Spelling suggestions: "subject:"epiphytic.""
71 |
Spatial complexity and microclimatic responses of epiphyte communities and their invertebrate fauna in the canopy of northern rata (Metrosideros robusta A. Cunn.: Myrtaceae) on the West Coast of the South Island, New ZealandAffeld, Kathrin January 2008 (has links)
Rain forest canopies are renowned for their very high biodiversity and the critical role they play in key ecological processes and their influence on global climate. Despite that New Zealand supports one of the most diverse and extensive epiphyte flora of any temperate forest system, few studies have investigated epiphyte communities and their invertebrate fauna along with factors that influence their distribution and composition. This thesis represents the first comprehensive study of entire epiphyte communities and their resident invertebrate fauna in the canopy of New Zealand’s indigenous forests. The aim of this study was to determine spatial patterns of epiphyte and invertebrate species richness, abundance and community composition in relation to abiotic variables, and in particular, the responses of these communities to elevated temperature and rainfall. This study was carried out in coastal lowland podocarp-broadleaved forests at two sites on the West Coast of the South Island of New Zealand. Samples from 120 mat-forming epiphyte assemblages located on inner canopy branches of 40 northern rata (Metrosideros robusta) trees were studied to characterise the component flora and fauna. Additionally, biomass, branch and tree characteristics and community responses to treatments designed to elevate temperature and rainfall to simulate predicted climate change were measured. This investigation revealed astonishing diversity and functional complexity of epiphyte and invertebrate life in this ecosystem. The 30.6 kg (dry weight) of epiphyte material collected contained a total of 567 species, 170 epiphyte and 397 invertebrate (excluding immature specimens and mites) species, including at least 10 species new to science and many undescribed species Epiphyte communities were found to be dominated by non-vascular plants (80 % of the total species richness), particularly liverworts and invertebrate communities were dominated with respect to abundance (~ 80 % of the total individuals) by Acari, Collembola and Hymenoptera (primarily ants) and functionally by scavengers and ants. Epiphyte and invertebrate communities were highly variable with respect to spatial patterning of species richness, abundance and composition across sites, among trees within sites and among branches within trees. Overall, a highly significant proportion, > 75 %, of the variance could be attributed to differences at the branch level, but these differences could not be explained by the environmental factors measured. There were no consistent relationships between the spatial pattern of epiphytes and invertebrates, or between vascular and non-vascular plants. However, there were significant positive correlations between epiphyte biomass and invertebrate species richness (r = 0.472; p < 0.0001) and abundance (r = -0.395; p < 0.0001), as well as non-living epiphyte biomass and scavenger species richness (r = 0.4; p < 0.0001). Microclimatic measurements taken on epiphyte mats were also highly variable with respect to temperature and relative humidity at similar physical locations within the same tree as well as across trees within sites. There was also considerable variation in the intensity and frequency of climatic extremes, although potentially harmful climatic conditions were experienced by all the epiphyte mats for which weather variables were measured. Negative correlations existed between both epiphyte and invertebrate community composition and increased temperatures expressed as cumulative degree days above 5˚C. However, variability was such that there was no direct evidence that increased temperature and rainfall treatments had an effect on invertebrate species richness, abundance or diversity. Northern rata host trees harbour an astonishingly diverse and complex canopy flora and fauna that is characterised by high spatial variability. Such variability highlights that to determine species distribution and community dynamics in canopy habitats in response to disturbance caused either by climate change or invasive species the structure of entire communities at different taxonomic and spatial scales, along with their responses to microclimatic factors, need to be studied. If such complexities are not taken into account, inappropriate interpretation may result in poor decisions concerning the conservation status, vulnerability and subsequent management of such unique ecosystems.
|
72 |
The interaction between a keystone plant species and its dominant epiphyte on Marion Island : climate change implicationsBuwa, Ziphokazi Siyasanga 12 1900 (has links)
Thesis (MSc)--University of Stellenbosch, 2007. / ENGLISH ABSTRACT: Climate has shown some remarkable changes over the past century, especially at the
polar and sub-polar regions. Southern Ocean Islands provide good models for studies
related to climate change effects, since effects may be evident in the short term and may
also be clearer. Marion Island is an example of such a system with a harsh abiotic
environment, and low species richness often vulnerable to change. Climate change is
predicted, and also reported, to have biological consequences on plant communities,
affecting the phenology, morphology, and the interaction between individuals and
species. This study examines the association between the keystone plant species, Azorella
selago Hook. (Apiaceace), and its dominant epiphyte Agrostis magellanica Lam.
(Poaceae). Two complimentary approaches were used, one observational and the other
experimental. The main objective for the observational study was to quantify bioticallyrelevant
microclimate temperature, as well as the morphology, epiphyte load and
phenology of A. selago at three different altitude sites on Marion Island. This provided
information on baseline variation for understanding specific variability in plant response
to the experimental part of this study, against which future patterns arising from
biological monitoring can be compared. Studying plants at different altitudes provides a
possible analogue for temperature-related climate change consequences for the ecology
of A. selago, and its interaction with A. magellanica. The microclimate temperature
associated with A. selago differed between the three sites examined. This difference was
related to local topographic conditions and altitude differences. Cushion size differed
distinctively between the three altitude sites, with this difference related to environmental
heterogeneity such as differences in age and substrate structure. Azorella selago annual
growth rate was estimated through stem length and the number of leaves on both exposed
and shaded stems. Within-site variability, as well as epiphyte cover were found to be the
contributing factors on A. selago annual growth rate. This highlights the importance of
site-specificity when estimating growth rate within and between different altitude sites.
Leaf characteristics differed between the sites, with this attributed to local habitat
conditions, such as topography, as well as epiphyte cover. As expected, the difference in
leaf size between exposed and shaded leaves demonstrated a larger specific leaf area on leaves shaded by A. magellanica. Agrostis magellanica abundance and density were
altitudinally related, with A. selago demonstrating facilitation effects on A. magellanica.
The trend shown in this study suggests that in spite of general facilitative effect of A.
selago on A. magellanica towards higher altitudes, the abiotic environmental threshold
for A. magellanica occurs at lower altitudes than it does for A. selago. Phenological
differences were also apparent between the three sites. The objectives of the experimental
part of this study were to quantify the effect of the dominant epiphyte, A. magellanica on
biotically-relevant microclimatic temperatures, as well as on the phenology and physical
condition of A. selago. Different treatments were applied to cushions at the three altitude
sites to examine the shading effect of epiphytic A. magellanica on cushion plants, as well
as the effect of treatment-related disturbance. Azorella selago microclimate temperature
showed no significant difference between treatments, suggesting that on average
epiphytic A. magellanica cover has no effect on cushion microclimate temperature. The
percentage of flower budding and flowering of A. selago was negatively related to
epiphyte cover. Cushion vitality was also responsive to epiphyte cover, with higher
vitality scores on low grass covered cushions than on high grass cushions. This shows
that A. magellanica competes with A. selago, while A. selago facilitates A. magellanica.
Heavy epiphyte numbers impose negative effects on A. selago vegetative and
reproductive performance, as well as cushion vitality. Therefore, the results of this
research show that the vegetative and reproductive performance of A. selago and cushion
vitality are likely to be negatively affected under ongoing climate change on Marion
Island if this brings about heavier epiphyte loads on this keystone cushion plant species. / AFRIKAANSE OPSOMMING: In die afgelope eeu het die klimaat in die Antarktiese en sub-Antarktiese gebiede
merkwaardige verandering getoon. Die Suidelike See Eilande dien as goeie modelle vir
studies verwant aan die gevolge van klimaatsverandering, aangesien die kort termyn
effekte in die gebiede duideliker mag wees in die toekoms. Marion Eiland is ‘n voorbeeld
van so ‘n sisteem, met ‘n ruwe abiotiese omgewing en lae spesies rykheid, wat vatbaar is
vir verandering. Daar word voorspel, en is reeds bevind dat klimaatsverandering
biologiese gevolge op plant gemeenskappe het, in terme van morfologie, fenologie en die
interaksie tussen individue en spesies. Hierdie studie ondersoek die assosiasie tussen die
hoeksteen plant spesie, Azorella selago (Apiaceace), en sy dominante epifietiese gras,
Agrostis magellanica Lam. (Poaceae). Die studie is op twee komplimentêre maniere
benader, naamlik deur waarneming en eksperiment. Die hoof doel van die studie was om
die biotiese belang van mikroklimaat temperatuur te kwantifiseer, en die hoeveelheid
epifiete, die morfologie en die fenologie van A. selago te bepaal by drie verskillende
hoogtes op Marion Eiland. Laasgenoemde het inligting verskaf oor die variasie in die
reaksie van plante tot die eksperimentele aspek van die studie, waarteen patrone vanaf
toekomstige biologiese beheer vergelyk kon word. Deur plante te bestudeer by
verskillende hoogtes bo seespieël word ‘n moontlike analoog vir die gevolge van
temperatuur-verwante klimaatverandering in terme van die ekologie van A. selago, en
laasgenoemde se interaksie met A. magellanica verskaf. Die mikroklimaat temperatuur
geassosieer met A. selago verskil tussen dié drie liggings. Die versil was verwant aan die
plaaslike topografiese toestande en die verskillende hoogtes bo seespieël. Die grootte van
die kussingplante het duidelik versil tussen die drie liggings, met die verskille verwant
aan die omgewing se heterogeneïteit, byvoorbeeld die verskille in ouderdom en substraat
struktuur. Azorella selago se jaarlikse groeitempo was bepaal deur die stingel lengte en
die aantal blare, op beide die wat oorskadu is deur die gras, en die was nie oorskadu is
nie. Daar is gevind dat die faktore wat bygedra het tot die jaarlikse groeitempo van A.
selago, varieër binne die verskillende liggings, en bedekking deur epifiete. Dit
beklemtoon die belang van spesifisiteit van ligging wanneer groeitempo in en tussen die
liggings van verskillende hoogtes bepaal word. Die blaar eienskappe het verskil tussen verskillende liggings, as gevolg van plaaslike habitat toestande, soos topografie en
bedekking deur epifiete. Soos verwag, het die blare wat oorskadu was deur A.
magellanica ‘n groter spesifieke blaar area getoon as blare wat blootgestel was. Die
hoeveelheid en digtheid van Agrosits magellanica was verwant aan hoogte bo seespieël,
met A. selago wat fasiliterende effekte toon op A. magellanica. Die tendens waargeneem
in hierdie studie is dat ten spyte van die algemene fasiliterende effek van A. selago op A.
magellanica, die abiotiese omgewingsdrempel op ‘n laer hoogte is vir A. magellanica as
vir A. selago. Fenologiese verskille was ook duidelik tussen die drie liggings. Die doel
van die eksperimentele deel van die studie was om die effek van die dominante epifiet, A.
magellanica, te bepaal op bioties relevante mikroklimaat temperature, asook op die
fenologie en fiesiese toestand van A. selago. Verskeie behandelings is aangewend op die
kussingplante by die drie liggings om die effek van skaduwee van die epifietiese A.
magellanica op die plante te bepaal, asook die effek van versteurings versoorsaak deur
die behandelings. Azorella selago se mikroklimaat temperatuur het geen betekenisvolle
verskille tussen behandelings getoon nie, wat voorstel dat epifitiese A. magellanica oor
die algemeen geen effek op die kussingplante se mikroklimaat temperatuur het nie. Daar
was ‘n negatiewe verwantskap tussen die hoeveelheid epifiete op A. selago en die
persentasie blomme en blomknoppe op die kussingplante. Die plante se vitaliteit was ook
afhanklik van epifiet bedekking, met ‘n hoër vitaliteit telling vir kussingplante bedek met
lae gras as die bedek met hoë gras. Dit toon dat A. magellanica met A. selago wedywer,
terwyl A. selago vir A. magellanica fasiliteer. Hoë epifiet getalle het negatiewe effekte op
A. selago se vegetatiewe en reproproduktiewe nakoming, asook die kussingplante se
vitaliteit. Die resultate van hierdie studie toon dus dat die vegetatiewe en reproduktiewe
nakoming van A. selago en kussingplant vitaliteit heel moontlik negatief geaffekteer sal
word indien klimaatsverandering op Marion Eiland hoër epifiet getalle op die sleutel
kussingplant spesie tot gevolg sal hê.
|
73 |
Écologie et implications trophiques de la cyanobactérie Lyngbya wollei dans le fleuve Saint-LaurentLévesque, David 04 1900 (has links)
Les proliférations nuisibles de la cyanobactérie filamenteuse benthique Lyngbya wollei qui forme des tapis déposés sur les sédiments ont augmenté en fréquence au cours des 30 dernières années dans les rivières, lacs et sources de l'Amérique du Nord. Lyngbya wollei produit des neurotoxines et des composés organiques volatils (géosmin, 2-méthylisobornéol) qui ont des répercussions sur la santé publique de même que des impacts d'ordre socioéconomiques. Cette cyanobactérie est considérée comme un habitat et une source de nourriture de piètre qualité pour les invertébrés en raison de sa gaine robuste et de sa production de toxines.
Les proliférations de L. wollei ont été observées pour la première fois en 2005 dans le fleuve Saint-Laurent (SLR; Québec, Canada). Nous avons jugé important de déterminer sa distribution sur un tronçon de 250 km afin d'élaborer des modèles prédictifs de sa présence et biomasse en se basant sur les caractéristiques chimiques et physiques de l'eau. Lyngbya wollei était généralement observé en aval de la confluence de petits tributaires qui irriguent des terres agricoles. L’écoulement d’eaux enrichies à travers la végétation submergée se traduisait par une diminution de la concentration d’azote inorganique dissous (DIN), alors que les concentrations de carbone organique dissous (DOC) et de phosphore total dissous (TDP) demeuraient élevées, produisant un faible rapport DIN :TDP. Selon nos modèles, DOC (effet positif), TP (effet négatif) et DIN :TDP (effet négatif) sont les variables les plus importantes pour expliquer la répartition de cette cyanobactérie. La probabilité que L. wollei soit présent dans le SLR a été prédite avec exactitude dans 72 % à 92 % des cas pour un ensemble de données indépendantes.
Nous avons ensuite examiné si les conditions hydrodynamiques, c'est-à-dire le courant généré par les vagues et l'écoulement du fleuve, contrôlent les variations spatiales et temporelles de biomasse de L. wollei dans un grand système fluvial. Nous avons mesuré la biomasse de L. wollei ainsi que les variables chimiques, physiques et météorologiques durant trois ans à 10 sites le long d'un gradient d'exposition au courant et au vent dans un grand (148 km2) lac fluvial du SLR. L'exposition aux vagues et la vitesse du courant contrôlaient les variations de biomasses spatiales et temporelles. La biomasse augmentait de mai à novembre et persistait durant l'hiver. Les variations interannuelles étaient contrôlées par l'écoulement de la rivière (niveau d'eau) avec la crue printanière qui délogeait les tapis de l'année précédente. Les baisses du niveau d'eau et l'augmentation de l'intensité des tempêtes anticipées par les scénarios de changements climatiques pourraient accroître la superficie colonisée par L. wollei de même que son accumulation sur les berges.
Par la suite, nous avons évalué l'importance relative de L. wollei par rapport aux macrophytes et aux épiphytes. Nous avons examiné l'influence structurante de l'échelle spatiale sur les variables environnementales et la biomasse de ces producteurs primaires (PP) benthiques. Nous avons testé si leur biomasse reflétait la nature des agrégats d'habitat basées sur l'écogéomorphologie ou plutôt le continuum fluvial. Pour répondre à ces deux questions, nous avons utilisé un design à 3 échelles spatiales dans le SLR: 1) le long d'un tronçon de 250 km, 2) entre les lacs fluviaux localisés dans ce tronçon, 3) à l'intérieur de chaque lac fluvial. Les facteurs environnementaux (conductivité et TP) et la structure spatiale expliquent 59% de la variation de biomasse des trois PP benthiques. Spécifiquement, les variations de biomasses étaient le mieux expliquées par la conductivité (+) pour les macrophytes, par le ratio DIN:TDP (+) et le coefficient d'extinction lumineuse (+) pour les épiphytes et par le DOC (+) et le NH4+ (-) pour L. wollei. La structure spatiale à l'intérieur des lacs fluviaux était la plus importante composante spatiale pour tous les PP benthiques, suggérant que les effets locaux tels que l'enrichissement par les tributaire plutôt que les gradients amont-aval déterminent la biomasse de PP benthiques. Donc, la dynamique des agrégats d'habitat représente un cadre général adéquat pour expliquer les variations spatiales et la grande variété de conditions environnementales supportant des organismes aquatiques dans les grands fleuves.
Enfin, nous avons étudié le rôle écologique des tapis de L. wollei dans les écosystèmes aquatiques, en particulier comme source de nourriture et refuge pour l'amphipode Gammarus fasciatus. Nous avons offert aux amphipodes un choix entre des tapis de L. wollei et soit des chlorophytes filamenteuses ou un tapis artificiel de laine acrylique lors d'expériences en laboratoire. Nous avons aussi reconstitué la diète in situ des amphipodes à l'aide du mixing model (d13C et δ15N). Gammarus fasciatus choisissait le substrat offrant le meilleur refuge face à la lumière (Acrylique>Lyngbya=Rhizoclonium>Spirogyra). La présence de saxitoxines, la composition élémentaire des tissus et l'abondance des épiphytes n'ont eu aucun effet sur le choix de substrat. Lyngbya wollei et ses épiphytes constituaient 36 et 24 % de l'alimentation in situ de G. fasciatus alors que les chlorophytes, les macrophytes et les épiphytes associées représentaient une fraction moins importante de son alimentation. Les tapis de cyanobactéries benthiques devraient être considérés comme un bon refuge et une source de nourriture pour les petits invertébrés omnivores tels que les amphipodes. / Harmful proliferations of the filamentous cyanobacterium L. wollei forming conspicuous benthic mats on the bottom sediment have been reported with increasing frequency in the last 30 years in rivers, lakes, and springs in North America. It is a known producer of neurotoxins and volatile organic compounds (geosmin, 2-methylisoborneol) thus exerting socioeconomic and public health impacts. Lyngbya wollei is also considered a poor nutritional source for invertebrates because of its robust sheath and toxin production.
Proliferation of L. wollei in St. Lawrence River (SLR; Quebec, Canada) was first noticed in 2005. We deemed important to determine its distribution over a 250 km stretch of the SLR to elaborate predictive models of its presence and biomass based on chemical and physical characteristics. Lyngbya wollei was generally found downstream of the inflow tributaries draining farmlands. As enriched waters flowed slowly through submerged vegetation, dissolved inorganic nitrogen (DIN) concentration dropped but dissolved organic carbon (DOC) and total dissolved phosphorus (TDP) remained high, leading to a low DIN:TDP ratio. Models identified DOC (positive effect), TP (negative effect), and DIN:TDP (negative effect) as the most important variables explaining L. wollei distribution. The risk of L. wollei occurrence in the SLR was correctly forecasted in 72%-92% of all cases with an independent data set.
We then examined if hydrodynamic conditions, namely currents generated by waves and river flow, control spatial and temporal variations of L. wollei biomass in a large river system. We measured L. wollei biomass together with meteorological, physical, and chemical variables over three years at 10 sites along a gradient of exposure to current and wind in a large (148 km2) fluvial lake of SLR. Wave exposure and current velocity controlled spatial and temporal biomass variations. Biomass increased from May to November and persisted during winter. Interannual variations were primarily controlled by river flow (water level) with spring discharge dislodging mats from the previous year. As anticipated under climate change scenarios, drops in water level and rising storm intensity may lead to an increase in the areas colonized by L. wollei, together with more frequent episodes of mat disruption and beach fouling.
Additionally, we evaluated the relative importance of L. wollei with respect to macrophytes and epiphytes. We assessed the influence of the spatial scale in structuring environmental variables and biomass of these benthic primary producers (PP). We also test to which extent their biomass reflected the nature of patches based on ecogeomorphology or the river continuum. To address these two questions, we used a nested design at 3 spatial scales within the SLR: 1) along a 250-km-long upstream-downstream river stretch, 2) among three fluvial lakes located within that river stretch and 3) within each fluvial lake. Environmental factors (conductivity and TP) and spatial structure together explained 59% of the variability in biomass of all three benthic PP. Spatial variability of biomass was best explained by conductivity (+) for macrophytes, DIN:TDP ratio (+) and water extinction coefficient (+) for epiphytes and DOC (+) and NH4+ (-) for L. wollei mats. Within-lake structure was the most important spatial component for all benthic PP, suggesting that local effects, such as enrichment by the inflow of tributaries, rather than upstream-downstream gradients, determined the biomass and composition of benthic PP. Therefore patch dynamics represents a general framework which adequately covers the spatial variability and wide variety of environmental conditions experienced by aquatic organisms found in large rivers.
Finally, we investigated the ecological role of L. wollei mats in aquatic ecosystems, especially as a food source and shelter for the amphipod Gammarus fasciatus. We offered amphipods a choice between mats of L. wollei and either chlorophytes or an artificial mat made of acrylic wool in laboratory experiment. Moreover, we reconstructed in situ amphipod diet using mixing model (δ13C and δ15N). Gammarus fasciatus selected the substratum offering the best light refuge (Acrylic > Lyngbya = Rhizoclonium > Spirogyra). Presence of saxitoxins, tissue elemental composition and epiphyte abundance had no significant effect on substratum choice. Lyngbya wollei and its epiphytes constituted 36 and 24% of the in situ diet of G. fasciatus whereas chlorophytes, macrophytes and associated epiphytes represented a less important fraction of its diet. Benthic cyanobacterial mats should be considered a good shelter and food source for small omnivorous invertebrates such as amphipods.
|
74 |
Epiphytic bryophytes in natural forests and cacao agroforests of Central Sulawesi, Indonesia / Epiphytische Mosse in Primärwäldern und Kakao-Agroforsten in Zentral Sulawesi, IndonesienSporn, Simone Goda 02 October 2008 (has links)
No description available.
|
75 |
Effekte anthropogener Störung auf die Diversität kryptogamischer Epiphyten (Flechten, Moose) in einem Bergregenwald in Südecuador / Effects of anthropogenic disturbance on the diversity of cryptogamic epiphytes (lichens, bryophytes) in mountain forest of southern EcuadorNöske, Nicole 27 January 2005 (has links)
No description available.
|
76 |
Diversity and Ecology of Bryophytes and Macrolichens in Primary and Secondary Montane Quercus Forests, Cordillera de Talamanca, Costa Rica / Diversität und Ökologie der Moose und Makroflechten in primären und sekundären montanen Quercus-Wäldern, Cordillera de Talamanca, Costa RicaHolz, Ingo 06 November 2003 (has links)
Folgende Themenkomplexe wurden behandelt:
Biogeographie, Pflanzendiversität, Verbreitungsmuster
von Lebensformen und Arten in Mikrohabitaten sowie
entlang ökologischer Gradienten,
Epiphyt-Porophyt-Beziehungen, Vergesellschaftung,
Sekundärsukzession und die Auswahl von Indikatorarten.
Zum ersten Mal wird bei einer derartigen Untersuchung
die sekundäre Sukzession von Kryptogamengesellschaften
in tropischen Bergregenwäldern voll berücksichtigt. Die
Untersuchung wurde im Einzugsgebiet des Río Savegre auf
der pazifikseitigen Abdachung der westlichen Cordillera
de Talamanca (Costa Rica) durchgeführt.Kapitel 1 gibt eine generelle Einführung in
Tropische Bergregenwälder und die Bedeutung von Moosen
und Makroflechten als wichtige Komponenten dieser
Ökosysteme. Der Leser wird in das Untersuchungsgebiet,
sein Klima, seine Geologie und seine Vegetation
eingeführt.Im Kapitel 2 werden die pflanzengeographischen
Muster der Moose montaner Eichenwälder der Cordillera
de Talamanca dargestellt und diskutiert.Kapitel 3 diskutiert Diversität,
Mikrohabitatdifferenzierung und Lebensformenspektren
der Moose in einem hochmontanen Eichenwald Costa Ricas.
Es wurde versucht, die Moosflora aller Mikrohabitate
eines Eichenwaldes, inklusive der Strauch- und
Bodenschicht zu erfassen. Kapitel 4 und 5 beinhalten
die Beschreibung epiphytischer
Kryptogamengesellschaften (Moose und Makroflechten) in
Primär- und Sekundärwäldern. Mit Hilfe einer aus dem
Alpinismus abgeleiteten Klettertechnik wurden Bäume von
der Stammbasis bis in die Zweige der äußeren Krone
beprobt. Die Vegetationsaufnahmen repräsentieren die
Variation der epiphytischen Vegetation. Prozentuale
Deckungsgrade der rindenbewohnenden Moose und
Makroflechten wurden geschätzt und mit Hilfe einer
Detrended Correspondence Analysis (DCA)' und
nicht-metrischer Multi-response Permutation Procedure
(MRPP)' verglichen. Rindenproben der untersuchten Bäume
wurden mit deionisiertem Wasser extrahiert und der
pH-Wert bestimmt.Kapitel 4 behandelt die epiphytischen
Kryptogamengemeinschaften auf den dominierenden
Baumarten (Quercus copeyensis und Q. costaricensis)
primärer, hochmontaner Eichenwälder Costa Ricas.
Kapitel 5 vergleicht Artenreichtum, Vergesellschaftung
und Ökologie der epiphytischen Kryptogamen in primären
und sekundären hochmontanen Eichenwäldern Costa Ricas.
Quercus copeyensis-Bäume der oberen Baumschicht von
Primär- und Sekundärwäldern wurden beprobt mit dem Ziel
einen Einblick in Regenerationspotential, -muster und
-prozesse der Epiphytensukzession nach anthropogener
Störung zu erhalten.
|
Page generated in 0.0533 seconds