PDF(1032 KB)
岷江上游干旱河谷地区油松和岷江柏细根生物量和根长密度
夏娟, 孙旭东, 王娜, 李锐, 陈娟, 高国强
PDF(1032 KB)
PDF(1032 KB)
岷江上游干旱河谷地区油松和岷江柏细根生物量和根长密度
)Fine Root Biomass and Root Length Density of Pinus tabulaeformis and Cupressus chengiana Plantations in the Arid Valleys of the Upper Minjiang River
)了解岷江上游干旱河谷地区12年生油松(Pinus tabulaeformis)和岷江柏(Cupressus chengiana)人工林细根(直径≤2 mm)生物量和根长密度在土层中的垂直分布状况,分析不同土层中细根系统的碳分配策略,为岷江上游干旱河谷地区植被恢复提供理论依据。以岷江上游干旱河谷地区的油松和岷江柏人工林为研究对象,采用土钻法进行取样,测定2种林分不同土层深度(h)(0 cm<h≤15 cm和15 cm<h≤30 cm)中吸收根(1~3级)和运输根(≥4级的细根)生物量和根长密度,以及吸收根占总细根生物量和根长密度比例。结果显示:油松和岷江柏吸收根生物量和根长密度在0 cm<h≤15 cm土层均显著高于15 cm<h≤30 cm土层,而运输根生物量和根长密度在土层间差异均不显著;油松和岷江柏吸收根占总细根生物量和根长密度比例在0 cm<h≤15 cm土层均显著高于15 cm<h≤30 cm土层(P<0.05);岷江柏吸收根占总细根生物量和根长密度比例在2个土层中均显著高于油松 (P<0.05)。研究结果表明,在养分有效性最高的土壤表层,油松和岷江柏细根系统内将更多的碳分配到吸收根。
To investigate the vertical distribution of root biomass(diameter≤2 mm) and root length density of Pinus tabulaeformis and Cupressus chengiana plantations in the arid valleys of the upper Minjiang River, and to analyze the carbon allocation strategy of fine root system in different soil layers, and to provide reference for vegetation restoration in the arid valleys of the upper Minjiang River. P. tabulaeformis and C. chengiana plantations were sampled by soil corer method, and the root biomass and root length density of absorptive roots(first to third order) and transport roots(≥fourth order) in different depth(h)(0 cm<h≤15 cm and 15 cm<h≤30 cm) were measured, as well as the proportions biomass and length density of absorptive roots to the total fine roots. The results showed that: the absorptive root biomass and root length density of P. tabulaeformis and C. chengiana were significantly higher in 0 cm<h≤15 cm than those in 15 cm<h≤30 cm, and the transport root biomass and root length density were not significantly different between soil layers; the proportions biomass and length density of absorptive roots to the total fine roots in 0 cm<h≤15 cm were significantly higher than that in 15 cm<h≤30 cm(P<0.05); the proportions biomass and length density of absorptive roots to the total fine roots in 0 cm<h≤15 cm and 15 cm<h≤30 cm of C. chengiana were significantly higher than those of P. tabulaeformis(P<0.05). These findings suggested that more carbon was allocated to the absorptive roots in the surface soil layers with the highest nutrient availability in P. tabulaeformis and C. chengiana root system.
吸收根 / 运输根 / 根生物量 / 根长密度 / 干旱河谷
absorptive roots / transport roots / root biomass / root length density / arid valleys
S728.2
| 1 | MCCORMACK M L, DICKIE I A, EISSENSTAT D M,et al.Redefining fine roots improves understanding of below-ground contributions to terrestrial biosphere processes[J].New Phytologist,2015,207(3):505-518. |
| 2 | LALIBERTé E.Below-ground frontiers in trait-based plant ecology[J].New Phytologist,2017,213(4):1597-1603. |
| 3 | ERKTAN A, ROUMET C, BOUCHET D,et al.Two dimensions define the variation of fine root traits across plant communities under the joint influence of ecological succession and annual mowing[J].Journal of Ecology,2018,106(5):2031-2042. |
| 4 | STRAND A E, PRITCHARD S G, MCCORMACK M L,et al.Irreconcilable differences:fine-root life spans and soil carbon persistence[J].Science,2008,319(5862):456-458. |
| 5 | WANG S Z, WANG Z Q, GU J C.Variation patterns of fine root biomass,production and turnover in Chinese forests[J].Journal of Forestry Research,2017,28(6):1185-1194. |
| 6 | WANG W N, WANG Y, HOCH G,et al.Linkage of root morphology to anatomy with increasing nitrogen availability in six temperate tree species[J].Plant and Soil,2018,425:189-200. |
| 7 | 杨雨,李芳兰,包维楷,等.川西亚高山11种常见灌木细根形态特征[J].应用与环境生物学报,2020,26(6):1376-1384. |
| 7 | YANG Y, LI F L, BAO W K,et al.Fine-root morphology of common shrubs in the subalpine forests of western Sichuan[J].Chinese Journal of Applied and Environmental Biology,2020,26(6):1376-1384. |
| 8 | HAN M G, CHEN Y, LI R,et al.Root phosphatase activity aligns with the collaboration gradient of the root economics space[J].New Phytologist,2022,234(3):837-849. |
| 9 | PREGITZER K S, DEFOREST J L, BURTON A J,et al.Fine root architecture of nine North American trees[J].Ecological Monographs,2002,72(2):293-309. |
| 10 | GUO D L, XIA M X, WEI X,et al.Anatomical traits associated with absorption and mycorrhizal colonization are linked to root branch order in twenty-three Chinese temperate tree species[J].New Phytologist,2008,180(3):673-683. |
| 11 | YAN H, KOU L, WANG H M,et al.Contrasting root foraging strategies of two subtropical coniferous forests under an increased diversity of understory species[J].Plant and Soil,2019,436:427-438. |
| 12 | 谷加存,王东男,夏秀雪,等.功能划分方法在树木细根生物量研究中的应用:进展与评述[J].植物生态学报,2016,40(12):1344-1351. |
| 12 | GU J C, WANG D N, XIA X X,et al.Applications of functional classification methods for tree fine root biomass estimation:advancements and synthesis[J].Chinese Journal of Plant Ecology,2016,40(12):1344-1351. |
| 13 | GILL R A, JACKSON R B.Global patterns of root turnover for terrestrial ecosystems[J].New Phytologist,2000,147(1):13-31. |
| 14 | TAYLOR B N, STRAND A E, COOPER E R,et al.Root length,biomass,tissue chemistry and mycorrhizal colonization following 14 years of CO2 enrichment and 6 years of N fertilization in a warm temperate forest[J].Tree Physiology,2014,34(9):955-965. |
| 15 | MCCORMACK M L, GUO D L, IVERSEN C M,et al.Building a better foundation:improving root-trait measurements to understand and model plant and ecosystem processes[J].New Phytologist,2017,215(1):27-37. |
| 16 | WANG Y N, GAO G Q, WANG N,et al.Effects of morphology and stand structure on root biomass and length differed between absorptive and transport roots in temperate trees[J].Plant and Soil,2019,442:355-367. |
| 17 | POORTER H, NIKLAS K J, REICH P B,et al.Biomass allocation to leaves,stems and roots:meta-analyses of interspecific variation and environmental control[J].New Phytologist,2012,193(1):30-50. |
| 18 | PREGITZER K S, KUBISKE M E, YU C K,et al.Relationships among root branch order,carbon,and nitrogen in four temperate species[J].Oecologia,1997,111:302-308. |
| 19 | RYSER P.The mysterious root length[J].Plant and Soil,2006,286:1-6. |
| 20 | 孙楠,张怡春,赵眉芳.长白落叶松人工林根系生物量及其垂直分布特征[J].森林工程,2021,37(6):17-24. |
| 20 | SUN N, ZHANG Y C, ZHAO M F.Root biomass and vertical distribution characteristics of larch plantation[J].Forest Engineering,2021,37(6):17-24. |
| 21 | 胡慧,包维楷,李芳兰.岷江上游4个栽培树种细根功能性状垂直分布的差异性[J].生态学杂志,2020,39(1):46-56. |
| 21 | HU H, BAO W K, LI F L.Differential vertical distribution of functional traits of fine roots of four cultivated tree species in the upper reaches of Minjiang River[J].Chinese Journal of Ecology,2020,39(1):46-56. |
| 22 | ZHOU Z C, SHANGGUAN Z P.Vertical distribution of fine roots in relation to soil factors in Pinus tabulaeformis Carr.forest of the Loess Plateau of China[J].Plant and Soil,2007,291:119-129. |
| 23 | GAO G Q, GOEBEL M, WANG Y,et al.Spatial-temporal variations of absorptive fine roots in the organic and soil layers of a Larix gmelinii forest[J].Trees,2021,35:1013-1023. |
| 24 | XIAO C W, YUSTE J C, JANSSENS I A,et al.Above- and belowground biomass and net primary production in a 73-year-old scots pine forest[J].Tree Physiology,2003,23(8):505-516. |
| 25 | KON?PKA B, YUSTE J C, JANSSENS I A,et al.Comparison of fine root dynamics in scots pine and pedunculate oak in sandy soil[J].Plant and Soil,2005,276:33-45. |
| 26 | 徐莹,邓磊.祁连山不同混交度青海云杉林细根形态特征及与土壤理化性质的关系[J].水土保持研究,2023,30(3):181-187. |
| 26 | XU Y, DENG L.Relationships of fine root morphology and soil physicochemical properties in different mingling intensity of Picea crassifolia in Qilian Mountains[J].Research of Soil and Water Conservation,2023,30(3):181-187. |
| 27 | 刘岩,毛子军.小兴安岭阔叶红松林不同演替系列森林细根生物量的研究[J].植物研究,2018,38(4):583-589. |
| 27 | LIU Y, MAO Z J.Root biomass in different secondary succession forests in the broad-leaved Korean Pine forest area of Xiaoxing'an Mountain[J].Bulletin of Botanical Research,2018,38(4):583-589. |
| 28 | WANG G L, FAHEY T J, XUE S,et al.Root morphology and architecture respond to N addition in Pinus tabuliformis,west China[J].Oecologia,2013,171(2):583-590. |
| 29 | KOU L, GUO D L, YANG H,et al.Growth,morphological traits and mycorrhizal colonization of fine roots respond differently to nitrogen addition in a slash pine plantation in subtropical China[J].Plant and Soil,2015,391:207-218. |
| 30 | WANG Y, LI Z Y, WANG Z Q,et al.Functional trait plasticity but not coordination differs in absorptive and transport fine roots in response to soil depth[J].Forests,2020,11(1):42. |
| 31 | 廖迎春,段洪浪,施星星,等.杉木(Cunninghamia lanceolate)人工林生长状况与根系生物量相关性研究[J].生态环境学报,2021,30(6):1121-1128. |
| 31 | LIAO Y C, DUAN H L, SHI X X,et al.The relationship between the stand growth and root biomass of Cunninghamia lanceolate plantations[J].Ecology and Environmental Sciences,2021,30(6):1121-1128. |
| 32 | FRANSEN B, DE KROON H.Long-term disadvantages of selective root placement:root proliferation and shoot biomass of two perennial grass species in a 2-year experiment[J].Journal of Ecology,2001,89(5):711-722. |
| 33 | LIU B T, LI H B, ZHU B,et al.Complementarity in nutrient foraging strategies of absorptive fine roots and arbuscular mycorrhizal fungi across 14 coexisting subtropical tree species[J].New Phytologist,2015,208(1):125-136. |
| 34 | EISSENSTAT D M, YANAI R D.The ecology of root lifespan[J].Advances in Ecological Research,1997,27:1-60. |
/
| 〈 |
|
〉 |
AI Summary
