Allometry, biomass and productivity in pinus massoniana forests of China: an updated review of published data

Jin, Ling; Li, Xiaodong; Huang, Qiuchan; Yang, Honglan; Huang, Ju

doi:10.3161/15052249PJE2020.70.1.001

Artykuł - szczegóły

Tytuł artykułu

Allometry, biomass and productivity in pinus massoniana forests of China: an updated review of published data

Autorzy

Jin Ling , Li Xiaodong , Huang Qiuchan , Yang Honglan , Huang Ju

Wybrane pełne teksty z tego czasopisma

http://www.miiz.waw.pl/index.php/pl/wydawnictwa/polish-journal-of-ecology

Identyfikatory

DOI

10.3161/15052249PJE2020.70.1.001

Warianty tytułu

Języki publikacji

Abstrakty

Field measurements of forest biomass are labor-consuming and usually destructive, but such direct datasets are the foundation for further developing indirect estimation such as biomass equation and biomass expansion factors that were used to scale biomass estimation or carbon storage from site or local surveys up to regional or national level. Pinus massoniana is widely distributed throughout 17 provinces of China and has a high economic value. This study is an updated review of the allometric equations, biomass allocation data and productivity estimations in Pinus massoniana forests of China published in articles during the period from 1982 to 2019. Different allometric equations of Pinus massoniana showed site-specific dependences. The aboveground and total tree biomass were expressed as power equations of mean age for Pinus massoniana forests. The mean value of aboveground tree biomass, total tree biomass and ecosystem biomass across all ages for Masson pine forests was 109.81, 127.65 and 138.76 Mg/ha, respectively. The mean proportion of stem, branch and foliage to aboveground tree biomass for Pinus massoniana was 77.1%, 15.9% and 7%, respectively. The tree root biomass continuously increased with the aboveground tree biomass and a power relationship was found between the tree root biomass and aboveground tree biomass for Pinus massoniana forests. The tree net primary productivity increased with aboveground tree biomass for Pinus massoniana forests, and the relationship was expressed as a linear equation. The mean tree, litter and ecosystem net primary productivity was 7.04, 4.88 and 8.30 Mg/ha/year, respectively. These findings provide key parameters for the biomass estimation and carbon accounting studies of widely planted Pinus massoniana forests in China.

Słowa kluczowe

allometric equation carbon biomass allocation Pinus massoniana net primary productivity

Wydawca

Museum and Institute of Zoology, Polish Academy of Sciences

Czasopismo

Polish Journal of Ecology

Rocznik

2022

Tom

Vol. 70, nr 1

Strony

1--32

Opis fizyczny

Bibliogr. 62 poz., tab., wykr.

Twórcy

autor

Jin Ling

Chongzuo College for Preschool Education, Chongzuo, 532200, China

autor

Li Xiaodong

xinanli@outlook.com

College of Chemical and Biological Engineering, Guangxi Normal University for Nationalities, Chongzuo, 532200, China

autor

Huang Qiuchan

College of Chemical and Biological Engineering, Guangxi Normal University for Nationalities, Chongzuo, 532200, China

autor

Yang Honglan

College of Chemical and Biological Engineering, Guangxi Normal University for Nationalities, Chongzuo, 532200, China

autor

Huang Ju

College of Chemical and Biological Engineering, Guangxi Normal University for Nationalities, Chongzuo, 532200, China

Bibliografia

1. Brown S., Lenart M., Mo J., Kong G. 1995 - Structure and organic matter dynamics of a human-impacted pine forest in a MAB reserve of subtropical China - Biotropica, 27: 276-289.
2. Cairns M.A., Brown S., Helmer E.H., Baumgardner G.A. 1997 - Root biomass allocation in the world's upland forests - Oecologia, 111: 1-11.
3. Clark D.A., Brown S., Kicklighter D.W., Chambers J.Q., Thomlinson J.R., Ni J. 2001 - Measuring net primary production in forests: Concepts and field methods - Ecological Applications, 11: 356-370.
4. Costanza R., d'Arge R., de Groot R., Farber S., Grasso M., Hannon B., Limburg K., Naeem S., O'Neill R.V., Paruelo J., Raskin R.G., Sutton P., van den Belt M. 1997 - The value of the world's ecosystem services and natural capital - Nature, 387: 253-260.
5. Deng, C., Zhang S., Lu Y., Froese R.E., Xu X., Zeng J., Ming A., Liu X., Xie Y., Li Q. 2020 - Thinning effects on forest evolution in Masson pine (Pinus massoniana Lamb.) conversion from pure plantations into mixed forests - Forest Ecology and Management, 477: 118503.
6. Ding G., Wang P. 2002 - Study on change laws of biomass and productivity of Masson pine forest plantation II. biomass and productivity of stand at different ages - Forest Research, 15: 47-53. (in Chinese, English summary).
7. Ding G., Wang P., Yan R. 1998 - Studies on the dynamic change of the commercial biomass of Masson pine pulpwood stands and its modeling - Scientia Silvae Sinicae, 34: 33-41 (in Chinese, English summary).
8. Dixon R.K., Solomon A.M., Brown S., Houghton R.A., Trexier M.C., Wisniewski J. 1994 - Carbon pools and flux of global forest ecosystems - Science, 263: 185-190.
9. Easdale T.A., Richardson S.J., Marden M., England J.R., Gayoso-Aguilar J., Guerra-Cárcamo J.E., McCarthy J.K., Paul K.I., Schwendenmann L., Brandon A.M. 2019 - Root biomass allocation in southern temperate forests - Forest Ecology and Management, 453: 117542.
10. Fang Y., Zou X., Lie Z., Xue L. 2018 - Variation in organ biomass with changing climate and forest characteristics across Chinese forests - Forests, 9: 521.
11. Feldpausch T.R., Banin L., Phillips O.L., Baker T.R., Lewis S.L., Quesada C.A., Affum-Baffoe K., Arets E.J.M.M., Berry N.J., Bird M., Brondizio E.S., de Camargo P., Chave J., Djagbletey G., Domingues T.F., Drescher M., Fearnside P.M., França M.B., Fyllas N.M., Lopez-Gonzalez G., Hladik A., Higuchi N., Hunter M.O., Iida Y., Salim K.A., Kassim A.R., Keller M., Kemp J., King D.A., Lovett J.C., Marimon B.S., Marimon-Junior B.H., Lenza E., Marshall A.R., Metcalfe D.J., Mitchard E.T.A., Moran E.F., Nelson B.W., Nilus R., Nogueira E.M., Palace M., Patiño S., Peh K.S.-H., Raventos M.T., Reitsma J.M., Saiz G., Schrodt F., Sonké B., Taedoumg H.E., Tan S., White L., Wöll H., Lloyd J. 2011 - Height-diameter allometry of tropical forest trees - Biogeosciences, 8, 1081-1106,
12. Feng Z., Chen C., Zhang J., Wang K., Zhao J., Gao H. 1982 - Determination of biomass of Pinus massoniana stand in Huitong county, Hunan province - Scientia Silvae Sinicae 18: 127-134 (in Chinese, English summary).
13. Fu L., Zeng W., Zhang H., Wang G., Lei Y., Tang S. 2014 - Generic linear mixed-effects individual-tree biomass models for Pinus massoniana in southern China - Southern Forests, 76: 47-56.
14. Fu L., Lei X., Hu Z., Zeng W., Tang S., Marshall P., Cao L., Song X., Yu L., Liang J. 2017a - Integrating regional climate change into allometric equations for estimating tree aboveground biomass of Masson pine in China. Annals of Forest Science, 74: 42.
15. Fu L.Y., Zeng W.S., Tang S.Z. 2017b - Individual tree biomass models to estimate forest biomass for large spatial regions developed using four pine species in China - Forest Science, 63: 241-249.
16. Fu L.Y., Lei Y.C., Wang G.X., Bi H.Q., Tang S.Z., Song X.Y. 2016 - Comparison of seemingly unrelated regressions with error-in-variable models for developing a system of nonlinear additive biomass equations - Trees - Structure and Function, 30: 839-857.
17. Gao X., Ding G., Zhai S., Chen M., Du H. 2014 - Spatial distribution of root biomass of Pinus massoniana plantations under different planting densities - Journal of Central South University of Forestry & Technology, 34: 71-75 (in Chinese, English summary).
18. Guo Z., Fang J., Pan Y., Birdsey R. 2010 - Inventory-based estimates of forest biomass carbon stocks in China: A comparison of three methods - Forest Ecology and Management, 259: 1225-1231.
19. He H., Zhang C., Zhao X., Fousseni F., Wang J., Dai H., Yang S., Zuo Q. 2018 - Allometric biomass equations for 12 tree species in coniferous and broadleaved mixed forests, Northeastern China - Plos One, 13: e0186226.
20. Hou Z., Zhang X., Xu D., Yu P. 2009 - Study on biomass and productivity of Chinese fir plantation - Chinese Agricultural Science Bulletin, 25: 97-103 (in Chinese, English summary).
21. Huang X., Dai D., Xiang Y., Yan Z., Teng M., Wang P., Zhou Z., Zeng L., Xiao W. 2021 - Radial growth of Pinus massoniana is influenced by temperature, precipitation, and site conditions on the regional scale: A meta-analysis based on tree-ring width index - Ecological Indicators, 126: 107659.
22. Jiang Y., Wang L. 2017 - Pattern and control of biomass allocation across global forest ecosystems - Ecology and Evolution, 7: 5493-5501.
23. Keeling H.C., Phillips O.L. 2007 - The global relationship between forest productivity and biomass - Global Ecology and Biogeography, 16: 618-631.
24. Lü C., Deng H., Wang S., Chen Z., Wang X. 2016 - Compatible tree volume and aboveground biomass equations for Pinus massoniana from different regions - Journal of Zhejiang Agriculture & Forestry University, 33: 790-797 (in Chinese, English summary).
25. Luo X., Hou E., Chen J., Li J., Zhang L., Zang X., Wen D. 2020 - Dynamics of carbon, nitrogen, and phosphorus stocks and stoichiometry resulting from conversion of primary broadleaf forest to plantation and secondary forest in subtropical China - Catena, 193: 104606.
26. Luo Y., Wang X., Zhang X., Booth T.H., Lu F. 2012 - Root:shoot ratios across China's forests: Forest type and climatic effects - Forest Ecology and Management, 269: 19-25.
27. Luo Y., Wang X., Zhang X., Ren Y., Poorter H. 2013 - Variation in biomass expansion factors for China's forests in relation to forest type, climate, and stand development - Annals of Forest Science, 70: 589-599.
28. Luo Y., Zhang X., Wang X., Lu F. 2014 - Biomass and its allocation of Chinese forest ecosystems - Ecology, 95: 2026-2026.
29. Luo Y., Wang X., Ouyang Z. 2018: A China's normalized tree biomass equation data-set, PANGAEA, https://doi.org/10.1594/PANGAEA.895244 .
30. Luo Y., Wang, X., Ouyang Z., Lu F., Feng L., Tao J. 2020 - A review of biomass equations for China's tree species - Earth System Science Data, 12: 21-40.
31. Luyssaert S., Inglima I., Jung M., Richardson A.D., Reichstein M., Papale D., Piao S.L., Schulze E.-D., Wingate L., Matteucci G., Aragao L., Aubinet M., Beer C., Bernhofer C., Black K.G., Bonal D., Bonnefond J.M., Chambers J., Ciais P., Cook B., Davis K.J., Dolman A.J., Gielen B., Goulden M., Grace J., Granier A., Grelle A., Griffis T., Grünwald T., Guidolotti G., Hanson P.J., Harding R., Hollinger D.Y., Hutyra L.R., Kolari P., Kruijt B., Kutsch W., Lagergren F., Laurila T., Law B.E., Le Maire G., Lindroth A., Loustau D., Malhi Y., Mateus J., Migliavacca M., Misson L., Montagnani L., Moncrieff J., Moors E., Munger J.W., Nikinmaa E., Ollinger S.V., Pita G., Rebmann C., Roupsard O., Saigusa N., Sanz M.J., Seufert G., Sierra C., Smith M.-L., Tang J., Valentini R., Vesala T., Janssens I.A. 2007 - CO2 balance of boreal, temperate, and tropical forests derived from a global database - Global Change Biology, 13: 2509-2537.
32. Ni J., Zhang X.-S., Scurlock J.M.O. 2001 - Synthesis and analysis of biomass and net primary productivity in Chinese forests - Annals of Forest Science, 58: 351-384.
33. Ni Y., Jian Z., Zeng L., Liu J., Lei L., Zhu J., Xu J., Xiao W. 2022 - Climate, soil nutrients, and stand characteristics jointly determine large-scale patterns of biomass growth rates and allocation in Pinus massoniana plantations - Forest Ecology and Management, 504: 119839.
34. Pan Y., Luo T., Birdsey R., Hom J., Melillo J. 2004 - New estimates of carbon storage and sequestration in China'sforests: Effects of age-class and method on inventory-based carbon estimation - Climatic Change, 67: 211-236.
35. Qi Y., Wei W., Chen C., Chen L. 2019 - Plant root-shoot biomass allocation over diverse biomes: A global synthesis - Global Ecology and Conservation, 18: e00606.
36. Somogyi Z., Cienciala E., Mäkipää R., Muukkonen P., Lehtonen A., Weiss P. 2007 - Indirect methods of large-scale forest biomass estimation - European Journal of Forest Research, 126: 197-207.
37. Su R., Wu Q., Yang Y., Hu T. 2021 - Relationship between diameter at breast height and tree age in populations of a rare and endangered plant, Davidia involucrata. Polish Journal of Ecology, 69: 84-95.
38. Tian D. 1989 - Studies of nutrient elements cycling and density effect of pole stage of Pinus massoniana stand - Scientia Silvae Sinicae 25: 106-112 (in Chinese, English summary).
39. Wang B., Wei W., Xing Z., You W., Niu X., Ren X., Liu C. 2012 - Biomass carbon pools of Cunninghamia lanceolata (Lamb.) Hook. forests in subtropical China: Characteristics and potential. Scandinavian Journal of Forest Research, 27: 545-560.
40. Wang L., Li L., Chen X., Tian X., Wang X., Luo G. 2014 - Biomass allocation patterns across China's terrestrial biomes - Plos One, 9: e93566.
41. Wen Y., Schuler J.L., Liu S.R., Mou P., Wang H., Yu H.L., Wang J.X. 2016 - Soil carbon dynamics in a Pinus massoniana plantation following clear-cutting and slash removal. Journal of Plant Ecology, 9: 20-29.
42. West G.B., Brown J.H., Enquist B.J. 1999 - A general model for the structure and allometry of plant vascular systems - Nature, 400: 664-667.
43. Woodwell G.M., Whittaker R.H. 1968 - Primary production in terrestrial ecosystems - American Zoologist, 8: 19-30.
44. Xiang W., Liu S., Deng X., Shen A., Lei X., Tian D., Zhao M., Peng C. 2011 - General allometric equations and biomass allocation of Pinus massoniana trees on a regional scale in southern China - Ecological Research, 26: 697-711.
45. Xu F., Gao Y., He K., Ding F., Dai Q. 2013 - Study on biomass and net productivity of Pinus massoniana of stand at different forest ages - Hubei Agricultural Sciences, 52: 1853-1858 (in Chinese, English summary).
46. Xu H., Song T., Huang G., Peng W., Zeng F., Zhang H., Du H. 2016 - Carbon storage and distribution in Pinus massoniana plantations at different stand ages in Guangxi province - Research of Agricultural Modernization, 37: 195-203 (in Chinese, English summary).
47. Xu L., Yu G., He N., Wang Q., Gao Y., Wen D., Li S., Niu S., Ge J. 2018 - Carbon storage in China's terrestrial ecosystems: A synthesis. Scientific Reports, 8: 2806.
48. Yang H., Wang S., Zhang J., Fan B., Zhang W. 2011 - Biomass and nutrients of Pinus massoniana plantations in southern China: Simulations for different managing practices - Journal of Food, Agricultural & Environment 9: 689-693.
49. Yao X., Yu K.Y., Deng Y.B., Zeng Q., Lai Z.J., Liu J. 2019 - Spatial distribution of soil organic carbon stocks in Masson pine (Pinus massoniana) forests in subtropical China - Catena, 178: 189-198.
50. Yuan Z., Jin X., Xiao W., Wang L., Sun Y., Guan Q., Meshack A.O. 2022 - Comparing soil organic carbon stock and fractions under natural secondary forest and Pinus massoniana plantation in subtropical China - Catena, 212: 106092.
51. Zeng W.S. 2014 - Development of monitoring and assessment of forest biomass and carbon storage in China - Forest Ecosystems, 1: 20.
52. Zeng W.S. 2015 - Using nonlinear mixed model and dummy variable model approaches to develop origin-based individual tree biomass equations - Trees - Structure and Function, 29: 275-283.
53. Zeng W.S., Fu L., Xu M., Wang X., Chen Z., Yao S. 2018 - Developing individual tree-based models for estimating aboveground biomass of five key coniferous species in China - Journal of Forestry Research, 29: 1251-1261.
54. Zeng W.S., He D., Pu Y., Xiao Q. 2019 - Individual tree biomass and volume equation system with region and origin in variables for Pinus massoniana in China - Scientia Silvae Sinicae, 55: 75-85 (in Chinese, English summary).
55. Zeng W.S., Zhang H.R., Tang S.Z. 2011 - Using the dummy variable model approach to construct compatible single-tree biomass equations at different scales - a case study for Masson pine (Pinus massoniana) in southern China - Canadian Journal of Forest Research, 41: 1547-1554.
56. Zeng W., Tang S. 2011 - Establishment of below-ground biomass equations for larch in northeastern and Masson pine in southern China - Journal of Beijing Forestry University, 33: 1-6 (in Chinese, English summary).
57. Zeng W., Tang S. 2012 - Modeling compatible single-tree aboveground biomass equations for masson pine (Pinus massoniana) in southern China - Journal of Forestry Research, 23: 593-598.
58. Zeng W., Xiao Q., Hu J., Liao Z. 2010 - Establishment of single-tree biomass equations for Pinus massoniana in southern China - Journal of Central South University of Forestry & Technology, 30: 50-56 (in Chinese, English summary).
59. Zeng Z.Q., Wang S.L., Zhang C.M., Gong C., Zhang Z., Wang Y., Yuan Y., Li Z., Cao L., Zhang G., Yu P., Wang Y. 2006 - Study on the biomass structure and natural secondary forest of Pinus massoniana - Journal of Hebei Agricultural University, 29: 37-43 (in Chinese, English summary).
60. Zhao M., Zhou G.-S. 2005 - Estimation of biomass and net primary productivity of major planted forests in China based on forest inventory data - Forest Ecology and Management 207: 295-313.
61. Zhuang Q., Zhang T., Xiao J., Luo T. 2009 - Quantification of net primary production of Chinese forest ecosystems with spatial statistical approaches - Mitigation and adaptation strategies for global change 14: 85-99.
62. Zou W.T., Zeng W.S., Zhang L.J., Zeng M. 2015 - Modeling crown biomass for four pine species in China - Forests, 6: 433-449.

Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).

Typ dokumentu

Bibliografia

Identyfikator YADDA

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