不同水肥处理对尾叶桉苗木生长及生物量分配的影响

为筛选适宜不同水肥条件的尾叶桉（Eucalyptus urophylla）优良无性系,以34个尾叶桉无性系为研究对象,采用2因素（水分、养分）3水平完全随机区组设计,对不同水肥处理下18个月的尾叶桉苗木生长和各器官生物量进行方差分析和遗传参数评估。结果表明：除少数性状外,尾叶桉生长（树高、地径）和生物量（主干、侧枝、根）在不同区组、水分、养分、水分×养分互作及无性系的差异间均达到显著或极显著水平,表明水分、养分和无性系会影响尾叶桉生长和各器官生物量大小。在水分和养分组合处理下,尾叶桉生长和各个器官生物量在组合33（高水高肥）和组合32（高水中肥）处理下表现较好。全株总鲜质量在组合32处理最大,与组合11处理相比增加了135.70%。主干、根、叶和总生物量的鲜质量与干质量相关系数最高,相关系数在0.90以上。无性系在树高、地径和生物量的方差分量为4.28~31 255.80,大部分性状的单株重复力在0.15以上,且都达到了显著水平。以15%无性系入选率,采用BLUP预测的尾叶桉无性系基因型值筛选出ZQUB39和ZQUC23尾叶桉在水分和养分梯度较低的土壤环境中生长较好,UD42、LDUC1和ZQUA3在水分和养分梯度较高的土壤环境中生长较好。这些优良无性系可能在多种立地进行推广种植。     

新疆呼图壁种牛场地区13种优势植物水溶性盐分的含量特点及数量分析

通过对新疆呼图壁种牛场地区１３种耐盐植物水溶性盐分含量的分析,结果阐述了盐分分布和积累的特点：１）大部分植物在盐分含量水平上是：Ｎａ＾＋〉Ｋ＾＋〉Ｍｇ＾２＋〉Ｃａ＾２＋,Ｃｌ＾－〉ＳＯ４＾２－〉ＨＣＯ３＾－〉ＣＯ３＾２－,Ｎａ＾＋超过２００００μｇ／ｇ,Ｃａ＾２＋不足８００μｇ／ｇ;Ｃｌ＾－达４．１６％,ＣＯ３＾２－仅为０．１１％。全盐量平均为２５．８１％;２）ＣＯ３＾２－、ＨＣＯ３＾－和Ｃａ＾２     

缓激肽对大鼠背根神经节分离神经元ATP激活电流的调制作用

在新鲜分离大鼠背根神经节（ＤＲＧ）的５６个细胞标本上,应用全细胞膜片箝技术进行记录。胞外加缓激肽（ＢＫ,１０＾－６￣１０＾－４ｍｏｌ／Ｌ）引坊的ＤＲＧ细胞膜反应结果如下：（１）７１．４％的细胞为内向电流,其电流反应的幅值具有明显的浓度信赖性;（２）１２．５％的细胞为外向电流;（３）１６．１％的细胞未引起可检测的膜反应,单独给予ＡＴＰ（１０＾－６￣１０＾－３ｍｏｌ／Ｌ）在大多数受栓细胞（５４／５６）     

裂叶沙参个体生长动态研究（1）：一个生长季地上部分的生长

在不同生境条件下的固定样地内,观察分析了裂叶沙参种群的地上部分在一个生长季的生长过程和物侯特点。生长于灌木群落下,裂叶沙参地上部分生物量生长（ｙ,ｇ）与时间（ｘ、ｄ）的关系可以用公式：ｙ＝０．２８７２－０．０１８７ｘ＋０．０００９ｘ＾２表示;地上各器官茎、叶、花枝、花芽、花和果的生物量（ｙ,克）与生长时间（ｘ,天）的关系可以用公式：ｙ＝ｂ０＋ｂ１ｘ＋ｂ２ｘ＾２表示。从４月１０日到８月１５日的速生期     

外加氮源对杉木叶凋落物分解及土壤养分淋失的影响

采用原位（Ｉｎ ｓｉｔｕ）模拟实验方法研究了外加Ｎ源对杉木叶凋落物分解及土壤养分淋失的影响,结果表明,施加ＮＨ＾＋４－Ｎ时,杉木叶凋落物的失重率与对照（未加任何Ｎ的处理）相比,没有差异：而施加ＮＯ＾－１－Ｎ时,使杉木叶凋落物分解速率显著提高（ｐ＝０．０５,达１０％以上,与施加ＮＨ＾＋４－Ｎ相比,施加ＮＯ＾－３－Ｎ明显促进了杉木叶凋落物的分解（ｐ＝０．０５）。施加ＮＨ＾＋４－Ｎ和ＮＯ３＾－－Ｎ会产生     

尖叶拟船叶藓营养元素生殖配置格局

为了揭示尖叶拟船叶藓营养元素生殖配置规律,本文对其12种营养元素的生殖配置格局和季节动态进行了研究。其结果如下：成熟孢子体的生物量配置为6．67％;在成熟孢子体中12种营养元素的含量顺序是：C（452mg／g）〉N（35mg／g）〉K（8439．9μg／g）〉Ca（7012．9μg／g）〉P（2129．2μg／g）〉Mg（1482．9μg／g）〉Na（432．9μg／g）〉Mn（196．3μg／g）〉Fe（177．7μg／g）〉Al（174．8μg／g）〉Zn（68．1μg／g）〉Cu（19．4μg/g）;成熟孢子体中营养元素生殖配置顺序是：K（17．7％）〉P（15．1％）〉Cu（13．3％）〉N（11．6％）〉Na（10．5％）〉Mn（7．8％）〉Zn（7．5％）〉C（6．9％）〉Mg（6．8％）〉Ca（5．4％）〉Fe（1．3％）〉Al（1．2％）。     

山西南部地木耳群落特征及其资源分布的研究

采用样方法对不同生境中地木耳分布规律进行了研究;分析了地木耳的群落特征及其生物量,结果表明：（１）群落种类组成,共有３８种,３４属,２１科,单科单种１４种;（２）群落垂直结构简单,只有灌木层、草本层和地被层;（３）地木耳平均生物量为１０ｋｇ／ｈｍ＾２,干重７．３ｋｇ／ｈｍ＾２,湿重１４０ｋｇ／ｈｍ;（４）地木耳的自然含水量４２％,持水量一８．６％,在海拔６００－８００ｍ之间,地木耳生物量最大;（５     

巨尾桉的引种与栽培

巨尾桉（ Ｅｕｃａｌｙｐｔｕｓ ｇｒａｎｄｉｓ×Ｅ.ｕｒｏｐｈｙｌｌａ）原产巴西,是采用巨桉为母本、尾叶按为父本经人工授粉杂交培育成功的树种。它材质良好,用途广,生长极迅速,在国外被推荐为非常有栽培前途的桉属树种之一。因此,我们在广东惠州市引种了组培苗无性系巨尾桉。经４年的生长后,林分平均树高１８．２３米,平均胸径１４．００厘米,林相整齐,显示出无性系巨尾桉速生、丰产的优越性。现将配套技术总结如下： ｌ．坚持引种地点的气候条件与原产地相似的原则引种种源自然分布于印度尼西亚的弗洛勒斯、伟塔、阿洛等一些…     

西双版纳热带季节雨林6种树种幼树在林下的光合作用

本文研究了西双版纳热带季节６种树种幼树在林下的光合作用。６种树种的叶单位重量面积为１６．０２－２８．６７ｍ＾２．ｋｇ＾－１、光合作用光补偿点为３．８－６．５μｍｏｌ．ｍ＾－２．ｓ－１、光量子产率为０．０１８－０．０４４、最大净光合速率为１．９７－４．７１μｍｏｌＣＯ２．ｍ＾－２．ｓ＾－１ ４６．９９－９２．３３μｍｏｌＣＯ．ｋｇ＾－１．ｓ＾－１（以单位叶干重表示）、暗呼吸速率为０．１５－０．３１μ     

接种促生菌对尾巨桉—降香黄檀混作幼苗光合生理特性和生长的影响

该试验以盆栽尾巨桉和降香黄檀幼苗为材料,设置BM处理(尾巨桉接种巨大芽孢杆菌,降香黄檀不接种)、RJ处理(降香黄檀接种大豆根瘤菌,尾巨桉不接种)以及对照组(CK,尾巨桉和降香黄檀均不接菌),探究接种2种促生细菌对尾巨桉-降香黄檀混作幼苗的光合生理、生长和生物量积累及分配的影响,明确在混交体系中接种促生菌对促进植物生长的优势。结果显示:(1)BM处理显著降低尾巨桉的叶绿素含量(P<0.05),BM和RJ处理均提高了尾巨桉和降香黄檀的苗高、地径以及叶片的氮素含量、净光合速率、气孔导度、蒸腾速率,但降低了胞间CO_(2)浓度。(2)RJ处理显著提高了尾巨桉及降香黄檀叶片和全株生物量,BM处理仅显著提高降香黄檀根、茎、叶、全株的生物量和尾巨桉叶的生物量(P<0.05)。(3)各接菌处理条件下2种植物幼苗叶片净光合速率与其生物量呈显著正相关。研究表明,接种大豆根瘤菌和巨大芽孢杆菌均促进尾巨桉-降香黄檀混作幼苗的生理代谢,2种促生菌能通过增强光合作用来促进植株生物量的累积;从植株生物量变化来看,接种菌株的利他作用更明显。     

The life history and production of Chaoborus punctipennis (Diptera: Chaoboridae) in Lake Norman,North Carolina,U.S.A.

A study of the life history and production of Chaoborus punctipennis (Say) in Lake Norman, North Carolina, U.S.A. was conducted from February 1978 through January 1979. Four sublittoral (～8 m) and two profundal (～30 m) locations were sampled. Larvae and pupae were collected with a modified Petersen grab and a plankton net, and adults were collected with emergence and light traps. Based on larval, pupal, and adult collections, there appear to be two generations per year — an overwintering spring generation and a summer generation. Annual dry weight standing stock biomass, dry weight production, and P/ B ratio were estimated from each sampling location and depth zone. Production was estimated by the size-frequency method. Standing stock biomass (30.9 mg · m^-2) and production (170.8 mg · m^-2) were highest in the profundal zone. In the sublittoral zone, standing stock biomass and production were 4.7 mg · m^-2, and 29.6 mg · m^-2, respectively. Annual P/ B ratios in the profundal and sublittoral zones were 5.5 and 6.3, respectively.     

Distribution, production and role of aquatic macrophytes in a southern Michigan marl lake

A typical marl lake of the Upper Great Lakes region has very few quantitatively important aquatic macrophytes. The macrophytes, however, dominate the total primary production of the lake. Submersed vegetation is extremely sparse on the shallow (less than I m) marl bench that characterizes the littoral of these lakes, and is completely dominated by one. little-known species (Scirpus subterminalis Torr.) between 1 and 7 m. A detailed investigation of the spatial and seasonal distribution of macrophytic species and biomass showed that S. subterminalis strongly dominated the lake (79% of total biomass). S. suhterminalis represented an almost pure stand (to 200 g m^?2 mean annual ash-free dry weight) at all times of the year at intermediate depths of macrophytic growth (1–6 m). Two species of Chara (of eight varieties and forms) were present in significant quantities (12% of total biomass; to 100 g m^?2) but were severely limited to shallow depths (0-S-l m) and protected areas. Several annual submersed angiosperms were present (9% of total biomass), but only two species were quantitatively important. Potamogeton illinoensis Morong. and P. praelongus Wulfen formed brief summer peaks (less than 100 g m^?2) at 3 and 4–6 m, respectively. A striking feature of the seasonal biomass distribution of Scirpus subterminalis was the higher, viable biomass (to 150g m^?2) throughout the winter under ice cover. Cyclic fluctuations of the S. subterminalis populations were discerned at different depths, each with different periodicities. The population at 2 m exhibited a fall peak; that at 4 m had a summer maximum. The lowest overall biomass of S. subterminalis occurred in the 2 m population in June. Chara populations at 0–2 m also exhibited a relatively constant biomass throughout the year. The appearance of Nitella at 7 m in July-October and of Chara at 5 m in September-October was interpreted as an interaction between light, thermal, and carbon stratification. Estimates of macrophytic productivity of perennial (‘evergreen’) species populations whose biomass remains relatively constant throughout the year were made employing several different methods of calculation and turnover factors. All methods resulted in productivity estimates in good agreement with the conservative value of 178 g m^?2 year^?1 for the entire lake. In comparison to the other components (phyto-planktonic, epiphytic and epipelic algae) of the primary production of Lawrence Lake, the aquatic macrophytes constituted a major portion (anuual mean 82·77 g C m^?2 year^?1 or 48·3 %) of the total production of the lake. The low diversity but relatively high quantitative importance of macrophytes in marl lakes is attributed to an adverse dissolved inorganic and organic chemical milieu which inhibits phytoplanktonic production and allows only certain adapted macrophytes to develop strongly. The phenomenon of perennial biomass levels throughout the year is believed to be much more common than previously suspected and has iikely resulted from adaptations of submersed macrophytes to ameliorated conditions of water and temperatures relative to the terrestrial situation in winter.     

Influence of pH and impeller tip speed on the cultivation of<Emphasis Type="Italic">Bifidobacterium pseudocatenulatum</Emphasis> G4 in a milk-based medium

Biomass production ofBifidobacterium pseudocatenulatum G4 in a milk-based medium was carried out in a 2- and 10-L stirred tank fermenters. The effects of impeller tip speed (0.28, 0.56, and 0.83 m/s) and pH control (6.0, 6.5, and 7.0) on the biomass production were investigated. The growth performance in the 2-L fermenter was significantly improved when the impeller tip speed was held constant at 0.56 m/s and the pH was controlled at 6.5. These conditions yielded a maximum biomass of 1.687×10⁹ cfu/mL, a maximum specific growth rate of 0.504 h⁻¹, a biomass productivity of 9.240×10⁷ cfu/mL·h, and a biomass yield of 9.791×10¹⁰ cfu/g lactose. The consumption of milk lactose resulted in the accumulation of 7.353 g/L acetic acid and 6.515 g/L lactic acid, with an acetic:lactic ratio of 1.129. Scale-up of the fermentation process to a 10-L fermenter based on a constant impeller tip speed of 0.56 m/s yielded reproducible results with respect to biomass production and cell viability.     

Life cycle assessment of biomass production in microalgae compact photobioreactors

This paper presents a life cycle assessment (LCA) of industrial scale microalgae biomass production in compact photobioreactor (PBR) systems (2 × 5 × 8 m) for supplying biofuel/electricity generation processes and synthesis of new materials. Other objectives are as follows: (i) to compare the impact of various raw materials, substances, and services; and (ii) to evaluate environment‐relevant aspects of the proposed system as compared to microalgae raceway ponds. The life cycle inventory assessment shows that (i) only atmospheric CO₂ is used for PBR microalgae cultivation, whereas in raceway ponds, injection of CO₂ from fossil origin is largely required to allow for microalgae growth; and (ii) the PBR daily production rate of dry biomass is currently at 1.5 kg m^?3 day^?1 for each PBR, which is 12.82 times larger than the reported average 0.117 kg m^?3 day^?1 raceway ponds production. It is found that in general the association of the effects of the production of steel, PVC, and the packaging contribute to more than 85% of the total impact in each analyzed category. Therefore, to achieve PBR biomass production impact reduction and sustainability, PVC and steel utilization need to be minimized, as well as packaging materials. Based on the PBR LCA results, that is, due to no CO₂ injection from fossil origin and low area occupation, it is expected that high density production of truly renewable microalgae biomass could be obtained from PBR systems.     

Epiphytes from a deep-water characean meadow in an oligotrophic New Zealand lake: species composition,biomass and photosynthesis

1. The epiphytic flora of a characean meadow in Lake Coleridge, a deep, oligotrophic lake on the South Island of New Zealand, was dominated by diatoms, particularly Eunotia pectinalis and Achnanthes minutissima. The meadows occupied a depth range from 5 to 30 m. Adnate taxa predominated at all depths below 5 m, while increased taxonomic diversity at 5 m resulted from an increased abundance of erect taxa, including chlorophytes and stalked diatoms. 2. Seasonal changes in epiphyte biomass were followed using artificial substrata and by estimating epiphyte chlorophyll a concentration on host plants. The latter required development of a novel technique utilizing the consistent relationship between fucoxanthin and chlorophyll a concentrations in the epiphyton. Epiphyte chlorophyll a on host plants varied with depth and host species between 0.1 and 0.3 mg g^–1 dry weight. Maximum epiphyte biomass was at 10–15 m depth. At depths of 15 m and less, epiphyte chlorophyll a reached a maximum of ≈ 200–300 mg m^–2 in mid-summer, while at greater depths maximum biomass was less and coincided with a period of clear water in spring. 3. Photosynthetic carbon fixation was estimated from photosynthesis–radiation curves and estimates of radiation flux at sampling depths. At depths greater than 10 m, variability of the vertical extinction coefficient of lake water rather than seasonal fluctuations in incident radiation were responsible for determining the temporal pattern of production. Chlorophyll a-specific photosynthesis was estimated to peak in summer at 5 m (8 mg mg^–1 day^–1), and in spring at all other depths. 4. Annual epiphyte production was estimated as 27 g C m^–2 year^–1 at 5 m depth, falling to 15 g C m^–2 year^–1 at 15 m and 1 g C m^–2 year^–1 at 30 m. Areal biomass changes tended to be temporally but not quantitatively coupled to estimated in situ photosynthesis, and we hypothesize that epiphyte biomass may have been controlled by grazing gastropod snails.     

Winter condition of marine plankton populations in Saanich Inlet,B.C., Canada. II. Micro-zooplankton

The abundance of micro-zooplankton (< 200 μm in size) was monitored weekly in Saanich Inlet throughout the winter, 1975–1976. Ciliate protozoans and metazoan nauplii were the major groups, with the former largely distributed in the top 5 m of the water column and the latter above 15 m. Average biomass throughout the winter was 3.1 mgC/m² for ciliates above 5 m and 5.5 mgC/m² for nauplii above 25 m, which made up 3.2 and 5.7% of the average phytoplankton biomass, respectively. They could consume over 30% of the phytoplankton production. Mesodinium sp. was an another abundant ciliate, but possibly a phyto-ciliate, with an average biomass of 8.2 mgC/m² above 5 m. Major energy flow at lower trophic levels during the winter was characterized by a ‘nanoflagellate → micro-zooplankton’ system which was comparable with the ‘centric diatoms → macro-zooplankton’ system occuring commonly at the other seasons in the inlet.     

Trophic structure and productivity of the lagoonal communities of Tikehau atoll (Tuamotu Archipelago,French Polynesia)

Carbon standing stocks and fluxes were studied in the lagoon of Tikehau atoll (Tuamotu archipelago, French Polynesia), from 1983 to 1988.The average POC concentration (0.7–2000 µm) was 203 mg C m^–3. The suspended living carbon (31.6 mg C m^–3) was made up of bacteria (53%), phytoplankton < 5 µm (14.2%), phytoplankton > 5 µm (14.2%), nanozooplankton 5–35 µm (5.7%), microzooplankton 35–200 µm (4.7%) and mesozooplankton 200–2000 µm (7.9%). The microphytobenthos biomass was 480 mg C m^–2.Suspended detritus (84.4% of the total POC) did not originate from the reef flat but from lagoonal primary productions. Their sedimentation exceeded phytobenthos production.It was estimated that 50% of bacterial biomass was adsorbed on particles. the bacterial biomass dominance was explained by the utilisation of 1) DOC excreted by phytoplankton (44–175 mg C m^–2 day ^–1) and zooplankton (50 mg Cm^–2 day^–1)2) organic compounds produced by solar-induced photochemical reactions 3) coral mucus.50% of the phytoplankton biomass belongs to the < 5 µm fraction. This production (440 mg C m^–2 day^–1) exceeded phytobenthos production (250 mg C m^–2 day^–1) when the whole lagoon was considered.The zooplankton > 35 µm ingested 315 mg C m^–2 day^–1, made up of phytoplankton, nanozooplankton and detritus. Its production was 132 mg C m^–2 day^–1.     

Spatial distribution and biomass of root nodules in a naturally regenerated stand of Alnus hirsuta (Turcz.) var. sibirica

To estimate nodule biomass of Alnus hirsuta var. sibirica, an N₂-fixing tree species, we examined the distribution pattern and size structure of nodules in a 17 to 18 year old stand naturally regenerated after disturbance by road construction in Japan. Nodules were harvested within 1 m from the outer edge of stems of plants with different sizes on four occasions from June to October. The diameter of the subtending root at the base of each nodule and nodule dry weight were measured in 20 cm increments outwards from the base of each stem. Horizontal distribution of nodules around each tree varied greatly among tree diameters at 1.3 m (dbh) within the even-aged stand. In particular, smaller individuals had a concentrated distribution of nodules close to the stem. Nodule abundance occurred further from the stems with increasing tree size. Nodule biomass within 1 m from the outer edge of individual stems increased with tree size ([nodule biomass] = 0.442 [dbh]^2.01, R ²?=?0.747, P?<?0.05). By using the relationship, nodule biomasses were estimated to be 84.1 kg ha^?1. These results suggest that it is necessary to take into account tree size and patterns of tree distribution in nodule biomass estimates.     

Abundance and biomass estimates of the benthic fauna in Admiralty Bay,King George Island,South Shetland Islands

Summary Quantitative benthic samples were collected along three transects in Admiralty Bay, King George Island, South Shetlands. At each of a total of 18 stations, between 15 and 250 m depth, we took 3 replicate samples with a van Veen grab. Animals collected were classed into major groups. Abundance and biomass per m² was calculated for each sampling site. Considerable population densities and high biomass values were found. Most abundant groups were Bivalvia, Polychaeta and Amphipoda, whereas the largest part of the biomass was due to Ascidiacea, Ophiuroidea, Echinoidea, Polychaeta and Bivalvia. The maximum abundance recorded was 36,000 ind m^-2 while the average was approximately 6500 ind m^-2. Maximum biomass was over 2400 g m^-2 with an average of ca. 700 g m^-2. The contribution to the total biomass by groups such as the Oligochaeta, Cumacea and Tanaidacea was higher in the inner shallow part of Admiralty Bay (Ezcurra Inlet) than in the deeper areas of the bay. Our results confirm the reports on an unusually high density and biomass of the Antarctic sublittoral benthic fauna. Sessile suspension feeders belonging to the Bivalvia, Ascidiacea, sedentary Polychaeta, and vagile scavengers of the Ophiuroidea, Amphipoda and errant Polychaeta are the most significant groups in the Antarctic Ecosystem. The total benthic biomass in Admiralty Bay, based on the present preliminary quantitative data, was estimated to be over 600,000 t. This value is probably still an underestimate.     

The influence of coastal upwelling on the distribution of Calanus chilensis in the Mejillones Peninsula (northern Chile): implications for its population dynamics

A field experiment was carried out in October 1998 during active upwelling in a coastal area off the Mejillones Peninsula (23° S). Zooplankton was sampled at day and night, during two subsequent days at 4 stations inside and outside of the upwelling plume. Three depth strata were sampled: 0–20 m, 20–80 m and 80–200 m. Oceanographic data were obtained in a grid of 23 stations using a CTDO, a fluorometer and a Doppler current meter. Calanus chilensis was mostly represented by late stages, i.e. copepodid C5 and adult males and females. There were no day/night effects on vertical distribution, and abundance was significantly higher inside the upwelling plume in the upper 20-m layer at nearly 14 ind. m^–3, compared to ca. 5 ind. m^–3 outside the upwelling plume. Temperature at 10 m depth and biomass, estimated from stage numbers and their mean dry weights, were used to estimate growth and daily production of Calanus at temperature-dependent rates. The potential loss of biomass from the upwelling center because of advection in the upwelling plume was estimated from current data in the Ekman layer and biomass density. The mean cross-shelf component of the current was estimated at 10.4 km d^–1 within the upwelling plume. This yielded a loss of biomass of 9.7 mg dry weight m^–2 . Production, estimated by a temperature-dependent approach, ranged between 44 and 35 mg dry weight m^–2 d^–1, at mean temperatures of 14.6 °C and 15.8 °C inside and outside of the upwelling plume respectively. Within the plume, as much as 22% of daily production may be advected offshore. However, a higher concentration of biomass in the upwelling plume allowed a greater production compared to surrounding areas. A mass balance approach suggests that advective losses may not have a major impact on the C. chilensis population, because of very high daily production at temperature-dependent rates.