N concentration of old leaves and twigs is more sensitive to stand density than that of young ones in Chinese fir plantations: a case study in subtropical China

Yuebao Di; Xiaoli Fu; Huimin Wang; Wenhua Li; Silong Wang

doi:10.1007/s11676-017-0431-6

Journal of Forestry Research ›› 2017, Vol. 29 ›› Issue (1) : 163 -169. DOI: 10.1007/s11676-017-0431-6

Original Paper

N concentration of old leaves and twigs is more sensitive to stand density than that of young ones in Chinese fir plantations: a case study in subtropical China

Yuebao Di ¹^,²^,³
, Xiaoli Fu ¹^,³
, Huimin Wang ¹^,²^,³^,^c
, Wenhua Li ¹
, Silong Wang ⁴

Author information +

History +

PDF

Abstract

Young leaves are conventionally used in the analysis to study the nutrient status of evergreen plants and their responses to environmental changes, but the role of old leaves remains poorly understood. We selected two stand types in 31-year-old Chinese fir (Cunninghamia lanceolata) plantations with similar soil conditions but different stand densities, to test the hypothesis that nitrogen (N) concentration of old leaves and twigs is more sensitive to stand density than that of young ones. Leaves and twigs were sampled and sorted into young (one-year-old) and old (two- and three-year-old) groups. Significant differences in N concentration and carbon: nitrogen ratio between the low-density stand and high-density stand were only found in the old leaves and twigs but not in the young ones. Although the N resorption efficiency did not vary significantly with stand density, the annual N resorption rates were increased in old leaves and relatively young twigs at high stand density. These results show the potential use of old tissues in the nutrient analysis in Chinese fir plantations. Testing the generality of these results could improve the use of foliar analysis as an indicator of nutrient status and environmental changes in evergreen tree species.

Keywords

Foliar analysis / Twig / Nitrogen / Nutrient resorption / Stand density

Cite this article

Download citation ▾

Yuebao Di, Xiaoli Fu, Huimin Wang, Wenhua Li, Silong Wang. N concentration of old leaves and twigs is more sensitive to stand density than that of young ones in Chinese fir plantations: a case study in subtropical China. Journal of Forestry Research, 2017, 29(1): 163-169 DOI:10.1007/s11676-017-0431-6

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Aerts R. Nutrient resorption from senescing leaves of perennials: Are there general patterns?. J Ecol, 1996, 84(4): 597-608.

[2]	Aschan G, Pfanz H. Non-foliar photosynthesis-a strategy of additional carbon acquisition. Flora, 2003, 198(2): 81-97.

[3]	Brix H. Lousier JD, Brix H, Brockley R, Carter R, Marshall VG. Mechanisms of response to fertilization. II. Utilization by trees and stands. Improving forest fertilization decision-making in British Columbia, 1991, Victoria: BCMoF 76 93

[4]	Bussotti F, Pollastrini M. Evaluation of leaf features in forest trees: methods, techniques, obtainable information and limits. Ecol Indic, 2015, 52: 219-230.

[5]	Carlyle JC. Nutrient management in a Pinus radiata plantation after thinning: the effect of thinning and residues on nutrient distribution, mineral nitrogen fluxes, and extractable phosphorus. Can J For Res, 1995, 25(8): 1278-1291.

[6]	Casper BB, Jackson RB. Plant competition underground. Annu Rev Ecol Syst, 1997, 28: 545-570.

[7]	Chen CY, Liao LP, Wang SL. Ecology of Chinese fir plantation forest, 2000, Beijing: Science Press 85 99 (in Chinese)

[8]	Chen FS, Niklas KJ, Liu Y, Fang XM, Wan SZ, Wang H. Nitrogen and phosphorus additions alter nutrient dynamics but not resorption efficiencies of Chinese fir leaves and twigs differing in age. Tree Physiol, 2015, 35(10): 1106-1117.

[9]	Escudero A, Mediavilla S. Decline in photosynthetic nitrogen use efficiency with leaf age and nitrogen resorption as determinants of leaf life span. J Ecol, 2003, 91(5): 880-889.

[10]	Ewers FW, Schmid R. Longevity of needle fascicles of Pinus longaeva (Bristlecone pine) and other North American pines. Oecologia, 1981, 51(1): 107-115.

[11]	Fu X, Wang J, Di Y, Wang H. Differences in fine-root biomass of trees and understory vegetation among stand types in subtropical forests. PLoS One, 2015 10 6 e0128894

[12]	Grove T. Twig and foliar nutrient concentrations in relation to nitrogen and phosphorus supply in a eucalypt (Eucalyptus diversicolor F. Muell.) and an understorey legume (Bossiaea laidlawiana Tovey and Morris). Plant Soil, 1990, 126(2): 265-275.

[13]	Hobbie SE, Gough L. Foliar and soil nutrients in tundra on glacial landscapes of contrasting ages in northern Alaska. Oecologia, 2002, 131(3): 453-462.

[14]	Inagaki Y, Kuramoto S, Torii A, Shinomiya Y, Fukata H. Effects of thinning on leaf-fall and leaf-litter nitrogen concentration in hinoki cypress (Chamaecyparis obtusa Endlicher) plantation stands in Japan. For Ecol Manag, 2008, 255(5): 1859-1867.

[15]	Jones JB, Case VW. Westerman RL. Sampling, handling, and analyzing plant tissue samples. Soil testing and plant analysis, 1990 3 Madison: SSSA 389 427

[16]	Kochsiek A, Tan S, Russo SE. Fine root dynamics in relation to nutrients in oligotrophic Bornean rain forest soils. Plant Ecol, 2013, 214(6): 869-882.

[17]	Lemaire G, Jeuffroy M-H, Gastal F. Diagnosis tool for plant and crop N status in vegetative stage: theory and practices for crop N management. Eur J Agron, 2008, 28(4): 614-624.

[18]	Litton CM, Ryan MG, Knight DH. Effects of tree density and stand age on carbon allocation patterns in postfire lodgepole pine. Ecol Appl, 2004, 14(2): 460-475.

[19]	Luo T, Luo J, Pan Y. Leaf traits and associated ecosystem characteristics across subtropical and timberline forests in the Gongga Mountains Eastern Tibetan Plateau. Oecologia, 2005, 142(2): 261-273.

[20]	Luo J, Li H, Liu T, Polle A, Peng C, Luo ZB. Nitrogen metabolism of two contrasting poplar species during acclimation to limiting nitrogen availability. J Exp Biol, 2013, 64(14): 4207-4224.

[21]	Luyssaert S, Raitio H, Vervaeke P, Mertens J, Lust N. Sampling procedure for the foliar analysis of deciduous trees. J Environ Monit, 2002, 4(6): 858-864.

[22]	Marschner H. Marschner’s mineral nutrition of higher plants, 2011, London: Academic press 301 312

[23]	Medhurst JL, Beadle CL. Photosynthetic capacity and foliar nitrogen distribution in Eucalyptus nitens is altered by high-intensity thinning. Tree Physiol, 2005, 25(8): 981-991.

[24]	Messina MG. Response of Eucalyptus regnans F. Muell. to thinning and urea fertilization in New Zealand. For Ecol Manag, 1992, 51(4): 269-283.

[25]	Millard P, Grelet G. Nitrogen storage and remobilization by trees: ecophysiological relevance in a changing world. Tree Physiol, 2010, 30(9): 1083-1095.

[26]	Mitchell A, Barclay H, Brix H, Pollard D, Benton R, DeJong R. Biomass and nutrient element dynamics in Douglas-fir: effects of thinning and nitrogen fertilization over 18 years. Can J For Res, 1996, 26(3): 376-388.

[27]	Moore JA, Mika PG, Shaw TM, Garrison-Johnston MI. Foliar nutrient characteristics of four conifer species in the interior northwest United States. West J Appl For, 2004, 19(1): 13-24.

[28]	Ollinger S, Smith M, Martin M, Hallett R, Goodale C, Aber J. Regional variation in foliar chemistry and N cycling among forests of diverse history and composition. Ecology, 2002, 83(2): 339-355.

[29]	Rennenberg H, Wildhagen H, Ehlting B. Nitrogen nutrition of poplar trees. Plant Biol, 2010, 12(2): 275-291.

[30]	Reuter DJ. Plant analysis: an interpretation manual, 1997, Australia: CSIRO publishing 3 27

[31]	Schreeg LA, Santiago LS, Wright SJ, Turner BL. Stem, root, and older leaf N: P ratios are more responsive indicators of soil nutrient availability than new foliage. Ecology, 2014, 95(8): 2062-2068.

[32]	Sterner RW, Elser JJ. Ecological stoichiometry: the biology of elements from molecules to the biosphere, 2002, Princeton: Princeton University Press 87 133

[33]	Thibodeau L, Raymond P, Camiré C, Munson AD. Impact of precommercial thinning in balsam fir stands on soil nitrogen dynamics, microbial biomass, decomposition, and foliar nutrition. Can J For Res, 2000, 30(2): 229-238.

[34]	Townsend AR, Cleveland CC, Asner GP, Bustamante M. Controls over foliar N: P ratios in tropical rain forests. Ecology, 2007, 88(1): 107-118.

[35]	Turner J. Effect of nitrogen availability on nitrogen cycling in a Douglas-fir stand. For Sci, 1977, 23(3): 307-316.

[36]	Turner MG, Smithwick EA, Tinker DB, Romme WH. Variation in foliar nitrogen and aboveground net primary production in young postfire lodgepole pine. Can J For Res, 2009, 39(5): 1024-1035.

[37]	Van den Driessche R. Prediction of mineral nutrient status of trees by foliar analysis. Bot Rev, 1974, 40(3): 347-394.

[38]	Wang Q, He T, Wang S, Liu L. Carbon input manipulation affects soil respiration and microbial community composition in a subtropical coniferous forest. Agric For Meteorol, 2013, 178: 152-160.

[39]	Wang M, Murphy MT, Moore TR. Nutrient resorption of two evergreen shrubs in response to long-term fertilization in a bog. Oecologia, 2014, 174(2): 365-377.

[40]	Will RE, Narahari NV, Shiver BD, Teskey RO. Effects of planting density on canopy dynamics and stem growth for intensively managed loblolly pine stands. For Ecol Manag, 2005, 205(1): 29-41.

[41]	Zhang J, Sheng W. The study on decay of dead branches and leaves on living trees taken from crown into litter environment in a Chinese fir plantation, compared with decay in canopy. Sci Silv Sin, 2001, 37(6): 2-10. (in Chinese)