Evolution of three-dimensional coherent structures in compressible axisymmetric jet

A high order difference scheme is used to simulate the spatially developing compressible axisymmetric jet. The results show that the Kelvin-Helmholtz instability appears first when the jet loses its stability, and then with development of jet the increase in nonlinear effects leads to the secondary instability and the formation of the streamwise vortices. The evolution of the three-dimensional coherent structure is presented. The computed results verify that in axisymmetric jet the secondary instability and formation of the streamwise vortices are the important physical mechanism of enhancing the flow mixing and transition occurring.

Intense upconversion and infrared emissions in Er3+;Yb3+ codoped Lu2 Si O5 and (Lu0.5 Gd0.5)2 Si O5 crystals

High optical quality Lu2SiO5 (LSO) and (Lu0.5Gd0.5)(2)SiO5 (LGSO) laser crystals codoped with Er3+ and Yb3+ have been fabricated by the Czochralski method. Intense upconversion (UC) and infrared emission (1543 nm) are observed under excitation of 975 nm. The luminescence processes are explained and the emission efficiencies are quantitatively obtained by measuring the UC efficiency and calculating the emission cross section. The temperature-dependent optical properties of the crystals are also investigated. Our study indicates that Er3+-Yb3+ : LSO and Er3+-Yb3+: LGSO crystals are promising gain media for developing the solid-state 1.5 mu m optical amplifiers and tunable UC lasers. (c) 2008 American Institute of Physics.

内蒙古半干旱温带草原土壤微生物对环境变化的响应

地处干旱半干旱区的我国北方温带草原是欧亚大陆草原生物区系的重要组成部分，对全球变化敏感。土壤微生物在联系生态系统地上和地下部分起着中枢作用，由于其周转速率快，对环境因子变化响应快速，可用来指示短期内环境因子的变化对生态系统的影响。目前关于内蒙古半干旱温带草原的研究主要集中在生态系统地上部分，对地下尤其是土壤微生物对全球变化及人为干扰的响应研究仍然缺乏。本研究选取位于内蒙古多伦县的代表性的半干旱温带草原，通过对多种环境因子变化及人为干扰下土壤微生物量、呼吸、氮可利用性及转化等参数进行测定，旨在探讨全球变化及人为干扰对土壤微生物的影响，为地上植物群落的响应及生态系统地上与地下部分的联系提供机理解释，研究结果如下： 通过研究土壤微生物生物量和呼吸生长季的动态变化，以及它们对地形、火烧、施用氮肥及其交互作用的响应，结果表明，土壤微生物参数在生长季表现出明显的季节变异。土壤微生物生物量碳(MBC)、氮(MBN)分别在坡下比坡上高出14.8%和11.5%。但是，有机碳微中生物量碳的百分比(Cmic/Corg)以及总氮中微生物量氮的百分比(Nmic/Ntot)分别在坡上比坡下高16.9%和26.2%。微生物呼吸(MR)和代谢熵(qCO2)都不受地形的影响。火烧在整个生长季分别提高MBC和MBN29.8%和14.2%，MR和qCO2 则有降低趋势，尤其是在八月份。火烧在坡上提高Cmic/Corg 和Nmic/Ntot，但是在坡下对二者没有影响。氮肥的施用在第一个生长季对所有土壤微生物指标都没有影响。 草原生态中环境因子的空间和时间变异可以影响土壤微生物以及它们对干扰的响应。通过对地形、火烧、施肥进行三年连续处理和观测土壤微生物指标发现，1)土壤微生物参数有明显的年际变异。2)在相对湿润的年份，土壤微生物量在坡下比坡上高，但是Cmic/Corg和Nmic/Ntot 在坡上高于坡下。但在干旱年份里，所有土壤微生物参数都是在坡下高于坡上，且由于地形引起的差异在干旱年份表现更强烈。MBC、MBN、MR 的变异系数在坡上高，表明土壤微生物量和活性在坡下稳定性高。说明了土壤水分含量在半干旱温带草原调节土壤微生物和其稳定性方面起着重要作用。地形对土壤可利用的氮没有影响。3)每年一次的火烧对土壤微生物量、Cmic/Corg、Nmic/Ntot 有正效应但正效应随处理时间延长和处理次数增加而降低。火烧在在第一年内不论在坡上还是坡下都降低MR，但是在干旱年份里，火烧在坡上降低MR，在坡下提高MR。火烧在第二年里在坡下提高了土壤无机氮含量，但在坡上降低了土壤无机氮含量。在第三年，不论坡上还是坡下，火烧使得土壤无机氮含量降低。4)施用氮肥提高土壤无机氮含量，但是它对土壤微生物参数产生负效应，且负效应随着处理时间延长和处理次数的增加而增强。此外，氮肥增加了MBC、MBN、MR的变异系数。 土壤微生物在生态系统碳氮循环中起着关键作用，但是关于氮素添加是否促进或抑制土壤微生物生物量和活动仍然存在争议。在我国北方温带草原的这项研究目的在于探讨土壤微生物沿着一个施氮梯度的响应。本研究设置了每年一次、连续四年的八个水平(0, 1, 2, 4, 8, 16, 32, 64 g N m-2以尿素形式施入土壤)N处理。并在第三年和第四年测定了土壤微生物生物量碳、氮、磷、微生物呼吸和代谢熵、土壤无机氮、净氮矿化和硝化。大多数测定的微生物参数都在低施氮处理下有所增加，相反在高施氮处理下降低。在取样测定的两年中，对土壤微生物生长和活动的最适施氮量大致为2 g N m-2 y-1；而施氮的阈值在16 和32 gN m-2 y-1之间，在此阈值之上，土壤pH、微生物生物量、微生物呼吸、Cmic/Corg、Nmic/Ntot 急剧降低，相反，土壤无机氮、净氮矿化和硝化急剧增加。土壤微生物对低施氮处理和高施氮处理的特异性响应(Differential Response)可能是由于微生物碳氮限制的转换、以及高施氮处理下土壤pH值降低的毒害影响而引起的。本研究中观察到的土壤微生物沿着施氮梯度的非线性响应有助于解决不同报道及不同生态系统中氮素添加对土壤微生物影响的争议。 气候变化将显著影响陆地生态系统的碳循环。以2005年4月开始的一项野外控制实验为平台，检验我国北方半干旱典型草原土壤和微生物呼吸以及微生物生物量对试验增温和增加降水的响应。在3 个实验年份内(2005-2007 年)测定了整个生长季节的土壤呼吸、微生物呼吸、微生物生物量碳和微生物生物量氮。结果表明，1)受到降水年际波动的影响，土壤和微生物呼吸以及微生物生物量均存在明显的年际变化。2)实验室内沿着一个水分梯度的培养实验揭示了微生物呼吸对温度的响应受到低土壤水分含量的限制。3)在三年时间内，试验增温引起土壤和微生物呼吸以及微生物生物量的显著降低，说明试验增温通过加剧土壤水分胁迫的间接负效应大于温度增加的直接正效应。试验增温所引起的蒸发散的增加导致土壤水分可利用性减少到某一胁迫阈值(Threshold)之下，并因此抑制了植物生长、根系和微生物活动。4)降水增加显著刺激了土壤和微生物呼吸以及其它微生物参数，而且这种正效应随着时间而增强。研究结果表明：在半干旱温带草原，土壤水分在调节土壤和微生物呼吸以及微生物生物量及其对气候变化的响应方面所起的作用比温度更为重要。比较温带草原土壤呼吸与总初级生产力的相对变化显示，相对于光合碳固定而言，增温导致更多而增雨引起较少的呼吸碳损失。这一发现说明：除非降水增加，气候变暖情形下，我国北方的干旱半干旱温带草原将可能作为一个净的碳源。

日本花鲈细胞色素b基因部分序列的研究

首次报道日本花鲈线粒体DNA细胞色素b基因片段的PCR扩增及其序列测 定。得到410bp的碱基序列，其A、T、G、C含量分别为99bp(24．15哟、113bp(27．56旧、 72bp(17．56嗡、126bp(30．73哟，与其他鱼类相同基因片段碱基序列含量相似。

1.55 mu m Ge islands resonant-cavity-enhanced detector with high-reflectivity bottom mirror

A 1.55 mum Ge islands resonant-cavity-enhanced (RCE) detector with high-reflectivity bottom mirror was fabricated by a simple method. The bottom mirror was deposited in the hole formed by anisotropically etching in a basic solution from the back side of the sample with the buried SiO2 layer in silicon-on-insulator substrate as the etch-stop layer. Reflectivity spectrum indicates that the mirror deposited in the hole has a reflectivity as high as 99% in the range of 1.2-1.65 mum. The peak responsivity of the RCE detector at 1543.8 nm is 0.028 mA/W and a full width at half maximum of 5 nm is obtained. Compared with the conventional p-i-n photodetector, the responsivity of RCE detector has a nearly threefold enhancement. (C) 2004 American Institute of Physics.

1.55 mu m Ge islands resonant-cavity-enhanced narrowband detector

The high quality Ge islands material with 1.55 mu m photo-response grown on Sol substrate is reported. Due to the modulation of the cavity formed by the mirrors at the surface and the buried SiO2 interface, seven sharp and strong peaks with narrow linewidth are found. And a 1.55 mu m Ge islands resonant-cavity-enhanced (RCE) detector with narrowband was fabricated by a simple method. The bottom mirror was deposited in the hole formed by anisotropically etching, in a basic solution from the backside of the sample with the buried SiO2 layer in silicon-on-insulator substrate as the etch-stop layer. Reflectivity spectrum indicates that the mirror deposited in the hole has a reflectivity as high as 99% in the range of 1.2-1.65 mu m. The peak responsivity of the RCE detector at 1543.8 nm is 0.028 mA/W and a full width at half maximum of 5 nm is obtained. Compared with the conventional p-i-n photodetector, the responsivity of RCE detector has a nearly threefold enhancement.

虚拟环境下基于语义的三维交互技术

自然、高效的三维交互技术是虚拟现实系统成功应用的关键．现有的交互技术主要是从几何层次上考虑如何有效实现交互任务，而对面向高层应用的交互任务的支持还不够．借鉴人类在真实世界中的认知原理，虚拟环境中的交互对象不仅具有外观意义上的几何属性，而且包含了与交互有关的规则、约束和供给等语义属性，这些虚拟对象称为语义对象．在系统导航、对象选择／操作等交互任务的执行中，通过语义对象可以实现高层交互语义的封装和解析．从应用角度提高交互技术的效率和可用性，为用户提供“直接操纵”之上的面向高层语义的交互隐喻．屏蔽交互技术的底层实现细节，使用户专注于应用领域相关的高层交互控制。

铟掺杂ZnO体单晶的生长及其性质

研究了In掺杂n型ZnO体单晶的化学气相传输法生长和材料性质.利用霍尔效应、X射线光电子能谱、光吸收谱、喇曼散射、阴极荧光谱等手段对晶体的特性和缺陷进行了分析.掺In后容易获得浓度为10~(18)～10~(19)cm~(-3)的n型ZnO单晶,掺入杂质的激活效率很高.随着掺杂浓度的提高,ZnO单晶的带边吸收和电学性质等发生明显的变化.分析了掺In-ZnO单晶的缺陷及其对材料性质的影响.

不同放牧强度下高山草甸生态系统碳氮分布格局和循环过程研究

本研究针对川西北高山草甸缺乏科学管理，过度放牧导致草场退化，并由此引发的一系列生态环境问题，选取红原县瓦切乡1996 年草地承包后形成的四个放牧强度草场，即不放牧、轻度（1.2 头牦牛hm-1）、中度（2.0 头牦牛hm-1）和重度放牧（2.9 头牦牛hm-1），作为研究对象，研究了不同放牧强度对草地植物-土壤系统中碳、氮这两个最基本物质的分布格局和循环过程的影响，并探讨了放牧干扰下高山草甸生态系统的管理。 1．放牧对草地植物群落物种组成，尤其是优势种，产生了明显的影响。不放牧、轻度、中度和重度放牧草地群落物种数分别为22，23，26，20 种，群落盖度分别是不放牧96.2%＞中度93.6%＞轻度89.7%＞重度73.6%。随放牧强度的增加， 原植物群落中的优势种垂穗鹅冠草（ Roegneria nutans ）、发草（Deschampsia caespitosa）和垂穗披碱草（Elymus nutans）等禾草逐渐被莎草科的川嵩草（Kobresia setchwanensis）和高山嵩草（Kobresia pygmaea）所取代成为优势种。同时，随放牧强度的增加，高原毛茛（Ranunculus brotherusii）、狼毒（Stellera chamaejasme）、鹅绒委陵菜（Potentilla anserina）和车前（Plantagodepressa）等杂类草的数量也随之增加。 2．生长季6～9 月份，草地植物地上和地下生物量（0～30cm）都是从6 月份开始增长，8 月份达到最高值，9 月份开始下降。每个月份，通常地上生物量以不放牧为最高，重度放牧总是显著小于不放牧；地下生物量随放牧强度的增加表现为增加的趋势，通常重度和中度放牧显著高于不放牧和轻度放牧草地。不放牧、轻度、中度和重度放牧草地6～9 月份4 个月的植物总生物量平均值分别是1543、1622、2295 和2449 g m-2，但随放牧强度的增加越来越来多的生物量被分配到了地下部分，地下生物量占总生物量比例的大小顺序分别是重度88%＞中度82%＞轻度76%＞不放牧69%。生物量这种变化主要是由于放牧使得群落优势种发生改变而引起的，其分配比例的变化体现了草地植物对放牧干扰的适应策略。 3．植物碳氮贮量的季节变化类似与生物量的变化。每个月份，不同放牧强度间植物地上碳氮的贮量有所不同，一般重度放牧会显著减少植物地上碳氮贮量。植物根系(0～30cm)碳氮贮量随放牧强度的增加表现为增加的趋势，通常重度和中度放牧显著高于不放牧和轻度放牧草地。不放牧、轻度、中度和重度放牧草地6～9 月份4 个月的植物总碳平均值分别是547、586、847 和909 g m-2，根系碳贮量占植物总碳的比例大小顺序分别是重度88%＞中度82%＞轻度76%＞不放牧69%；放牧、轻度、中度和重度放牧草地6～9 月份4 个月的植物总氮平均值分别是17、17、23 和26 g m-2，根系氮贮量占植物总氮的比例大小顺序分别是重度79%＞轻度71%＞中度70%＞不放牧65%。 4. 土壤有机碳贮量（0～30cm）的季节变化表现为7 月份略有下降，8 月开始增加，9 月份达到的最大值。土壤氮贮量的季节变化表现为随季节的推移逐渐增加的趋势。增加的放牧强度不同程度的增加土壤有机碳氮的贮量。不放牧、轻度、中度和重度放牧6～9 月份4 个月的土壤有机碳贮量的平均值分别是9.72、10.36、10.62 和11.74 kg m-2，土壤氮贮量分别为1.45、1.56、1.66 和1.83 kg m-2。土壤中有机碳（氮）的贮量都占到了植物-土壤系统有机碳（氮）的90%以上，但不同放牧强度之间的差异不明显。 5. 土壤氮的总硝化和反硝化，温室气体N2O 和CO2 的释放率的季节变化表现为从6 月份开始增加，7 月份达到最大值，8 月份开始下降，9 月份降为最小值。增加的放牧强度趋向于增加土壤氮的总硝化和反硝化作用，温室气体N2O和CO2 的释放率，通常情况下，中度放牧和重度放牧显著地加强了这些过程。 6．垂穗鹅冠草（Roegneria nutans）和川嵩草（Kobresia setchwanensis）凋落物在不同放牧强度下经过1 年的分解，两种凋落物的失重率及其碳氮的损失率3都随放牧增加表现为增加的趋势。在同一放牧强度下，川嵩草凋落物的失重率和碳氮的损失率都高于垂穗鹅冠草凋落物。 7. 尽管重度放牧显著增加了土壤碳氮的贮量，但同时也显著降低了植被群落盖度，降低了植物地上生物量，因此，久而久之会减少植物向土壤中的碳氮归还率；与不放牧和轻度放牧相比，重度放牧又显著增加了土壤CO2 和NO2 的排放量，这是草地生态系统碳氮损失的重要途径。由此可见，对于这些地处青藏高原的非常脆弱的高山草甸生态系统，长期重度放牧不仅导致植物生产力降低，而且将导致草地生态系统退化，甚至造成土壤中碳氮含量减少。 Long-term overgrazing has resulted in considerable deterioration in alpine meadowof the northwest Sichan Province. In order to explore management strategies for thesustainability of these alpine meadows, we selected four grasslands with differentgrazing intensity (no grazing-NG: 0, light grazing-LG: 1.2, moderate grazing-MG: 2.0,and heavy grazing-HG: 2.9 yaks ha-1) to evaluate carbon, nitrogen pools and cyclingprocesses within the plant-soil system in Waqie Village, Hongyuan County, Sichuan Province. 1. Grazing obviously changed the plant species composition, especially ondominant plant species. Total number of species is 22, 23, 26, and 20 for NG, LG, MGand HG, respectively. Vegetation coverage under different grazing intensity ranked inthe order of 96.2% for HG＞93.6% for MG＞89.7% for LG＞73.6% for NG. Thedominator of HG community shifted from grasses-Roegneria nutans andDeschampsia caespitosa dominated in the NG and LG sites into sedges-Kobresiapygmaea and K. setchwanensis. At the same time, with the increase of grazingintensity, the numbers of forbs, such as Ranunculus brotherusii, Stellera chamaejasme,Potentilla anserine and Plantago depressa, increased with grazing intensity. 2. Over the growing season, aboveground and belowground biomass showed a 5single peak pattern with the highest biomass in August. For each month, abovegroundbiomass usually was the highest in the NG site and lowest in the HG site.Belowground biomass showed a trend of increase as grazing intensity increased and itwas significantly higher in the HG and MG site than in the NG and LG sites. Totalplant biomass averaged over the growing season is 1543, 1622, 2295 and 2449 g m-2for NG, LG, MG and HG, respectively. The proportion of biomass to total plantbiomass for NG, LG, MG and HG is 88%, 82%, 76% and 69%, respectively. Higherallocation ratio for is an adaptive response of plant to grazing. 3. Carbon and nitrogen storage in plant components followed the similar seasonalpatterns as their biomass under different grazing intensities. Generally, heavy grazingsignificantly decreases aboveground biomass carbon and nitrogen compared to nograzing. Carbon and nitrogen storage in root tended to increase as grazing increasedand they are significantly higher in the HG and MG sites compared to the LG and NGsite. Total Carbon storage in plant system averaged over the growing season is 547,586, 847 and 909 g m-2 for NG, LG, MG and HG, respectively, while 17, 17, 23 and 26g m-2 for nitrogen. The proportion of carbon storage in root to total plant carbon forNG, LG, MG and HG is 88%, 82%, 76%, 69%, respectively, while 65%, 71%, 70%and 79% for nitrogen. 4. Carbon storage in soil (0-30cm) decreased slightly in July, then increased inAugust and peaked in September. Nitrogen storage in soil tended to increase withseason and grazing intensity. Total Carbon storage in soil averaged over the growingseason is 9.72, 10.36, 10.62 and11.74 kg m-2 for NG, LG, MG and HG, respectively,while 1.45, 1.56, 1.66 and 1.83 for nitrogen. The proportion of carbon (nitrogen)storage in soil to plant-soil system carbon (nitrogen) storage for NG, LG, MG and HGis more than 90%, which is not markedly different among different grazing intensities. 5. Gross nitrification, denitrification, CO2 and N2O flux rates in soil increasedfrom June to July and then declined until September, all of which tended to increasewith the increase of grazing intensity. Generally, heavy and moderate grazing intensitysignificantly enhanced these process compared to no and light grazing intensity. 6. After decomposing in situ for a year, relative weight, carbon and nitrogen loss in the litter of Roegneria nutans and Kobresia setchwanensis tended to increase asgrazing intensity increased. Under the same grazing intensity, relative weight, carbonand nitrogen loss in the litter of Kobresia setchwanensis were higher than these in thelitter of Roegneria nutans. 7. Although heavy grazing intensity resulted in higher levels of carbon andnitrogen in plant and soil, it decreased vegetation coverage and aboveground biomass,which are undesirable for livestock production and sustainable grassland development.What is more, heavy grazing could also introduce potential carbon and nitrogen lossvia increasing CO2 and N2O emission into the atmosphere. Grazing at moderateintensity resulted in a plant community dominated by forage grasses with highaboveground biomass productivity and N content. The alpine meadow ecosystems inTibetan Plateau are very fragile and evolve under increasing grazing intensity by largeherbivores; therefore, deterioration of the plant-soil system, and possible declines insoil C and N, are potential without proper management in the future.