Are secondary forests second-rate? Comparing peatland greenhouse gas emissions, chemical and microbial community properties between primary and secondary forests in Peninsular Malaysia.
暂无分享,去创建一个
[1] D. Murdiyarso,et al. Greenhouse gas emissions in restored secondary tropical peat swamp forests , 2019, Mitigation and Adaptation Strategies for Global Change.
[2] L. Brussaard,et al. Organic management and cover crop species steer soil microbial community structure and functionality along with soil organic matter properties , 2018, Agriculture, Ecosystems & Environment.
[3] Doreen S. Boyd,et al. Tropical Peatland Vegetation Structure and Biomass: Optimal Exploitation of Airborne Laser Scanning , 2018, Remote. Sens..
[4] Benjamin L Turner,et al. Root exudate analogues accelerate CO2 and CH4 production in tropical peat , 2018 .
[5] P. Dargusch,et al. A review of the drivers of tropical peatland degradation in South-East Asia , 2017 .
[6] B. Thornton,et al. Cross continental increase in methane ebullition under climate change , 2017, Nature Communications.
[7] L. Verchot,et al. Total and heterotrophic soil respiration in a swamp forest and oil palm plantations on peat in Central Kalimantan, Indonesia , 2017, Biogeochemistry.
[8] Martin Herold,et al. An expert system model for mapping tropical wetlands and peatlands reveals South America as the largest contributor , 2017, Global change biology.
[9] H. Behling,et al. Environmental dynamics and carbon accumulation rate of a tropical peatland in Central Sumatra, Indonesia , 2017 .
[10] N. M. Tahir,et al. Spatial and Seasonal Variations of Organic Carbon-Based Nutrients in Setiu Wetland, Malaysia , 2017 .
[11] N. Maie,et al. Evaluation on the decomposability of tropical forest peat soils after conversion to an oil palm plantation. , 2017, The Science of the total environment.
[12] T. Hirano,et al. Soil carbon dioxide emissions from a rubber plantation on tropical peat. , 2017, The Science of the total environment.
[13] Paul Aplin,et al. Impacts of conversion of tropical peat swamp forest to oil palm plantation on peat organic chemistry, physical properties and carbon stocks , 2017 .
[14] R. Padfield,et al. Keep wetlands wet: the myth of sustainable development of tropical peatlands – implications for policies and management , 2017, Global change biology.
[15] J. Juan,et al. The contribution of leaching to nutrient release from leaf litter of two emergent tree species in a Malaysian tropical peat swamp forest , 2017, Hydrobiologia.
[16] Edward T. A. Mitchard,et al. Age, extent and carbon storage of the central Congo Basin peatland complex , 2017, Nature.
[17] S. Sørensen,et al. Coping with copper: legacy effect of copper on potential activity of soil bacteria following a century of exposure. , 2016, FEMS microbiology ecology.
[18] I. Prentice,et al. Peatlands and Climate Change , 2016 .
[19] S. Frolking,et al. Impacts of land use, restoration, and climate change on tropical peat carbon stocks in the twenty-first century: implications for climate mitigation , 2016, Mitigation and Adaptation Strategies for Global Change.
[20] Soo Chin Liew,et al. Land cover distribution in the peatlands of Peninsular Malaysia, Sumatra and Borneo in 2015 with changes since 1990 , 2016 .
[21] S. Claassens,et al. Phospholipid fatty acid profiling of microbial communities–a review of interpretations and recent applications , 2015, Journal of applied microbiology.
[22] R. Yin,et al. Effects of copper on methane emission, methanogens and methanotrophs in the rhizosphere and bulk soil of rice paddy , 2015 .
[23] apani,et al. Biodiversity loss associated with oil palm plantations in Malaysia: Serving the need versus saving the nature , 2015 .
[24] B. Klarner,et al. Impact of tropical lowland rainforest conversion into rubber and oil palm plantations on soil microbial communities , 2015, Biology and Fertility of Soils.
[25] Benjamin L Turner,et al. Tropical wetlands: A missing link in the global carbon cycle? , 2014, Global biogeochemical cycles.
[26] Richard D. Bardgett,et al. Belowground biodiversity and ecosystem functioning , 2014, Nature.
[27] D. Vitt,et al. N2-fixation by methanotrophs sustains carbon and nitrogen accumulation in pristine peatlands , 2014, Biogeochemistry.
[28] L. Verchot,et al. Greenhouse gas emission factors for land use and land-use change in Southeast Asian peatlands , 2014, Mitigation and Adaptation Strategies for Global Change.
[29] E. Tuittila,et al. Methanotrophy induces nitrogen fixation during peatland development , 2013, Proceedings of the National Academy of Sciences.
[30] C. Justice,et al. High-Resolution Global Maps of 21st-Century Forest Cover Change , 2013, Science.
[31] R. Artz,et al. Microbial communities in natural and disturbed peatlands: A review , 2013 .
[32] S. Vermette,et al. The “black waters” of Malaysia: Tracking water quality from the peat swamp forest to the sea , 2012, 2012 International Symposium on Geomatics for Integrated Water Resource Management.
[33] George D. Gann,et al. Patterns of Soil Bacteria and Canopy Community Structure Related to Tropical Peatland Development , 2012, Wetlands.
[34] D. Edwards,et al. The conservation value of South East Asia's highly degraded forests: evidence from leaf-litter ants , 2011, Philosophical Transactions of the Royal Society B: Biological Sciences.
[35] L. Verchot,et al. Opportunities for reducing greenhouse gas emissions in tropical peatlands , 2010, Proceedings of the National Academy of Sciences.
[36] Andreas Richter,et al. Negligible contribution from roots to soil-borne phospholipid fatty acid fungal biomarkers 18:2ω6,9 and 18:1ω9 , 2010, Soil biology & biochemistry.
[37] Soo Chin Liew,et al. Degradation and development of peatlands in Peninsular Malaysia and in the islands of Sumatra and Borneo since 1990 , 2010 .
[38] Catherine M. Yule,et al. Loss of biodiversity and ecosystem functioning in Indo-Malayan peat swamp forests , 2010, Biodiversity and Conservation.
[39] B. Kløve,et al. Leaching of nutrients and emission of greenhouse gases from peatland cultivation at Bodin, Northern Norway , 2010 .
[40] M. Bradford,et al. Global patterns in belowground communities. , 2009, Ecology letters.
[41] Hans Joosten,et al. Greenhouse gas fluxes from tropical peatlands in south‐east Asia , 2009 .
[42] Anne J Anderson,et al. Antimicrobial activities of commercial nanoparticles against an environmental soil microbe, Pseudomonas putida KT2440 , 2009, Journal of biological engineering.
[43] Catherine M. Yule,et al. Leaf litter decomposition in a tropical peat swamp forest in Peninsular Malaysia , 2009, Wetlands Ecology and Management.
[44] C. Jackson,et al. Structural and Functional Changes with Depth in Microbial Communities in a Tropical Malaysian Peat Swamp Forest , 2009, Microbial Ecology.
[45] C. Tisdell,et al. The orangutan–oil palm conflict: economic constraints and opportunities for conservation , 2009, Biodiversity and Conservation.
[46] T. Elliott,et al. Antimicrobial efficacy of copper surfaces against spores and vegetative cells of Clostridium difficile: the germination theory. , 2008, The Journal of antimicrobial chemotherapy.
[47] L. P. Koh,et al. Is oil palm agriculture really destroying tropical biodiversity? , 2008 .
[48] R. Dick,et al. PLFA Profiling of Microbial Community Structure and Seasonal Shifts in Soils of a Douglas-fir Chronosequence , 2008, Microbial Ecology.
[49] Stephen G. Perz,et al. Road building, land use and climate change: prospects for environmental governance in the Amazon , 2008, Philosophical Transactions of the Royal Society B: Biological Sciences.
[50] D. Dowrick,et al. Sulphate reduction and the suppression of peatland methane emissions following summer drought , 2006 .
[51] S. Tyerman,et al. The role of molybdenum in agricultural plant production. , 2005, Annals of botany.
[52] Kah Joo Goh,et al. Methane fluxes from three ecosystems in tropical peatland of Sarawak, Malaysia , 2005 .
[53] A. Floren,et al. The Importance of Primary Tropical Rain Forest For Species Diversity: An Investigation Using Arboreal Ants as an example , 2005, Ecosystems.
[54] O. Nybroe,et al. Copper amendment of agricultural soil selects for bacterial antibiotic resistance in the field , 2005, Letters in applied microbiology.
[55] R. Hatano,et al. Soil CO2 flux from three ecosystems in tropical peatland of Sarawak, Malaysia , 2005 .
[56] R. J. Haynes,et al. Effects of irrigation-induced salinity and sodicity on soil microbial activity , 2003 .
[57] E. Bååth. The Use of Neutral Lipid Fatty Acids to Indicate the Physiological Conditions of Soil Fungi , 2003, Microbial Ecology.
[58] R. Gifford,et al. Soil carbon stocks and land use change: a meta analysis , 2002 .
[59] V. Wolters,et al. PLFA profiles of microbial communities in decomposing conifer litters subject to moisture stress , 2002 .
[60] K. Paustian,et al. Influence of microbial populations and residue quality on aggregate stability , 2001 .
[61] P. Hammond,et al. The diversity of beetle assemblages in different habitat types in Sabah, Malaysia. , 2000, Bulletin of entomological research.
[62] W Shotyk,et al. Interdependence of peat and vegetation in a tropical peat swamp forest. , 1999, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.
[63] R. Forman,et al. ROADS AND THEIR MAJOR ECOLOGICAL EFFECTS , 1998 .
[64] D. Bossio,et al. Impacts of Carbon and Flooding on Soil Microbial Communities: Phospholipid Fatty Acid Profiles and Substrate Utilization Patterns , 1998, Microbial Ecology.
[65] E. Smit,et al. Detection of shifts in microbial community structure and diversity in soil caused by copper contamination using amplified ribosomal DNA restriction analysis , 1997 .
[66] T. Kieft,et al. Changes in Ester-Linked Phospholipid Fatty Acid Profiles of Subsurface Bacteria during Starvation and Desiccation in a Porous Medium , 1994, Applied and environmental microbiology.
[67] E. Bååth,et al. Microbial biomass measured as total lipid phosphate in soils of different organic content , 1991 .
[68] D C White,et al. Lipid analysis in microbial ecology: quantitative approaches to the study of microbial communities. , 1989, Bioscience.
[69] B. Wilke. Effects of sodium selenite on microbial activity of mull, moder and mor soils , 1988, Biology and Fertility of Soils.
[70] M. Hamdy,et al. Effect of sodium bicarbonate on microbial activity in the rumen. , 1963 .
[71] W. J. Dyer,et al. A rapid method of total lipid extraction and purification. , 1959, Canadian journal of biochemistry and physiology.
[72] J. Holden,et al. PEATMAP: Refining estimates of global peatland distribution based on a meta-analysis , 2018 .
[73] G. Jin,et al. Effects on rhizospheric and heterotrophic respiration of conversion from primary forest to secondary forest and plantations in northeast China , 2015 .
[74] Richard T. Corlett,et al. Biodiversity and Conservation of Tropical Peat Swamp Forests , 2011 .
[75] R. Bardgett. The biology of soil , 2005 .
[76] R. Kaushik,et al. Phospholipid fatty acid - A bioindicator of environment monitoring and assessment in soil ecosystem , 2005 .
[77] R. Sass,et al. Effects of copper concentration on methane emission from rice soils. , 2005, Chemosphere.
[78] K. Inubushi,et al. Factors influencing methane emission from peat soils: Comparison of tropical and temperate wetlands , 2004, Nutrient Cycling in Agroecosystems.
[79] J. Laine,et al. Changes in mineral element concentrations in peat soils drained for forestry in Finland , 1995 .
[80] D. Fowler,et al. The response of peat wetland methane emissions to temperature, water table and sulphate deposition , 1995 .