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1.
对川南天然常绿阔叶林及其人工更新成檫木林、柳杉林和水杉林后土壤不同形态氮素含量、微生物数量和脲酶活性进行研究,并探讨了它们之间的相互关系。结果表明:土壤全氮、微生物量氮、铵态氮和硝态氮含量、细菌、真菌和放线菌数量及脲酶活性,各林分均为秋季>春季>冬季>夏季,各季节均为天然常绿阔叶林>檫木林>水杉林>柳杉林。这说明天然常绿阔叶林人工更新后土壤不同形态氮素含量、微生物数量和脲酶活性下降,土壤保肥和供肥能力降低,而各人工林下降程度不同。土壤不同形态氮素含量与微生物数量和脲酶活性之间呈显著正相关,说明微生物数量及脲酶活性的变化能够表征土壤氮素含量变化。研究结果为保护天然常绿阔叶林、选择适宜的更新树种和天然常绿阔叶林人工更新后林地土壤的科学管理提供依据,也为退耕还林中树种的选择提供参考。  相似文献   

2.
 运用分形模型研究了川南天然常绿阔叶林及其人工更新成檫木(Sassafras tzumu)林 、柳杉(Cryptomeria fortunei)林和水杉(Metasequoia glyptostroboides)林后土壤团粒结构,探讨了分形维数与林地土壤水源涵养功能、肥力特征和微生物数量之间的关系。结果表明:天然常绿阔 叶林人工更新后土壤团粒结构的分形维数和结构体破坏率增大、土壤物理性质变差、养分含量和微生物数量降低,3种人工林中,檫木林较好、 水杉林次之、柳杉林最差;土壤团聚体、水稳性团聚体和水稳性大团聚体含量越高分形维数越小;在湿筛条件下, 土壤结构体破坏率随分形维 数的降低而减小;土壤团粒结构的分形维数与土壤物理性质、养分含量和微生物数量之间存在显著的回归关系。这表明天然常绿阔叶林人工更 新后由于不同林分对林地土壤组成结构的维护效果不同,导致更新后林地土壤物理、化学和生物性质变化 ,林地土壤团粒结构的变化,进而影 响其分形维数的大小。因此,分形维数可作为天然常绿阔叶林及其人工更新后林地土壤水源涵养功能、肥力特征和微生物活动情况的一项综合 性定量化评价指标。同时,为保护天然常绿阔叶林、选择适宜的更新树种和天然常绿阔叶林人工更新后林地土壤的科学管理提供依据,也为退 耕还林中树种的选择提供参考。  相似文献   

3.
浙江天童地区常绿阔叶林退化对土壤养分库和碳库的影响   总被引:3,自引:0,他引:3  
闫恩荣  王希华  陈小勇 《生态学报》2007,27(4):1646-1655
为了解常绿阔叶林退化对土壤碳库和养分库的影响,采用空间代替时间的研究方法,以常绿阔叶林顶级群落为参照,选择了次生常绿阔叶幼年林、次生针阔混交林、次生针叶林、灌丛和灌草丛代表不同的退化类型,分别对其土壤氮磷养分库、碳库进行了调查和分析。结果表明:土壤氮库贮量从大到小依次为,成熟常绿阔叶林、次生常绿阔叶幼年林、灌丛、次生针叶林、灌草丛和次生针阔混交林;土壤总磷含量也是在成熟林最高,次生针阔混交林和次生针叶林的总磷含量显著高于次生常绿阔叶幼年林和灌丛;土壤有机碳含量从高到低依次为:成熟常绿阔叶林,次生针叶林、次生常绿阔叶幼年林、灌丛、灌草丛和次生针阔混交林;土壤铵态氮在成熟林、灌丛和灌草丛的库容量最大,其次分别为次生幼年常绿阔叶林、次生针阔混交林,最小的为次生针叶林;硝态氮则在灌草丛的库容量最大,其次分别为次生针叶林、次生针阔混交林和成熟林针叶林,最小的为次生常绿阔叶幼年林和灌丛。统计显示,常绿阔叶林退化不仅导致土壤有机碳库含量的显著下降,也使得土壤氮磷养分库含量显著下降。可以认为,砍伐导致的大量生物量输出和森林管理措施的影响,植物种类组成的改变,土壤物理性质的改变以及养分和有机碳的主要生物化学转化环节发生改变是导致此类变化的主要因素,常绿阔叶林顶极群落土壤是该地区土壤的最大养分库和碳库。  相似文献   

4.
研究了湖南省会同县森林植被从地带性植被天然常绿阔叶林到杉木人工林再到杉木火力楠混交林的转变过程中土壤微生物生物量碳和酶活性的变化趋势。结果表明:杉木纯林和混交林土壤微生物生物量碳含量均显著低于常绿阔叶林,分别仅为常绿阔叶林的76.8%和71.5%;与天然阔叶林相比,杉木人工林土壤蔗糖酶、脲酶和磷酸酶活性分别降低了35.8%、22.1%和45.1%,而多酚氧化酶活性增高了40.0%;相反,杉木火力楠混交林土壤蔗糖酶、脲酶和磷酸酶活性比杉木纯林分别增加了20.3%、12.6%和67.8%,而土壤多酚氧化酶活性则降低了41.0%;表明森林植被转变对土壤微生物生物量碳和土壤酶活性能够产生较大的影响,不同的树种对土壤微生物生物量碳和土壤酶活性的影响差异较大。  相似文献   

5.
天然林改造为人工林后,由于植被覆盖类型和经营管理措施发生改变,从而显著影响土壤有机碳库的特征.测定浙江省临安市相邻的天然常绿阔叶林和板栗林(板栗林由常绿阔叶林改造而来,集约经营10年)表层(0~20 cm)和亚表层(20~40 cm)土壤有机碳储量和不同形态活性有机碳库,用固态核磁共振方法分析土壤有机碳的化学结构特征,研究天然常绿阔叶林改造为板栗林对土壤有机碳库的影响.结果表明: 常绿阔叶林改造为板栗林后,土壤表层有机碳储量、水溶性有机碳、热水溶性有机碳、微生物生物量碳和易氧化碳含量分别下降19.7%、34.4%、25.8%、30.4%和25.2%,土壤亚表层的各指标分别下降13.5%、38.4%、19.8%、34.1%和22.2%.土壤表层烷氧碳含量、芳香碳含量以及芳香度显著降低,而烷基碳含量、羰基碳含量以及A/O-A值均显著增加;土壤亚表层烷氧碳含量显著降低,而烷基碳含量和A/O-A值显著增加,而芳香碳含量、羰基碳含量以及芳香度无显著变化.天然常绿阔叶林改造为板栗林并长期集约经营后,土壤有机碳储量和活性有机碳库均显著下降,有机碳的化学结构发生显著变化.  相似文献   

6.
研究了湖南会同红黄壤区杉木人工林和常绿阔叶林土壤微生物量和养分状况.结果表明,该区杉木人工林取代地带性常绿阔叶林和杉木连栽后,土壤微生物碳、氮和土壤养分含量下降,土壤严重退化.在0~10 cm土层内,常绿阔叶林土壤微生物碳和氮含量为800.5和84.5 mg·kg-1,分别是第1代杉木林的1.90和1.03倍、第2代杉木林的2.16和1.27倍;在10~20 cm土层内,常绿阔叶林土壤微生物碳和氮含量为475.4和63.3 mg·kg-1,分别是第1代杉木纯林的1.86、1.60倍和第2代杉木林的2.11和1.76倍.在0~10 cm 和10~20cm土层内,杉木人工林取代常绿阔叶林和杉木栽植代数增加后,土壤全氮、全钾、铵态氮和速效钾含量均明显降低,但差异并不显著.人工杉木林林分组成单一,其凋落物分解慢、归还养分数量少;炼山等造成的表土流失是杉木人工林土壤微生物量和养分库退化的重要原因.土壤微生物碳与土壤全氮、铵态氮、全钾和速效钾含量呈极显著的正相关,土壤微生物氮与土壤养分含量也达到极显著水平.  相似文献   

7.
揭示不同砍伐频率对森林土壤养分库和氮周转的影响,对于理解森林养分循环的干扰响应具有重要意义。本研究以浙江天童常绿阔叶林为对象,选择了3个具有不同砍伐频率的群落比对组,分析各组内土壤有机碳和氮磷养分库,以及氮素矿化、硝化速率的变化。结果表明:3组群落中,重复砍伐群落的土壤总氮和总有机碳储量显著减小(P0.05),而土壤总磷、铵态氮和硝态氮储量、土壤容重显著增加(P0.05)。土壤氨化速率和氮矿化速率在比对组间无显著差异(P0.05),但硝化速率在重复砍伐后显著增加(P0.05)。本研究表明,土壤养分库和氮转化对森林重复砍伐的响应方式不同。森林重复砍伐后,土壤有机碳库和氮库含量降低,磷库和无机氮库含量增加,氮素矿化和氨化速率变化不显著,硝化速率显著提高。  相似文献   

8.
湘中丘陵区不同演替阶段森林土壤活性有机碳库特征   总被引:5,自引:0,他引:5  
孙伟军  方晰  项文化  张仕吉  李胜蓝 《生态学报》2013,33(24):7765-7773
为了解天然次生林保护对土壤活性有机碳库的影响,采用空间替代时间研究方法,对湘中丘陵区不同演替阶段4种林分类型(杉木人工林、马尾松+石栎针阔混交林、南酸枣落叶阔叶林、青冈+石栎常绿阔叶林)土壤活性有机碳及其与土壤养分相关性进行研究。结果表明:1)各土层总有机碳(TOC)、微生物生物量碳(MBC)、水溶性有机碳(DOC)、易氧化有机碳(EOC)含量均表现为:青冈+石栎常绿阔叶林 > 南酸枣落叶阔叶林 > 马尾松+石栎针阔混交林 > 杉木人工林,在0-30cm土层,马尾松+石栎针阔混交林、南酸枣落叶阔叶林、青冈+石栎常绿阔叶林TOC含量比杉木人工林分别高出13.40%、19.40%和29.91%,MBC含量分别高出15.62%、32.89%和53.33%,DOC含量分别高出8.52%、8.75%和13.76%,EOC含量分别高出32.79%、38.48%和78.30%;2)天然次生林各土层MBC占TOC的比率以南酸枣落叶阔叶林最高,青冈+石栎常绿阔叶林为其次,马尾松+石栎混交林最低,均高于同一土层杉木人工林(除马尾松+石栎混交林15-30cm土层外),天然次生林各土层DOC占TOC的比率随着演替进展而下降,均低于同一土层杉木人工林(除马尾松+石栎混交林0-15cm土层外),天然次生林各土层EOC占TOC的比率随着演替进展而增加,且均高于同一土层杉木人工林;3)土壤MBC、DOC、EOC含量与TOC含量的相关性均达到极显著水平,且天然次生林土壤MBC、DOC、EOC含量与TOC含量的相关系数随着演替进展而增高,均高于杉木人工林;4)4种林分土壤TOC、MBC、DOC、EOC含量与土壤全N、碱解N、全P、有效P、全K、速效K含量之间的相关性均达到显著或极显著水平。  相似文献   

9.
从2013年11月至2015年12月,通过原位试验,在华西雨屏区常绿阔叶林内设置了对照(CK)、氮沉降(N)、减雨(R)、增雨(A)、氮沉降+减雨(NR)、氮沉降+增雨(NA)6个处理水平,研究了模拟氮沉降和降雨量改变对常绿阔叶林土壤有机碳的影响。结果表明:华西雨屏区常绿阔叶林土壤各土层有机碳含量表现为夏季较高,春冬季较低,0—10 cm土层有机碳含量高于10—20 cm土层。从各处理土壤有机碳含量的平均值来看,0—10 cm土层土壤有机碳含量高低顺序表现为:RNRCKANNA;10—20 cm土层表现为:RNRACKNAN。模拟氮沉降和增雨处理促进了华西雨屏区常绿阔叶林土壤有机碳的累积,模拟减雨抑制了土壤有机碳的累积。常绿阔叶林0—10cm土层土壤C/N值显著高于10—20 cm,土壤C/N值随土层加深而呈现出增加的趋势,降雨使土壤C/N降低,增雨使土壤C/N增高。同一氮沉降条件下,增雨处理增加了土壤有机碳的含量,减雨处理减少了土壤有机碳的含量;同一降雨条件下,氮沉降增加土壤有机碳的含量。氮沉降和降雨对土壤可溶解性有机碳和微生物生物量碳含量产生显著影响(P0.05),对土壤活性碳含量影响不显著(P0.05);其交互作用对土壤有机碳、可溶解性有机碳、微生物生物量碳和活性碳含量影响不显著(P0.05)。  相似文献   

10.
稻草还田方式对双季水稻产量和土壤碳库管理指数的影响   总被引:16,自引:0,他引:16  
采用田间定位试验,设置不施肥(CK)、单施化肥(NPK)、稻草切碎全量还田+化肥(SNPK)和稻草全部烧灰还田+化肥(SINPK)4个处理,研究不同稻草还田方式对双季稻产量和土壤碳素形态、碳库管理指数的影响.结果表明:2010—2011年两年四季的水稻平均产量SNPK与SINPK处理基本持平,但均显著高于NPK处理,增幅为5.7%~7.3%.与NPK和SINPK相比,SNPK能显著提高早稻产量,增幅在3.8%~8.8%.与单施化肥和稻草烧灰还田相比,SNPK提高了土壤不同形态碳素含量和碳库管理指数,总有机碳、活性碳、矿化碳和碳库管理指数分别提高了1.8%~2.0%、5.9%~6.5%、16.0%~41.6%和7.3%~7.8%.土壤碳库管理指数与早、晚稻产量呈显著抛物线关系,相关系数分别为0.999和0.980.SNPK能显著提高翌年早稻产量及土壤不同形态碳素含量和碳库管理指数.  相似文献   

11.
Riparian zones provide critically important ecological functions, including the interception of nutrients and sediments before they enter waterways. Consequently, riparian zones, and the vegetation they support, are often considered as an important ‘final buffer’ between waterways and adjacent land. In agricultural ecosystems, riparian zones are therefore increasingly recognized as an important component of strategies aimed at minimizing the flow of nutrients and sediments into waterways. Accordingly, riparian zones are increasingly afforded protection and are targeted for restoration. Here we present results of a study in which we aimed to identify patterns of change in soil and vegetation properties in riparian zones, under different management regimes, adjacent to tributary streams in one of south‐eastern Australia's main agricultural regions. We compared riparia that were heavily impacted by agricultural activities, were in remnant condition or had undergone some restoration activities and were thus in a transitional state. There was an increase in plant cover and soil C concentration between impacted through to remnant sites, with transitional sites intermediate, suggesting that improvements in soil conditions were becoming evident following restoration activities. In our assessment of soil physicochemical properties we investigated the relationships between riparian condition and soil properties, taking into account the influence of adjacent land use on these relationships. Importantly, the concentrations of NO3 and plant available P in riparian surface soils were more or less influenced by concentrations in the adjacent land depending upon riparian condition. This will, in turn, have consequences for nutrient inputs into streams. This study emphasizes that riparian zones need to be managed within their wider landscape context. Furthermore, the results of this study will inform efforts seeking to minimize impacts of agricultural activities on waterways, through the conservation and/or restoration of riparian ecosystems.  相似文献   

12.
土壤微生物资源管理、应用技术与学科展望   总被引:4,自引:0,他引:4       下载免费PDF全文
林先贵  陈瑞蕊  胡君利 《生态学报》2010,30(24):7029-7037
土壤中蕴藏着高度的微生物多样性,在陆地生态系统中发挥着非常重要的功能,加强对土壤微生物资源的综合管理与开发应用是提升生态系统稳定性与生产力及农产品质量的重要途径。首先,土壤微生物多样性具有全球性的重大意义,有待完善对土壤微生物的检测与监测技术研究,进而实现土壤微生物多样性与土壤功能的耦合以及对土壤质量的评定;其次,土壤微生物作为一种宝贵的生产资料和可持续资源,要加强其在土壤肥力强化与保育、土壤障碍消减与调节、土壤污染控制与修复等3个领域的应用研究。最后,未来土壤微生物学发展将会形成土壤微生物系统学、土壤微生物过程学与土壤微生物功能学3个子学科,要建立土壤微生物种质资源库与遗传信息库,推进土壤微生物生理代谢过程、生物化学过程及生态行为过程的研究,联结土壤微生物与土壤功能的关系,并从土壤中的功能微生物出发对环境变化作出积极响应和主动调控。此外,原创性方法的建立与应用是限制土壤微生物学发展的技术瓶颈,联合生物地理学与生物信息学破译重要基因的特定生态功能,并将其应用到生态模型以及生态系统未知领域的研究中去,是土壤微生物学面临的挑战。  相似文献   

13.
以黄土高原9年生红富士果园生态系统为对象,研究不同地表覆盖模式(清耕、生草覆盖、地膜覆盖、秸秆覆盖和砂石覆盖)对果园土壤性状及果树生长和产量的影响.结果表明:生草覆盖土壤水分剖面分异最低,砂石覆盖土壤水分剖面分异最高;砂石覆盖提高了根层水分含量,有利于果树对水分的利用.不同地表覆盖模式土壤热量状况变化显著,处理间差异明显,极端最高温度下降,但地膜覆盖处理夏季地温超过果树根系生长的上限温度,对果树根系生长和生理功能发挥不利.除地膜覆盖外,其他地表覆盖模式均能提高土壤CO2释放速率,其中生草覆盖的效果最为显著.不同地表覆盖模式对果树枝条类型比例及产量影响较大,砂石覆盖处理的中短枝比例和果实产量最高;生草覆盖处理的果实产量最低.因子分析结果表明,对于黄土高原沟壑区盛果期果园,砂石覆盖处理是较为适宜的地表覆盖模式.  相似文献   

14.
The terms ''''soil health'''' or ''''soil quality'''' as applied to agroecosystems refer to the ability of soil to support and sustain crop growth while maintaining environmental quality. High-quality soils have the following characteristics: (i) a sufficient, but not excess, supply of nutrients; (ii) good structure (tilth); (iii) sufficient depth for rooting and drainage; (iv) good internal drainage; (v) low populations of plant disease and parasitic organisms; (vi) high populations of organisms that promote plant growth; (vii) low weed pressure; (viii) no chemicals that might harm the plant; (ix) resistance to being degraded; and (x) resilience following an episode of degradation. Management intended to improve soil health involves creatively combining a number of practices that enhance the soil''s biological, chemical, and physical suitability for crop production. The most important general strategy is to add plentiful quantities of organic matter—including crop and cover crop residues, manures, and composts. Other important strategies include better crop rotations, reducing tillage and keeping the soil surface covered with living and dead residue, reducing compaction by decreasing heavy equipment traffic, and using best nutrient management practices. Practices that enhance soil quality frequently reduce plant pest pressures.  相似文献   

15.
A study was made of the effect of soil and crop type on the soil and total ecosystem respiration rates in agricultural soils in southern Finland. The main interest was to compare the soil respiration rates in peat and two different mineral soils growing barley, grass and potato. Respiration measurements were conducted during the growing season with (1) a closed-dynamic ecosystem respiration chamber, in which combined plant and soil respiration was measured and (2) a closed-dynamic soil respiration chamber which measured only the soil and root-derived respiration. A semi-empirical model including separate functions for the soil and plant respiration components was used for the total ecosystem respiration (TER), and the resulting soil respiration parameters for different soil and crop types were compared. Both methods showed that the soil respiration in the peat soil was 2–3 times as high as that in the mineral soils, varying from 0.11 to 0.36 mg (CO2) m–2 s–1 in the peat soil and from 0.02 to 0.17 mg (CO2) m–2 s–1 in the mineral soils. The difference between the soil types was mainly attributed to the soil organic C content, which in the uppermost 20 cm of the peat soil was 24 kg m–2, being about 4 times as high as that in the mineral soils. Depending on the measurement method, the soil respiration in the sandy soil was slightly higher than or similar to that in the clay soil. In each soil type, the soil respiration was highest on the grass plots. Higher soil respiration parameter values (Rs0, describing the soil respiration at a soil temperature of 10°C, and obtained by modelling) were found on the barley than on the potato plots. The difference was explained by the different cultivation history of the plots, as the potato plots had lain fallow during the preceding summer. The total ecosystem respiration followed the seasonal evolution in the leaf area and measured photosynthetic flux rates. The 2–3-fold peat soil respiration term as compared to mineral soil indicates that the cultivated peat soil ecosystem is a strong net CO2 source.  相似文献   

16.
Soil Erosion Impact on Agronomic Productivity and Environment Quality   总被引:3,自引:0,他引:3  
R. Lal 《植物科学评论》1998,17(4):319-464
Soil erosion is a global issue because of its severe adverse economic and environmental impacts. Economic impacts on productivity may be due to direct effects on crops/plants on-site and off-site, and environmental consequences are primarily off-site due either to pollution of natural waters or adverse effects on air quality due to dust and emissions of radiatively active gases. Off-site economic effects of erosion are related to the damage to civil structure, siltation of water ways and reservoirs, and additional costs involved in water treatment. There are numerous reports regarding the on-site effects of erosion on productivity. However, a vast majority of these are from the U.S., Canada, Australia, and Europe, and only a few from soils of the tropics and subtropics. On-site effects of erosion on agronomic productivity are assessed with a wide range of methods, which can be broadly grouped into three categories: agronomic/soil quality evaluation, economic assessment, and knowledge surveys. Agronomic methods involve greenhouse and field experiments to assess erosion-induced changes in soil quality in relation to productivity. A widely used technique is to establish field plots on the same soil series but with different severity of past erosion. Different erosional phases must be located on the same landscape position. Impact of past erosion on productivity can also be assessed by relating plant growth to the depth of a root-restrictive horizon. Impact of current erosion rate on productivity can be assessed using field runoff plots or paired watersheds, and that of future erosion using topsoil removal and addition technique. Economic evaluation of the on-site impact involves assessment of the losses of plant available water and nutrients and other additional inputs needed due to erosion. Knowledge surveys are conducted as a qualitative substitute for locations where quantitative data are not available. Results obtained from these different techniques are not comparable, and there is a need to standardize the methods and develop scaling procedures to extrapolate the data from plot or soil level to regional and global scale. There is also a need to assess on-site impact of erosion in relation to soil loss tolerance, soil life, soil resilience or ease of restoration, and soil management options for sustainable use of soil and water resources. Restoration of degraded soils is a high global priority. If about 1.5×109?ha of soils in the world prone to erosion can be managed to effectively control soil erosion, it would improve air and water quality, sequester C in the pedosphere at the rate of about 1.5?Pg/year, and increase food production. The risks of global annual loss of food production due to accelerated erosion may be as high as 190×106?Mg of cereals, 6×106?Mg of soybeans, 3×106?Mg of pulses, and 73×106?Mg of roots and tubers. The actual loss may depend on weather conditions during the growing season, farming systems, soil management, and soil ameliorative input used. Erosion-caused losses of food production are most severe in Asia, Sub-Saharan Africa, and elsewhere in the tropics rather than in other regions.  相似文献   

17.
通过4个土壤深度100个样品14个波长(250、254、260、265、272、280、285、300、340、350、365、400、436和465 nm)土壤溶液吸光度值和土壤碳(可溶性碳DOC、全碳SOC)、土壤氮(可溶性氮DON、全氮SON)的测定,旨在探讨土壤溶液吸光度指示土壤碳氮指标的可行性及土壤深度对其可能影响。结论如下:(1)表层土壤和深层土壤吸光度值均随波长增加而指数下降,但表层土壤吸光度值较高,下降速度较快,较低波长更有利于区分表层和深层土壤溶液吸光度差异;和深层土壤相比,表层0~20 cm土壤SOC、DON和SON与不同波长吸光度有更好的相关性,但DOC与不同波长吸光度的相关性表层和深层差异较小;(2)250~300 nm的8个吸光度值具有高度相关性,它们在分析土壤溶液吸光度变化时具有等效性;基于所有数据的拟合分析发现,低波长(如254 nm)吸光度与土壤SOC、DON和SON相关性最高(R2=0.53~0.59),而更高波长(340 nm及以上)相关性明显降低。但DOC与254、340、365和400 nm吸光度相关性相差不大(R2=0.25~0.33)。这些发现说明,土壤溶液吸光度值,特别是低波长(250~300 nm)可以表征落叶松林土壤碳、氮相关指标的变化,但是需要考虑不同碳氮指标以及不同土层之间的差异。  相似文献   

18.
不饱和土壤CH4的吸收与氧化   总被引:12,自引:1,他引:11  
李俊  同小娟  于强 《生态学报》2005,25(1):141-147
不饱和土壤是已知唯一的 CH4 生物壑。综述了不饱和土壤 CH4 的吸收、氧化过程及其影响因素。不饱和土壤中 CH4 氧化的临界浓度低 ,因而甲烷氧化菌可氧化大气 CH4 并将其当作唯一的碳源和能源。土壤 CH4 吸收率与土壤湿度通常呈负相关关系。土壤湿度过高 ,大气 CH4 和 O2 向土壤中扩散受阻 ;或土壤湿度过低引起水分胁迫均导致甲烷氧化菌活性下降。NH 4对土壤中 CH4 氧化的抑制作用可归结为 NH3和 CH4 在甲烷单氧酶水平上的竞争、由氧化作用向硝化作用的转移以及 NH 4氧化生成的 NO- 2 的毒性。NH 4对 CH4 氧化的抑制作用与土壤有效氮含量成正比。各类氮肥对 CH4 氧化抑制作用 :化肥 >有机肥 ;铵态氮肥 >尿素。 NO- 3对 CH4 氧化没有抑制效应。阳离子代换量 (CEC)高的土壤 NH 4对 CH4 氧化的抑制作用轻。 CH4 氧化菌对大气 CH4 的高亲和力及 CH4 氧化所需较低的活化能导致其温度系数 Q1 0 较小。地温较低时 ,土壤氧化 CH4 的能力随温度升高而升高。当地温高于 CH4 氧化的最佳温度时 ,CH4 氧化菌难以与硝化细菌及其它微生物竞争利用土壤空气中的 O2 ,导致其活性降低。甲烷氧化菌对 p H值变化不敏感。团粒结构较好的壤土可保护 CH4 氧化菌免受干扰。未受干扰的森林土壤 CH4 氧化率的峰值一般出现在亚表  相似文献   

19.
刘爽  王雅  刘兵兵  刘海龙  刘勇 《生态学报》2019,39(12):4376-4389
晋西北丘陵区受干旱大风气候以及人为活动的影响,土壤肥力较低,土壤质量退化严重,不同的土地利用和管理方式,因植被覆被、人为活动等不同,对土壤质量产生影响不同。为了更好地了解晋西北地区不同土地管理方式对土壤质量的影响,于山西省北部忻州市五寨县,研究不同管理方式对土壤肥力、土壤酶活性、微生物群落结构及多样性的影响,以及微生物与土壤环境因子的关系,为晋西北地区土地管理和生态建设提供参考。研究中设置4种土地管理方式:苜蓿样地(MX)、免耕样地(MG)、翻耕样地(FG)和荒地(HD),采用野外采集土壤样品、室内测定和分析的研究方法,其中土壤pH值利用电位法测定,土壤有机碳(OC)采用重铬酸钾氧化-分光光度法测定;土壤硝态氮、铵态氮利用全自动间断化学分析仪测定,其原理为紫外分光光度和靛酚蓝比色法。土壤过氧化氢酶、蔗糖酶、脲酶和磷酸酶活性分别采用KMnO_4滴定法、3,5-二硝基水杨酸法、苯酚钠-次氯酸钠比色法、磷酸苯二钠比色法测定,采用高通量测序测定土壤细菌和真菌的群落组成,利用统计分析软件SPSS和Canoco以及QIIME、USEARCH和Uclust生物信息软件分析不同土地管理方式对土壤质量的影响。结果表明,不同土地管理方式对土壤化学性质、土壤酶活性、细菌和真菌的群落结构及多样性均有影响。苜蓿和免耕2种土地管理方式可显著提高表层土壤养分并增加土壤酶活性;4种土地管理方式共有9个细菌门和11个真菌门,细菌相对丰度较大的为变形菌门、放线菌门和酸杆菌门,真菌的子囊菌门相对丰度最大;苜蓿和免耕样地土壤细菌和真菌群落丰富度和多样性都较高,荒地土壤细菌和真菌群落丰富度较低,但多样性较高;RDA分析结果表明,土壤pH、NH~+_4-N和NO~-_3-N含量和过氧化氢酶活性对细菌群落影响较大,pH、有机碳含量、蔗糖酶、脲酶和过氧化氢酶活性对真菌群落影响最大。苜蓿和免耕2种土地管理方式能够提高土壤质量,是晋西北地区较为适宜的管理措施。  相似文献   

20.
渭北旱塬苹果园土壤紧实化现状及成因   总被引:3,自引:0,他引:3  
本研究通过分析渭北旱塬苹果园土壤的紧实化现状及其诱导因素,找出影响当地苹果园健康发展的土壤退化隐性因素,为果园科学管理提供理论依据。分别选取种植年限<10年(4~6年)、10~20年(14~16年)和>20年(24~26年)的苹果园各4个,分析0~60 cm土层土壤容重和紧实度随土层深度的变化规律,探明果园土壤内部紧实化发生的部位和退化程度,同时,通过分析土壤团聚体数量及其稳定性、土壤黏粒和有机质含量,揭示引起渭北果园土壤内部紧实化的原因。结果表明: 渭北果园0~60 cm土层土壤容重和紧实度均随植果年限和土层深度的增加而显著增大。以20 cm土层为界,渭北各园龄段苹果园土壤具有明显的“上松下实”变异特征,20 cm以上土层上述各指标基本满足苹果树的正常生长需求,20 cm以下土层土壤则已超出了苹果树健康生长的阈值。造成渭北苹果园亚表层以下土壤紧实化的原因主要是土壤团聚作用差、有机质含量低,加之植果期间人为扰动少,土壤中分散的黏粒会向下层移动。此外,随着植果年限的增加,土壤紧实化过程更加明显。  相似文献   

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