中国沙棘克隆生长对造林密度的早期响应及其生物量分配调节机制

doi:10.11707/j.1001-7488.20171004

摘要/Abstract

摘要： [目的]探讨中国沙棘克隆生长对造林密度的早期响应及其生物量分配调节机制，确定利于种群稳定性长期维持的适宜造林密度。[方法]设置4个造林密度，即2 500、4 444、10 000、40 000株·hm^-2。调查测定时，分株生长能力采用每木检尺法，克隆繁殖能力采用子株个体计数法，克隆扩散能力采用跟踪挖掘法，地上生物量采用平均标准木法，垂直根生物量测定采用格子样方法和全挖法，水平根生物量测定采用跟踪挖掘法。[结果]随着造林密度的增大，分株地径和冠幅生长量呈对数函数下降，而树高生长量差异不显著；克隆繁殖、克隆扩散能力呈上凸抛物线变化即先升后降，且两者之间具有协同作用；地上生物量分配下降、地下生物量分配上升，水平根生物量分配也呈上凸抛物线变化即先升后降；分株生长能力与地上生物量分配呈正相关，克隆繁殖、克隆扩散能力与水平根生物量分配呈正相关。[结论]种群通过地上与地下、水平根与垂直根生物量分配调节，在分株生长与克隆繁殖、克隆扩散之间做出权衡，从而形成与造林密度相适应的个体形态和克隆生长格局。随着造林密度的增大，分株形态呈粗-中-细的变化过程，克隆繁殖和克隆扩散能力呈低-高-低的变化过程，即克隆生长格局呈离散型-聚集型-离散型、种群稳定性呈低-高-低的变化过程。最有利于克隆生长和种群稳定性维持的适宜造林密度为15 000~20 000株·hm^-2。相应的株行距为0.5 m×1.0 m~0.7 m×1.0 m。

关键词: 克隆繁殖, 克隆扩散, 生物量分配, 造林密度, 中国沙棘, 毛乌素沙地

Abstract: [Objective] The population stability of Hippophae rhamniodes ssp. sinensis depends on clonal growth ability and also on levels of environmental resources. However, the effects of the planting density are not well illustrated. This study aims to determine the optimal planting density according to the clonal growth response to the planting density and the regulation mechanism of the biomass allocation.[Method] Four planting densities, namely 2 500, 4 444, 10 000, and 40 000 plants·hm^-2 were applied. The ramet growth ability was measured for each tally tree. The clonal propagation ability was obtained by counting the daughter ramets. The clonal expansion capability was quantified by tracking the clones. Aboveground biomass was estimated from the average standard trees. The vertical and horizontal root biomasses were determined by weighting all the roots in the grid quadrats and tracked, respectively.[Result] The basal stem diameter and crown growth of the ramets showed logarithmic decreases with increasing planting density, while the height growth was independent of the density. The clonal propagation and expansion abilities showed parabola profiles, with synergistic effect between them. The biomass was allocated more to the belowground and less to the aboveground. The biomass allocation of horizontal roots showed a parabola. The growth ability of the ramets was positively correlated with the aboveground biomass allocation, and the clonal propagation and expansion abilities were positively correlated with the biomass allocation of the horizontal roots.[Conclusion] The population is traded-off in the biomass allocation between the above-and the below-ground and between the vertical and horizontal roots, and between ramet growth and the clonal propagation and expansion, by which forms individual shape and clonal growth configuration to adapt planting dnesity. With the increase of initial planting density, the ramet morphology changes from thick to medium and to slender, and the clonal propagation and expansion abilities did as a low-high-low pattern. That is to say, the clonal growth configuration went as a guerrilla-aggregation-guerrilla pattern, and the population stability exhibit a low-high-low changing process. According to this study, the suitable initial planting density is about 15 000 to 20 000 plants·hm^-2, which is most conducive to the clonal growth and the population stability maintenance.

Key words: clonal propagation, clonal expansion, biomass allocation, initial planting density, Hippophae rhamniodes ssp. sinensis, Mu Us sandy land

中图分类号:

S718.43

姜准, 刘丹一, 陈贝贝, 高海银, 刘春红, 张增悦, 邹旭, 李根前. 中国沙棘克隆生长对造林密度的早期响应及其生物量分配调节机制[J]. 林业科学, 2017, 53(10): 29-39.

Jiang Zhun, Liu Danyi, Chen Beibei, Gao Haiyin, Liu Chunhong, Zhang Zengyue, Zou Xu, Li Genqian. Clonal growth of Hippophae Rhamniodes ssp. sinensis at the Early Stage in Response to Initial Planting Density and Its Regulation Mechanism of Biomass Allocation[J]. Scientia Silvae Sinicae, 2017, 53(10): 29-39.

参考文献

董鸣. 1996. 资源异质性环境中的植物克隆生长:觅食行为. 植物学报, 38 (10):828-835.
(Dong M. 1996. Clonal growth in plants in relation to resource heterogeneity foraging behavior. Act a Botanica Sinica, 38 (10):828-835.[in Chinese])
段爱国, 张建国, 何彩云, 等. 2013. 沙棘良种 ‘白丘杂’. 林业科学, 49 (11):196.
(Duan A G, Zhang J G, He C Y, et al. 2013. A new Hippophae rhamniodes hybrid ‘Baiqiuza’. Forest Research, 49 (11):196.[in Chinese])
高志义, 张玉胜. 1989. 沙棘根系特性的观察与研究. 北京林业大学学报, 11 (4):53-59.
(Gao Z Y, Zhang Y S. 1989. The observation and investigation on the feature of root system of seabuckthorn. Journal of Beijing Forestry University, 11 (4):53-59.[in Chinese])
韩江万. 2004. 甘南白龙江流域沙棘育苗及造林技术. 甘肃农业科技, (5):36-37.
(Han J W. 2004. Seedling raising and afforestation techniques of Hippophae rhamniodes subsp. sinensis in Longjiang white Gannan River Basin.Agricultural Science and Technology, (5):36-37.[in Chinese])
贺斌, 赵粉侠, 李根前, 等. 2012. 毛乌素沙地中国沙棘克隆生长对土壤水分含量的响应. 南京林业大学学报:自然科学版, 36(4):46-50.
(He B, Zhao F X, Li G Q, et al. 2012. The response of clonal growth of Hippophae rhamniodes L. subsp sinensis to the availability of soil moisture in Mu Us sand land. Journal of Nanjing Forestry University:Natural Science Edition, 36 (4):46-50.[in Chinese])
贺斌, 李根前, 高海银, 等. 2007a. 不同土壤水分条件下中国沙棘克隆生长的对比研究. 云南大学学报:自然科学版, 29(1):101-107.
(He B, Li G Q, Gao H Y, et al. 2007a. A comparison study on theclonal growth of Hippophae rhamniodes L.subsp.sinensis at different soil moisture condition. Journal of Yunnan University:Natural Sciences Edition, 29 (1):101-107.[in Chinese])
贺斌, 李根前. 2007b. 木本克隆植物中国沙棘种群数量与结构对土壤水分的响应. 西北农林科技大学学报:自然科学版, 35(3):183-187.
(He B, Li G Q. 2007b. Population quantity and population structure in response to soil moisture in the clonal tree species Hippophae rhamniodes L.subsp.sinensis. Journal of Journal of Northwest Agriculture and Forest University:Natural Sciences Edition, 35 (3):183-187.[in Chinese])
贺斌, 李根前, 徐德兵, 等. 2006. 沙棘克隆生长及其生态学意义. 西北林学院学报, 21 (3):54-59.
(He B, Li G Q, Xu D B, et al. 2006. The clonal growth and its ecological significance of Hippophae. Journal of Northwest Forestry University, 21 (3):54-59.[in Chinese])
黄铨. 2001. 种植沙棘加速"三北"生态环境建设. 林业科学, 37(2):20.
(Huang Q. 2001. Accelerate the Hippophae cultivation of ecological environment construction of ‘Three North’. Scientia Silvae Sinicae, 37 (2):20.[in Chinese])
惠兴学, 洪新, 于欣, 等. 2009. 辽西地区沙棘退化林分的修复与前景. 国际沙棘研究与开发, 6 (4):24-27.
(Hui X X, Hong X, Yu X, et al. 2009. Restoration of degraded seabuckthorn stands and prospects in the western Liaoning. The Global Seabuckthorn Research and Development, 6 (4):24-27.[in Chinese])
李根前, 黄宝龙, 唐德瑞, 等. 2001a. 毛乌素沙地中国沙棘无性系种群年龄结构动态与遗传后果研究. 应用生态学报, 12 (3):347~350.
(Li G Q, Huang B L, Tang D R, et al. 2001a. Age structure dynamics and genetic consequences of Hippophea rhamnoides L. subsp.sinensis clone population in Mu Us Sand. Chinese Journal of Applied Ecology, 12 (3):347-350.[in Chinese])
李根前, 黄宝龙, 唐德瑞, 等. 2001b. 毛乌素沙地中国沙棘克隆生长调节. 应用生态学报, 12 (5):682-686.
(Li G Q, Huang B L, Tang D R, et al. 2001b. Regulation of clonal growth of Hippophae rhamnoides L. subsp sinensis population in Mu Us Sandland. Chinese Journal of Applied Ecology, 12 (5):682-686.[in Chinese])
李根前, 黄宝龙, 唐德瑞, 等. 2001c. 毛乌素沙地中国沙棘无性系生长格局与生物量分配. 西北农林科技大学学报:自然科学版, 29 (2):51-55.
(Li G Q, Huang B L, Tang D R, et al. 2001c. Studies on the clonal growth pattern and biomass allocation of Hippophae rhamnoides L. subsp sinensis population in Mu Us Sandland. Journal of Journal of Northwest Agriculture and Forest University:Natural Sciences Edition, 29 (2):51-55.[in Chinese])
李根前, 赵粉侠, 李秀寨, 等. 2004. 毛乌素沙地中国沙棘种群数量动态研究. 林业科学, 40 (1):180-185.
(Li G Q, Zhao F X, Li X Z,et al. 2004. Density and biomass dynamics of Hippophae rhamnoides L.subsp.sinensis population in Mu Us Sand. Scientia Silvae Sinicae, 40 (1):180-185.[in Chinese])
李根前, 唐德瑞, 赵一庆, 等. 2000. 沙棘林培育技术研究. 沙棘, 13 (3):12-17.
(Li G Q, Tang D R, Zhao Y Q, et al. 2000. Studying on Cultivation Technology of Hippophae rhamniodes subsp. sinensis. Hippophae, 13 (3):12-17.[in Chinese])
李孙玲, 李甜江, 李根前, 等. 2011. 毛乌素沙地中国沙棘存活及生长对灌水和密度的响应. 西北林学院学报, 26 (3):107-111.
(Li S L, Li T J, Li G Q, et al. 2011. The growth and survival of Hippophae rhamniodes L. ssp.sinensis in response to irrigation intensity and initial density in Mu Us Sand. Journal of Northwest Forestry University, 26 (3):107-111.[in Chinese])
李甜江, 李根前, 徐德兵, 等. 2010a. 中国沙棘克隆生长对灌水强度的响应. 生态学报, 30 (24):6952-6960.
(Li T J, Li G Q, Xu D B, et al. 2010a. The clonal of Hippophae rhamniodes L.ssp.sinensis in response to irrigation intensity. Acta Ecologica Sinica, 30 (24):6952-6960.[in Chinese])
李甜江, 李根前, 徐德兵, 等. 2010b. 克隆植物中国沙棘生长对外源植物激素的响应. 生态学报, 30 (3):0659-0667.
(Li T J, Li G Q, Xu D B, et al. 2010b. The growth of clonal plant Hippophae rhamnoides L. ssp. sinensis in response to exogenous phytohorm one. Acta Ecologica Sinica, 30 (3):0659-0667.[in Chinese])
李秀寨, 李根前, 韦宇, 等. 2005. 中国沙棘大面积死亡原因的探讨. 沙棘, 18 (1):24-28.
(Li X Z, Li G Q, Wei Y, et al. 2005. Causes of seabuckthorn death in large acreage in China. Hippophae, 18 (1):24-28.[in Chinese])
廉永善, 陈学林, 郭建魁, 等. 1989. 甘肃省的沙棘资源及开发设想. 林业科学, 25 (1):82-85.
(Lian Y S, Chen X L, Guo J K, et al. 1989. Resources and exploitative assumption for Hippophae.L.in Gansu Province. Forest Research, 25 (1):82-85.[in Chinese])
刘丹一, 李甜江, 李根前, 等. 2012. 初植密度对中国沙棘林木生长特征的影响. 西部林业科学, 41 (6):78-83.
(Liu D Y, Li T J, Li G Q, et al. 2012. Effect of planting density on growing characteristics of Hippophae rhamniodes subsp. sinensis. Journal of West China Forestry Science, 41 (6):78-83.[in Chinese])
刘明, 唐翠平, 郭峰, 等. 2014. 克隆植物中国沙棘种群动态及其生物量调节机制. 南京林业大学学报:自然科学版, 38 (4):57-63.
(Liu M, Tang C P, Guo F, et al. 2014. A study on the population dynamics andits biomass adjustment mechanisms of clonal plant Hippophae rhamhoides L. ssp. sinensis. Journal of Nanjing Forestry University:Natural Science Edition, 38 (4):57-63.[in Chinese])
唐翠平. 2015. 中国沙棘克隆生长对组织含水率的响应.昆明:西南林业大学硕士学位论文.
(Tang C P. 2015. The Clonal growth of Hippophae rhamnoides L. ssp. sinensis in response to tissue water content. Kunming:MS thesis of Southwest Forestry University.[in Chinese])
吴宗凯, 刘广全, 匡尚富, 等. 2009. 黄土高原半干旱区退耕地沙棘林密度调控. 国际沙棘研究与开发, 7 (3):5-10.
(Wu Z K, Liu G Q, Kuang S F, et al. 2009. Controlling seabuckthorn densities for returning into woodland in semi-arid region of The Loess Plateau. The Global Seabuckthorn Research and Development, 7(3):5-10.[in Chinese])
肖智勇, 李根前, 代光辉, 等. 2011. 黄土高原不同坡向中国沙棘种群生物量投资与分配. 东北林业大学学报, 39 (5):44-46.
(Xi Z Y, Li G Q, Dai G H, et al. 2011. Biomass allocation and investment of Hippophae rhamnoides ssp.sinensis populations under different aspects of slope in the Loess Platea. Journal of Northeast Forestry University, 39 (5):44-46.[in Chinese])
曾诚, 陈贝贝, 李根前, 等. 2016. 毛乌素沙地土壤水分对中国沙棘人工林稳定性及生产力的影响. 林业资源管理, (1):99-104.
(Zeng C, Chen B B, Li G Q, et al. 2016. Influence of soil physico-chemical properties in Maowusu Sandland on the stability and productivity of Hippophae rhamnoides subsp. sinensis Plantation. Forest Resources Management, (1):99-104.[in Chinese])
张建国, 罗红梅, 黄铨, 等. 2005. 大果沙棘不同品种果实特性比较研究. 林业科学研究, 18 (6):643-650.
(Zhang J G, Luo H M, Huang Q, et al. 2005. A comparative study on berry characteristics of large berry cultivars of sea buckthorn. Forest Research, 18 (6):643-650.[in Chinese])
Alpert P. 1991. Nitrogen sharing among ramets increases clonal growth in Fragaria chiloensis. Ecol, 72 (1):69-80.
Cao Z L, Li T J, Li G Q. 2016. Modular growth and clonal propagation of Hippophae rhamnoides subsp. sinensis in response to irrigation intensity. Journal of Forestry Research, 27 (5):1019-1028.
Charpentier A, Anand M, Bauch C T. 2012. Variable offspring size as an adaptation to environmental heterogeneity in a clonal plant species:integrating experimental and modeling approaches. Journal of Ecology, 100 (1):184-195.
Dong B C, Wang J Z, Liu R H, et al. 2013. Effects of heterogeneous competitor distribution and ramet aggregation on the growth and size structure of a clonal plant. Plos One, 8 (7):1-12.
Dong B C,Alpert P, Guo W, et al. 2012. Effects of fragmentation on the survival and growth of the invasive, clonal plant Alternanthera philoxeroides. Original Paper, 14 (6):1101-1110.
Evans J P. 1992. The effect of local resource availability and clonal integration on ramet functional morphology in Hydrocotyle honariensis. Oecologia, 89:265-276.
Gough L, Cross K L, Cleland E E, et al. 2012. Incorporating clonal growth form clarifies the role of plant height in response to nitrogen addition. Oecologia, 169 (4):1053-1062.
Hutchings M J, de Kroon H. 1994. Foraging in plants:the role of morphological plasticity in resource acquisition. Advances in Ecological Research, 25:159-238.
Luo D, Qian Y Q, Han L,et al. 2013. Phenotypic responses of a stoloniferous clonal plant Buchloe dactyloides to scale-dependent nutrient heterogeneity. Plos One, 8 (6):1591-1594.
Luo X G, Dong M.2002. Architectural plasticity in response to soil moisture in the stoloniferous Herb, Duchesnea indica. Acta Botanica Sinica, 44 (1):97-100.
Ning Y, Zhang Z X, Cui L J, et al. 2014. Adaptive significance of and factors affecting plasticity of biomass allocation and rhizome morphology:a case study of the clonal plant Scirpus planiculmis. Polish Journal of Ecology, 62 (1):77-88.
Qiang Y Q, Luo D, Gong G, et al. 2014. Effects of spatial scale of soil heterogeneity on the growth of a clonal plant producing both spreading and clumping ramets. J Plant Growth Regul, 33 (2):214-221.
Ronald H K, Terence P H, Susan R K. 1996. Density-dependent dynamics of soft coral aggregations:the significance of clonal growth and form. Ecology, 77 (5):1592-1599.
Salzman A G. 1985. Habitat selection in a clonal plant. Science, 228 (4699):603-604.
Slade A J, Hutchings M J.1987a. The effects of nutrient availability on foraging in the clonal herb Glechoma hederacea. J of Ecol, 75(1):95-112.
Slade A J, Hutchings M J. 1987b. The effects of light intensity on foraging in the clonal herb Glechoma hederacea. J of Ecol, 75 (3):639-650.
Silvertown J W. 1993. Introduction to plant population.3^rd edition. New York.
Takahashi M K, Horner L M, Kubota T, et al. 2011. Extensive clonal spread and extreme longevity in saw palmetto, a foundation clonal plant. Molecular Ecology, 20 (18):3730-3742.
Wang J C, Shi X, Zhang D Y,et al. 2011. Phenotypic plasticity in response to soil moisture availability in the clonal plant Eremosparton songoricum(Litv.) Vass. Journal of Arid Land, 3 (1):34-39.
Yan X, Wang H W, Wang Q F. 2013. Risk spreading, habitat selection and division of biomass in a submerged clonal plant:responses to heterogeneous copper pollution. Environmental pollution, 174(5):114-120.

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