基于熵权法评价调控林凋落物层水文特性——以贵州马尾松林和5种阔叶树调控林为例

doi:10.16843/j.sswc.2021.06.006

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摘要为明晰不同阔叶树种调控对马尾松人工林凋落物层水文特性的影响，在贵州龙里林场对不同阔叶树种（伯乐、桂南木莲、连香、深山含笑和油茶）调控15年后的马尾松人工林凋落物层进行研究，结合室外调查和室内浸水实验测得凋落物层水文特性指标，通过熵权法计算指标权重以比较调控前后的凋落物层水文特性差异。结果表明：1）调控前后凋落物层现存量表现为：马尾松+桂南木莲（8.62 t/hm²） > 马尾松+伯乐（8.03 t/hm²） > 马尾松纯林（7.73 t/hm²） > 马尾松+深山含笑（7.17 t/hm²） > 马尾松+连香（6.94 t/hm²） > 马尾松+油茶（6.34 t/hm²）；2）各林型中凋落物叶占比均最大达到61%及以上，未分解层现存量、厚度明显大于半分解层；3）在不同树种调控后的人工林凋落物水文特性评价指标中，各指标权重大小排序为：凋落物器官密度（0.174 0） > 现存量（0.157 2） > 有效拦蓄率（0.157 0） > 最大持水率（0.144 1） > 最大吸水率（0.141 9） > 厚度（0.133 4） > 叶面积（0.092 6）；4）各调控林与未调控马尾松纯林之间凋落物水文特性综合评分排序为：马尾松+桂南木莲 > 马尾松+伯乐 > 马尾松纯林 > 马尾松+深山含笑 > 马尾松+连香 > 马尾松+油茶。综上：桂南木莲和伯乐调控后的马尾松林凋落物水文效益较为显著，油茶调控林的凋落物水文特性较差；因此，在对马尾松纯林进行物种调控时，为保证调控林凋落物层水文生态功能，应考虑到调控阔叶树种特性之间的差异。

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关键词 ：马尾松, 物种调控, 凋落物, 水文特性, 熵权法

Abstract：[Background] Soil erosion under Pinus massoniana forest is a current problem to be solved, it is an effective method to plant different broad-leaved trees in P. massoniana forest. However, different broad-leaved trees may cause diffident control results. Therefore, there is great significance to clarify the influence of control of broad-leaved species on the hydrological characteristics of litter layer.[Methods] We chose 5 broad-leaved control forests and P. massoniana forest in Guizhou Longli forest zone. Combining with the outdoor investigation and indoor experiment measured the litter layer hydrology characteristic indexes, compared before and after the control of litter layer hydrology's feature differences through the entropy weight method to calculate index weight of different broad-leaved species control after 15 years of study of P. massoniana forst.[Results] 1) Before and after the regulation of litter layer standing crop is shown as:P. massoniana+Manglietia chingii (8.62 t/hm²) > P. massoniana+Bretschneidera sinensis (8.03 t/hm²) > P. massoniana (7.73 t/hm²) > P. massoniana+Michelia maudiae (7.17 t/hm²) > P. massoniana+Cercidiphyllum japonicum (6.94 t/hm²) > P. massoniana+Camellia oleifera (6.34 t/hm²). 2) The leaf in litter layer took up the highest proportion at least 61%,stock and thicknes of the undercomposed layer are significantly greater than semi-decomposition layer. 3) Among the indexes for evaluating the hydrological characteristics of litters after regulation by different tree species, the weight of each index was ranked as follows:the density of litters' organ (0.174 0) > stock (0.157 2) > effective retention rate(0.157 0) > maximum water holding rate (0.144 1) > maximum water absorption rate (0.141 9) > thickness (0.133 4) > leaf area (0.092 6). 4) Between controled forest and P. massoniana, the comprehensive hydrological characteristics score of litters is ranked as:P. massoniana+M. chingii > P. massoniana+B. sinensis > P. massoniana > P. massoniana+M. maudiae > P. massoniana+C. japonicum > P. massoniana+C. oleifera.[Conclusions] After being controlled by broad-leaved trees, the significant effect of litter layer hydrologic are M. chingii and B. sinensis and the worst is C. oleifera. In order to ensure the hydrological and ecological functions of the forest in the study area, it should be considered the differences between controlled broad-leaved tree species.

Key words： Pinus massoniana species control litter hydrological characteristics entropy weight method

收稿日期: 2020-05-29

PACS:

S774

基金资助:国家重点研发计划项目"马尾松大径才定向培育技术研究"（2017YFD0600302），"马尾松人工林地力长期维护和调控技术"（2017YFD0600304）；贵州省一流学科建设项目（GNYL[2017]007）；贵州省"百层次"培养计划项目（QKHRC-2015-4022）；贵州省科技计划项目（QKHZC[2018]2305）；贵州省人才团队项目（QKHPTRC20195614，[2018]5261）

通讯作者: 周运超(1964-),男,博士,教授。主要研究方向:森林土壤学。E-mail:yc409@163.com E-mail: yc409@163.com

作者简介: 张薰元(1996-),女,硕士研究生。主要研究方向:林业及水土保持。E-mail:2801381141@qq.com

引用本文:

张薰元, 周运超, 白云星, 杜姣姣. 基于熵权法评价调控林凋落物层水文特性——以贵州马尾松林和5种阔叶树调控林为例[J]. 中国水土保持科学, 2021, 19(6): 44-53.
ZHANG Xunyuan, ZHOU Yunchao, BAI Yunxing, DU Jiaojiao. Hydrological characteristics of controlled forest litter layer based on entropy weight method: A case study of 5 broad-leaved control forests and Pinus massoniana forest in Guizhou province. SSWC, 2021, 19(6): 44-53.

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http://journal12.magtechjournal.com/Jweb_stbc/CN/10.16843/j.sswc.2021.06.006 或 http://journal12.magtechjournal.com/Jweb_stbc/CN/Y2021/V19/I6/44

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