Application of stable isotopic approach in ecology: A review

Abstract

CLC Number:

S124

YI Xianfeng, ZHANG Xiaoai . Application of stable isotopic approach in ecology: A review[J]. cje, 2005, (3): 306-314.

[1]苏波,韩兴国,黄建辉.1999.15N自然丰度法在生态系统氮素循环研究中的应用[J].生态学报,19:408～416.
[2]易现峰,张晓爱,李来兴,等.2004.高寒草甸生态系统食物链结构分析--来自稳定性碳同位素的证据[J].动物学研究,25:1～6.
[3]易现峰.2004.基于稳定性碳氮同位素的高寒草甸生态系统营养结构研究[D].西宁:中国科学院西北高原生物研究所.
[4]蔡德陵,孟凡,韩贻兵,等.1999.13C/12C比值作为海洋生态系统食物网示踪剂的研究:崂山湾水体生物食物网的营养关系[J].海洋与湖沼,30:671～678.
[5]蔡德陵,洪旭光,毛兴华,等.2001a.崂山湾潮间带食物网结构的碳稳定同位素初步研究[J].海洋学报,23:41～47.
[6]蔡德陵,王荣,毕洪生.2001b.渤海生态系统的营养关系:碳同位素研究的初步结果[J].生态学报,21:1354～1359.
[7]Alisauskas RT, Hobson KA. 1993. Determination of lesser snow goose diets and winter distribution using stable isotope analysis[J]. J. Wild Man., 57:49 ～ 54.
[8]Ambrose SH, DeNiro MJ. 1986. The isotope ecology of East African mammals [J]. Oecologia ,69:395～406.
[9]Ambrose SH, Norr L. 1993. Carbon isotope evidence for routing of dietary protein to bone collagen, and whole diet to bone apatite carbonate: Purified diet growth experiments [A]. In: Lambert J,Grupe G, eds. Molecular Archaeology of Prehistoric Human Bone[C]. Berlin Heidelberg, New York: Springer, 1 ～ 37.
[10]Ben-David M, Bowyer RT, Faro JB. 1996. Niche separation by mink and river otters:Coexistence in a marine environment [J].Oikos, 75:41 ～48.
[11]Ben-David M, Flynn RW, Schell DM. 1997a. Annual and seasonal changes in diets of martens: Evidence from stable isotope analysis[J]. Oecologia, 111:280～291.
[12]Ben-David M, Harley TA, Klein DR, et al. 1997b. Seasonal changes in diets of costal and riverine mink: The role of spawning Pacific salmon [ J ] . Can . J . Zool . , 75 : 803 ～ 811.
[13]Bender MM. 1971. Variation in the 13C/12C ratios of plants in relation to the pathway of photosynthetic carbon dioxide fixation[J]. Phytochemistry, 10:1239～ 1244.
[14]Bender MM, Rouhani I, Vines HM, et al. 1972. 13C/12C ratio changes in CAM plant [J]. Plant Physiol., 52:427～430.
[15]Best PB, Schell DM. 1996. Stable isotopes in southern right whale (Eubalaena austrilis ) baleen as indicators of seasonal movements,feeding and growth [J]. Mar.Biol., 124:483～494.
[16]Bloom AJ, Troughten JH. 1979. High productivity and photosynthetic flexibility in a CAM plant [J]. Oecologia, 38:35 ～ 43.
[17]Bolton JK, Bravn RH. 1980. Photosynthetic in grass species differing in carbon dioxide fixation pathway V. Response of Panicum maximum, Panicum milioides and Tall fescue to nitrogen nutrition [J ]. Plant Physiol., 66: 97～ 100.
[18]Briones MJL, Bol R, Sleep D, et al. 2001. Spatio-temporal variation of stable isotopic ratios in earthworms under grassland and maize cropping systems [J]. Soil Biol. Biochem., 33:1673 ～1682.
[19]Cerling TE, Harris JM, MacFadden BJ, et al. 1997. Global changes through the Miocene/Pliocene boundary [J]. Nature, 389: 153～158.
[20]Cerling TE, Harris JM. 1999. Carbon isotope fractionation between diet and bioapatite in ungulate mammals and implications for ecological and paleoecological studies [J]. Oecologia, 120:347～363.
[21]Chamberlain CP, Blum JD, Holmes RT, et al. 1997. The use of isotope tracers for identifying populations of migratory birds [J].Oecologia, 109:132～ 241.
[22]Cormie AB, Schwartz HP, Gray J. 1994. Determination of the hydrogen isotopic composition of bone collagen and correction for hydrogen exchange [J]. Geochim. Cosmochim. Acta, 58: 365 ～375.
[23]Craig H. 1954. Carbon-13 in plants and the relationships between carbon- 13 and carbon- 14 variations in nature [ J ]. J. Geol., 62:115～149.
[24]DeNiro MJ, Epstein S. 1978. Influence of diet on the distribution of carbon isotopes in animals [J]. Geochim. Cos mochim. Acta,42: 495～ 506.
[25]DeNiro MJ, Epstein S. 1981. Influence of diet on the distribution of nitrogen isotopes in animals [J]. Geochim. Cosmochim. Acta,45:341～351.
[26]Ehleringer JR, Field CB, Lin ZF, et al. 1986. Leaf carbon isotope and mineral composition in subtropical plants along an irradiance cline [ J ]. Oecologia, 70: 520～ 526.
[27]Ehleringer JR. 1993. Evolutionary and ecological aspects of pbotosynthetic pathway variation [J]. Ann. Rev. Ecol. Syst., 24:411 ～439.
[28]Farquhar GD, Ehleringer JR, Hubick KT. 1976. Carbon isotope discrimination and photosynthesis [J ]. Ann. Rev. Inc., 7:503～537.
[29]Fleming TH, Nunez RA, Sternberg LSL. 1993. Seasonal changes in the diets of migrant and non-migrant nectarivorous hats as revealed by carbon stable isotope analysis [J ]. Oecologia, 94:72 ～75.
[30]Forsberg BR, Araujo-Lima CARM, Martinelli LA, et al. 1993.Autotrophic carbon sources for fish of the central Amazon [J].Ecology, 74: 643 ～ 652.
[31]Fry B, Joern A, Paker PL. 1978. Grasshopper food web analysisUse of carbon isotope ratios to examine feeding relationships among terrestrial herbivores [J ]. Ecology, 59: 498～ 506.
[32]Fry B, Arnold C. 1982. Rapid 13C/12C turnover during growth of brown shimp (Penaeus aztecus ) [J ]. Oecologia, 54: 200～ 204.
[33]Fry B, Lutes R, Northam MP, et al. 1982. A 13C/12C comparison of food webs in Caribbean seagrass meadows and coral reefs [J].Aquat . Bot., 14:389～398.
[34]Fry B, Sherr EB. 1984.δ13C measurements as indicators of carbon flow in marine and freshwater ecosystems [ J ]. Contrib.Mar. Sci., 27:13～ 47.
[35]Fureder L, Welter C, Jackson JK. 2003. Dietary and stable isotope (δ 13C, δ 15N) analyses in alpine stream insects [J]. Internat. Rev. Hydrobiol. , 88: 314～ 331.
[36]Goldman CR, Kimmel BL. 1978. Biological processes associated with suspended sediment and detritus in lakes and reservoirs [ A ]. In:Cairns J, eds. Current Perspectives on River Reservoir Ecosystems[C]. North American Bentbological Society, 19 ～ 44.
[37]Haines EB, Montague CL. 1979. Food sources of estuarine invertebrates analyzed using 13C/12C ratios [J]. Ecology, 60: 48 ～ 56.
[38]Hattersly PW. 1992. C4 photosynthetic pathway variation in grasses (Poaceaae): Its significance for arid and semi-arid lands [ A]. In:Champman GP, eds. Decertified Grasslands: Their Biology and Management [C]. London:The Linnaean Society of London, 181～212.
[39]Herrera LG, Hobson KA, Rodriguez M, et al. 2003. Trophic partitioning in tropical rain forest birds: Insights from stable isotope analysis [J]. Oecologia, 136:439～444.
[40]Hesslein RH, Hallard KA, Ramlal P. 1993. Replacement of sulfur, carbon and nitrogen in tissue of growing broad whitefish (Coregonus nasus ) in response to a change in diet traced by δ34S, δ 13C and δ15N [J ]. Can. J. Fish. Aquat. Sci., 50:2071～2076.
[41]Hilderbrand GV, Farley SD, Robbins CT, et al. 1996. Use of stable isotope to determine diets of living and extinct bears [ J ].Can. J. Zool., 74:2082～ 2088.
[42]Hobson KA. 1990. Stable isotope analysis of marbled murrelets:Evidence for freshwater feeding and determination of trophic level [J]. Condor, 92: 896～ 903.
[43]Hobson KA, Clark RW. 1992a. Assessing avian diets using stable isotopes I. Turnover of carbon-13 [J]. Condor, 94:181 ～ 188.
[44]Hobson KA, Clark RW. 1992b. Assessing avian diets using stable isotopes Ⅱ. Factors influencing diet-tissue fractionation [J]. Condor, 94:189～ 197.
[45]Hobson KA, Clark RW. 1993. Turnover of δ13C in cellular and plasma fractions of blood: Implications for nondestructive sampling in avian dietary studies [J]. Auk, 110:638～641.
[46]Hobson KA, Schell DM, Renouf D, et al. 1996. Stable carbon and nitrogen isotopic fractionation between diet and tissues of captive seals: Implications for dietary reconstructions involving marine mammals [J ]. Can. J. Fish. Aquat. Sci., 5: 528～ 533.
[47]Hobson KA, Wassenaar LI. 1997. Linking breeding and wintering grounds of neotropical migrant songbirds using stable hydrogen isotopic analysis of feathers [J ]. Oecologia, 109:142～148.
[48]Hobson KA, Wassenaar LI, Taylor O. 1999. Stable isotopes are geographic indicators of monarch butterfly natal origins in eastern North America [ J ]. Oecologia, 36: 227～ 240.
[49]Hobson KA, Wassenaar LI, Mila B, et al. 2003. Stable isotopes as indicators of altitudinal distributions and movements in an Ecuadorean hummingbird community [J]. Oecologia, 136:302～308.
[50]Iacumin P, Nikolaev V, Ramigni M. 2000. C and N stable isotope measurements on Eurasian fossil mammals, 40 000 to 10 000years BP:Herbivore physiologies and palaenenvironmental reconstruction [J ]. Palaeogeogr. Palaeoclim. Palaeoecol., 163:33 ～47.
[51]Jarman WM, Hobson KA, Sydeman WJ, et al. 1996. Influence of trophic position and feeding location on contaminant levels in the Gulf of the Farallones food web revealed by stable isotope analysis[J]. Environ. Sci. Technol., 30: 654～ 660.
[52]Killingley JS. 1980. Migrations of California gray whales tracked by oxygen-18 variations in their epizoic barnacles [ J ]. Science,207:759～ 760.
[53]Kingdon J. 1979. East African mammals:An atlas of evolution in Africa, Vol Ⅲ. Large mammals [C]. Chicago: University of Chicago Press.
[54]Krueger HW, Sullivan CH. 1984. Models for carbon isotope fractionation between diet and bone [A]. Stable Isotopes in Nutrition[C]. Washington DC:American Chemical Society, 205～220.
[55]Li LX, Yi XF, Li MC, et al. 2004. Analysis on diet of upland buzzards using stable carbon and nitrogen isotope ratios [J ]. Israel J. Zool . , 51: 75～ 85.
[56]Macko SA. 1994. Compound - specific approaches to using stable isotopes [A]. In: Michener RH, eds. Stable Isotopes in Ecology and Environmental Science [C]. Oxford:Blackwell, 45～62.
[57]Markow TA, Anwar S, Pfeiler E. 2000. Stable isotope ratios of carbon and nitrogen in natural populations of Drosophila species and their hosts [J]. Funct. Ecol., 14:261 ～266.
[58]Mashall JD, Zhong P. 1994. Carbon isotope discrimination and water use efficiency in native plants of the North-Central Rockies[J]. Ecology, 75:1887～ 1895.
[59]McConnanghey T, McRov CP. 1979. Food web structure and the fractionation of carbon isotopes in the Bering Sea[J]. Mar. Biol., 53: 257～ 262.
[60]Meehan TD, Lott CA, Sharp ZD, et al. 2001. Using hydrogen isotope geochemistry to estimate the natal latitudes of immature Cooper's hawks migrating through the Florida Keys [J ]. The Condor, 103:11～20.
[61]Melville K J, Connolly RM. 2003. Spatial analysis of stable isotope data to determine primary sources of nutrition for fish [J]. Oecologia, 136: 499 ～ 507.
[62]Merwe NJ, van der Medina E. 1989. Photosynthesis and 13C/12C ratios in Arnzonian rain forests [J]. Geochim. Cosmochim. Acta, 53:1091 ～ 1094.
[63]Merwe NJ, van der Medina E. 1991. The canopy effect, carbon isotope ratios and food webs in Aruzonia [J ]. J. Archaeol. Sci.,18:249～259.
[64]Michael JD, Samuel E. 1978. Carbon isotope evidence for different feeding patterns in two hyrax species occupying the same habitat [J]. Science, 201: 906 ～ 908.
[65]Mizutani H, Fukuda M, Kabaya Y, et al. 1990. Carbon isotope ratio of feathers reveals feeding behavior of cormorants [ J ].Auk, 107:400～437.
[66]Page HM, Lastra M. 2003. Diet of intertidal bivalves in the Ria de Arosa (NW Spain): Evidence from stable C and N isotope analysis [J]. Mar. Biol., 143:519 ～ 532.
[67]Peterson BJ, Howarth RW, Garritt RH. 1985. Multiple stable isotopes used to trace the now of organic matter in estuarine food webs [J]. Science, 227:1361 ～ 1363.
[68]Peterson BJ, Fry B. 1987. Stable isotopes in ecosystem studies[J]. Ann. Rev. Ecol. Syst . , 18:293～320.
[69]Phillips DL. 2001. Mixing models in analyses of diet using multiple stable isotopes: A critique[J ]. Oecologia, 127:166～170.
[70]Phillips DL, Gregg JW. 2001. Uncertainty in source partitioning using stable isotopes[ J ]. Oecologia, 127:171 ～ 179.
[71]Phillips DL, Koch PL. 2002. Incorporating concentration dependence in stable isotope mixing models[J]. Oecologia, 130:114～125.
[72]Pinder JE, Kroh GC. 1987. Insect herbivore and photosynthetic pathway in old-field ecosystems [J ]. Ecology, 68:254 ～ 259.
[73]Quade J, Cerling TE, Barry JC, et al. 1992. A 16-Ma record of paleodiets using carbon and oxygen isotopes in fossil teeth from Pakistan [J]. Chem. Geol., 94:183～ 192.
[74]Robbins CT, Hilderbrand GV, Farley SD. 2002. Incorporating concentration dependence in stable isotope mixing models:A response to Phillips and Koch (2002) [J]. Oecologia, 133:10～13.
[75]Rosing MN, Ben-David M, Barry RP. 1998. Novel branchedchain fatty acids in certain fish oils [J]. Lipids, 12:170 ～ 176.
[76]Rounick JS, Winterbourn MJ, Lyon GL. 1982. Differential utilization of allochthonous and autochthonous inputs by aquatic invertebrates in some New Zealand streams: A stable carbon isotope study [J]. Oikos, 39:191 ～ 198.
[77]Rounick JS, Winterbourn MJ. 1986. Stable carbon isotopes and carbon now in ecosystems [J]. Biol. Sci., 36:171～ 177.
[78]Ruess L, Haggblom MM, Langel R, et al. 2004. Nitrogen isotope ratios and fatty acid composition as indicators of animal diets in belowground systems [J ]. Oecologia, 139: 336～ 346.
[79]Schaffner FC, Swart PK. 1991. Influence of diet and environmental water on the carbon and oxygen isotopic signatures o fseabird eggshell carbonate [ J ]. Bull. Mar. Sci., 48: 23 ～ 38.
[80]Schell DM, Saupe SM, Haubenstock N. 1989. Bowhead whale (Balaena mysticetus) growth and feeding as estimated by δ13C techniques [J]. Mar. Biol., 103:433～443.
[81]Schell DM, Saupe SM. 1993. Feeding and growth as indicated by stable isotopes [A]. In:Burns JJ, eds. The Bowhead Whale.Special Publication No. 2 of the Society for Marine Mammology[C]. Lawrence, Kans: Allen Press, 491 ～ 509.
[82]Scboeninger MJ, DeNiro MJ. 1984. Nitrogen and carbon isotopic composition of bone collagen from marine and terrestrial animals [J]. Geochim . Cosmochim . Acta, 48:625～639.
[83]Sealey JC, van Der Merwe NJ, Lee Thorp JA, et al. 1987. Nitrogen isotopic ecology in southern Africa: Implications for environmental and dietary tracing [J]. Geochim. Cosmochim. Acta, 51: 2707 ～ 2717.
[84]Sheppard SMF, Neilsen RL, Talor HP. 1969. Oxygen and hydrogen isotope ratios of clay minerials from porphyry copper deposition [J]. Econ. Geol., 64:755～777.
[85]Smith BN, Epstein S. 1971. Two categories of 13C/12C ratios for higher plants [J]. Plant Physiol., 47:380～384.
[86]Smith RJ, Hobson KA, Koopman HN, et al. 1996. Distinguishing between populations of fresh and saltwater harbour seals (Phoca vitulina ) using stable-isotope ratios and fatty acid profiles [J]. Can . J. Fish. Sci., 53:272～279.
[87]Smith KF, Sharpz ZD, Brown JH. 2002. Isotopic composition of carbon and oxygen in desert fauna: Investigations into the effects of diet, physiology, and seasonality [ J ]. J. Arid Environ., 52:419～430.
[88]Szepanski M, Ben-David M, Ballenberghe V. 1999. Assessment of anadromous salmon resources in the diet of the Alexander Archipelago wolf using stable isotopic analysis [J]. Oecologia,120: 327～ 335.
[89]Tayasu I, Hyodo F, Abe T, et al. 2002. Nitrogen and carbon stable isotope ratios in the syspatric Australian termites, Amitermes laurensis end Drepanotermes rubriceps (Isoptera:Termitidae) in relation to their feeding habits and the quality of their food materials[J]. Soil Biol. Biochem. ,34:297～301.
[90]Thompson DR, Furness RW. 1995. Stable isotope ratios of carbon and nitrogen in feathers indicate seasonal dietary shift in Northern fulmars [J] . Auk, 112:493～498.
[91]Tieszen LL, Boutton TW. 1988. Stable isotopes in terrestrial ecosystem research [A]. In: Rundel PW, ds. Stable Isotopes in Ecological Research [ C ]. Berlin Heidelberg, New York:Springer, 167～ 195.
[92]Ulrich S, Alexander VA, Maren G, et al. 2002. Tracing the diet of the monitor lizard Varanus mabitang by stable isotope analyses (δ15N, δ13C)[J]. Naturwissenschaften, 89:470～473.
[93]Vander Zanden MJ, Casselman JM, Rasmussen JB. 1999. Stable isotope evidence for the food web consequences of species invasions in lakes [J]. Nature, 401:464～467.
[94]Vogel JC, Talma AS, Hall-Main AJ, et al. 1990a. Carbon and nitrogen isotopes in elephants [J]. South Afr. J. Sci., 86:147～150.
[95]Vogel JC, Eglington B, Auret JM. 1990b. Isotope fingerprints in elephant bone and ivory [J]. Nature, 346:747～749.
[96]Wada E, Teragski M, Kobaya Y, et al. 1987. 15N and 13C abundances in the Arctic Ocean with emphasis on the biogeochemical structure of the food web [ J ]. Deep Sea Res., 34: 829～ 841.
[97]Wang Y, Cerling TE. 1994. A model of fossil tooth enamel and bone digenesis:Implications for stable isotope studies and paleoenvironment reconstruction [ J ]. Paleogeor. Paleoclim.Palacoecol., 107:281～289.
[98]Whalen JK, Janzen HH. 2002. Labeling earthworms uniformly with 13C and 15N: Implications for monitoring nutrient fluxes[J]. Soil Biol. Biochem . , 34:1913～ 1918.
[99]Whelan T, Sackett WM, Benedict CR. 1973. Enzymetic fractionation of carbon isotope by Phosphoenol pyruvate carboxylation from C4 plants [J] .Plant Physiol. ,51:1051～1054.
[100]William EM, Carmozina de Araujo M, Renato C, et al. 1999.Contributions of C3 and C4 plants to higher trophic levels in an Amazonian savanna [J ]. Oecologia, 119: 91 ～ 96.
[101]Winterbourn MJ, Rounick JS. 1985. Benthic faunas and food resources of inseas in small New Zealand streams subjected to different forestry practices[J]. Verh. Internat . Verein . Limnol . ,22:2148～2152.
[102]Yapp CJ, Epstein S. 1982. A re-examination of cellulose carbonbound hydrogen D measurements and some factors affecting plant-water D/H relationships [J]. Geochim. Cosmochim. Acta, 46:955 ～ 965.

Application of stable isotopic approach in ecology: A review

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	CHEN Benxue, LI Yanbing, ZHANG Huibin, WANG Yating, LI Wenbo. Effects of root excision mulched with film on photosynthesis of Paulownia fortunei in farmland shelterbelts in eastern Henan Plain. [J]. Chinese Journal of Ecology, 2024, 43(4): 1008-1016.
[2]	. Soil nutrients and enzyme activities in different types of forest plantations in karst degraded mountainous sites. [J]. Chinese Journal of Ecology, 2024, 43(3): 616-622.
[3]	FENG Yongxia, CHEN Ruisi, NI Xiuya, SHANG He, CHEN Zhan. Planting Cinnamomum camphora can effectively mitigate soil acidity and improve soil nutrients in acid rain area of Chongqing. [J]. Chinese Journal of Ecology, 2024, 43(3): 633-643.
[4]	YANG Yuanzheng, MENG Zhouju, SU Hongxin, WANG Jiali, CAI Wenhua, YANG Jian, ZU Jiaxing. Relationship between forest gap characteristics and woody species diversity in a subtropical forest in Jinzhong Mountain. [J]. Chinese Journal of Ecology, 2024, 43(3): 675-681.
[5]	GAO Xiaomei, LI Yanli, XIONG Qinxue, XU Le, LI Jifu, LI Xinzhu, WANG Xiaojun. Hyperspectral estimation of SPAD in different leaf positions of waterlogged winter wheat. [J]. Chinese Journal of Ecology, 2024, 43(3): 733-740.
[6]	GUO Anqi, LIU Yukun, YU Xinwen, ZHANG Xu, CHEN Yan, LUO Li, GAO Jiajun, YANG Caiyun. Soundscape composition and acoustic activity assessment of Nomascus hainanus habitat. [J]. Chinese Journal of Ecology, 2024, 43(3): 804-814.
[7]	WU Qingyun, WU Zhiwei, LIN Shitao, LI Shun, XIE Gu’ai. Classification of forest fuels and prediction of fire behavior in southern Jiangxi. [J]. Chinese Journal of Ecology, 2024, 43(2): 314-324.
[8]	SUO Aoli, DU Jianhua, GAO Yu, WANG Yiwen, CHEN Feng, LIU Xiaodong. Effects of forest fire on surface fuel loading and regional carbon emission of Pinus yunnanensis forest. [J]. Chinese Journal of Ecology, 2024, 43(2): 325-332.
[9]	ZHENG Chenyue, LIN Haichuan, ZHAN Xiaoyu, HUANG Ziyan, MA Yuanfan, ZHENG Wenxia, ZHU Zhongpan, GUO Futao. Correlation analysis of element contents between forest fuel and PM_2.5 released by combustion of main tree species in Fujian Province.#br# [J]. Chinese Journal of Ecology, 2024, 43(2): 333-341.
[10]	JIA Xiang, JIN Hui, WANG Chao, ZHAO Ying, QIN Liwu, BING Guiping, WANG Runlin, CHEN Qinghong, YIN Hang. Short-term effects of forest fire on the species composition and community structure of Larix olgensis forest. [J]. Chinese Journal of Ecology, 2024, 43(2): 352-361.
[11]	HU Tongxin, DING Hailei, SUN Long. Research progress on effects of fire disturbance on nitrogen cycling and transformation in forest soil. [J]. Chinese Journal of Ecology, 2024, 43(2): 372-382.
[12]	YAN Ming, LIU Xiaoyu, LIU Zhiping, LIU Qingqing, XI Weimin. Post-drought carbon dynamics and driving factors in East Texas national forests, USA. [J]. Chinese Journal of Ecology, 2024, 43(2): 395-406.
[13]	LI Xiaopeng, BU Yuankun, CHEN Jiahui, WANG Yongping, ZHOU Jianyun, LI Weizhong. Relationship between niche and diversity characteristics and distribution pattern of Quercus wutaishanica secondary forest in Qiaoshan. [J]. Chinese Journal of Ecology, 2024, 43(2): 415-423.
[14]	LIN Xingwu, ZHU Jianguo, XIE Zubin. Evolution of soil quality of temperate conifer and broad-leaved mixed forests at different successional stages in Jiaohe, Jilin Province, China. [J]. Chinese Journal of Ecology, 2024, 43(2): 433-444.
[15]	HE Zhihang, LIU Yue, TAO Yuzhu, WU Miaolan, GAO Chang, WANG Yiying, YU Yaohong, ZHOU Qing, MO Qifeng. Effects of altered seasonal precipitation distribution on root morphological traits of different function-type seedlings in a tropical secondary forest. [J]. Chinese Journal of Ecology, 2024, 43(1): 96-105.