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2019 | 67 | 1 |

Tytuł artykułu

Quantification of individual tree competition index taking Chinese-fir plantations in subtropical low hilly area as an example

Warianty tytułu

Języki publikacji

EN

Abstrakty

EN
Competition among trees is a fundamental interaction process within plant community, which is the theoretical basis of thinning. Plant competitive intensity is generally measured using a competition index (CI) that can be classified into two major categories: distance-independent and distance-dependent. The current study used Cunninghamia lanceolata (Lamb.) Hook as the test subject and used Hegyi's CI (distance-dependent), to quantify individual CI and their relationship with tree diameter at breast height (DBH). Five different criteria were used to select potential competitors for the calculation of CI. Seven basic linear and nonlinear mathematical functions were used to test and quantify the relationships between DBH of the target tree and the individual CI. Results showed that individual CI was negatively correlated with target tree DBH: as DBH increased, competition intensity weakened. The adjusted R² with five different criteria of selection competitors simulated by seven functions ranged from 0.30 to 0.82. Considering the root mean square error (RMSE), P-value, and adjusted-R², our results suggested that the best model to simulate the relationship between individual CI and focal tree DBH was power function (CI = 43.98 × DBH⁻¹‧⁰⁸, adjusted R² = 0.81) and with the Voronoi diagram method as the criteria for selecting competitors. These results can demonstrate a clearer understanding of the spatial structure of forests, and can be used to guide the selection of thinning trees in the process of thinning practice.

Wydawca

-

Rocznik

Tom

67

Numer

1

Opis fizyczny

p.1-16,fig.,ref.

Twórcy

autor
  • Faculty of Life Science and Technology, Central South University of Forestry and Technology, Changsha, Hunan 410004, China
  • Lingnan Integrated Exploration and Design Institute of Guangdong, Guangzhou, 510663, China
autor
  • Faculty of Life Science and Technology, Central South University of Forestry and Technology, Changsha, Hunan 410004, China
  • National Engineering Laboratory for Applied Technology of Forestry and Ecology in South China, Changsha, 410004, China
  • Huitong National Field Station for Scientific Observation and Research of Chinese Fir Plantation Ecosystem in Hunan Province, Huitong 438107, China
autor
  • Faculty of Life Science and Technology, Central South University of Forestry and Technology, Changsha, Hunan 410004, China
autor
  • Faculty of Life Science and Technology, Central South University of Forestry and Technology, Changsha, Hunan 410004, China
autor
  • Faculty of Life Science and Technology, Central South University of Forestry and Technology, Changsha, Hunan 410004, China
  • National Engineering Laboratory for Applied Technology of Forestry and Ecology in South China, Changsha, 410004, China
  • Huitong National Field Station for Scientific Observation and Research of Chinese Fir Plantation Ecosystem in Hunan Province, Huitong 438107, China
autor
  • Faculty of Life Science and Technology, Central South University of Forestry and Technology, Changsha, Hunan 410004, China
  • National Engineering Laboratory for Applied Technology of Forestry & Ecology in South China, Changsha, 410004, China
  • Huitong National Field Station for Scientific Observation and Research of Chinese Fir Plantation Ecosystem in Hunan Province, Huitong 438107, China

Bibliografia

  • Aakala T., Fraver S., D'Amato A.W, Palik B.J. 2013 – Influence of competition and age on tree growth in structurally complex old-growth forests in northern Minnesota, USA – Forest Ecol. Manag. 308: 128–135.
  • Amiri M., Naghdi R. 2016 – Assessment of competition indices of an unlogged oriental beech mixed stand in Hyrcanian forests, Northern Iran – Biodiversitas, Journal of Biological Diversity, 17: 306–314.
  • Bauer S., Wyszomirski T., Berger U., Hildenbrandt H., Grimm V. 2004 – Asymmetric competition as a natural outcome of neighbour interactions among plants: results from the field-of-neighbourhood modelling approach – Plant Ecol. 170: 135–145.
  • Bérubé-Deschênes A., Franceschini T., Schneider R. 2017 – Quantifying competition in white spruce (Picea glauca) plantations – Ann. Forest Sci. 74: 26.
  • Biging G.S., Dobbertin M. 1992 – A comparison of distance-dependent competition measures for height and basal area growth of individual conifer trees – For. Sci. 38: 695–720.
  • Biging G.S., Dobbertin M. 1995 – Evaluation of competition indices in individual tree growth models – For. Sci. 41: 360–377.
  • Bragg D.C. 2001 – A local basal area adjustment for crown width prediction – North J. Appl. For. 18: 22–28.
  • Burkhart H.E., Tomé M. 2012 – Indices of individual-tree competition (In: Modelling Forest Trees and Stands) – Springer Netherlands, pp. 201–232.
  • Burton P.J. 1993 – Some limitations inherent to static indices of plant competition – Can. J. Forest Res. 23: 2141–2152.
  • Chao L., Hong T., Li J., Chen C., Hong W., Wu C.Z. 2015 – [Intraspecific competition in a Cunninghamia lanceolata plantation with different age and diameter classes] – Journal of Zhejiang A & F University, 32: 353–360 (in Chinese, English summary).
  • Chen H.J. 2003 – Phosphatase activity and P fractions in soils of an 18-year-old Chinese fir (Cunninghamia lanceolata) plantation – Forest Ecol. Manag.178: 301–310.
  • Colbert K.C., Larsen D.R., Lootens J.R. 2002 – Height-diameter equations for thirteen Midwestern bottom land hardwood species – North J. Appl. For.19: 171–176.
  • Craine J.M., Dybzinski R. 2013 – Mechanisms of plant competition for nutrients, water and light – Funct. Ecol.27: 833–840.
  • Cunha T.A.D., Finger C.A.G., Hasenauer H. 2016 – Tree basal area increment models for Cedrela, Amburana, Copaifera and Swietenia growing in the Amazon rain forests – Forest Ecol. Manag.365: 174–183.
  • Daniels R.F., Burkhart H.E., Clason T.R. 1986 – A comparison of competition measures for predicting growth of loblolly pine trees – Can. J. For. Res.16: 1230–1237.
  • Daniels R.F. 1976 – Notes: simple competition indices and their correlation with annual loblolly pine tree growth – Forest Sci.22: 454–456.
  • Duan R.Y, Wang X.A. 2005 – [Intraspecific and interspecific competition in Larix Chinensis] – Chinese Journal of Plant Ecology, 29: 242–250 (in Chinese, English summary).
  • Duan R.Y., Wang X.A. 2004 – [Study on neighborhood zone and neighborhood competition intensity in Larix chinensis population] – Acta Botanica Boreali - Occidentalia Sinica, 24): 2335–2340 (in Chinese, English summary).
  • Fu L.Y., Sun H., Sharma R.P., Lei Y.C., Zhang H.R., Tang S.Z. 2013 – Nonlinear mixed-effects crown width models for individual trees of Chinese fir (Cunninghamia lanceolata) in south-central China – Forest Ecol. Manag.302: 210–220.
  • Girona M.M., Rossi S., Lussier J.M., Walsh D., Morin H. 2017 – Understanding tree growth responses after partial cuttings: A new approach – PloS ONE, 12: e0172653.
  • Haase P. 1995 – Spatial pattern analysis in ecology based on Ripley's K-function: Introduction and methods of edge correction – J. Veg. Sci.6: 575–582.
  • Hegyi F. 1974 – A simulation model for managing jack-pine stands. Growth Models for Tree and Stand Simulation – For. Res.30: 74–90.
  • Hynynen J., Ojansuu R. 2003 – Impact of plot size on individual-tree competition measures for growth and yield simulators – Can. J. Forest Res.33: 455–465.
  • Kang D., Deng J., Qin X., Hao F., Guo S., Han X., Yang G. 2017 – Effect of competition on spatial patterns of oak forests on the Chinese Loess Plateau – J. Arid Land.9: 122–131.
  • Kimmins J.P. 2004 – Forest Ecology – A foundation for Sustainable Forest Management and Environmental Ethics in Forestry, third Edition.
  • Krejza J., Světlík J., Pokorný R. 2015 – Spatially explicit basal area growth of Norway spruce – Trees - Struct. Funct.29: 1545–1558.
  • Ledermann T. 2010 – Evaluating the performance of semi-distance-independent competition indices in predicting the basal area growth of individual trees – Can. J. Forest Res.40: 796–805.
  • Lei X.D., Peng C.H., Wang H.Y., Zhou X.L. 2009 – Individual height-diameter models for young black spruce (Picea mariana) and jack pine (Pinus banksiana) plantations in New Brunswick, Canada – Forest Chron.85: 43–56.
  • Li Y.Q., Deng X.W., Huang Z.H., Xiang W.H., Lei P.F., Zhou X.L., Peng C.H. 2015 – Development and evaluation of models for the relationship between tree height and diameter at breast height for Chinese-fir plantations in subtropical China – PloS ONE, 10(4): e0125118.
  • McTague J.P., Weiskittel A.R. 2016 – Individual-Tree Competition Indices and Improved Compatibility with Stand-Level Estimates of Stem Density and Long-Term Production – Forests, 7(10): 238; https://doi.org/10.3390/f7100238.
  • Moeur M. 1993 – Characterizing spatial patterns of trees using stem-mapped data – Forest Sci.39: 756–775.
  • Monserud R.A., Sterba H. 1996 – A basal area increment model for individual trees growing in even-and uneven-aged forest stands in Austria – Forest Ecol. Manag.80: 57–80.
  • Munro D.D. 1974 – Forest growth models-a prognosis. Growth models for tree and stand simulation – Research Note, 30. Department of Forest Yield Research, Royal College of Forestry, Stockholm, 30: 7–21.
  • Neufeld B.A., Morris D.M., Luckai N., Reid D.E., Bell F.W., Shahi C., Meyer M.L., Adhikary S. 2014 – The influence of competition and species mixture on plantation- grown white spruce: Growth and foliar nutrient response after 20 years – Forest Chron.90: 70–79.
  • Pedersen R.Ø., Bollandsås O.M., Gobakken T., Næsset E. 2012 – Deriving individual tree competition indices from airborne laser scanning – Forest Ecol. Manag.280: 150–165.
  • Porté A., Bartelink H.H. 2002 – Modelling mixed forest growth: a review of models for forest management – Ecol. Model.150: 141–188.
  • Pretzsch H. 2009 – Forest dynamics, growth, and yield: From Measurement to Model – Springer Berlin Heidelberg. pp. 1–39.
  • Pukkala T., Kolström T. 1987 – Competition indices and the prediction of radial growth in Scots pine – Silva Fennica, 21: 55–67.
  • Renka R.J., Gebhardt A., Eglen S., Zuyev S., White D. 2016 – Tripack: triangulation of irregularly spaced data.R package version 1.3-8, https://CRAN.R-project.org/package=tripack.
  • Richards M., McDonald A.J.S., Aitkenhead M.J. 2008 – Optimisation of competition indices using simulated annealing and artificial neural networks – Ecol. Model.214: 375–384.
  • Rivas J.J.C., Gonzalez J.G.A., Aguirre O., Aguirre O., Hernández F.J. 2005 – The effect of competition on individual tree basal area growth in mature stands of Pinus cooperi Blanco in Durango (Mexico) – Eur. J. For. Res.124: 133–142.
  • Scharf I., Fischer-Blass B., Foitzik S. 2011 – Spatial structure and nest demography reveal the influence of competition, parasitism and habitat quality on slavemaking ants and their hosts – BMC Ecol.11: 9.
  • Shi H.J., Zhang L.J. 2003 – Local analysis of tree competition and growth – Forest Sci.49: 938–955.
  • Soares P., Tomé M. 1999 – Distance-dependent competition measures for eucalyptus plantations in Portugal – Ann. Forest Sci.56: 307–319.
  • Souml T. 2009 – Diameter at breast height-crown diameter prediction models for Picea orientalis – Ar. J. Agr. Res.4: 215–219.
  • Sterner R.W., Ribic C.A., Schatz G.E. 1986 – Testing for life historical changes in spatial patterns of four tropical tree species – J. Ecol.74: 621–633.
  • Sun J.N., Wang X.A., Guo H., Wang S.X. 2010 – [Competitive relationships of dominant tree in Pinus tabulaeformis f. shekannesis community on Loess Plateau] – Chinese Journal of Ecology, 29: 2162–2167 (in Chinese, English summary).
  • Tian D.L., Xiang W.H., Chen X.Y., Yan W.D., Fang X., Kang W.X., Deng X.W., Peng C.H., Peng Y.Y. 2011 – A long-term evaluation of biomass production in first and second rotations of Chinese fir plantations at the same site – Forestry, 84: 411–418.
  • Tilman D. 1994 – Competition and biodiversity in spatially structured habitats – Ecology, 75: 2–16.
  • Tomé M., Burkhart H.E. 1989 – Distance-dependent competition measures for predicting growth of individual trees – Forest Sci.35: 816–831.
  • Van de Peer T., Verheyen K., Kint V., Van Cleemput E., Muys B. 2017 – Plasticity of tree architecture through interspecific and intraspecific competition in a young experimental plantation – Forest Ecol. Manag.385: 1–9.
  • Von Gadow K., Hui G. 2001 – Modelling forest development – Springer Science & Business Media. Vol. 57.
  • VonOheimb G., Lang A.C., Bruelheide H., Forrester D.I., Wäsche I., Yu M., Härdtle W. 2011 – Individual-tree radial growth in a subtropical broad-leaved forest: the role of local neighbourhood competition – Forest Ecol. Manag.261: 499–507.
  • Weber P., Bugmann H., Fonti P., Rigling A. 2008 – Using a retrospective dynamic competition index to reconstruct forest succession – Forest Ecol. Manag.254: 96–106.
  • Weigelt A., Jolliffe P. 2003 – Indices of plant competition – J. Ecol.91: 707–720.
  • Wen H.F., Deng X.W., Zhang Y.F., Wei X.C., Wang G.J., Zhou B., Xiang W.H., Zhu N.H. 2018 – Cunninghamia lanceolata variant with red-heart wood: a mini-review – Dendrobiology, 79: 156–167. http://dx.doi.org/10.12657/denbio.079.014
  • Xia J.B., Zhang G.C., Zhang S.Y., Shao H.B. 2009 – Growth process and diameter structure of Pinus tabulaeformis forest for soil and water conservation in the hilly loess region of China – Afr. J. Biotechnol.8: 5415–5421.
  • Xiang X.Y., Wu G.L., Duan R.Y., Yan Y.M., Zhang X.P. 2015 – [Intraspecific and interspecific competition of Pinus dabeshanesis] – Acta Ecologica Sinica, 35: 389–395 (in Chinese, English summary).
  • Zhou R.W., An Y.T., Wang H., Ren Y.M., Wang Q.F., He B.H., Chen P.F., Lin D.Y. 2010 – [Quantitative relationships of intra- and inter-specific competition of Platycladus orientalis plantation in Beijing Xishan National Forest Park] – Journal of Beijing Forestry University, 32: 27–32(in Chinese, English summary).
  • Zhou W.S., Han H.R., Kang F.F., Cheng X.Q., Wu R., Yang J., Tian P., Huang L.S. 2017 – [Intra- and inter-specific interactions of Larix principis-rupprechtii plantation in Mt. Taiyue, Shanxi, China]– Chinese Journal of Ecology, 36: 335–342 (in Chinese, English summary).

Typ dokumentu

Bibliografia

Identyfikator YADDA

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