The biology of vesicular-arbuscular mycorrhizas with special reference to their role in nutrient transfer between plants

Francis, R.

January 1985

No description available.

611

Fungal nutrient transfer

Functional diversity of mycorrhizal fungi with regard to nutrient transfer

Valtanen, Kerttu

18 December 2012

No description available.

333

577

Ökologie {Biologie} (PPN619463619)

Mechanism of Positive, Non-Additive Litter Decomposition

Yin, Na

01 July 2019

Litter decomposition is a fundamental ecosystem process. It is responsible for nutrient cycling and influences carbon (C) sequestration, and soil physical and chemical properties. In nature, litter is usually heterogeneous and may not decompose the way homogeneous litter does. For example, heterogeneous litter decomposition is frequently non-additive. This makes the rate of nutrient cycling as well as fluxes of C into and out of soil C pools impossible to predict. The most frequently proposed mechanisms for positive, non-additive decomposition include the supply of limiting mineral nutrients, the supply of available C (priming), and the improvement of micro-environmental conditions. However, all three mechanisms are controversial in the sense that no single mechanism accounts for all cases of non-additive decomposition. In mesic ecosystems, both soil microbes and soil fauna are the major causes of decomposition. Microbes decompose litter by producing extracellular enzymes. The comminution of litter by soil animals interacts with microbial activities by increasing substrate surface area. In our study, positive, non-additive decomposition of oat straw when mixed with clover was not due to enhancing microarthropod density in oat straw but associated with significantly increased microbial activity in oat straw. We further investigated the factors that contribute to positive, non-additive decomposition by testing several common hypotheses used to explain non-additive decomposition (increased water content, and the transfer of C and/or nitrogen (N) compounds from clover to oat straw). We also tested a new hypothesis, which is that C, N and other nutrients are simultaneously supplied by clover to stimulate the decomposition of oat straw. Our study indicated that the addition of water to oat straw did not increase oat straw decomposition and adding ammonium chloride only or glucose and ammonium chloride together to oat straw had no significant effect on oat straw decomposition. Glucose addition alone (Low concentration) increased oat straw decomposition but was not sufficient to predict the effect of clover litter. Either the addition of glucose, ammonium chloride and other minerals together to oat straw, or soil was in contact with oat straw and glucose and ammonium chloride were added, oat straw decomposition was stimulated as if clover were present. These results suggest that the limiting resources are some combination of C, N and other mineral nutrients and that soil itself may be a source of limiting nutrients in litter decomposition. In nature, some combination of high quality litter and soil itself may supply resources that stimulate the decomposing organisms’ activity on low quality litter and then the decomposition of low quality litter. Our research provides insight into the dynamics of heterogeneous litter decomposition and will allow us to better model nutrient cycling.

litter mixture

positive

non-additive decomposition

microarthropod density

microbial activity

C transfer

mineral nutrient transfer

Biology

Life Sciences

Sea-to-land nutrient transfer by seals and seabirds on Sable Island : isoscapes revealed by stable isotope analysis of vegetation with an echo in the island's feral horses

2013 October 1900

Recent research using stable isotope analysis has shown a dependence on migrating or breeding populations of vertebrates as vectors for the transfer of marine-derived nutrients within coastal ecosystems. Sable Island, Nova Scotia, Canada supports numerous species of plants, a variety of seabird colonies (including common [Sterna hirundo] and Arctic [Sterna paradisaea] terns), the world’s largest grey seal (Halichoerus grypus) breeding colony, and a self-sustaining population of wild (feral) horses (Equus ferus caballus). I hypothesize that nitrogen cycling within this island ecosystem is highly influenced by the input of nutrients from seals and seabirds (‘biogenic vectors’), affecting primary production and potentially stabilizing higher trophic levels (i.e., horses). To examine this relation I developed a spatially-explicit isoscape for Sable Island through stable isotope analysis of nitrogen (δ15N) in samples (n = 282) of marram grass (Ammophila breviligulata). I incorporated significant variables (i.e., distance to vector colony and distance to shoreline, r2 = 0.41) into the final parsimonious interpolation model using universal co-kriging techniques. The greatest 15N enrichment occurred within the tips and along the perimeter of the island, coinciding with greater densities of grey seals, while the lowest values occurred within the centre of the island. I then identified individual contributions of seal-, tern- and horse-mediated transfer of marine-derived nutrients inland. Marram grass exhibited higher δ15N within seal (μ = 7.5‰) and tern (μ = 5‰) colonies, while horses and biogeochemical processes (i.e., volatilization, ammonification, etc.) most likely contributed to the homogeneity within the centre of the island (μ = 3.6‰). Due to the higher densities, wider distribution, and greater 15N enrichment of marram tissues, grey seals appear to be the most important vector species while seabirds have a more localized effect. The greater availability of N within vector colonies supplemented the local vegetation community, contributing to greater vegetation cover within colony boundaries. This relation had secondary effects on the horse population, which showed correspondingly higher horse δ15N values within the tips of the island (δ15N + 1.6‰) due to consumption of 15N enriched forage. I conclude that biogenic vector species promote nutrient transfer by establishing nutrient gateways which indirectly cause cascading effects throughout the food web.

isoscape

stable isotope

nutrient transfer

trophic enrichment

nutrient cycling

nitrogen isotope

Sable Island horse

grey seal

tern

nitrogen

biogenic vector

marine-derived

kriging

nutrient gateway

Contribution à la modélisation des processus d'agrégation et de transfert d'éléments nutritifs dans les Technosols construits à partir de déchets / Contribution to the modelling of aggregation process and nutrient transfert in Technosols constructed with waste materials

Rokia, Sarah

10 January 2014

La végétalisation d'espaces en zone urbaine nécessite l'utilisation de grandes quantités de ressource naturelle terreuse. Pour préserver cette ressource non renouvelable, le génie pédologique propose une stratégie de construction de Technosols fertiles à partir du recyclage de déchets et sous-produits. Les propriétés des Technosols sont alors fortement influencées par les matériaux technogéniques qui les constituent. La formulation de mélanges performants pour la croissance des végétaux urbains passe par une analyse scientifique préalable. La fertilité des mélanges et leur évolution au cours du temps peuvent être appréciées par l'étude du processus d'agrégation et du transfert d'éléments nutritifs lors des stades précoces de la pédogenèse. Le modèle expérimental de Technosol construit proposé dans la Thèse développe une méthodologie aboutissant à la sélection de 11 matériaux (ballasts, béton, boues de station d'épuration urbaine, briques, compost de boues et de déchets verts, déchets de balayage de rue, déchets de démolition, déchets verts, terres excavées de profondeur, sous produits papetiers) représentatifs des gisements de déchets recensés au niveau européen et compatibles avec la construction de sol fertile. Le potentiel fertile initial de chaque matériau pur et de certaines combinaisons de mélanges a été mesuré. Puis des expériences menées en conditions contrôlées ont permis d'évaluer l'effet de différents facteurs pédogénétiques (e.g. anthropique, climatique et biologique) sur les processus déterminant de la fertilité des Technosols construits. Les résultats indiquent (i) qu'il est possible de construire un Technosol fertile exclusivement à partir de deux ou trois déchets aux propriétés physico-chimiques complémentaires; (ii) que les propriétés des mélanges sélectionnés peuvent être modélisées à partir des propriétés initiales de leurs matériaux parents.(iii) que lors des premiers stades d'évolution pédogénétique des mélanges, des agrégats stables se forment en fonction de la nature et des propriétés des matériaux parents, (iv) que les transferts d'éléments nutritifs sont fortement dépendants de la nature des matières organiques et du procédé de mélange des particules entre elles. La libération d'éléments nutritifs (e.g. phosphore) serait liée à la taille et la quantité des agrégats formés et en corollaire à la mise en place d'une organisation porale. Les connaissances acquises sur le fonctionnement et l'évolution des Technosols construits à partir de déchets apportent des connaissances nouvelles pour le génie pédologique. La méthode de choix de déchets ainsi que le procédé de formulation de mélanges développés dans ces travaux permettent d'obtenir des mélanges voire des sols construits performants par rapport à des usages attendus. Les modèles d'évolution des mélanges permettent de prédire au cours du temps la fertilité physico-chimique des Technosols construits. Dans le cadre du programme SITERRE-ADEME (2010-2015), les résultats acquis constituent des bases incontournables dans le développement d'un outil d'aide à la décision pour les gestionnaires (e.g. collectivités, bureaux d'étude, entreprises) auquel doit être associée une expertise sur la construction de sol pour la production de biomasse végétale / Greening of urban spaces requires large amounts of arable soil which is a non-renewable resource. To preserve this resource, a strategy is proposed to build fertile Technosols from wastes and by-products by pedological engineering. The properties of Technosols are highly influenced by their constitutive technogenic materials. In order To create favourable mixtures of materials for urban plant growth a preliminary scientific analysis is required. The fertility of the mixtures and their evolution can be assessed by the study of the aggregation process and nutrients transfer during the first stage of pedogenesis. An experimental model of constructed Technosol is proposed in this work. From this model a methodology is developed for the selection of eleven constitutive materials (e.g. bricks, compost made of sludge and green waste, concrete, demolition rubble, excavated earth materials, green wastes, paper mill sludge, sewage sludge, street sweeping wastes, track ballast). Each of these materials is representative of wastes deposits listed European wide and they are suitable candidates for the construction of fertile soils. The fertility of each pure material and of selected mixtures has been determined. Thereafter, experiments under controlled conditions enabled to assess the impact of different pedogenesis factors (e.g. anthropogenic, climatic and biological) involved in the definition of the fertility of constructed Technosols. The results demonstrate (i) the feasibility of the formulation of fertile constructed Technosols exclusively with two or three wastes presenting contrasted physico-chemical properties; and (ii) that the properties of selected mixtures can be modelled using the initial properties of their constitutive parent materials ; (iii) that during the first stage of pedogenesis of the mixtures, depending on parent materials nature and properties, stable aggregates can be formed, (iv) that nutrients transfer are highly dependent on organic matter nature and the process of particles mixing. The delivery of nutrients (e.g. phosphorus) seems to be related to the amounts and size of the formed aggregates and, consequently, to the established porosity. The understanding of the functioning and evolution of Technosols constructed with waste materials provides new knowledge for the development of pedological engineering. The methodology of wastes selection and the mixing process developed in this work enables us to propose mixtures and constructed soils favourable to various uses. The evolution models of the mixtures developed in this work allow the prediction of the physico-chemical fertility of constructed Technosols. The results acquired during this thesis are the main basis of a decision support tool for green spaces operators developed in the framework of the research program SITERRE-ADEME (2010-2015). The use of this decision support tool for plant biomass production, has to be associated with an expertise in soil construction

Technosol construit

Génie pédologique

Déchets

Agrégation

Transfert d'éléments

Fertilité

Phosphore

Constructed Technosols

Pedological engineering

Wastes

Aggregation

Nutrient transfer

Fertility

Phosphorus

631.422