15 results on '"Murray, Phil J."'
Search Results
2. Attribution of explanatory factors for change in soil organic carbon density in the native grasslands of Inner Mongolia, China
- Author
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Jin, Dongyan, Murray, Phil J., Xin, Xiaoping, Qin, Yifei, Chen, Baorui, Qing, Gele, Zhang, Zhao, and Yan, Ruirui
- Published
- 2018
- Full Text
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3. Modest enhancements to conventional grassland diversity improve the provision of pollination services
- Author
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Orford, Katherine A., Murray, Phil J., Vaughan, Ian P., and Memmott, Jane
- Published
- 2016
4. Larger phylogenetic distances in litter mixtures: lower microbial biomass and higher C/N ratios but equal mass loss
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Pan, Xu, Berg, Matty P., Butenschoen, Olaf, Murray, Phil J., Bartish, Igor V., Cornelissen, Johannes H., Dong, Ming, and Prinzing, Andreas
- Published
- 2015
5. Impacts of field margin orientation on populations of soil‐dwelling invertebrates in relation to the direction and intensity of field traffic.
- Author
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Carlesso, Léa, Beadle, Andrew, Cook, Samantha M., Hartwell, Graham, Mead, Andrew, Ritz, Karl, Sparkes, Debbie, Wu, Lianhai, and Murray, Phil J.
- Subjects
INVERTEBRATE populations ,SOIL invertebrates ,SOIL management ,CROP rotation ,INDUCTIVE effect - Abstract
Sown field margins are a central part of agri‐environmental schemes aiming to improve biodiversity and ecosystem services in agricultural landscapes. Despite the knowledge that key services are delivered by belowground biodiversity, the impacts of field margins on populations of soil invertebrates both within the margins and the neighbouring crops remain unclear. We investigated the effect of field margin orientation with respect to the direction of the tramlines upon populations of soil‐dwelling mesofauna with focus on Acari (mites) and Collembola (springtails). Two margins on adjacent sides of the same field and their neighbouring cropped areas were examined: one margin oriented perpendicular to the tramlines, and one parallel to the tramlines. This sampling design was repeated on two farms with distinct soil management (no till vs. minimum tillage) and crop rotation (diverse‐long‐rotation vs. cereal/oilseed‐short‐rotation) in two seasons (autumn vs. spring) over two years. The distribution of invertebrates in the cropped areas depended on the orientation of the margins and the taxa studied. Reduced abundance of Collembola and Acari were found at both farms in the cropped area where machinery turns (margin perpendicular to tramlines), in comparison with the cropped area where margins and tramlines were parallel. This study suggests the existence of interacting impacts between the margins and field operations (trafficking and resulting compaction) on populations of soil mesofauna. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
6. High‐yielding forage grass cultivars increase root biomass and soil organic carbon stocks compared with mixed‐species permanent pasture in temperate soil.
- Author
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Gregory, Andrew S., Joynes, Adrian, Dixon, Elizabeth R., Beaumont, Deborah A., Murray, Phil J., Humphreys, Mike W., Richter, Goetz M., and Dungait, Jennifer A. J.
- Subjects
FLUVISOLS ,CULTIVARS ,LOLIUM perenne ,PASTURES ,BIOMASS ,CROP yields ,GRASSLAND soils ,RYEGRASSES - Abstract
Agricultural grass cultivars bred for increased forage yield commonly have extensive root systems. As roots are an important input of organic matter into the soil, it follows that such cultivars could lead to important increases in soil organic carbon (SOC), but this, and the mechanisms involved, are poorly understood with little empirical field evidence. We assessed the effect of two cultivars, Lolium perenne L. cv. "AberMagic" and L. perenne L. × Festuca pratensis Huds. cv. "Prior", in comparison with mixed‐species permanent pasture ("Pasture") in a field experiment on temperate alluvial soil in the southwest UK. Root and SOC stocks, and specific plant‐derived lipids as mechanistic biomarkers for shoot and root inputs of C, were measured on intact 1‐m volumetric soil cores collected on four dates in 2013–2015. Total grass yields were greater for both grass cultivars (40–43 Mg ha−1) than Pasture (39 Mg ha−1), and by 2015 root stocks in the upper 0.1 m were significantly greater by more than 4.7 Mg ha−1. At 0.1–0.3 m depth, SOC stocks (per 0.1‐m depth) were significantly greater under the two grass cultivars (24–50 Mg ha−1) compared to Pasture (18–32 Mg ha−1). In the full 1‐m profile, mean SOC stocks were 137, 133 and 110 Mg ha−1 for AberMagic, Prior and Pasture, respectively, matching root biomass distribution. Odd‐chain n‐alkane concentrations were significantly greater for shoots than roots (274 vs. 64 mg kg−1, respectively), and roots had significantly greater concentrations than shoots of even‐chain hydroxy fatty acids (1829 vs. 305 mg kg−1, respectively) and diacids (317 vs. 93 mg kg−1, respectively). This confirmed lipids as candidate biomarkers for distinguishing shoot and root inputs into the soil, with roots being the dominant source of SOC. Based on the observations of increased forage yield and SOC stock, high‐yielding forage grass cultivars can contribute to future strategies for climate‐smart agriculture in grassland‐dominated temperate regions. Highlights: Selected root traits for increased depth, density and diameter may increase SOC in grassland.The effect of two high‐yielding forage grass cultivars were assessed in a field trial.Fast‐growing, high‐yielding cultivars enhanced root and SOC stocks compared to typical pasture.Lipid biomarkers confirmed that root inputs were the predominant C input to soil. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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7. Influence of N doses and form on 15N natural abundance of pepper plants: considerations for using δ15N values as indicator of N source.
- Author
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Flores, Pilar, Murray, Phil J, Hellín, Pilar, and Fenoll, Jose
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- 2011
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8. Soil compaction effects on litter decomposition in an arable field: Implications for management of crop residues and headlands.
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Carlesso, Lea, Beadle, Andrew, Cook, Samantha M., Evans, Jess, Hartwell, Graham, Ritz, Karl, Sparkes, Debbie, Wu, Lianhai, and Murray, Phil J.
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SOIL compaction , *PLANT litter decomposition , *CHEMICAL decomposition , *CROP residues , *CROP management - Abstract
Abstract Soil compaction is a major threat to agricultural soils. Heavy machinery is responsible for damaging soil chemical, physical and biological properties. Among these, organic matter decomposition, which is predominantly mediated by the soil biota, is a necessary process since it underpins nutrient cycling and the provision of plant nutrients. Understanding factors which impact the functionality of the biota is therefore necessary to improve agricultural practices. To better understand the effects of compaction on the soil system, we determined the effects of soil bulk density and soil penetration resistance on the decomposition rates of litter in three distinct field zones: a grass margin, sown at the edge of the field adjacent to the crop, tramlines in the crop:margin interface, and crop. Three litters of different quality (ryegrass, straw residues and mixed litter) were buried for 1, 2, 4 and 6 months in litter bags comprising two different mesh sizes (0.02 and 2 mm). Bulk density and soil penetration resistance were greater in the compacted tramline than in the margin or the crop. The greatest amount of litter remaining in the bags after 6 months was found in the tramline, and the least in the grass margin. Differences between treatments increased with burial time. No significant differences in mass loss between the two mesh sizes was detected before the fourth month, implying that microbial activities were the main processes involved in the early stages of decomposition. Decomposition in the tramline was clearly affected by the degradation of soil structure due to heavy compaction. This study shows that soil conditions at the edges of arable fields affect major soil processes such as decomposition. It also reveals the potential to mitigate soil degradation by managing the headland, the crop residues and the machinery traffic in the field. [ABSTRACT FROM AUTHOR]
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- 2019
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9. Assessment of soil water, carbon and nitrogen cycling in reseeded grassland on the North Wyke Farm Platform using a process-based model.
- Author
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Li, Yuefen, Liu, Yi, Harris, Paul, Sint, Hadewij, Murray, Phil J., Lee, Michael R.F., and Wu, Lianhai
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AGRICULTURAL mathematics , *GRASSLANDS , *FORESTS & forestry , *PLANT-soil relationships , *SOIL moisture - Abstract
The North Wyke Farm Platform (NWFP) generates large volumes of temporally-indexed data that provides a valuable test-bed for agricultural mathematical models in temperate grasslands. In our study, we used the primary datasets generated from the NWFP ( https://nwfp.rothamsted.ac.uk/ ) to validate the SPACSYS model in terms of the dynamics of water loss and forage dry matter yield estimated through cutting. The SPACSYS model is capable of simulating soil water, carbon (C) and nitrogen (N) balance in the soil-plant-atmosphere system. The validated model was then used to simulate the responses of soil water, C and N to reseeding grass cultivars with either high sugar ( Lolium perenne L. cv. AberMagic) or deep rooting ( Festulolium cv. Prior) traits. Simulation results demonstrated that the SPACSYS model could predict reliably soil water, C and N cycling in reseeded grassland. Compared to AberMagic, the Prior grass could fix more C in the second year following reseeding, whereas less C was lost through soil respiration in the first transition year. In comparison to the grass cultivar of the permanent pasture that existed before reseeding, both grasses reduced N losses through runoff and contributed to reducing water loss, especially Prior in relation to the latter. The SPACSYS model could predict these differences as supported by the rich dataset from the NWFP, providing a tool for future predictions on less characterized pasture. [ABSTRACT FROM AUTHOR]
- Published
- 2017
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10. Janzen-Connell patterns are not the result of Janzen-Connell process: Oak recruitment in temperate forests.
- Author
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Deniau, Maud, Jung, Vincent, Le Lann, Cécile, Morra, Thibault, Murray, Phil J., and Prinzing, Andreas
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OAK , *SEEDLINGS , *TREE mortality , *PLANT diversity , *STATISTICAL hypothesis testing - Abstract
According to the Janzen-Connell hypothesis, seedling mortality is greater close to conspecific (or closely related) adult trees because of higher enemy pressure, ultimately increasing local tree-species diversity. However, this pattern ( i.e. a decline of seedling performance close to conspecific or closely related adults) could also result from other processes: (1) heterospecific adults might positively affect seedlings; (2) conspecific (or closely related) adults might negatively affect seedlings by causing a deterioration of the microenvironment. We tested these hypotheses, accounting also for sizes of adults. We planted oak-seedlings in a temperate forest, characterized their adult neighbourhoods, measured 26 microenvironmental conditions, seedling mortality during one year, budburst and leaf herbivory. We detected Janzen-Connell-like patterns (frequent lack of budburst close to conspecific adults; high seedling mortality close to closely related adults) that were consistent with the Janzen-Connell process. However, these patterns were either counteracted by non-Janzen-Connell processes such as a favourable microenvironment or were weak with little explained variance. We detected Janzen-Connell-like patterns that were not consistent with the Janzen-Connell process: proximity to heterospecific adults per se decreased leaf herbivory partly due to microenvironmental effects, such that a lower leaf herbivory decreased seedling mortality. Overall, the spatial pattern of tree recruitment may resemble that predicted by Janzen-Connell but result from different processes: notably heterospecific adults creating refuges from enemies, facilitating the establishment of oaks below non-oaks without hindering their establishment below oaks. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
11. Mycorrhizae support oaks growing in a phylogenetically distant neighbourhood.
- Author
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Yguel, Benjamin, Courty, Pierre-Emmanuel, Jactel, Hervé, Xu Pan, Butenschoen, Olaf, Murray, Phil J., and Prinzing, Andreas
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MYCORRHIZAS , *HOST plants , *OAK , *MUTUALISM (Biology) , *ECTOMYCORRHIZAL fungi , *SOIL fertility , *PHYSIOLOGY - Abstract
Host-plants may rarely leave their ancestral niche and in which case they tend to be surrounded by phylogenetically distant neighbours. Phylogenetically isolated host-plants might share few mutualists with their neighbours and might suffer from a decrease in mutualist support. In addition host plants leaving their ancestral niche might face a deterioration of their abiotic and biotic environment and might hence need to invest more into mutualist partners. We tested whether phylogenetic isolation of hosts from neighbours decreases or increases abundance and activity of their mutualists and whether mutualist activity may help to compensate deterioration of the environment. We study oak-hosts and their ectomycorrhizal fungi mutualists established in the litter layer formed by the phylogenetically closely or distantly related neighbourhood. We find that oaks surrounded by phylogenetically distant neighbours show increased abundance and enzymatic activity of ectomycorrhizal fungi in the litter. Moreover, oaks surrounded by phylogenetically distant neighbours also show delayed budburst but ectomycorrhizal fungi activity partly compensates this negative effect of phylogenetic isolation. This suggests decreased nutrient availability in a phylogenetically distant litter partly compensated by increased litter-degradation by ectomycorrhizal fungi activity. Most observed effects of phylogenetic isolation cannot be explained by a change in baseline soil fertility (as reflected by nutritional status of fresh oak litter, or soil microbial biomass and activity) nor by simple reduction of percentages of oak neighbours, nor by the presence of gymnosperms. Our results show that colonizing new niche represented by the presence of distantly related neighbours may delay plant phenology but may be supported by mycorrhizal mutualists. Studies on other host-plant species are required to generalize our findings. [ABSTRACT FROM AUTHOR]
- Published
- 2014
- Full Text
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12. Long-term exclusion of plant-inputs to soil reduces the functional capacity of microbial communities to mineralise recalcitrant root-derived carbon sources
- Author
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Paterson, Eric, Sim, Allan, Osborne, Shona M., and Murray, Phil J.
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MICROORGANISM populations , *BIOMINERALIZATION , *PLANT roots , *CARBON in soils , *SOIL microbiology , *BIOMASS , *HUMUS , *BIOMARKERS - Abstract
Abstract: Microbial communities in soil are highly species-rich, recognition of which has led to the view that functional redundancy within communities may buffer many impacts of altered community structure on soil functions. In this study we investigated the impact of long-term (>50 years) exclusion of plant-inputs (bare-fallow treatment) on soil microbial community structure and on the ability of the microbial biomass to mineralise tracer additions of 13C-labelled plant-derived C-substrates. Exclusion of plant-inputs resulted in depletion of soil organic matter (SOM) and a reduction in microbial biomass size. The microbial community structure was also strongly affected, as indicated by the distinct phospholipid fatty acid (PLFA) profiles in bare-fallow and grassland soils. Mineralisation of labile plant-derived substrates was not perturbed by the bare-fallow treatment. The incorporation of labile plant-derived C into PLFA biomarkers was found to differ between soils, reflecting the distinct community structures of the soils and indicating that these substrates were utilised by a broad range of microbial groups. In contrast, the mineralisation of recalcitrant plant-derived substrates was reduced in bare-fallow soil and the fate of substrate-derived C within PLFA biomarkers was, initially, similar between the soils. These results indicate that utilisation of these recalcitrant substrates was a function restricted to specific groups, and that exclusion of plant-derived inputs to soil had reduced the capacity of bare-fallow microbial communities to utilise this substrate type. Therefore, the study suggests that long-term selective pressure on microbial communities, resulting in altered community structure, may also result in altered functional attributes. This structure–function relationship was apparent for utilisation of recalcitrant plant-derived substrates, but not for the more widely distributed attribute of labile C-substrate utilisation. [Copyright &y& Elsevier]
- Published
- 2011
- Full Text
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13. Starving the soil of plant inputs for 50 years reduces abundance but not diversity of soil bacterial communities
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Hirsch, Penny R., Gilliam, Lucy M., Sohi, Saran P., Williams, Jennie K., Clark, Ian M., and Murray, Phil J.
- Subjects
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SOIL microbiology , *PLANT-soil relationships , *BIODIVERSITY , *BIOTIC communities , *SOIL invertebrates , *COMPARATIVE studies , *TILLAGE , *CARBON in soils , *GRASSLANDS , *BACTERIA - Abstract
Abstract: If soil communities rely on plant-derived carbon, is biodiversity lost when this primary source is removed? Soil microbial and mesofaunal communities at the Rothamsted Highfield site were compared under a mixed grass sward, arable rotation and a section maintained as a bare-fallow for the past 50 years by regular tillage. Organic matter reserves have been degraded and microbial and mesofaunal numbers and mite diversity have declined in this unique bare-fallow site, where fresh carbon inputs have been drastically reduced. However, it supports a species-rich metabolically active bacterial community of similar diversity to that in soil maintained as grass sward. Thus in contrast to soil mesofauna, bacterial diversity (but not abundance) is apparently independent of plant inputs. [Copyright &y& Elsevier]
- Published
- 2009
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14. The effects of the insecticide chlorpyrifos on spider and Collembola communities
- Author
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Fountain, Michelle T., Brown, Valerie K., Gange, Alan C., Symondson, William O.C., and Murray, Phil J.
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ACARICIDES , *ORGANOPHOSPHORUS compounds , *CHOLINESTERASE-inhibiting insecticides , *POLLUTION - Abstract
Summary: The effects of chlorpyrifos on aquatic systems are well documented. However, the consequences of the pesticide on soil food webs are poorly understood. In this field study, we hypothesised that the addition of a soil insecticide to an area of upland grassland would impact spider and Collembola communities by decreasing numbers of spiders, consequently, causing an increase in detritivore numbers and diversity. Chlorpyrifos was added to plots on an upland grassland in a randomised block design. Populations of Collembola and spiders were sampled by means of pitfall traps (activity density) and identified to species. Twelve species of Collembola were identified from the insecticide-treated and control plots. Species diversity, richness and evenness were all reduced in the chlorpyrifos plots, although the total number of Collembola increased ten-fold despite the abundance of some spider species being reduced. The dominant collembolan in the insecticide-treated plots was Ceratophysella denticulata, accounting for over 95% of the population. Forty-three species of spider were identified. There were a reduced number of spiders in insecticide-treated plots due mainly to a lower number of the linyphiid, Tiso vagans. However, there was no significant difference in spider diversity between the control and insecticide treatments. We discuss possible explanations for the increase in abundance of one collembolan species in response to chlorpyrifos and the consequences of this. The study emphasises the importance of understanding the effects of soil management practices on soil biodiversity, which is under increasing pressure from land development and food production. It also highlights the need for identification of soil invertebrates to an ‘appropriate’ taxonomic level for biodiversity estimates. [Copyright &y& Elsevier]
- Published
- 2007
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15. Influence of N doses and form on ¹⁵N natural abundance of pepper plants: considerations for using δ¹⁵N values as indicator of N source.
- Author
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Flores P, Murray PJ, Hellín P, and Fenoll J
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- Algorithms, Feasibility Studies, Manure, Nitrates metabolism, Nitro Compounds metabolism, Nitrogen Compounds metabolism, Nitrogen Isotopes, Plant Roots metabolism, Plant Shoots metabolism, Quaternary Ammonium Compounds metabolism, Capsicum growth & development, Capsicum metabolism, Fertilizers, Food Inspection methods, Food, Organic analysis, Fruit metabolism, Nitrogen Cycle
- Abstract
Background: The aim of this study was to ascertain the effect of the N form (NO(3) (-) , NH(4) (+) and organic N) and N concentration on plant isotopic fractionation and on the contribution of the different N sources to the plant N budget, in order to evaluate the feasibility of using plant δ(15) N values for discriminating between conventional and organic crops. To this end, different N concentrations (applied as NO(3) (-) ), N forms (NO(3) (-) versus NH(4) (+) ), and increasing NO(3) (-) applications to an organic N-based fertilization regime were studied., Results: When using NO(3) (-) as N source, intra-plant fractionation was significant and tended to increase when NO(3) (-) concentration increased in the root medium. However, negligible net isotopic fractionation was observed when comparing theoretical and measured plant δ(15) N values. On the other hand, when plants are fertilized with a mixture of NO(3) (-) and NH(4) (+) , differences in uptake patterns for both salts could result in variation in plant δ(15) N regarding to the expected value. Finally, the application of NO(3) (-) to plants was detected when it was combined with high levels of organic N sources, from 99:1 organic:inorganic N ratio., Conclusion: Under certain conditions and following some considerations concerning sampling, δ(15) N values can be considered to be a potential tool to guarantee the authenticity of organic products., (Copyright © 2011 Society of Chemical Industry.)
- Published
- 2011
- Full Text
- View/download PDF
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