Effects of labile soil carbon on nutrient partitioning between an arctic graminoid and microbes

We measured partitioning of N and P uptake between soil microorganisms and potted Festuca vivipara in soil from a subarctic heath in response to factorial addition of three levels of labile carbon (glucose) combined with two levels of inorganic N and P. The glucose was added to either non-sterilized or sterilized (autoclaved) soils in quantities which were within the range of reported, naturally occurring amounts of C released periodically from the plant canopy. The aims were, firstly, to examine whether the glucose stimulated microbial nutrient uptake to the extent of reducing plant nutrient uptake. This is expected in nutrient-deficient soils if microbes and plants compete for the same nutrients. Secondly, we wanted to test our earlier␣interpretation that growth reduction observed in graminoids after addition of leaf extracts could be caused directly by labile carbon addition, rather than by phytotoxins in the extracts. Addition of high amounts of N did not affect the microbial N pool, whereas high amounts of added P significantly increased the microbial P pool, indicating a luxury P uptake in the microbes. Both plant N and in particular P uptake increased strongly in response to soil sterilization and to addition of extra N or P. The increased␣uptake led to enhanced plant growth when both elements were applied in high amounts, but only led to increased tissue concentrations without growth responses when the nutrients were added separately. Glucose had strong and contrasting effects on plant and microbial N and P uptake. Microbial N and P uptake increased, soil inorganic N and P concentrations were reduced and plant N and P uptake declined when glucose was added. The responses were dose-dependent within the range of 0–450 μg C g⁻¹ soil added to the non-sterilized soil. The opposite responses of plants and microbes showed that plant acquisition of limiting nutrients is dependent on release of nutrients from the soil microbes, which is under strong regulation by the availability and microbial uptake of labile C. Hence, we conclude, firstly, that the microbial populations can compete efficiently with plants for nutrients to an extent of affecting plant growth when the microbial access to labile carbon is high in nutrient deficient soils. We also conclude that reduced growth of plants after addition of leaf extracts to soil can be caused by carbon-induced shifts in nutrient partitioning between plants and microbes, and not necessarily by phytotoxins added with the extracts as suggested by some experiments. Received: 15 February 1997 / Accepted: 12 July 1997     

Microbial biomass C,N and P in two arctic soils and responses to addition of NPK fertilizer and sugar: implications for plant nutrient uptake

The soil microbial carbon (C), nitrogen (N) and phosphorus (P) pools were quantified in the organic horizon of soils from an arctic/alpine low-altitude heath and a high-altitude fellfield by the fumigation-extraction method before and after factorial addition of sugar, NPK fertilizer and benomyl, a fungicide. In unamended soil, microbial C, N and P made up 3.3–3.6%, 6.1–7.3% and 34.7% of the total soil C, N and P content, respectively. The inorganic extractable N pool was below 0.1% and the inorganic extractable P content slightly less than 1% of the total soil pool sizes. Benomyl addition in spring and summer did not affect microbial C or nutrient content analysed in the autumn. Sugar amendments increased microbial C by 15 and 37% in the two soils, respectively, but did not affect the microbial nutrient content, whereas inorganic N and P either declined significantly or tended to decline. The increased microbial C indicates that the microbial biomass also increased but without a proportional enhancement of N and P uptake. NPK addition did not affect the amount of microbial C but almost doubled the microbial N pool and more than doubled the P pool. A separate study has shown that CO₂ evolution increased by more than 50% after sugar amendment and by about 30% after NPK and NK additions to one of the soils. Hence, the microbial biomass did not increase in response to NPK addition, but the microbes immobilized large amounts of the added nutrients and, judging by the increased CO₂ evolution, their activity increased. We conclude: (1) that microbial biomass production in these soils is stimulated by labile carbon and that the microbial activity is stimulated by both labile C and by nutrients (N); (2) that the microbial biomass is a strong sink for nutrients and that the microbial community probably can withdraw substantial amounts of nutrients from the inorganic, plant-available pool, at least periodically; (3) that temporary declines in microbial populations are likely to release a flush of inorganic nutrients to the soil, particularly P of which the microbial biomass contained more than one third of the total soil pool; and (4) that the mobilization-immobilization cycles of nutrients coupled to the population dynamics of soil organisms can be a significant regulating factor for the nutrient supply to the primary producers, which are usually strongly nutrient-limited in arctic ecosystems.     

不同稻蟹生产模式对土壤活性有机碳和酶活性的影响

采取田间定位试验与室内分析相结合的方法,研究了有机稻蟹、常规稻蟹与单作水稻生产模式对土壤活性有机碳和酶活性的影响。结果表明,与单作水稻模式相比,有机稻蟹模式下的土壤总有机碳(TOC)、活性有机碳(LOC)、中活性有机碳(MLOC)、高活性有机碳(HLOC)含量及碳库管理指数(CMI)均显著或者极显著提高,且有机肥用量越大,效果越显著;有机稻蟹模式显著提高了土壤过氧化氢酶、脲酶、转化酶及碱性磷酸酶活性,与2009年相比,2010年中量有机肥稻蟹模式(M3)的LOC和MLOC含量增幅最高,分别达10.11%和5.14%;低量有机肥稻蟹模式(M4)的脲酶和碱性磷酸酶活性增幅最为明显,分别达80.25%和46.62%;常规稻蟹模式各指标的变化也有其类似的规律,但均明显低于有机稻蟹模式。相关分析表明,TOC、LOC、MLOC与4种土壤酶活性呈显著或者极显著正相关,相关系数最低为0.584*(P<0.05),最高可达0.940**(P<0.01)。因此,有机稻蟹生产模式不仅能显著提高土壤有机质的数量和质量,而且能增加土壤酶活性,提高土壤肥力。     

In situ mineralization of nitorgen and phosphorus of arctic soils after perturbations simulating climate change

Seasonal net nitrogen (N) and phosphorus (P) mineralization was investigated at Abisko, Swedish Lapland in soils of a subarctic heath and in soils of a colder (by about 4° C), high altitude fellfield by (a) using in situ soil incubation in soils which had been shaded or subjected to two levels of increased temperature, combined with (b) reciprocal transplantation of soils between the two sites. Proportionally large and significant net seasonal mineralization of N, in contrast to non-significant P mineralization, was found in untransplanted and transplanted fellfield soil. In contrast, P was mineralized in proportionally large amounts, in contrast to low N mineralization, in the transplanted and untransplanted heath soil. The differences indicate that P was strongly immobilized in relation to N at the fellfield and that N was more strongly immobilized than P in the heath soil. The immobilization in both soils remained high even after a temperature change of 4–5° C experienced by transplanted soils. Air temperature increases of up to 4–5° C in greenhouses resulted in a soil temperature increase of 1–2° C and did not cause any extra increase of net N and P mineralization. The results suggest that soil temperature increases of up to 2° C, which are likely to occur by the end of the next century as an effect of a predicted 4–5° C rise in air temperature, have only small effects on net mineralization in at least two characteristic tundra soils. These effects are probably smaller than the natural fluctuation of plant available nutrients from site to site, even within the same plant community. A further soil temperature increase of up to 4–5° C may enhance decomposition and gross mineralization, but the rate of net mineralization, and hence the change of nutrient availability to the plants, depends on the extent of microbial immobilization of the extra nutrients released.     

增氮对青藏高原东缘典型高寒草甸土壤有机碳组成的影响

土壤有机碳动态是陆地生态系统碳平衡研究的关键环节,有关青藏高原高寒草甸土壤有机碳组成对大气氮沉降增加的响应研究至今尚未开展。基于中国科学院海北生态站的大气氮沉降模拟控制实验平台,于2010年5月、7月和9月中旬分别测定不同施氮处理下0—10cm、10—20cm、20—30cm土壤中粗颗粒态有机碳(CPOC)、细颗粒态有机碳(FPOC)和矿质结合有机碳(MOC)含量,研究不同施氮类型(NH4Cl,(NH4)2SO4和KNO3)和施氮水平(0、10、20、40 kgN.hm-.2a-1)对土壤POC和MOC含量以及POC/MOC比值的影响。结果表明:青藏高原高寒草甸土壤POC积聚在土壤表层,占总土壤有机碳(SOC)含量的64%以上,稳定性较差。施氮水平显著改变了土壤CPOC、FPOC和MOC含量,而施氮类型的影响不显著。不同月份土壤POC和MOC含量对增氮的响应不同,反映了SOC组分对增氮响应的时间异质性。在生长季中期,施氮倾向于增加表层土壤POC含量,而在生长季初期和末期恰好相反。土壤MOC对增氮的响应不敏感。另外,施氮显著降低生长季初期表层土壤POC/MOC比例,SOC稳定性增加。表明,青藏高原高寒草甸土壤有机碳活性组分较高,未来大气氮沉降增加短期内即可降低活性有机碳含量,相应地改变了其组成和稳定性。     

南亚热带森林土壤碳库稳定性与碳库管理指数对模拟酸雨的响应

通过对土壤总有机碳(SOC)、易氧化有机碳(ROC_(333)、ROC_(167)、ROC_(33))、颗粒有机碳(POC)、微生物量碳(SMBC)、溶解性有机碳(DOC)的测定,探讨模拟酸雨(pH 3.0、pH 3.5、pH 4.0、对照CK)对鼎湖山三个不同演替阶段森林(季风常绿阔叶林、针阔混交林、马尾松针叶林)土壤碳库稳定性及碳库管理指数的影响。结果表明:模拟酸雨增加了总有机碳的含量和各组分活性有机碳的含量(P0.05),但酸雨在一定程度上抑制了土壤中微生物量与活性。土壤中各组分活性有机碳与总有机碳呈显著相关,其中ROC_(333)和POC的含量与SOC关系最为密切,相关系数分别为0.853、0.846;碳库管理指数(CMI)结果表明,碳库活度(L)及碳库活度指数(LI)随森林的正向演替有下降的趋势,CPI与CMI呈现相反的趋势。在土壤有机碳及部分活性碳组分增加,碳库活性降低的前提下,土壤碳库稳定性增加。从各项指标的变化幅度可以得出:南亚热带森林土壤随森林群落正向演替而对模拟酸雨响应有更加敏感的趋势,各指标间的敏感性表现为CMIR_(333)POCSMBCR_(167)R_(33)LIDOCCPISOC。     

人工油松林表层土壤团聚体活性有机碳含量对短期氮添加的响应

大气氮沉降正在显著影响着森林生态系统的土壤碳循环过程。目前关于大气氮沉降如何影响土壤不同粒级团聚体内活性有机碳含量还不是十分清楚,制约人们对森林土壤碳循环的认识和有关碳循环模型的发展。通过近2年的林地梯度氮添加(0、3、6、9 g Nm~(-2)a~(-1))实验,研究了短期氮添加对人工油松林表层土壤团聚体中不同活性有机碳含量的影响。结果表明:短期氮添加对表层土壤(0—10 cm)水稳性团聚体分布无显著影响;随着氮添加水平增加,大、微团聚体有机碳含量,大、微团聚体中活性和高活性有机碳含量呈先升高后降低的变化规律,并在N6处理(6 g Nm~(-2)a~(-1))下上述各指标达到最大;同一处理下土壤大、微团聚体活性有机碳含量都表现为高活性有机碳中活性有机碳低活性有机碳;相比CK处理,N6处理大团聚体低、中、高活性有机碳含量分别增加115.06%、178.73%和79.61%,微团聚体低、中、高活性有机碳含量增加32.84%、166.79%和62.05%。大、微团聚体中活性有机碳含量增幅最大,表明团聚体中活性有机碳对氮添加响应最为明显。研究发现,短期氮添加主要通过影响表层大、微团聚体中的中活性有机碳进而影响土壤表层有机碳含量。主成分分析表明,N添加改变了土壤理化性质,进而导致根系生物量增加并促进凋落物分解,是表层土壤团聚体活性有机碳变化的主要原因。     

马尾松(Pinus massoniana)人工林林窗对土壤不同形态活性有机碳的影响

研究了四川盆地低山丘陵区马尾松人工林不同大小林窗对表层土壤活性有机碳(水溶性有机碳、微生物量碳、易氧化碳)含量、分配比例及碳库管理指数的影响。结果表明:(1)林窗下土壤微生物量碳含量与分配比例较林下土壤有所升高,而水溶性有机碳与易氧化碳含量及水溶性有机碳分配比例有所降低。(2)林窗大小显著影响林窗中心土壤活性有机碳含量与分配比例。随林窗面积增大,水溶性有机碳、微生物量碳与易氧化碳含量呈现较为一致的升高趋势;水溶性有机碳和微生物量碳分配比例也升高,易氧化碳分配比例先下降后升高,稳定态碳先升高后降低;总体表现为较大林窗(900—1225m2)微生物活性强,活性有机碳含量高,且有机碳库稳定性较好。(3)土壤碳库管理指数随林窗面积增大无显著变化,但与各形态活性有机碳含量及总有机碳含量显著相关,说明土壤碳库管理指数能够相对全面地反映林窗大小对土壤碳库的影响。     

易分解有机碳输入量对武夷山不同林型土壤激发效应的影响

土壤有机碳库是陆地生态系统中最大的碳储量库,其微小的变化也能使大气中CO₂浓度发生巨大的改变,植物来源碳的输入能通过激发效应促进或抑制土壤有机碳(SOC)的分解,对SOC的动态平衡产生影响。以武夷山三个林型(阔叶林、马尾松林、针阔混交林)土壤为研究对象,通过向土壤中添加不同量的¹³C标记葡萄糖(0、100、200、400 mg C/kg)研究易分解有机碳输入量对不同林型土壤激发效应的影响,并在此基础上探讨易分解有机碳输入量对土壤激发效应影响的作用机理。结果表明,葡萄糖输入对土壤激发效应的影响与葡萄糖输入量和林型有关。葡萄糖的输入均抑制了三个林型SOC的分解(即,呈现负的激发效应)。阔叶林土壤和针阔混交林土壤激效应强度随着葡萄糖输入量的增加而增加,而马尾松林土壤的激发效应强度对葡萄糖输入量的响应并不明显。然而在马尾松林土壤中由葡萄糖所引起的激发效应强度显著高于其他两种林型土壤。研究结果表明,易分解有机碳的输入可以抑制SOC的矿化,形成负激发效应,阔叶林土壤的激发效应强度与土壤可利用氮、葡萄糖添加量与微生物碳量比值有关,而针阔混交林与马尾松林土壤...     

Microbial dynamics and carbon and nitrogen cycling following re-wetting of soils beneath two semi-arid plant species

Sporadic summer rainfall in semi-arid ecosystems can provide enough soil moisture to drastically increase CO₂ efflux and rates of soil N cycling. The magnitudes of C and N pulses are highly variable, however, and the factors regulating these pulses are poorly understood. We examined changes in soil respiration, bacterial, fungal and microfaunal populations, and gross rates of N mineralization, nitrification, and NH₄⁺ and NO₃^– immobilization during the 10 days following wetting of dry soils collected from stands of big sagebrush (Artemisia tridentata) and cheatgrass (Bromus tectorum) in central Utah. Soil CO₂ production increased more than tenfold during the 17 h immediately following wetting. The labile organic C pool released by wetting was almost completely respired within 2–3 days, and was nearly three times as large in sagebrush soil as in cheatgrass. In spite of larger labile C pools beneath sagebrush, microbial and microfaunal populations were nearly equal in the two soils. Bacterial and fungal growth coincided with depletion of labile C, and populations peaked in both soils 2 days after wetting. Protozoan populations, whose biomass was nearly 3,000-fold lower than bacteria and fungi, peaked after 2–4 days. Gross N mineralization and nitrification rates were both faster in cheatgrass soil than in sagebrush, and caused greater nitrate accumulation in cheatgrass soil. Grazing of bacteria and fungi by protozoans and nematodes could explain neither temporal trends in N mineralization rates nor differences between soil types. However, a mass balance model indicated that the initial N pulse was associated with degradation of microbial substrates that were rich in N (C:N <8.3), and that microbes had shifted to substrates with lower N contents (C:N =15–25) by day 7 of the incubation. The model also suggested that the labile organic matter in cheatgrass soil had a lower C:N ratio than in sagebrush, and this promoted faster N cycling rates and greater N availability. This study provides evidence that the high N availability often associated with wetting of cheatgrass soils is a result of cheatgrass supplying substrates to microbes that are of high decomposability and N content.     

米亚罗林区土地利用变化对土壤有机碳和微生物量碳的影响

为了解土地利用变化对土壤有机碳和微生物量碳的影响,分析了川西米亚罗林区原始冷杉林、20世纪60年代云杉人工林、20世纪80年代云杉人工林和农地的土壤有机碳和微生物量碳状况.结果表明,土地利用变化明显地影响了土壤有机碳和微生物量碳含量.土壤有机碳和微生物量碳含量原始林最高,其次为60年代人工林和80年代人工林,农地最低.农地土壤有机碳含量分别比原始林、60年代人工林和80年代人工林低83%、53%和52%,微生物量碳含量分别低23%、25%和21%.土壤有机碳和微生物量碳含量均随土壤深度的增加而降低,并且两者在不同土地利用类型的变化趋势基本一致.相关分析表明,土壤有机碳和土壤微生物量碳与全氮、水解氮、速效磷呈极显著相关(P＜0.01),说明土壤微生物量碳可作为衡量土壤有机碳变化的敏感指标,而土壤有机碳和微生物量碳含量可作为衡量土壤肥力和土壤质量变化的重要指标.     

垦殖对新疆绿洲农田土壤有机碳组分及团聚体稳定性的影响

土壤有机碳是土壤质量变化的重要指标,土壤活性有机碳组分在土壤质量变化方面发挥重要作用。采用有机碳分组技术,研究了干旱荒漠区自然土壤开垦对绿洲农田土壤有机碳活性组分及团聚体稳定性的影响。结果表明:低有机碳含量的自然土壤垦殖后,有利于干旱荒漠区绿洲棉田土壤有机碳的积累,且垦殖(0-5a)增加显著,年均增加在0.65gkg-1以上,上升幅度为76%-286%,5a后维持在相对平衡的水平;土壤活性有机碳、轻组有机碳在垦殖0-5a显著增加,平均增加72%和99%,5a后下降;颗粒有机碳则表现出垦殖0-10a明显增加,增加在275%以上,10a后下降;土壤水稳性团聚体含量随垦殖年限的延长显著增加,0-20a内较自然土壤提高了75%。垦殖可能是干旱区绿洲农田潜在碳汇的重要影响因素;但随垦殖年限延长,土壤有机碳活性组分下降,土壤质量又存在一定的退化风险。     

易分解有机碳对不同恢复年限森林土壤激发效应的影响

土壤有机碳库作为陆地生态系统最大的碳库,其微小的改变都将引起大气CO_2浓度的急剧改变。易分解有机碳的输入可以通过正/负激发效应加快/减缓土壤有机碳(SOC)的矿化,并最终影响土壤碳平衡。以长汀县不同恢复年限森林(裸地、5年、15年、30年马尾松林以及天然林)土壤为研究对象,通过室内培养向土壤中添加~(13)C标记葡萄糖研究易分解有机碳输入对不同恢复阶段森林土壤激发效应的影响。研究结果表明,易分解有机碳输入引起的土壤激发效应的方向和强度因不同恢复阶段而异。易分解有机碳输入的初期对各恢复阶段森林土壤均产生正的激发效应,然而随着时间的推移,15年、30年马尾松林以及天然林相继出现负的激发效应。从整个培养期(59 d)来看,易分解有机碳的输入促进了裸地与5年生马尾松林土壤有机碳的矿化,有机碳的矿化量分别提高了131%±27%与25%±5%;但是减缓了15年生马尾松林土壤有机碳的矿化,使其矿化量减少了10%±1%;然而,易分解有机碳输入对30年生马尾松林及天然林土壤有机碳的矿化则无明显影响。土壤累积激发碳量与葡萄糖添加前后土壤氮素的改变百分比呈显著正相关关系(R~2=0.44,P0.05),表明易分解有机碳输入诱导的土壤激发效应受土壤氮素可利用性的调控,土壤微生物需要通过分解原有土壤有机碳释放的氮素来满足自身的需求。     

滇南喀斯特断陷盆地土地利用方式对土壤有机碳及其活性组分的影响

土地利用方式是影响土壤有机碳库的重要因素,为探究喀斯特断陷盆地土壤有机碳库对土地利用方式及环境因素的响应,以滇南喀斯特地区5种典型土地利用方式(耕地、草地、灌丛、人工林、天然林)为研究对象,分析不同土地利用方式土壤有机碳(SOC)及活性有机碳(LOC)组分,即可溶性有机碳(DOC)、易氧化性有机碳(EOC)及微生物量碳(MBC)的含量、储量及分配比例在土壤垂直剖面(0-60 cm)的变化特征。结果表明：5种土地利用方式的SOC含量随土层深度的增加逐渐降低,其储量依次为灌丛(191.77 t/hm²)、草地(166.86 t/hm²)、耕地(142.47 t/hm²)、人工林(134.31 t/hm²)和天然林(102.62 t/hm²);EOC和MBC的平均含量及储量均以草地及灌丛最高、人工林及天然林次之,二者在土壤垂直剖面上与SOC含量的变化特征一致,但EOC和MBC含量在土层间的下降幅度大于SOC;土地利用方式和土层深度对DOC无显著影响(P>0.05);活性有机碳的分配比例受土地利用方式及土层深度的显著影响(P<0.01),其中人工林的EOC/SOC和MBC/SOC显著低于草地、灌丛及天然林。通径分析指出SOC和EOC主要受C/P比、全磷、砂粒和交换性钙的影响,砂粒和C/P比是影响MBC的主要因子。研究阐明在喀斯特断陷盆地地区EOC和MBC对土地利用方式的响应比SOC更敏感。另外,今后在土壤碳库的研究中应更多关注土壤磷和物理结构对其的影响。     

若尔盖沙化草地不同生态恢复模式土壤活性有机碳及碳库管理指数变化

研究退化林草地不同生态恢复模式土壤活性有机碳和碳库管理指数变化,可为评价生态恢复措施提升土壤质量的效果,以及优化生态恢复模式的选择提供重要参考。结合野外调查和室内分析法,研究了若尔盖沙化草地不同生态恢复模式土壤有机碳组分及碳库管理指数变化。若尔盖沙化草地的生态恢复模式有:灌草间作模式Ⅰ(条带状红柳间植草本植物,SGⅠ)、灌草间作模式Ⅱ(环状红柳间植草本植物,SGⅡ)、沙障+灌草模式(红柳沙障+红柳间植草本植物,SBSG)。结果表明,与沙化草地(DG)相比,3种恢复模式都能提高土壤有机碳及其活性组分含量。SGⅠ模式的全剖面土壤微生物量碳(MBC)、溶解性有机碳(DOC)、易氧化有机碳(EOC)、颗粒有机碳(POC)含量分别增加36.6%、139.0%、89.4%、130.9%;SGⅡ模式的分别增加2.7%、-43.9%、15.0%、49.7%;SBSG模式的分别增加82.4%、21.8%、56.2%、170.3%。表明SGⅠ与SBSG提高土壤有机碳的效应相近,而且二者都远大于SGⅡ。3种生态恢复模式土壤活性有机碳分配比例与DG的差异表现不一致,显著体现是SGⅠ模式土壤DOC分配比例的垂直变化出现分馏现象。3种生态恢复模式土壤碳库管理指数(CPMI)均大于100%,能不同程度地提升土壤质量,其效应大小为SGⅠSGⅡSBSG。易氧化有机碳可作为反映沙化草地生态修复模式土壤质量变化的优选指标,CPMI也可用于表征生态恢复措施提升沙化草地土壤质量的效果。     

Effects of climate change on labile and structural carbon in Douglas-fir needles as estimated by δ13C and Carea measurements

Models of photosynthesis, respiration, and export predict that foliar labile carbon (C) should increase with elevated CO₂ but decrease with elevated temperature. Sugars, starch, and protein can be compared between treatments, but these compounds make up only a fraction of the total labile pool. Moreover, it is difficult to assess the turnover of labile carbon between years for evergreen foliage. Here, we combined changes in foliar C_area (C concentration on an areal basis) as needles aged with changes in foliar isotopic composition (δ¹³C) caused by inputs of ¹³C‐depleted CO₂ to estimate labile and structural C in needles of different ages in a four‐year, closed‐chamber mesocosm experiment in which Douglas‐fir (Pseudotsuga menziesii (Mirb.) Franco) seedlings were exposed to elevated temperature (ambient + 3.5 °C) and CO₂ (ambient + 179 ppm). Declines in δ ¹³C of needle cohorts as they aged indicated incorporation of newly fixed labile or structural carbon. The δ ¹³C calculations showed that new C was 41 ± 2% and 28 ± 3% of total needle carbon in second‐ and third‐year needles, respectively, with higher proportions of new C in elevated than ambient CO₂ chambers (e.g. 42 ± 2% vs. 37 ± 6%, respectively, for second‐year needles). Relative to ambient CO₂, elevated CO₂ increased labile C in both first‐ and second‐year needles. Relative to ambient temperature, elevated temperature diminished labile C in second‐year needles but not in first‐year needles, perhaps because of differences in sink strength between the two needle age classes. We hypothesize that plant‐soil feedbacks on nitrogen supply contributed to higher photosynthetic rates under elevated temperatures that partly compensated for higher turnover rates of labile C. Strong positive correlations between labile C and sugar concentrations suggested that labile C was primarily determined by carbohydrates. Labile C was negatively correlated with concentrations of cellulose and protein. Elevated temperature increased foliar %C, possibly due to a shift of labile constituents from low %C carbohydrates to relatively high %C protein. Decreased sugar concentrations and increased nitrogen concentrations with elevated temperature were consistent with this explanation. Because foliar constituents that vary in isotopic signature also vary in concentrations with leaf age or environmental conditions, inferences of c_i/c_a values from δ ¹³C of bulk leaf tissue should be done cautiously. Tracing of ¹³C through foliar carbon pools may provide new insight into foliar C constituents and turnover.     

Potential impacts of climate warming on active soil organic carbon contents along natural altitudinal forest transect of Changbai Mountain

Understanding soil carbon fractions and their responses to the global warming is important for improving soil carbon management of natural altitudinal forest ecosystem. In this study, the contents of soil total organic carbon (SOC), soil labile organic carbon (LOC), and microbial biomass carbon (MBC) in soil upper layers (0–20 cm) were measured along a natural altitudinal transect in the north slope of Changbai Mountain. The results showed that under natural conditions the contents of SOC and LOC were largest in Betula ermanii forest (altitude 1996 m), moderate in spruce-fir forest (altitude 1350 m), and smallest in Korean pine mixed broad-leaf tree forest (altitude 740 m). MBC contents in different forest ecosystems decreased in the order of Betula ermanii forest, Korean pine mixed broad-leaf tree forest, and dark coniferous forest. In addition, the responses of SOC, LOC, and MBC to soil warming were conducted by relocating intact soil cores from high- to low-elevation forests for one year. As expected, the soil core relocation caused significant increase in soil temperature but made no significant effect on soil moisture. After one year incubation, soil relocation significantly decreased SOC contents, whereas the contents of LOC, MBC, and the ratios of LOC to SOC and MBC to SOC increased.     

植物过程对土壤有机碳含量的影响

从全球和生态系统角度,综述了植物过程对土壤有机碳含量的影响和可能的作用机理,揭示了植物过程对土壤有机碳的源和汇的影响及对土壤有机碳的动态影响,讨论了植物过程对土壤有机碳影响研究的任务和发展前景,及减少土壤表层向空气呼出CO₂的数量、维持现时的生态平衡的途径,指出了植物过程影响土壤有机碳的研究方向和有待解决的问题.增加植物生物量,可以增加土壤有机碳贮量.     

外源碳输入对中亚热带森林深层土壤碳矿化和微生物决策群落的影响

在陆地生态系统中,深层土壤是重要的有机碳库.外源碳输入可改变土壤有机碳(SOC)矿化速率(激发效应),进而影响土壤碳排放.然而深层土壤对外源碳输入的响应程度和方向如何还不清楚,引起激发效应的机理尚不明确.本文利用¹³C标记葡萄糖添加试验,分析亚热带森林不同层次SOC矿化的激发作用,并通过微生物决策群落(r-K策略者)的相对变化来探讨激发效应的机理.结果表明: 深层土壤矿化速率显著低于表层土壤,添加标记葡萄糖后能增加所有层次土壤原有SOC的矿化(正激发效应),但是深层土壤的激发效应强度(156%)显著高于表层土壤(45%).葡萄糖添加显著降低了各层次土壤微生物的最大比生长速率,表明r策略者相对比例下降而K策略者相对比例增加.推测SOC矿化的正激发效应主要由K策略者的相对比例变化引起.此外,葡萄糖添加后可溶性有机碳和可溶性氮的比值在深层土壤中(76.03)显著高于表层土壤(13.00),暗示深层土壤存在更为强烈的氮限制作用.深层土壤微生物为获取氮源,可能会加剧对原有SOC的矿化,进而产生更强烈的激发效应.深层土壤SOC矿化受碳源和氮源的限制,更容易受外源碳输入的影响,对未来气候变化也更敏感.     

长期不同施肥措施对双季稻田土壤活性有机碳组分和水解酶活性的影响

施肥是改善土壤质量、提高土壤肥力和影响土壤微生物多样性的关键措施.为了探明南方双季稻区长期不同施肥处理下稻田土壤活性有机碳组分和水解酶活性的变化特征,本研究以34年大田定位试验为平台,设置化肥(MF)、秸秆还田+化肥(RF)、30％有机肥+70％化肥(OM)3个处理,并以无肥处理为对照(CK),分析了长期不同施肥处理下...