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Recherches sur le sac embryonnaire des plantes grassesHubert, E. d' January 1896 (has links)
Thesis--Paris. / Bibliography: p. 52-54, 124.
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A study on an altitudinal gradient investigating the potential effects of climate change on Fynbos and the Fynbos-succulent Karoo boundary /Agenbag, Lize. January 2006 (has links)
Thesis (MSc)--University of Stellenbosch, 2006. / Bibliography. Also available via the Internet.
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Population biology and ecology of the critically endangered succulent adenium swazicumVan der Walt, Karin 22 January 2016 (has links)
A dissertation submitted to the Faculty of Science, University of the Witwatersrand,
Johannesburg, in fulfilment of the requirements for the degree of
Masters of Science June 2015 / Adenium swazicum is currently listed as Critically Endangered due to past and future
population declines, which have been estimated to be 80% over three generations. Although
10-20% of the population is present in formal protected areas, no studies have been published
on the species population biology and ecology, which are essential to ensure its effective
conservation. The broad aim of this research was to investigate the population biology and
ecology of Adenium swazicum by investigating factors such as current distribution,
population structure, reproductive characteristics, germination, herbivory and current threats.
The current distribution of Adenium swazicum was determined by searching all herbarium
records on the National Herbarium Pretoria Computerised Information System as well as
additional suitable habitat through fieldwork, conducted during the flowering period (October
to April) between 2009 and 2011. The current Extent of Occurrence (EOO) and Area of
Occupancy (AOO) were determined by incorporating all confirmed localities of Adenium
swazicum. To determine the population biology of Adenium swazicum, fifty plants in four
representative populations were studied with regards to plant size, extent and intensity of
herbivory, flower production as well as follicle and seed production. The reproduction of
Adenium swazicum was determined through pollinator observations while the number of
flowers and fruit (follicles) produced, as well as fruit and seed set were compared in the four
representative populations. Seed viability was determined through tetrazolium staining,
while germination experiments were used to determine minimum, maximum and optimum
temperature ranges as well as mean germination time. Seedling emergence and establishment
were determined for various soil media, depth of seed planting, watering regimes and
shading.
The current distribution of A. swazicum included 23 localities in South Africa, Swaziland and
Mozambique, while the Extent of Occurrence (EOO) was approximately 8 392km² (839 246
ha) and the Area of Occupancy (AOO) was estimated to be 8.5km² (850ha). Although this
indicates that A. swazicum might be more widespread than previously believed, the
population sizes were all small (between 1 and 141) and most of the populations were still
threatened, mostly by habitat destruction and harvesting for medicinal purposes.
The research found that adult A. swazicum plants were found to have a high tolerance to
natural disturbance (fire, herbivory) and resprout from the underground tuber even if all
above ground parts were destroyed. It is however unlikely that seedlings and juveniles will
be able to withstand significant impact on the above ground parts since the underground tuber
only develops in plants older than 24 months.
Despite big and bright floral displays which should attract insect pollinators, low diurnal
insect activity was observed around A. swazicum. However, a fast flying Sphingidae (Hawk
Moth), which is most likely a pollinator, was observed at A. swazicum flowers at dusk. Small
population size and isolation might have been the cause of no reproduction (very few follicles
and no seed) in at least one population in 2010. Continued reproduction failure as well as
destruction of remaining adult plants by housing developments and collection for medicinal
purposes might lead to the local extinction of this population.
With sufficient available moisture, high germination success (82 to 90%) for A. swazicum
was achieved at temperatures between 20°C and 35°C, without any pre-treatment, and
‘maximum’ germination was reached in less than 90 hours. The cultivation of A. swazicum
from seed is highly successful, with different soil media having no apparent influence on
seedling emergence and establishment. Seedling emergence was highly dependent on water,
and although shading did not influence seedling emergence, seedling establishment/survival
was highly dependent on shading. Since seed release from A. swazicum coincides with the
start of the rainy season (October), as well as short germination responses, it is highly
unlikely that A. swazicum forms persistent soil seed banks.
The uncomplicated propagation of A. swazicum has resulted in a significant ex situ collection
at the Lowveld National Botanical Garden, with more than 2000 plants (adults and seedlings)
grown from seeds which were collected from four different populations over an eight year
period. In addition, the Skukuza indigenous nursery in Kruger National Park has more than
250 plants (adults and seedlings) all of which were grown from seed collected in the KNP.
These living ex situ collections provide a valuable source of plant material for future
restoration projects.
Despite an increase in the number of known Adenium swazicum populations, the population
sizes are small (1 to 141) and most populations are still threatened by habitat destruction and
high levels of exploitation by medicinal plant harvesters. It is therefore recommended that
Adenium swazicum remains listed as Critically Endangered (A4acd;B2cb). Criteria A4acd:
“An observed, estimated, inferred, projected or suspected population reduction (up to a
maximum of 100 years) where the time period must include both the past and future, and
where the causes of reduction may not have ceased or, may not be understood, or may not be
reversible based on”. This assessment was based on (a) the causes of reduction of Adenium
swazicum populations have not ceased and may not be reversible, (c) there is a decline in
AOO, EOO and habitat quality; and (d) there is actual, continuing exploitation of A.
swazicum. Adenium swazicum also qualifies as CR under criteria B2b(iv,v): “Geographic
range in the form of Area of Occupancy (AOO) of <10km² with (b) continuing decline in (iv)
number of locations or subpopulations and (v) number of mature individuals”.
No immediate management intervention is needed for populations which are located in
formal protected areas, although it is recommended that these populations be monitored,
especially with regards to reproduction to inform future management decisions. It is possible
that low seed viability recorded in population C in 2009 and 2010 could be due to inbreeding
depression caused by the destruction of surrounding populations due to sugarcane fields and
harvesting of adult plants for medicinal uses. The Low veld National Botanical Garden had
collected parental material from populations surrounding population C since 2003; it is
recommended that restoration of decimated populations be conducted in secure areas on for
example private land and community schools. Lastly, seed collected from various
populations should be banked at the Kew Millennium Seed Bank Project, England to ensure
viable ex situ collections.
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A taxonomic study of succulents, exclusive of cacti, occuring native or cultivated in southwestern gardensMurray, Mary Aileen, 1914- January 1938 (has links)
No description available.
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Megaherbivores in succulent thicket: resource use and implicationsLandman, Marietjie January 2012 (has links)
This study aims to develop a predictive understanding of the resource use, impacts and interactions of elephant Loxodonta africana and black rhinoceros Diceros bicornis in the succulent thickets of the Eastern Cape, South Africa. While these megaherbivores typically dominate the biomass, elephant are more abundant, such that their impacts off-set that of all other herbivores. Consequently, this thesis has three main foci: first, developing a mechanistic understanding of the influences of elephant; second, developing predictive insights into elephant impacts on plant communities; finally, an understanding of the knockon-effects of the impacts for coexisting rhinoceros. Thus, by documenting the diet and dietary preferences of elephant, I firstly show that only about 18 percent of the species previously thought vulnerable to herbivory, occur in the diet. This refutes the generally held belief that elephant herbivory is the primary driver of decline among plants, and emphasizes the likely contribution of other mechanisms (e.g. trampling, knock-on-effects, etc.). Thus, the accurate prediction of the impacts caused by elephant requires an understanding of previously marginalized mechanisms. From here, I quantify >50 years of impacts on the thicket shrub community and test their spatial and temporal extent near water. I confirm the vulnerability of thicket to transformation (particularly near water) as the accumulated influences of elephant reduce community composition and structure, and predict that these impacts will eventually bring about landscape-level degradation and a significant loss of biodiversity. Importantly, results show an uneven distribution of effects between elements of this community: from community composition and structure, to the structure of individual canopy species and ecological functioning. While these findings confound our interpretation of the extent of the impacts, it demonstrates the importance of explicitly recognizing biodiversity and heterogeneity for the conservation management of elephant. Finally, I test the consequences of the impacts for coexisting rhinoceros. While I show that this causes rhinoceros to change their foraging strategies in the presence of elephant at high densities, I also show that elephant may facilitate access to food for rhinoceros at reduced densities. These findings indicate the importance of elephant in driving the structure and composition of the thicket shrub community and the consequences of this for coexisting large herbivores. Thus, developing a predictive understanding of the spatial and temporal variations of elephant impacts between elements of biodiversity and the mechanisms driving these changes are key to their management. This implies that the effective conservation management of elephant can only be achieved through the careful, scientific design of monitoring programmes.
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Effects of gaseous emissions from the Namakwa Sands Mineral Separation Plant near Lützville on the adjacent succulent Karoo vegetation : a pilot study /Lukama, Beatrice M. K. January 2006 (has links)
Thesis (MSc)--University of Stellenbosch, 2006. / Bibliography. Also available via the Internet.
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Restoration of degraded subtropical thickets in the Baviaanskloof Megareserve, South Africa : the role of carbon stocks and Portulacaria afra survivorship /Powell, Michael John January 2009 (has links)
Thesis (M.Sc. (Environmental Science)) - Rhodes University, 2009.
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The effects of goat browsing on ecosystem patterns and processes in succulent thicket, South AfricaLechmere-Oertel, Richard Geoffrey January 2003 (has links)
Transformation in the arid succulent thicket of the Eastern Cape of South Africa in response to unsustainable livestock production has been widespread, with less than 10 percent remaining intact. Transformation in succulent thicket has resulted in large areas of dense thicket (comprising a two-phase mosaic of perennial-vegetated patches separated by animal paths and bare patches) being replaced with a ‘pseudo-savanna’ of remnant canopy trees with a structurally simple field layer of ephemeral and short- lived perennial grasses and forbs. There is an extensive literature describing the transformation of succulent thicket, with many speculative statements about the underlying mechanisms of transformation. The central focus of this study was to improve our mechanistic understanding of transformation in succulent thicket using field experiments. Hopefully these results will set another foundation upon which future management of succulent thicket can be improved and large-scale restoration initiated. This study comprises four themes that are linked to the concept of landscape function. The central premise of landscape function is that functional landscapes have mechanisms that capture and retain scarce resources. Conversely, as landscapes become increasingly dysfunctional, so these mechanisms become disrupted. In succulent thicket, dysfunctio n appears to be linked to the reduced ability to harvest water, cycle carbon and a loss of organic carbon. In this thesis I examined some of the key processes that influence water and organic carbon fluxes: perennial vegetation cover, soil fertility, litter fall and decomposition, and runoff and soil erosion. The experimental design that was used for all this work was a factorial ANOVA based on replicated fenceline contrasts that reflect differences in long-term management history. The main objectives of this thesis were to: quantify the patterns of transformation in an arid form of succulent thicket, including changes in the biomass, cover and structure of the dominant vegetation guilds; test the stability of the transformed succulent thicket ecosystem to show whether it is a new stable state or an intermediate stage in a trajectory towards a highly desertified state where only the ephemeral grasses and forbs persist; describe and compare soil fertility across transformation contrasts, concentrating on changes in the spatial patterns of soil resources and the ability of the soil to harvest precipitation; to compare litter fall and decomposition of leaf material from the dominant plants in intact and transformed succulent thicket; to quantify and compare run-off and erosion from run-off plots in intact and transformed succulent thicket. Transformation and stability I quantified the changes in plant diversity, physiognomy and biomass that occur across transformation contrasts. Thicket transformation results in a significant loss of plant diversity and functional types. There is also a significant reduction in the biomass (c. 80 t.ha-1) and structural complexity of the vegetation, both vertically and horizontally. These results were interpreted in terms of their implications for ecosystem functioning and stability. To test the stability of the transformed succulent thicket I used aerial photographs and ground-truthing to track the survivorship of canopy trees over 60 years in pseudo-savanna landscapes. I also measured seedling establishment in different habitats. I show that the pseudo-savanna is not a stable state owing to ongoing adult mortality and no recruitment of canopy trees. Soil fertility and water status I hypothesised that the above-ground changes in ve getation would be accompanied by similar trends in the pattern and levels of soil nutrient resources and the ability of the landscape to harvest precipitation. I compared soil fertility (organic carbon, available nitrogen and phosphorus), texture, matric potential, and surface micro-topography in the two main micro- habitats on either side of the replicated fenceline contrasts. The results show that intact spekboom thicket has a distinct spatial pattern of soil fertility where nutrients and organic carbon are concentrated under the patches of perennial shrubs, compared to under canopy trees and open spaces. Transformation results in a significant homogenisation out of this pattern and an overall reduction in the fertility of the landscape. The proportion of the landscape surface that would promote infiltration of water decreases from 60 – 0.6 percent. Soil moisture retention (matric potential) also decreases with transformation. I interpreted these patterns in terms of the ability of the landscape to harvest and release water after rainfall events. Litter fall and decomposition Surface litter and soil organic matter are critical components to wooded ecosystems; contributing to several ecosystem functions. The rates of litter fall and decomposition are ratelimiting steps in nutrient cycling and incorporation of organic matter into the soil. The ecological mechanisms behind the collapse of succulent thicket in the face of domestic herbivory are not fully understood, but are believed to include the breakdown of several ecosystem processes, including litter fall and decomposition. I quantified the changes in litter fall and litter decomposition of four of the dominant perennial woody plants (Euclea undulata, Pappea capensis, Portulacaria afra and Rhus longispina) across the replicated fenceline. Litter fall was measured over 14 months using mesh traps. Decomposition was measured over 15 months using a combination of litterbags and unprotected leaf packs. I also quantified soil microclimate during the experimental period; hypothesising that transformation would lead to soil conditions less amenable for biotic activity. Litter fall in succulent thicket was very high for a semi-arid system, comparing more to temperate forests. The leaf-succulent P. afra contributed the largest single component of the total litter production at a landscape scale. The effect of transformation on litter fall was species specific. Deep-rooted or drought-adapted species showed no change in litter yield with transformation; shallow-rooted species showed a significant decrease. There were few significant differences in decomposition rates across the transformation gradient and between litter types. Portulacaria afra litter had the steepest rate of mass loss, and was most affected by transformation. The more recalcitrant (high C:N ratio) leaves of P. capensis remained largely unaffected by transformation. These results indicate the critical role of the perennial vegetation in incorporating organic carbon into the soil. Transformation of succulent thicket leads to a disruption of the flow of carbon into the soil, reinforcing the cycle of transformation through reduced fertility. Rehabilitation of this ecosystem will require the active establishment of species, such as P. afra, that will restart the flow of carbon into the soil. Run-off & Erosion The landscape function model predicts that functional semi-arid shrublands efficiently conserve limiting resources such as water and water-bourn sediments (soil and organic matter). As these rangelands become transformed through unsustainable livestock production, so their ability to conserve resources decreases. The primary determinant of landscape function and conservation of resources appears to be the proportional cover of perennial vegetation. I hypothesised that the switch from a two-phase mosaic dominated by perennial succulent and woody shrubs to a single phase system dominated by an ephemeral field layer would be accompanied by disruption of the mechanisms that conserve resources. Specifically, I tested the hypothesis that transformation of succulent thicket increases runoff volume, sediment concentration of runoff, soil erosion and loss of organic matter at a patch scale (c. 100 m2). Runoff and water-borne sediment were measured from runoff plots established across replicated fenceline contrasts. Data were collected from eight extreme weather events over two years. There were no significant differences between runoff and erosion across the transformation contrast, as each extreme weather event was unique in terms of its runoff response. The transformed runoff plots alone also gave inconsistent results, largely due to differences in the cover of ephemeral forbs and weakly perennial grasses. Runoff and erosion were not predictable from the data across the transformation gradient due to complex interactions between the nature of the above-ground vegetation, soil micro-topography and land use history. The results highlighted the need for longer-term catchment experiments to generate a predictive understanding of the effect of transformation on runoff and erosion in succulent thicket.
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Cremnophilous succulents of southern Africa : diversity, structure and adaptationsVan Jaarsveld, Ernst Jacobus 29 May 2012 (has links)
The vertical cliff-face habitat is renowned for many specifically adapted plant species that exhibit a high degree of local endemism. Over a period of nine years the succulents and bulbous succulents on cliff faces in South Africa and Namibia were systematically surveyed and documented. Distinction was made between succulents growing on cliffs as part of a wider habitat and those found only on cliffs (obligate cremnophytes). Most major cliff-face habitats in the study area were visited and all plants were documented. A check list and descriptions (including adaptive traits) of the 220 obligate cremnophilous taxa are provided. During the study some 45 new cremnophilous succulent taxa were discovered and named, representing almost 20% of the total and proving that cliff habitats are some of the least studied environments, not only in southern Africa but globally. Among the newly described cremnophilous taxa is the genus Dewinteria (Pedaliaceae). Using stem length, three basic cliff-face growth forms are identified - compact or cluster-forming ‘cliff huggers’, cliff shrublets or ‘cliff squatters’ and pendent ‘cliff hangers’. Compact growth (often tight clusters or mats) is mainly associated with the winter-rainfall Succulent Karoo and Thicket regions, especially Namaqualand. However, further north the same compact growth forms are associated with an increase in altitude such as the Drakensberg Escarpment and other northern mountains. Most pendent growth forms are associated with the eastern and southeastern summer-rainfall regions; a number of smaller pendent shrublets occur on the high quartzitic sandstone mountains of the Western Cape. The degree of specialisation varies from highly adapted (smaller percentage) to less specialised (often eco-forms), and some taxa have no obvious adaptations. This study revealed a general increase in succulence in most obligate cremnophilous succulent species (compared to closely related species in other habitats), a reflection of their xeric habitat, and plants tend to be more compact. Also, there is a shift in reproductive output, including an increase in vegetative reproduction (backup), wind-dispersed seed and enriched flowering associated with certain species. Most obligate cremnophilous succulent plants in the study area have cliff-adapted features, ensuring long-term survival. / Thesis (PhD)--University of Pretoria, 2012. / Plant Science / unrestricted
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The relevance of fog and dew precipitation to succulent plant hydrology in an arid South African ecosystemMatimati, Ignatious January 2009 (has links)
Magister Scientiae (Biodiversity and Conservation Biology) / Fog and dew interception and utilization by plant canopies remains one of the least
considered aspects of vegetation studies at any scale yet the few studies that have been conducted point to their considerable influence on ecological processes and a critical role in modulating climate in southern African arid ecosystems. Their relevance to succulent plant hydrology was investigated in this study.The first study measured stable 18O and 2H isotope ratios in samples of rain, fog and dew water and compared these with those assayed monthly in stem xylem water of six
succulent shrub species over a one year period. Negative 18O and 2H ratios were observed in the stem xylem water of all six species signifying a predominance of water derived from fog and dew precipitation which was most conspicuous during the wet winter. This implied that fog and dew are even more important sources of water than rain and corroborated by significant correspondence found between fog and dew frequencies, succulent foliar water
contents and quantum yields of photochemistry.The second study monitored variations in stem diameter at 2-hourly intervals in 8 succulent shrub species of diverse growth form over a 9-month period. Two groups of species were distinguished based on whether their daily amplitudes in stem diameter were
consistently positively correlated with daily fluxes in vapour pressure deficit, which were indicative of a persistent CAM photosynthetic mode, or intermittently correlated with daily fluxes in vapour pressure deficit, which were indicative of mixed CAM and C3 photosynthetic modes. Among species displaying a persistent CAM photosynthetic mode, high nocturnal fog and dew precipitation amounts corresponded with low daily amplitudes in stem diameter, and vice versa, which pointed to reduced nocturnal stomatal water loss. These patterns, which were indistinct among species displaying mixed CAM and C3 photosynthetic modes, were
corroborated by small daily amplitudes in stem diameter also consistently observed in one species displaying a CAM photosynthetic mode in ambient than artificially fog and dew excluded environments.The third study monitored changes in water mass at hourly intervals of quartz gravel substrates with different dwarf succulent species assemblages over an 8-month period.Consistently greater net amounts of water were intercepted daily by quartz gravel substrates containing Agyroderma pearsonii than Cephalophylum spissum plants as well as those without plants. These attributed to a high water repellence of A. pearsonii leaves and less
radiation absorbed by the paler silvery to grey-green leaves of A. pearsonii leaves than the dark green leaves of C. spissum resulting in lower leaf temperatures and less water loss by transpiration. Quartz gravel soils devoid of plants intercepted nearly 5-times greater amounts of precipitation contributed by fog and dew than that contributed by rain. These precipitation amounts exceeding the high percentages of total hydrological input contributed by fog and dew reported in other ecosystems.The study concludes that fog and dew are a vital source of water for succulent shrubs in arid South African ecosystems and imply that diminished fog and dew frequencies associated with elevated night time temperatures accompanying global warming could exacerbate plant drought stress.
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