报告题目一:Carbon storage and soil biodiversity in forest landscapes in Ethiopia
报 告 人:Prof. Douglas
报告时间:2018年11月23日(星期五)18:00-20:00
报告地点:丹青楼(二教)408(多媒体录播室)
报告题目二:Mycorrhizas in cold places: an attempt to link community structure to ecosystem function
报 告 人:Prof. Douglas
报告时间:2018年11月25日(星期日)15:30-17:30
报告地点:丹青楼(二教)408(多媒体录播室)
报告人简介:
Prof. Douglas L. Godbold,维也纳自然资源和生命科学恒峰体育(原维也纳农业恒峰体育)教授,世界知名的林学家和森林生态学家。担任Forestry与Journal of Plant Nutrition & Soil Science两个期刊的编委。是以下国际主流刊物的特约审稿人:Plant & Soil, Canadian Journal of Forestry Research, Forest Ecology & Management, Tree Physiology, Global Change biology, Water Air & Soil Pollution, Plant Ecology, Canadian Journal of Botany, Chemosphere Ecology Letters, Environmental Pollution, Journal of Arid Environments, Journal of Environmental Quality, Journal of Experimental Botany, Journal of Plant Physiology, Journal of Tropical Ecology, New Phytologist, Pedobiologia, Plant Cell & Environment, Plant Physiology & Biochemistry, Scanning Microscopy.
1、主要学习经历
1976—1979年,英国苏塞克斯恒峰体育(University of Sussex)生物系,理学学士;1979—1983,英国利物浦恒峰体育(University of Liverpool)植物系,博士;1983—1985,德国哥廷根恒峰体育(University of G?ttingen)森林植物研究所,博士后.
2、主要工作经历
1984—1986,德国哥廷根恒峰体育(University of G?ttingen),森林植物研究所,皇家学会研究奖学金;1986—1997,德国哥廷根恒峰体育(University of G?ttingen),森林植物研究所,研究员;其中1992年,加拿大埃德蒙顿阿尔伯塔恒峰体育,植物系,访问科学家;1995—1996,美国哈佛恒峰体育生物和进化生物学系,Charles Bullard Fellowship奖学金;1998—2011,英国班戈恒峰体育(Bangor University),环境、自然资源和地理学院,森林科学教授;2011—至今,维也纳自然资源和生命科学恒峰体育,森林生态研究所,森林生态学教授.
3、他本人及其所在团队近期代表性论文
(1)Diversionary feeding can reduce red deer habitat selection pressure on vulnerable forest stands, but is not a panacea for red deer damage. Forest Ecology & Management. 2018, 407: 166-173.
(2)Soil organic carbon changes following degradation and conversion to cypress and tea plantations in a tropical mountain forest in Kenya. Plant & Soil. 2018, 422(1-2): 527-539.
(3)Fine Root Morphology, Biochemistry and Litter Quality Indices of Fast- and Slow-growing Woody Species in Ethiopian Highland Forest. Ecosystems. 2018, 21(3): 482-494.
(4)Effects of crown architecture and stand structure on light absorption in mixed and monospecific Fagus sylvatica and Pinus sylvestris forests along a productivity and climate gradient through Europe. Journal of Ecology. 2018; 106(2): 746-760.
(5)The Carbon Sequestration Potential of Degraded Agricultural Land in the Amhara Region of Ethiopia. Forests. 2018, 9(8).
(6)Seed Dispersal, Microsites or Competition: What Drives Gap Regeneration in an Old-Growth Forest? An Application of Spatial Point Process Modelling. Forests. 2018; 9(5).
(7)Mycorrhizas and soil ecosystem function of co-existing woody vegetation islands at the alpine tree line. Plant and Soil, 2017, 411: 467–481
(8)Response of soil microbial community to afforestation with pure and mixed species. Plant and Soil, 2017. DOI: 10.1007/s11104-016-3073-0
(9)Turbulent energy and carbon dioxide exchange along an early-successional windthrow chronosequence in the European Alps. Agricultural and Forest Meteorology, 2017, 232, 576-594
(10)Increase in heterotrophic soil respiration by temperature drives decline in soil organic carbon stocks after forest windthrow in a mountainous ecosystem. Functional Ecology, 2017. DOI: 10.1111/1365-2435.12805
(11)Elevated CO2 and Tree Species Affect Microbial Activity and Associated Aggregate Stability in Soil Amended with Litter. Forests, 2017, 8, 70; doi:10.3390/f8030070.
(12)Deforestation and land use strongly effect soil organic carbon and nitrogen stock in Northwest Ethiopia. Catena, 2017, 153, 89-99.
(13)Evaluation of the microbiome of decaying alder nodules by next generation sequencing. Endocytobiosis and Cell Research, 2017.
(14)Adaptive root foraging strategies along a boreal-temperate forest gradient. New Phytologist, 2017. doi: 10.1111/nph.14643.
(15)Fine root morphology, biochemistry and litter quality indices of fast- and slow-growing woody species in Ethiopian highland forest. Ecosystems, 2017.
(16)Fine root dynamics in Afromontane forest and adjacent land uses in the northwest Ethiopian highlands. Forests 2017, 8, 249; doi:10.3390/f8070249
(17)Tree species identity influences the vertical distribution of labile and recalcitrant carbon in a temperate deciduous forest soil. Forest Ecology & Management, 2016, 359:352-360
(18)Overyielding of temperate deciduous tree mixtures is maintained under throughfall reduction. Plant & Soil, 2016, DOI 10.1007/s11104-016-2930-1
(19)Potassium fertilization affects the distribution of fine roots but does not change ectomycorrhizal community structure. Annals of Forest Science, 2016, DOI 10.1007/s13595-016-0556-3
(20)Elevated Atmospheric CO2 Affects Ectomycorrhizal Species Abundance and Increases Sporocarp Production under Field Conditions. Forests. 2015, 6(4):256-1273.?
(21)Bacterial growth and respiration responses upon rewetting dry forest soils: Impact of drought-legacy. Soil Biol Biochem. 2013, 57: 477-486.
(22)Elevated atmospheric CO2 and humidity delay leaf fall in Betula pendula, but not in Alnus glutinosa or Populus tremula×tremuloides. Ann Forest Sci. 2014, 71(8): 831-842.
(23)Elevated CO2 enrichment induces a differential biomass response in a mixed species temperate forest plantation. New Phytol. 2013, 198(1):156-168.
(24)Effects of Elevated CO2 on Litter Chemistry and Subsequent Invertebrate Detritivore Feeding Responses. Plos One. 2014: 9(1)(25)It’s Complicated: Intraroot System Variability of Respiration and Morphological Traits in Four Deciduous????
Tree Species. Plant Physiol. 2014, 166(2):736-745.
(26)Deciduous woodland exposed to elevated atmospheric CO2 has species-specific impacts on anecic earthworms. Appl Soil Ecol. 2014, 80: 84-92.
(27)The production and turnover of extramatrical mycelium of ectomycorrhizal fungi in forest soils: role in carbon cycling. Plant & Soil. 2013, 366(1-2): 1-27.
(28)Bacterial growth and respiration responses upon rewetting dry forest soils: Impact of drought-legacy. Soil Biol Biochem. 2013, 57: 477-486.
(29)Drivers of increased soil respiration in a poplar coppice exposed to elevated CO2. Plant & Soil. 2013; 362(1-2): 93-106(30)Tree species diversity interacts with elevated CO2 to induce a greater root system response. Global Change Biol. 2013, 19(1): ???
217-228.
(31)Evaluation of methods to estimate production, biomass and turnover of ectomycorrhizal mycelium in forests soils-A review. Soil Biol Biochem. 2013, 57: 1034-1047.
(32)Bacterial salt tolerance is unrelated to soil salinity across an arid agroecosystem salinity gradient. Soil Biol Biochem. 2011, 43, 1881-1887.
(33)Free atmospheric CO2 enrichment (FACE) did not affect symbiotic N2-fixation or soil carbon content and stabilization in a mixed deciduous stand in Wales. Biogeosciences, 2010, 8, 353-364.
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