Organic mound-building ants: their impact on soil properties in temperate and boreal forests

Ants are important components of most soil invertebrate communities, and can affect the flow of energy, nutrients and water through many terrestrial ecosystems. The vast majority of ant species build nests in the mineral soil, but a small group of ants in temperate and boreal forests of Eurasia and North America build large parts of their nests above‐ground using organic materials collected from the surrounding soil. Many studies have shown that ants nesting in mineral soil can affect water infiltration rates, soil organic matter (OM) content, and nutrient cycling, but much less is known on how mound‐building ants influence soil physical and chemical properties. In this paper we summarize what is known on the soil impacts of organic mound‐building ants in temperate and boreal forests, and how these ants could be affected by ecosystem disturbance and future climate change. Much of this information comes from studies on Formica rufa group ants in Europe, which showed that CO₂ emissions and concentrations of C, N, and P are usually higher in ant mounds than in the surrounding forest soil. However, ant mounds are a minor component of total soil C and nutrient pools, but they do increase spatial heterogeneity of soil water and available nutrients. Mound‐building ants can also impact tree growth, which could change the quantity and quality of OM added to soil. Forest management, fire, and projected climate change, especially in boreal forests, could affect mound‐building ant population dynamics, and indirectly, soil properties.     

蚂蚁筑巢对不同恢复阶段热带森林土壤易氧化有机碳时空动态的影响

为探明热带森林恢复过程中蚂蚁筑巢对土壤易氧化有机碳(readily oxidizable carbon, ROC)时空动态的影响及机制, 本研究以西双版纳白背桐(Mallotus paniculatus)群落、野芭蕉(Musa acuminata)群落和崖豆藤(Mellettia leptobotrya)群落3种恢复阶段热带森林为研究对象, 设置“蚂蚁筑巢地”与“非巢地”2种处理进行野外控制实验, 对比分析蚁巢和非蚁巢土壤ROC含量的时空变化特征, 并揭示这些变化与土壤微生物生物量碳及理化性质之间的相互关系。结果表明: (1)蚂蚁筑巢显著影响热带森林土壤ROC含量(P < 0.05), 蚁巢土壤ROC含量较非蚁巢提高了14.2%。不同恢复阶段蚁巢与非蚁巢土壤ROC含量大小顺序为: 野芭蕉群落 > 崖豆藤群落 > 白背桐群落。(2)不同恢复阶段热带森林蚁巢与非蚁巢土壤ROC含量均呈单峰型的时间变化趋势(P < 0.05), 最大值出现在6月, 且各月份蚁巢土壤ROC含量均高于非蚁巢。(3)不同恢复阶段热带森林蚁巢和非蚁巢土壤ROC含量均随土层深度增加呈显著递减的垂直变化趋势(P < 0.05), 且蚁巢土壤ROC含量均大于非蚁巢(P < 0.05)。(4)蚂蚁筑巢引起的土壤理化性质变化对土壤ROC含量产生了一定的影响。土壤ROC含量与土壤pH和容重呈显著负相关(P < 0.05), 与土壤有机碳、微生物生物量碳、全氮、铵态氮及硝态氮呈显著正相关(P < 0.05)。土壤微生物生物量碳与总有机碳是蚁巢土壤ROC时空变化的主要贡献者, 而铵态氮、全氮和总有机碳是非蚁巢ROC时空变化的主控因子。因此, 蚂蚁筑巢改变热带森林土壤微生物量(如微生物生物量碳)及土壤理化性质(如总有机碳、铵态氮与全氮等), 进而显著影响土壤ROC的时空动态。     

蚂蚁筑巢对西双版纳热带森林土壤有机氮矿化的影响

蚂蚁作为生态系统工程师能够调节土壤微生物及理化环境,进而对热带森林土壤有机氮矿化速率及其时间动态产生显著影响。以西双版纳白背桐热带森林群落为研究对象,采用室内需氧培养法测定土壤有机氮矿化速率,比较蚁巢和非蚁巢土壤有机氮矿化速率的时间动态,揭示蚂蚁筑巢活动引起土壤无机氮库、微生物生物量碳及化学性质改变对有机氮矿化速率时间动态的影响。结果表明：（1）蚂蚁筑巢显著影响土壤有机氮矿化速率（P<0.01）,相较于非蚁巢,蚁巢土壤有机氮矿化速率提高了261%;（2）土壤有机氮矿化速率随月份推移呈明显的单峰型变化趋势,即6月最大（蚁巢1.22 mg kg^-1 d^-1、非蚁巢0.41 mg kg^-1 d^-1）,12月最小（蚁巢0.82 mg kg^-1 d^-1、非蚁巢0.18 mg kg^-1 d^-1）;（3）两因素方差分析表明,不同月份及不同处理对土壤有机氮矿化速率、NH₄-N及NO₃-N产生显著影响（P<0.05）,但对NO₃-N的交互作用不显著;（4）蚂蚁筑巢显著提高了无机氮库（NH₄-N与NO₃-N）、微生物生物量碳、有机质、水解氮、全氮及易氧化有机碳等土壤养分含量,而降低了土壤pH值;（5）回归分析表明,铵态氮和硝态氮对土壤有机氮矿化速率产生显著影响,分别解释87.89%、61.84%的有机氮矿化速率变化;（6）主成份分析表明NH₄-N、微生物生物量碳及有机质是影响有机氮矿化速率时间动态的主要因素,而全氮、NO₃-N、易氧化有机碳、水解氮及pH对土壤有机氮矿化速率的影响次之,且pH与土壤有机氮矿化速率呈显著负相关。总之,蚂蚁筑巢活动主要通过影响土壤NH₄-N、微生物生物量碳及有机质的状况,进而调控西双版纳热带森林土壤有机氮矿化速率的时间动态。研究结果将有助于进一步提高对土壤氮矿化生物调控机制的认识。     

蚂蚁筑巢对西双版纳热带森林土壤易氧化有机碳时空动态的影响

蚂蚁筑巢定居能够形成与巢穴周围显著不同的微生境和土壤养分环境,从而对土壤易氧化有机碳(EOC)产生重要影响.本研究以中国科学院西双版纳勐仑热带植物园白背桐群落为研究对象,比较蚂蚁巢地与非巢地土壤EOC时空分布特征,并分析蚂蚁筑巢引起土壤理化性质的改变对土壤EOC时空动态的影响.结果表明: 研究区蚁巢和非蚁巢地土壤EOC随月份均呈明显的单峰型变化规律,表现为6月>9月>3月>12月;土壤EOC沿土层呈逐渐降低的变化趋势,在0～5 cm土层,蚁巢土壤EOC显著大于非巢地,在5～10和10～15 cm土层的差异不显著.蚂蚁筑巢显著提高了土壤温度、土壤有机碳、土壤易氧化有机碳、土壤微生物生物量碳、全氮、硝态氮和水解氮含量,显著降低了土壤含水率和容重,但对铵态氮、pH值的影响不显著.土壤有机碳、土壤微生物生物量碳是调控蚁巢和非巢地土壤EOC时空变化的主要因子,土壤温度、含水率、全氮和硝态氮等土壤指标对土壤EOC的影响次之.蚂蚁筑巢主要通过改变微生境(土壤温度和水分)及土壤养分(主要是土壤有机碳和微生物生物量碳)的状况,进而调控热带森林土壤易氧化有机碳的时空动态.     

Harvester ant nests, soil biota and soil chemistry

Many ant species accumulate organic debris in the vicinity of their nests. These organic materials should provide a rich resource base for the soil biota. We examined the effect of harvester ant nests (Pogonomyrmex barbatus) on the soil community and soil chemistry. Ant nest soils supported 30-fold higher densities of microarthropods and 5-fold higher densities of protozoa than surrounding, control soils. The relative abundances of the major groups of protozoa differed as well: amoebae and ciliates were relatively overrepresented, and flagellates underrepresented, in ant nest versus control soils. Densities of bacteria and fungi were similar in the two soil types. Concentrations of nitrate, ammonium, phosphorus, and potassium were significantly higher in ant nest soils, while concentrations of magnesium, calcium, and water were similar in nest and control soils. Ant nest soils were marginally more acidic than controls. The results demonstrate that P. barbatus nests constitute a significant source of spatial heterogeneity in soil biota and soil chemistry in arid grasslands. Received: 17 March 1997 / Accepted: 10 June 1997     

Ant-nest soil and seedling growth in a neotropical ant-dispersed herb

Summary A major hypothesis concerning the benefits of myrmecochory, seed dispersal by ants, to plants is that ant nests are nutrient-enriched microsites that are beneficial to seedling growth. We experimentally test this hypothesis for a neotropical myrmecochore, Calathea ovandensis, asking two questions: 1) is soil of nests of a seed-dispersing ant chemically or structurally distinct from surrounding soils, and 2) do seedlings grow better in soil collected from ant nests than in randomly collected soil? We found that although ant-nest soil was significantly enriched in nitrate-nitrogen, magnesium, iron, manganese, cadmium and percent organic matter compared to randomly collected soil, seedling growth was not significantly improved by ant-nest soil.     

Correlation of abundance of arbuscular mycorrhizal fungi, bacteria and saprophytic microfungi with soil carbon, nitrogen and phsophorus

A significant positive correlation between the concentration of CFU of soil saprophytic microfungi and total soil carbon content, organic matter (oxidizable carbon) and available phosphorus was observed in field collected soil samples. Concentration of CFU of culturable bacteria correlated negatively with soil organic matter. Specific length of hyphae of arbuscular mycorrhizal fungi in the soil correlated only with soil respiration rate. The results indicate that arbuscular mycorrhizal fungi are associated with soil microsites rich in some easily mineralizable fraction of soil, organic matter rather than with total or oxidizable organic carbon.     

佛山地区存留自然林和存留人工林的土壤无机磷组分

为探讨热带亚热带森林,尤其城市及其周边地区残存森林土壤磷的有效性,对佛山地区14个残存林(7个自然林和7个人工林)的0~3 cm和3~23 cm矿质土壤的P有效性进行研究。结果表明,铁结合态无机P和还原剂可溶解无机P是土壤无机P的主要组分。在0~3 cm矿质层中,自然林土壤铝结合态无机P、Bray 1提取无机P和总无机P含量显著高于人工林;而在3~23 cm矿质土层中,自然林土壤钙结合态无机P含量显著高于人工林。其它土壤营养指标在自然林和人工林间差异不显著。相关分析结果表明,土壤有机质含量与钙结合态无机P除外的其它无机P组分含量均成显著正相关。聚类分析结果表明14个残存林土壤P有效性可分成3组,整体上人工林土壤P有效性比自然林低。这有助于认识城市化影响下城市及其周边地区残存森林土壤营养状况及加强养分管理。     

Respiration of wood ant nest material affected by material and forest stand characteristics

We studied differences in respiration of materials from different parts of wood ant nest (top, bottom, and rim) and from the nest surroundings (humus layer and mineral soil). Samples were taken from 8 wood ant (Formica aquilonia) nests in each of the two types of forest (birch and pine) in eastern Finland. The differences were related to material and forest stand characteristics (i.e., moisture, pH, carbon content, and C:N ratio). As a result, the highest respiration per g DW was measured at the top of ant nests in the birch forest. However, respiration did not significantly differ between the parts of ant nests in the pine forest. Respiration of the humus layers in both forest stands was on average higher, whereas respiration of the mineral soils in both forest stands was lower in comparison with respiration of the nest materials. The respiration per g C did not show any significant differences between different parts of nests and surrounding soil. The most important factors influencing respiration of the materials appeared to be moisture, carbon content, and pH. In conclusion, respiration of wood ant nest material is affected by the specific material and forest stand characteristics.     

蚂蚁筑巢对西双版纳热带森林土壤碳矿化动态的影响

蚂蚁作为生态系统工程师,能够通过筑巢定居活动增加有机物的输入、改变理化环境及刺激微生物活动,进而影响土壤有机碳矿化动态.本研究以西双版纳高檐蒲桃热带森林群落为研究对象,比较了蚁巢地与非巢地土壤有机碳矿化速率的动态特征,分析蚂蚁筑巢引起的土壤理化性质改变对土壤碳矿化速率的影响.结果表明: 蚂蚁筑巢显著影响土壤有机碳的矿化,相较于非巢地,蚁巢地平均土壤有机碳矿化速率提高19.2%;巢地与非巢地土壤有机碳矿化速率均表现为6月>9月>3月>12月;蚁巢地土壤有机碳矿化速率最大值出现在10～15 cm土层,而非巢地土壤有机碳矿化速率0～5 cm土层最高;蚂蚁筑巢对土壤理化性质产生了显著影响,相较于非蚁巢地,蚁巢地土壤温度、水分、有机碳、微生物生物量碳、全氮、水解氮、硝态氮和铵态氮平均增加幅度分别为7.6%、5.4%、9.9%、14.8%、13.4%、9.9%、24.1%、6.6%和19.4%,而土壤容重和pH平均降幅分别为1.4%和2.5%.相关性分析及主成分分析表明,土壤有机碳和土壤微生物量碳是影响土壤有机碳矿化速率的主控因子,土壤全氮、水解氮、铵态氮、硝态氮、温度和土壤含水率对土壤有机碳矿化的贡献次之.蚂蚁筑巢主要显著改变有机碳矿化的底物组分(土壤有机碳和土壤微生物生物量碳),进而调控西双版纳热带森林土壤有机碳矿化速率的时空动态.     

蚂蚁筑巢对西双版纳热带森林土壤微生物生物量碳及熵的影响

蚂蚁筑巢能够改变热带森林土壤理化环境,从而对土壤微生物生物量碳及熵的时空动态产生重要影响.本研究以西双版纳高檐蒲桃热带森林群落为对象,采用氯仿熏蒸法对蚂蚁巢地和非巢地土壤微生物生物量碳及熵时空动态进行测定.结果表明: 1)蚁巢地平均微生物生物量碳及熵(1.95 g·kg^-1,6.8%)显著高于非巢穴(1.76 g·kg^-1,5.1%);蚁巢地和非蚁巢地土壤微生物生物量碳呈单峰型时间变化趋势,而土壤微生物熵呈“V”型变化格局.2)蚁巢地和非巢地土壤微生物生物量碳及熵均具有明显的垂直变化:微生物生物量碳随土层加深显著降低,微生物熵则沿土层加深显著升高,但蚁巢微生物生物量碳及熵的垂直变化较非巢穴显著. 3)蚂蚁筑巢引起了巢内水分和温度的显著改变,进而影响土壤微生物生物量碳及熵的时空动态.土壤水分分别解释微生物生物量碳及熵的66%～83%和54%～69%,而土壤温度分别解释土壤微生物生物量碳及熵的71%～86%和67%～76%. 4)蚂蚁筑巢引起土壤理化性质变化对土壤微生物生物量碳和熵产生重要影响.蚁巢土壤微生物生物量碳与土壤有机碳、温度、全氮、含水率呈极显著正相关,与容重、硝态氮,水解氮呈显著正相关,与土壤pH呈极显著负相关;除土壤微生物熵与pH呈显著正相关外,与其他土壤理化指标均呈显著负相关.土壤总有机碳、全氮和温度对微生物生物量碳的贡献最大,而土壤总有机碳和全氮对微生物熵的负作用最小.因此,蚂蚁筑巢能够显著改变微生境(如土壤水分与温度)及土壤理化性质(如总有机碳及全氮),进而调控热带森林土壤微生物生物量碳及熵的时空动态.     

Organic phosphorus in soil water under a European beech (Fagus sylvatica L.) stand in northeastern Bavaria, Germany: seasonal variability and changes with soil depth

Organically bound phosphorus (P) is a mobile form of phosphorus in many soils and thus its dynamics relevant for the leaching and cycling of this element. Despite its importance, little is known about the chemical composition of dissolved organic P. We studied the concentrations, fluxes, and chemical composition of organic P in forest floor leachates and soil solutions in a Rendzic Leptosol under a 90-year-old European beech (Fagus sylvatica L.) forest over a 27-month period (1997–1999). The chemical composition of organic P was analysed using XAD-8 fractionation and ³¹P-nuclear magnetic resonance (NMR) spectroscopy. Organic P was the dominant P form in forest floor leachates as well as in porewaters of the mineral soil. The largest concentrations of organic P were observed during summer and peaked (330–400 g dissolved organic P l^–1) after rain storms following short dry periods, concurrently with the concentrations of organic carbon (OC). Because of high rainfall, fluxes of organic P (and C) were greatest in autumn although concentrations of organic C and P were lower than in summer. In forest floor leachates, the hydrophilic fraction of dissolved organic matter contained 83 ± 13% of the bulk organic P. In soil solutions from 90 cm depth, organic P was almost exclusively in the hydrophilic fraction. Because of the low retention of the hydrophilic fraction of dissolved organic matter in the mineral soils, concentrations of organic P in soil water remained almost constant with depth. Consequently, organic P contributed > 95% of the total P leached into deeper subsoils. The overall retention of organic P in the weakly developed mineral soils was little and so the average annual fluxes of organic P in subsoils at 90 cm depth (38 mg m^–2) comprised 67% of those from the forest floors (57 mg m^–2) during the study period. Hence, organic P proved to be mobile in the studied soil. ³¹P-NMR spectroscopy confirmed the dominance of organic P species in soil water. Signals due to inorganic P occurred only in spectra of samples collected in winter and spring months. Spectra of samples from summer and autumn revealed traces of condensed phosphates. Due to low P contents, identification of organic P species in samples from winter and spring was not always possible. In summer and autumn, monoester and diester phosphates were the dominant organic species and varied little in their relative distributions. The distribution of organic species changed little from forest floor leachates to the subsoil solutions indicating that the composition of P-containing compounds was not influenced by sorptive interactions or biological transformation.     

腾格里沙漠人工植被区掘穴蚁(Formica cunicularia)的生态功能

掘穴蚁（Formica cunieularia）营筑丘活动,并通过营巢活动影响土壤的物理化学特性,是中国干旱和半干旱地区营巢的优势蚁类。在沙坡头人工固沙植被区调查了掘穴蚁对不同固沙年代和不同地形人工固沙区土壤的影响;研究了掘穴蚁的营巢活动对土壤水分、理化性质和种子库的影响。 研究结果表明：随着固沙年代的延长,掘穴蚁的筑丘活动加强;掘穴蚁筑丘活动对地形的选择顺序依次分别为：丘间低地〉迎风坡〉丘顶〉背风坡;与邻近土壤相比,蚁丘的土壤含水量升高,土壤容重（0～10cm深）、有机质、电导率、全氮、全磷、全钾、可溶性氮、可溶性磷和可溶性钾在蚁丘富集;土壤容重（10～20cm深）和pH值下降;蚁丘对土壤种子库有明显影响（p〈0．01）,种子密度和多样性指数在不同取样点间的大小顺序为：苔藓结皮上的蚁丘〉苔藓结皮〉地衣结皮上的蚁丘〉地衣结皮。 在沙坡头人工固沙植被区,由于生态环境的改善,特别是土壤环境的提高,导致掘穴蚁大量定居,它的筑巢对土壤具有反馈作用,这种反馈作用导致土壤异质性增强,改善了土壤环境的状况,加速了土壤和植被的演变。     

降水变率对森林土壤有机碳组分与分布格局的影响

2006年12月-2008年6月,通过加倍降水、自然降水和去除降水3种处理的人工控制试验,研究了降水变率改变对南亚热带不同演替阶段的季风常绿阔叶林、针阔叶混交林和马尾松针叶林土壤有机碳组分与空间分布格局的影响.结果表明：在3种降水强度条件下,相同森林类型的同一层次土壤总有机碳（TOC）含量差异不显著（P>0.05）;去除降水处理下土壤表层（0～10 cm）颗粒有机碳（POC）和轻组有机碳(LFOC)含量有明显的积累趋势,加倍降水和自然降水处理下增加了POC、LFOC向下层土壤（10～20 cm、20～30 cm、30～50 cm）的运输;去除降水处理下,马尾松林土壤易氧化有机碳（ROC）含量显著高于降水处理（P<0.05）;演替早期森林土壤的POC、ROC、LFOC占总有机碳的比例大于演替后期土壤,不利于土壤有机碳的存埋.森林土壤总有机碳含量变化缓慢,而其活性有机碳组分（POC、LFOC、ROC）对降水变率改变的响应更敏感.     

Dissolved organic sulphur in soil water under <Emphasis Type="Italic">Pinus sylvestris</Emphasis> L. and <Emphasis Type="Italic">Fagus sylvatica</Emphasis> L. stands in northeastern Bavaria,Germany variations with seasons and soil depth

Organically bound species have been identified as prominent and mobile forms of nitrogen and phosphorus in soils. Since a large portion of sulphur (S) in soil is bonded to carbon (C) also dissolved organic S likely is a significant constituent in soil water. To investigate the role of dissolved organic forms in leaching and cycling of S in forest soils, we examined concentrations, fluxes, and chemical composition of organic S in forest floor leachates and in soil solutions of Rendzic Leptosols under 90-year-old European beech (Fagus sylvatica L.) and Haplic Arenosols under 160-year-old Scots pine (Pinus sylvestris L.) for 27 months. These soils are low in adsorbed SO₄^2- and receive little atmospheric S depositions at present. The chemical composition of organic S was estimated by fractionation with XAD-8 and wet-chemical characterisation (HI reduction) of binding forms. Although not as prominent as the organic forms of other nutrient elements, organic S proved to be an important contributor to S dissolved in forest floor leachates and in mineral soil solutions. Dissolved organic matter contained on average 29% of total S in forest floor leachates at the pine site and 34% at the beech site. The largest portion of organic S occurred in the subsoil solutions under beech in summer and autumn (up to 53%). Mean concentrations of organic S peaked (up to 1.1 mg l^-1) in summer after rainstorms that followed dry periods. Fluxes with forest floor leachates and at 90 cm soil depth were largest in autumn because of huge amounts of rainfall. Organic S contributed significantly to the fluxes of S in the subsoils under beech comprising on average 39% of total dissolved S at 90 cm depth. Organic S produced in the forest floor layers was mainly in the hydrophilic fraction of dissolved organic matter (62 ± 6% at the pine site, 85 ± 4% at the beech site). The major binding form of organic S in the hydrophobic fraction was C-bonded S while in the hydrophilic fraction ester sulphate S, possibly associated with carbohydrates, was more prominent. Since the hydrophobic fraction increased in summer and autumn, C-bonded S was of greater importance during that time of the year than in winter and spring. With depth, concentrations and composition of organic S (and also of C) hardly changed at the pine site because of little retention of dissolved organic matter, presumably because of the small sorption capability of that soil. At the beech where organic C showed a marked decrease with depth, only a slight decrease in organic S, exclusively from the hydrophobic fraction, was found indicating that organic S was mobile compared with organic C. This was probably due to the concentration of S in the hydrophilic fraction of dissolved organic matter. Because of being concentrated in the mobile hydrophilic fraction, ester sulphate S was more mobile in the soil under beech than C-bonded S.     

Vegetation-soil relations in the lowlands of south-west Tasmania

A geographic survey of 14 south-west Tasmanian sedgeland-heaths revealed that soil organic matter is related to: water content: total nitrogen (N): total and exchangeable sodium (Na), calcium (Ca) and magnesium (Mg); exchangeable potassium (K) cation exchange capacity; and total exchangeable bases. However, total and available phosphorus (P), total K and Iron (Fe). pH level and percentage base saturation were found to be Independent of organic content. Most of the soil nutrient capital is contained In the A₀ horizon, the depth of which was found to be positively related to the time elapsed since the last fire. There is no clear relationship between rock type and soil fertility, but there is evidence of soil-vegetation interaction. The sedgeland-heath species have lower concentrations of P, Ca and Mg in their foliage and are more efficient In the withdrawal of P and K upon tissue senescence than the surrounding scrub and forest species. Over a vegetation transition from sedgeland-heath to forest on uniform geology there was a change in soil type. The forest was found to have more fertile soils and a higher concentration of nutrients in the above-ground biomass than the adjacent sedgeland-heath. The ecotone was burnt between 20–30 years prior to sampling, but the fire did not kill all the forest trees, and the structural differences suggest a mare rapid recovery of forest species. Soil fertility appears to be an important factor in controlling the rate of recovery and succession following a fire, especially if the nutrient-rich organic layer is burnt.     

Diel pattern driven by free convection controls leaf-cutter ant nest ventilation and greenhouse gas emissions in a Neotropical rain forest

Leaf-cutter ant nests are biogeochemical hot spots where ants live and import vegetation to grow fungus. Metabolic activity and (in wet tropical forests) soil gas flux to the nest may result in high nest CO2 concentrations if not adequately ventilated. Wind-driven ventilation mitigates high CO2 concentrations in grasslands, but little is known about exchange for forest species faced with prolonged windless conditions. We studied Atta cephalotes nests located under dense canopy (leaf area index > 5) in a wet tropical rainforest in Costa Rica, where wind events are infrequent. We instrumented nests with thermocouples and flow-through CO2 sensing chambers. The results showed that CO2 concentrations exiting leaf-cutter ant nests follow a diel pattern with higher values at night. We developed an efflux model based on pressure differences that evaluated the observed CO2 diel pattern in terms of ventilation by (1) free convection (warm, less dense air rises out the nest more prominently at night) and (2) episodic wind-forced convection events providing occasional supplemental ventilation during daytime. Average greenhouse gas emissions were estimated through nest vents at about 78 kg CO2eq nest−1 year−1. At the ecosystem level, leaf-cutter ant nest vents accounted for 0.2% to 1% of total rainforest soil emissions. In wet, clayey tropical soils, leaf-cutter ant nests act as free convection-driven conduits for exporting CO2 and other greenhouse gases produced within the nest (fungus and ant respiration, refuse decay), and by roots and soil microbes surrounding the nest. This allows A. cephalotes nests to be ventilated without reliable wind conditions.     

不同密度樟子松人工林土壤碳氮磷化学计量特征

以科尔沁沙地不同密度(490、750、1550、1930、2560株·hm-2)樟子松人工林(栽植于1980年)为研究对象,分析林分密度对土壤碳、氮、磷浓度及其计量比的影响,研究林分密度与土壤养分状况的关系。结果表明:随着樟子松林密度增加,各土层(0～10、10～20和20～40 cm)土壤有机碳、全氮、全磷浓度和C∶N呈先增加后降低趋势,而土壤有效磷浓度呈先降低后增加趋势。土壤有机碳浓度在490株·hm-2密度小于其他密度,而有效磷浓度大于其他密度;土壤C∶P和N∶P在2560株·hm-2密度显著大于其他密度。各密度樟子松林土壤有机碳、全氮、全磷和有效磷浓度在0～10 cm土层显著大于10～20和20～40cm土层,樟子松人工林土壤养分具有表聚性。通过典范对应分析发现,密度对樟子松林土壤养分影响的主要因子是土壤有机碳、全氮和全磷,且密度为1550株·hm-2时土壤有机碳、全氮、全磷和碱解氮浓度较高,而C∶P和N∶P较低。因此,当樟子松人工林密度为1550株·hm-2时,土壤养分浓度较高,林木生长较好,为最佳经营密度。     

Effects of afforestation on phosphorus dynamics and biological properties in a New Zealand grassland soil

Selected chemical, biochemical and biological properties of mineral soil (0–30 cm) were measured under a 19 year old forest stand (mixture of Pinus ponderosa and Pinus nigra) and adjacent unimproved grassland at a site in South Island, New Zealand. The effects of afforestation on soil properties were confined to the 0–10 cm layer, which reflected the distribution of fine roots (< 2 mm) in the soil profile. Concentrations of organic C, total N and P and all organic forms of P were lower under the forest stand, while concentrations of inorganic P were higher under forest compared with grassland, supporting the previously described suggestion that afforestation may promote mineralisation of soil organic matter and organic P. On the other hand, microbial biomass C and P, soil respiration and phosphatase enzyme activity were currently all lower and the metabolic quotient was higher in soil under forest compared with grassland, which is inconsistent with increased mineralisation in the forest soil. Reduced biological fertility by afforestation may be mainly attributed to changes in the quantity, quality and distribution of organic matter, and reduction in pH of the forest soil compared with the grassland soil. We hypothesize that the lower levels of C, N and organic P found in soil under forest are due to enhanced microbial and phosphatase activity during the earlier stages of forest development. Forest floor material (L and F layer) contained large amounts of C, N and P, together with high levels of microbial and phosphatase enzyme activity. Thus, the forest floor may be an important source of nutrients for plant growth and balance the apparent reduction in C, N and P in mineral soil through mineralisation and plant uptake. This revised version was published online in June 2006 with corrections to the Cover Date.     

Utilization of harvester ant nest sites by Persian goitered gazelle in steppes of central Iran

Ants are among the most important elements in many ecosystems and known as famous ecosystem engineers. By changing physical and chemical properties of soil, ants may provide suitable habitats for other species. Based on previous observations, we hypothesized that Persian goitered gazelles (Gazella subgutturosa subgutturosa) exhibit a preference for utilizing sites close to seed harvester ant (Messor spp.) nests. We tested our hypothesis by (1) mapping the occurrence of harvester ant nests and aggregated gazelle pellet groups along 31 strip transects, (2) monitoring pellet group accumulation bimonthly at 56 pairs of permanent plots established on ant nests and at adjacent control sites for a complete year, and (3) comparing vegetation and soil parameters between ant nest sites used by gazelles and paired control plots without ant nests. Although the area of Messor spp. nest sites covered only about 0.29% of the sampled transects, 84% of the gazelle pellet group aggregation sites were positioned upon ant nests, suggesting that gazelles actively selected Messor spp. nest sites. Pair-wise comparisons between ant nest plots and paired control plots also confirmed higher use of ant nest sites by gazelles compared to sites without ant nests in all time periods. Percent soil organic matter, percent cover of gravel, and annual herb vegetation significantly differed between ant nest and paired control plots in all the vegetation communities. We suggest that the alterations brought about by harvester ants on soil and vegetation make these sites attractive to gazelles. Gazelle territoriality behaviour and use of ant nests as bedding sites may be the reasons for selection of ant nest sites by gazelles.