长尾雀繁殖生态的研究

长尾雀在长白山为留鸟,是典型的“素食”瘪类,仅在育雏期有很少的动物性食物。繁殖期在筑巢适宜生境１．３对／ｈｍ＾２,冬季在繁殖期相同生境为０．０７４只／ｈｍ＾２．４月初开始有求偶追逐和争雌行为。５月下旬产卵。孵化期１２－１３ｄ．６日龄喂雏３５次／ｄ。６日龄喂雏３５次／ｄ,雏鸟在１０日龄后体温恒定,育雏期１３－１４ｄ。９月中旬后幼鸟换成成鸟羽色。     

攀雀繁殖生态的研究

攀雀的一般繁殖生物学及营巢过程,欧洲曾有过记述(Merkel,1935;Kortner,1981),但较少涉及生态学。我们根据所获的65巢攀雀,对其营巢程序及巢中112枚卵和118只雏进行了观察与研究。本文报道攀雀的繁殖习性、种群关系、分布密度以及雏鸟的生长、孵化率、繁殖率、食性等。     

OBSERVATIONS ON THE BEHAVIOUR AND ECOLOGY OF THE FLIGHTLESS CORMORANT NANNOPTERUM HARRISI

From 25 September to 8 October 1963 daily observations were made on a group of Flightless Cormorants Nannopterum harrisi nesting on the west side of Albemarle Island in the Galápagos. Flightless Cormorants are apparently bottom-feeders, and confined to shallow coasts at the western end of the Galapagos Archipelago where there is an upwelling of cold nutrient-rich water. There is no reason to suppose that they are declining in numbers. Males are very much larger than females, the size difference between the sexes being greater than in other species of cormorants. Courtship behaviour, nest-building and mating are described. The earliest phases of courtship take place on the water, later phases at the nest-site. Homologies are traced with other cormorant species. In contrast to other members of the family, allopreening apparently does not occur. Both sexes incubate and care for the young. Observations on families of different ages over the 12-day period allowed the development of the young to be traced up to the age of about 40 days. Egg-laying takes place in most months of the year, with a peak in April-June and perhaps a second peak about October. Observations on birds colour-ringed on an earlier visit suggested that individuals do not breed more than once in the year. Nesting success appeared to be very low in 1963.     

长白山沼泽山雀的生态习性研究

沼泽山雀(Parus palustris brevirostris Taczanovski)是中山、低山带较常见的典型森林鸟类。关于它的生态习性,La Touche(1925—30),ⅡeMe~TKCB,r.n.等(1954),郑作新等(1958),郑作新等(1963)、范忠民等(1965)及李桂垣等(1982)均有过报道;但鉴于其生态习性的地区差异及某些环节的不足,尤其是对其生长发育的研究欠缺。为此,笔者将1963—1965,1979—1983年,在长白山北坡对该鸟生态习性的研究结果,报道如下。     

ASPECTS OF THE BEHAVIOUR AND ECOLOGY OF MIXED-SPECIES BIRD FLOCKS IN KASHMIR

Mixed-species flocks of birds were observed between the end of July and late August, principally at Daksum, Kashmir, 2250 m. The species composition and the numbers of individuals in flocks changed during this period; these changes are attributed to resident territory holders and migrant birds joining the flocks. Within the flock different species showed some differences in foraging stations, but nevertheless often appeared to be taking the same type of food. Participant species had different roles in the flock organization. Behaviours involving the entire mixed-flock acting as a unit included path reversal after encounters with avian predators and a tendency to follow set routes. The mixed- species flock exerted an attractive influence on aggregations of species not normally participant.
Similarities between the flocks described in this study and those recorded by other workers are discussed. While different species may derive different benefits from joining these flocks, advantages that could benefit some or all participants include the receipt of information on good feeding areas in an unfamiliar locality, the avoidance of time wasted on feeding on substrates which have been very recently harvested, the beating effect to increase prey availability, and enhanced safety from predators, perhaps through differential alertness of different species and specialized anti-predator behaviour.     

ECOLOGY AND BEHAVIOUR OF THE LITTLE AUK ALLE ALLE IN WEST GREENLAND

A study of the breeding biology, feeding ecology, and behaviour of the Little Auk was carried out on Horse Head Island (73° 38′ N, 57° 08′ W) in west Greenland between July and August 1974. Distinct subcolony groups were recognized within the colony. During incubation, attendance at the colony increased to a peak between 2100 and 2400 h, with large rafts building up on the sea before engaging in aerial flights and then settling on land. During the nestling period, this pattern changed with further peaks at 0600 and 1800 h, and a decline during the afternoon, particularly during the late nestling period. Little Auks fed exclusively on copepods and amphipods (94%Calanus finmarchicus) usually captured within 2.5 km of the colony. Feeding rhythms fitted closely the known diurnal vertical migrations of Calanus with peaks between 2200 and 0800 h. Some individuals within subcolony groups showed synchrony of feeds, mainly between 1800 and 2400 h. The mean number of feeds to a chick in 24 h was 5.25. Growth rates of young were comparable between all four experimental groups and controls, although the latter attained higher weights. Mean daily weight increases were constant until 18 days of age when they declined sharply. This was not reflected in a change in mean daily weight increases with date and so suggests that food availability had not declined. Instead there was a reduced feeding rate to chicks from age 21 days to fledging. Breeding success was 50 %, mainly the result of egg desertion and predation by Arctic Foxes, and this may have been reduced by our own activities. Behaviour postures and the responses they elicited are described together with the diurnal patterns of different activities. Aerial flights are also described and their possible function discussed. It is concluded that the shortness of the time when abundant food is available has encouraged close breeding synchrony and this is achieved by mass flights and rafting on the sea beside the colony, and subdivision of the colony into groups with communal behaviour close to the nests.     

ECOLOGY AND BEHAVIOUR OF THE SOUTH GEORGIA PINTAIL ANAS G. GEORGICA

A study of the feeding ecology and breeding biology of the South Georgia Pintail was conducted in East Cumberland Bay during November and December 1971. Of a variety of water areas available, pintails fed and reared their broods in tussock-trimmed ponds. The second most important feeding areas were sheltered fjords and seashores. Food included freshwater invertebrates such as fairy shrimp, marine amphipods and snails, and small amounts of marine algae. Considering the climatic conditions, the breeding season spans a long season from late October to early March. Courtship and social behaviour are very similar to that of the pintail, and displays and calls could not be differentiated from those of A. g. spinicauda. There is now one other species of duck on South Georgia, the Speckled Teal, but, because it occurs sympatrically with A. g. spinicauda throughout temperate South America and tends to use different food resources, no serious competition is expected. It is concluded that these species have successfully adapted to South Georgia because of the availability of protected, food-rich ponds for rearing young and because of the semimarine adaptations that have developed in Tierra del Fuego and the Falkland Islands.     

FEEDING BEHAVIOUR AND ECOLOGY OF NEW GUINEA RAINFOREST INSECTIVOROUS PASSERINES

Fifty species of insectivorous warblers Sylviidae, flycatchers Muscicapidae and whistlers Pachycephalidae were studied in primary rainforest at various localities in New Guinea. The structure of the various forest types is described and the birds' feeding ecology and behaviour analysed by recognizing three main foraging techniques and five horizontal and three vertical basic structural divisions of the habitats. Altitudinal ranges of the species are assessed to determine potential co-existence and they are divided into lowland and lower montane groups (either side of the main avifaunal discontinuity at 1500 m) with a third small group occurring in both areas and a fourth group of 12 lower montane species that occur also in the structurally much simpler Upper Montane forest. The feeding behaviour and ecology of the species within each major habitat are compared, with particular attention to taxonomically related and ecologically similar species. Other important considerations—additional behavioural differences, notable morphological distinctions, altitudinal separation of ranges within the habitat—are also noted. The likely importance of differences in foraging behaviour and feeding sites for reducing competition between related species is amply demonstrated, members of several pairs and groups of species have nearly mutually exclusive preferences. The overall pattern of habitat utilization is, however, extremely complex with nearly all stations used, in a variety of ways, by several species and there are many instances of substantial similarity between pairs of species, often involving congeners. The calculation of information theory derived indices of foraging diversity and overlap enables more general comparisons between the altitudinally graded habitats to be made and differences related to current ideas on tropical species diversity. Between Lowland and Lower Montane forest there is a fairly general trend of reduction in foraging diversity and decrease in the mean overlap between species in many genera and groups. The 12 species that continue into the simpler Upper Montane forest show very significantly reduced foraging diversity (compared with their values in lower montane forest) and also less overlap, indicating a different relationship between these species in the absence of the other Lower Montane forest birds. Together these results suggest that the most tropical (i.e., lowland) species show greatest overlap but do not necessarily have smaller niches. In progressively higher habitats there is a bias to the disappearance of generalist (high diversity index) species. These mainly use flycatcher-gleaning techniques supporting suggestions that the increase in insectivorous species in the tropics is partly due to exploitation of feeding strategies related to hovering. Habitat and ecological factors influencing this are assessed. The importance of altitudinal isolating mechanisms is also discussed and, amongst the species studied, both on average and in specific cases, those with the greatest similarities in foraging behaviour and ecology are segregated altitudinally and do not co-exist. It is suggested, however, that substantial overlap between many co-existing tropical species may not be abnormal, but rather an adaptation for ensuring maximum efficiency of habitat utilization in the prevailing environmental conditions of tropical rainforest.     

单殖吸虫生物学及生态学

单殖吸虫是隶属于扁形动物门的一大类蠕虫。       

北京地区大仓鼠种群繁殖生态研究

1983-1985年,作者在北京农田区研究了大仓鼠的种群生态。获得标本1101号(♀497,♂604),解剖、观察、测量、记录雌雄生殖系统的变化及繁殖特征。对大仓鼠的雌雄性比、平均胎仔数、怀孕率等作了分析。结果:春季出生的雌鼠,两个月左右即达性成熟,并参加繁殖,在7月以后出生的雌鼠当年不参加繁殖。越冬鼠一年可繁殖2-3次。在数量较高的1983年,性比(♂/♀)为1.33,平均胎仔数为9.24;数量次高的1984年,性比为1.20,平均胎仔数为9.29;数量较低的1985年,性比为0.95,平均胎仔数为9.94。在数量较低的年份,大仓鼠种群的各项繁殖指标均优于数量较高的年份。     

大山雀和褐头山雀种间关系研究

在地理分布重叠地区的大山雀Parus major和褐头山雀Parus montanus栖息地海拔高度不同。大山雀栖于海拔2,370米以下,集中于次生杨桦林和老年人工杨树林;褐头山雀栖于海拔2,300米以上,集中于混交林和山杨栎林。它们的栖息地有一定重叠,但重叠值较低。重叠地带觅食生态位的四维中,树种选择一维有所不同,其余三维生态位重叠值均较大。两个种营养生态位有一定重叠,食物大小的重叠值更大。在进化发展过程中,两种山雀间完全的生态分离没有发生。     

THE ECOLOGY OF ARCTIC AND ALPINE PLANTS

‘How are plants adapted to the low temperatures and other stresses of arctic and alpine environments ?’ At present it is not possible to answer this question completely. Much work remains to be done, particularly on low-temperature metabolism, frost resistance, and the environmental cues and requirements for flowering, dormancy, regrowth, and germination. However, in brief, we can say that plants are adapted to these severe environments by employing combinations of the following general characteristics: 1. Life form: perennial herb, prostrate shrub, or lichen. Perennial herbs have greatest part of biomass underground. 2. Seed dormancy: generally controlled by environment; seeds can remain dormant for long periods of time at low temperatures since they require temperatures well above freezing for germination. 3. Seedling establishment: rare and very slow; it is often several years before a seedling is safely established. 4. Chlorophyll content: in both alpine and arctic ecosystems not greatly different on a land-area basis from that in temperate herbaceous communities. Within a single species there is more chlorophyll in leaves of arctic populations than in those of alpine populations. 5. Photosynthesis and respiration: (a) These are at high rates for only a few weeks when temperatures and light are favourable. (b) Optimum photosynthesis rates are at lower temperatures than for ordinary plants; rates are both genetically and environmentally controlled with phenotypic plasticity very marked. (c) Dark respiration is higher at all temperatures than for ordinary plants; rate is both genetically and environmentally controlled, with phenotypic plasticity very pronounced, i.e. low-temperature environment increases the rate at all temperatures. (d) Alpine plants have higher light-saturation values in photosynthesis than do arctic or lowland plants; light saturation closely tied to temperature. (e) There is some evidence that alpine plants can carry on photosynthesis at lower carbon dioxide concentrations than can other plants. (f) Annual productivity is low, but daily productivity during growing season can be as high as that of most temperate herbaceous vegetation. Productivity can be increased by temperature, nutrients, or water. 6. Drought resistance: most drought stress in winter in exposed sites is due to frozen soils and dry winds. It is met by decreased water potentials, higher concentrations of soluble carbohydrates, and closed stomates. Little drought resistance in snowbank plants. Alpine plants adapted to summer drought stress can carry on photosynthesis at low water potentials; alpine or arctic plants of moist sites cannot do this. 7. Breaking of dormancy: controlled by mean temperatures near or above 0° C., and in some cases by photoperiod also. 8. Growth: very rapid even at low positive temperatures. Respiration greatly exceeds photosynthesis in early re-growth of perennials. Internal photosynthesis may occur in hollow stems of larger plants during early growth. Nitrogen and phosphorus often limiting in cold soil. 9. Food storage: characteristic of all alpine and arctic plants except annuals. Carbohydrates mostly stored underground in herbaceous perennials. Lipids in old leaves and stems of prostrate evergreen shrubs. Depleted in early growth, and usually restored after flowering. 10. Winter survival: survival and frost resistance are excellent after hardening. Cold resistance closely tied to content of soluble carbohydrates, particularly raffinose. 11. Flowering: flower buds are pre-formed the year before. Complete development and anthesis dependent upon temperature of the flowering year and also, in some cases, upon photoperiod. 12. Pollination: mostly insect-pollinated in alpine regions and even in Arctic, but to a lesser extent. Wind-pollination increasingly more important with increasing latitude. Diptera more important than bees in the Arctic and in the highest mountains. 13. Seed production: opportunistic, and dependent upon temperature during flowering period and latter half of growing season. 14. Vegetative reproduction: by rhizomes, bulbils, or layering. More common and important in Arctic than in alpine areas. 15. Onset of dormancy: triggered by photoperiod, low temperatures, and drought. Dormant plant extremely resistant to low temperatures.     

THE BIRDS OF TASMANIA: ECOLOGY AND EVOLUTION

SUMMARY Tasmania, about the size of Ireland, separated from the Australian mainland by 140 miles of sea, and isolated for about the last 12,000 years, has 104 species of native breeding land-birds, with the addition of ten introduced species. The environment is described; in particular the vegetation is classified into nine natural types and three produced by European man; and the distribution of the bird species among these is defined and discussed. The other vertebrates are briefly considered. No extinction is definitely known to have taken place as a result of European settlement except of the Tasmanian Emu (and of course Tasmanian Man). An attempt is made to reconstruct the Late Pleistocene history of Tasmania and its vegetation, with special reference to the Last Glaciation, when the island would have been joined to the mainland. When the avifauna is divided into categories, water-birds, raptors, etc., it is found to have much the same proportional composition as the Australian mainland avifaunas with which it is compared, though it consists of many fewer species. The vegetation types of the colder and wetter areas of Tasmania house far fewer species of birds than the drier and warmer habitats. The 104 breeding species include 14 endemics, which are considered in detail, and 27 endemic subspecies. As shown by comparison with other islands, the total proportionate endemism is extraordinarily high for a recent continental island (though it is actually lower than that in the remote ecological island formed by the sclerophyll of southwestern Western Australia). A contributory cause may be that Tasmania is not regularly visited by land-birds from the continent (though at least one-fifth of the Tasmanian species are partial or total migrants in winter). The most noteworthy endemics are two monotypic genera, Lathamus and Acanthornis, and the Native Hen Tribonyx mortierii, which has become flightless apparently in the face of a formidable array of local predators. Considerations of climate and habitat suggest that at least half the avifauna, including 19 of the endemic subspecies and six of the members of superspecies, arrived in Tasmania some time after the amelioration of the Last Glaciation began, some 18,000 years ago. Geographical considerations suggest that four of those six members of superspecies existed in their present form when the land-bridge to the mainland was cut, 12,000 years ago. Certain habitats, widespread over southeastern Australia during the glaciation, are now virtually confined to Tasmania where they form the stronghold of certain species, such as the Pink Robin Petroica rodinogaster, which occur only as relicts on the mainland. The endemic Scrub Tit Acanthornis magnus is practically confined to such habitats, where its ecology suggests it would have been well adapted to glacial conditions. Among the local endemics there is a strong tendency for colouration to be more saturated than on the continent of Australia (Gloger's rule) but there is less consistency in tendency to greater size (Bergmann's rule). A noteworthy proportion of the Tasmanian species have duller plumage than their mainland relatives, usually with an assimilation to female or juvenile plumage—unexpected in an island as big as Tasmania with so considerable an avifauna.     

白鹇海南亚种的生态和现状

海南白鹇是仅分布于我国海南岛的特殊的白鹇海岛亚种。其结群个体少；雏鸟孵出后，每群雏数少；亲鸟损失严重，有极其罕见的纯雏群现象；种群繁殖力低，出生率仅７７．５％；保护区核心区种群密度１９７８年２０．２只／ｋｍ~２，１９９２年１２只／ｋｍ~２。天敌、人类危害是种群数量严重下降的主要原因。目前全岛有白鹇分布的残存林区面积仅７４０ｋｍ~２，乐观估计白鹇数量已不足８８００只，白鹇海南亚种已处于渐危至濒危级别，必须尽快采取有效的保护措施。     

中国虎纹捕鸟蛛的生态学

文中首次报道了虎纹捕鸟蛛种群生态分布特点、洞穴结构、活动规律、捕食、繁殖、防御和进攻行为，并初步分析了其种群分布与栖息地结构之间的关系。