的植物群落发育有完善的利用水资源的能力，能够保证在很大降水波动条件下分布有丰富的植物群落和较高的生物生产力，构成该特殊类型生态系统很强的恢复潜力。另外，浑善达克沙地沙丘的存在是该类生态系统恢复弹性较高的另一重要原因。 　　4)本地种与引入种在生理生态上表现出不同的适应能力。在相似的太阳辐射和叶片温度下，引入种旱柳的叶片水势较高，而净光合速率、气孔导度、水分利用效率则较低。这表明它的光合潜能在改变环境中没有正常发挥。同时，引入种较低的最大光化学效率进一步表明它抵抗环境胁迫的能力较低。当土壤水分可利用程度降低而导致水分竞争时，引入种很可能在竞争中被淘汰。因此，在生态恢复中，应尽量避免引入外来种，大量使用本地种。 　　5) 生态恢复不仅是自然科学问题，更重要的是社会经济问题。为了充分认识当地社区的参与对生态恢复的作用，在实验过程中，调查了当地居民自本实验开展以来的思想观念、经济收入和生产效益等变化。在生态恢复中当地社区的积极参与是保证恢复成功与否的关键因素。从发挥“自然力” 和“以人为本”的指导思想出发，在生态恢复中应注重充分利用自然的力量;在管理方面，要以解决社区居民的生产生活实际需求为目标。只有这样，才能保证生态、社会和经济可持续发展。