[Impact of industrial pollution on emission of carbon dioxide by soils in the Kola Subarctic Region].

IF 0.3 4区生物学 Q4 BIOLOGY

Zhurnal obshchei biologii Pub Date : 2015-01-01

G N Koptsik, M S Kadulin, A I Zakharova

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引用次数: 0

Abstract

Soil emission of carbon dioxide, the key component of carbon cycle and the characteristic of soil biological activity, has been studied in background and polluted ecosystems in the Kola subarctic, the large industrial region of Russia. Long-term air pollution by emissions of "Pechenganikel" smelter, the largest source of sulphur dioxide and heavy metals in Northern Europe, has caused the technogenic digression of forest ecosystems. As a result of the digression, the tree layer was destructed, the number of plant species was diminished, the activity of soil biota was weakened, the soils were polluted and exhausted, biogeochemical cycles of elements were disturbed and productivity of ecosystems shrunk. Field investigations revealed the decrease of the in.situ soil respiration in average from 190-230 mg C-CO2/m2 x per h in background pine forests to 130-160, 100, and 20 mg C-CO2/m2.per h at the stages of pine defoliation, sparse pine forest and technogenic barrens of the technogenic succession, respectively. The soil respira- tion in birch forests was more intense than in pine forests and tended to decrease from about 290 mg C-CO2/m2 x per h in background forests to 210-220 and 170-190 mg C-CO2/m2 x per h in defoliating forests and technogenic sparse forests, respectively. Due to high spatial variability of soil respiration in both pine and birch forests significant differences from the background level were found only in technogenic sparse forests and barrens. Soil respiration represents total production of carbon dioxide by plant roots and soil microorganisms. The decrease in share of root respiration in the total soil respiration with the rise of pollution from 38-57% in background forests up to zero in technogenic barrens has been revealed for the first time for this region. This indicates that plants seem to be more sensitive to pollution as compared to relatively resistant microorganisms. Soil respiration and the contribution of roots to the total respiration positively correlated with distance from the smelter and the content of carbon and nitrogen and negatively correlated with the content of available nickel and copper in the soils. Remediation of technogenic barrens promoted intensification of soil biological activity. At the same time, the willow planting along with grass seeding into the new constructed fertile soil layer was much more effective for activation of soil respiration and the contribution of roots to the total respiration than the planting into the limed and fertilized polluted soils (chemo-phytostabilization).

本刊更多论文

[工业污染对科拉亚北极地区土壤二氧化碳排放的影响]。

土壤二氧化碳排放是碳循环的关键组成部分，也是土壤生物活动的特征，本文在俄罗斯大工业区科拉亚北极地区的背景生态系统和污染生态系统中进行了研究。“佩琴镍”冶炼厂是北欧最大的二氧化硫和重金属来源，其排放造成的长期空气污染导致了森林生态系统的技术偏离。越轨造成乔木层被破坏，植物种类减少，土壤生物群活性减弱，土壤被污染枯竭，元素生物地球化学循环受到干扰，生态系统生产力萎缩。实地调查显示，在减少。本底松林的原位土壤呼吸从平均190 ~ 230 mg C-CO2/m2 x / h增加到130 ~ 160、100和20 mg C-CO2/m2。技术演替的松枝落叶阶段、松疏林阶段和技术荒无区阶段的Per h。白桦林土壤呼吸比松林更强烈，并有从背景林290 mg C-CO2/m2 x / h下降到落叶林210 ~ 220 mg C-CO2/m2 x / h和科技疏林170 ~ 190 mg C-CO2/ h的趋势。由于松林和白桦林土壤呼吸具有较高的空间变异性，只有在技术改造的疏林和荒无人烟的土壤呼吸与背景水平存在显著差异。土壤呼吸是指植物根系和土壤微生物产生的二氧化碳总量。本研究首次揭示了该地区根呼吸在土壤呼吸总量中所占的比例随着污染的增加而下降，从背景林的38-57%上升到技术荒滩的零。这表明，与相对抗性的微生物相比，植物似乎对污染更敏感。土壤呼吸和根系对总呼吸的贡献与离冶炼厂的距离和土壤碳、氮含量呈正相关，与土壤有效镍、铜含量呈负相关。技术荒地的修复促进了土壤生物活性的增强。与此同时，在新建的肥沃土壤层中种植柳树和播草比在石灰和施肥的污染土壤中种植更有效地激活土壤呼吸和根系对总呼吸的贡献(化学植物稳定)。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Zhurnal obshchei biologii 生物-生物学

自引率

25.00%

发文量

审稿时长

>12 weeks

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