LEADER 04943nam 2201237z- 450 001 9910557498503321 005 20231214133139.0 035 $a(CKB)5400000000042846 035 $a(oapen)https://directory.doabooks.org/handle/20.500.12854/69373 035 $a(EXLCZ)995400000000042846 100 $a20202105d2020 |y 0 101 0 $aeng 135 $aurmn|---annan 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 10$aNutrient Cycling in Forest Ecosystems 210 $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2020 215 $a1 electronic resource (218 p.) 311 $a3-03936-800-1 311 $a3-03936-801-X 330 $aThe long-term productivity of forest ecosystems depends on the cycling of nutrients. The effect of carbon dioxide fertilization on forest productivity may ultimately be limited by the rate of nutrient cycling. Contemporary and future disturbances such as climatic warming, N-deposition, deforestation, short rotation sylviculture, fire (both wild and controlled), and the invasion of exotic species all place strains on the integrity of ecosystem nutrient cycling. Global differences in climate, soils, and species make it difficult to extrapolate even a single important study worldwide. Despite advances in the understanding of nutrient cycling and carbon production in forests, many questions remain. The chapters in this volume reflect many contemporary research priorities. The thirteen studies in this volume are arranged in the following subject groups: ? N and P resorption from foliage worldwide, along chronosequences and along elevation gradients; ? Litter production and decomposition; ? N and P stoichiometry as affected by N deposition, geographic gradients, species changes, and ecosystem restoration; ? Effects of N and P addition on understory biomass, litter, and soil; ? Effects of burning on soil nutrients; ? Effects of N addition on soil fauna. 606 $aResearch & information: general$2bicssc 606 $aBiology, life sciences$2bicssc 606 $aForestry & related industries$2bicssc 610 $aleaf stoichiometry 610 $aCyclocarya paliurus 610 $ageographic variations 610 $anatural populations 610 $aclimate variables 610 $anitrogen 610 $aphosphorus 610 $aN:P ratio 610 $asoil stoichiometry 610 $asoil nutrient 610 $anutrient limitations 610 $anatural grassland 610 $anatural forest 610 $asoil fauna 610 $aN addition 610 $asoil profile 610 $acommunity structure 610 $afood resources 610 $apoplar plantations 610 $aexperimental nitrogen addition 610 $aunderstory plant growth 610 $aplant nutrient 610 $anonstructural carbohydrates 610 $aAlpine treeline 610 $aNitrogen 610 $aNon-structural carbohydrates 610 $aPhosphorus 610 $aPotassium 610 $aRemobilization 610 $aStorage 610 $aUpper limits 610 $anutrient resorption 610 $anitrogen and phosphorous 610 $aplanted forests 610 $aclimate zones 610 $aplant functional types 610 $aprecipitation 610 $agreen leaf nutrient 610 $anitrogen deposition 610 $aN and P colimitation 610 $aleaf N:P stoichiometry 610 $asoil N:P stoichiometry 610 $aseasonal variations 610 $anutrition resorption 610 $aecological stoichiometry 610 $aplant-soil feedback 610 $astand age 610 $aRobinia pseudoacacia L. 610 $aforests 610 $anutrients 610 $adisturbance 610 $amanagement 610 $adiversity 610 $abiomass 610 $asoil properties 610 $aexperimental fires 610 $aUV-spectroscopy analysis 610 $athermal infrared thermometer 610 $anitrogen and phosphorus addition 610 $aunderstory plants 610 $astoichiometric ratio 610 $alitter decomposition 610 $alitter standing crop carbon 610 $aconversion coefficient 610 $aclimatic factors 610 $aTibetan Plateau 610 $ashrublands 610 $aCunninghamia lanceolata 610 $amixture effect 610 $anutrient cycling 610 $arhizosphere effect 610 $aspecies competition 615 7$aResearch & information: general 615 7$aBiology, life sciences 615 7$aForestry & related industries 700 $aQualls$b Robert G$4edt$01322911 702 $aQualls$b Robert G$4oth 906 $aBOOK 912 $a9910557498503321 996 $aNutrient Cycling in Forest Ecosystems$93035255 997 $aUNINA