Biblio
Export 140 results:
Author Title [ Type] Year Filters: First Letter Of Last Name is L [Clear All Filters]
Long-term interactive effects of N addition with P and K availability on N status of Sphagnum.. Environmental Pollution . 237
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2018. Long-term interactive effects of N addition with P and K availability on N status of Sphagnum.. Environmental Pollution . 237
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2018. Long-term nitrogen deposition increases phosphorus limitation of bryophytes in an ombrotrophic bog. Plant Ecology. 196(1):111-121.
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2008. Long-term nitrogen deposition increases phosphorus limitation of bryophytes in an ombrotrophic bog. Plant Ecology. 196:111-121.
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2008. Methane emissions from soils: synthesis and analysis of a large UK data set. Global Change Biology. 18(5):1657-1669.
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2012. Methane indicator values for peatlands: a comparison of species and functional groups. Global Change Biology. 19(4):1141-1150.
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2013. Methane indicator values for peatlands: a comparison of species and functional groups. Global Change Biology. 19(4):1141-1150.
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2013. Nitrous oxide emissions from a peatbog after 13 years of experimental nitrogen deposition.. Biogeosciences. 14(24):5753-5764.
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2017. Nitrous oxide emissions from a peatbog after 13 years of experimental nitrogen deposition.. Biogeosciences. 14(24):5753-5764.
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2017. Physiological and morphological effects of long-term ammonium or nitrate deposition on the green and red (shade and open grown) Sphagnum capillifolium. Environmental and Experimental Botany. 72(2):140-148.
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2011. PK additions modify the effects of N dose and form on species composition, species litter chemistry and peat chemistry in a Scottish peatland. Biogeochemistry. 116(1-3):39-53.
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2013. PK additions modify the effects of N dose and form on species composition, species litter chemistry and peat chemistry in a Scottish peatland. Biogeochemistry. 116(1-3):39-53.
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2013. Potassium and phosphorus additions modify the response of Sphagnum capillifolium growing on a Scottish ombrotrophic bog to enhanced nitrogen deposition.. Applied Geochemistry. 22(6):1111-1121.
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2007. Quantification of uncertainty in trace gas fluxes measured by the static chamber method. European Journal of Soil Science. 62(6):811-821.
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2011. Quantification of uncertainty in trace gas fluxes measured by the static chamber method. European Journal of Soil Science. 62(6):811-821.
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2011. Quantifying dry NH3 deposition from an automated NH3 release system to ombrotrophic bog vegetation. Water, Air and Soil Pollution: Focus. 4:207-218.
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2004. The recovery of Sphagnum capillifolium following exposure to temperatures of simulated moorland fires: a glasshouse experiment.. Plant Ecology & Diversity. 10(1):77-88.
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2017. Response of a peat bog vegetation community to long‐term experimental addition of nitrogen. J Ecol. . 107:1167-1186
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2019. Response of a peat bog vegetation community to long‐term experimental addition of nitrogen. J Ecol. . 107:1167-1186
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2019. Response of a peat bog vegetation community to long‐term experimental addition of nitrogen. J Ecol. . 107:1167-1186
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2019. Response of enchytraeid worm populations to different forms of nitrogen (ammonia, ammonium, and nitrate) deposition.. Soil Organisms. 81(2):225-236.
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2009. Response of phosphomonoesterase activity in the lichen Cladonia portentosa to nitrogen and phosphorus enrichment in a field manipulation experiment. New Phytologist. 186(4):926-933.
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2010. Response of Sphagnum papillosum and Drosera rotundifolia to Reduced and Oxidized Wet Nitrogen Deposition. Folia Geobotanica. 47(2)
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2012. Sphagnum can ‘filter’ N deposition, but effects on the plant and pore water depend on the N form. Science of the Total Environment . 559:113–120.
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2016. Sphagnum can ‘filter’ N deposition, but effects on the plant and pore water depend on the N form. Science of the Total Environment. 559:113-120.
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2016.