中亚热带不同母质和森林类型土壤生态酶化学计量特征

土壤生态酶化学计量比作为衡量土壤微生物能量和养分资源限制状况的重要指标,是当前生态学领域研究的热点之一,然而关于土壤母质和森林类型在调控土壤生态酶化学计量比中所扮演的角色及作用机制尚不明确。分别以砂岩和花岗岩发育的米槠林和杉木林土壤为研究对象,通过测定土壤物理化学性质、微生物量碳、氮和磷及土壤酶活性,探讨不同母岩发育的米槠林和杉木林土壤生态酶化学计量特征。结果显示,花岗岩发育的土壤酸性磷酸酶活性(AP)显著高于砂岩发育的土壤,βG:AP和NAG:AP的值显著低于砂岩发育的土壤。其中,花岗岩发育的米槠林土壤βG:AP和NAG:AP的值都显著高于杉木林,砂岩发育的土壤βG:AP和NAG:AP的值在两个林分间呈相反的结果。结果表明土壤生态酶化学计量比能够反映不同森林土壤之间磷养分限制强度,花岗岩比砂岩土壤受磷养分限制更严重。相关分析表明,土壤酶活性及生态酶化学计量比与土壤生物因子和非生物因子密切相关,而冗余分析发现土壤pH、总磷(TP)和微生物量碳(MBC)分别解释土壤酶活性和生态酶化学计量比变异的56.9%、27.9%和12.3%。未来森林经营及管理应考虑土壤母质和森林类型差异对区域森林土壤养分循环的影响。     

中亚热带森林转换对土壤磷积累的影响

磷是植物生长的必需元素之一,是维持亚热带森林生态系统生产力的关键因子。研究森林转换后土壤因素对磷素的影响,对生态系统的稳定和森林经营具有重要意义。选取由亚热带常绿阔叶林转换而成的米槠次生林(SF)、米槠人促林(AR)和杉木人工林(CF)为研究对象,测定了土壤理化性质、铁铝氧化物、各形态磷含量以及酸性磷酸酶活性,旨在探究土壤磷对森林转换的响应和驱动土壤磷变化的影响因子。结果显示:米槠人促林土壤的全磷、有机磷和微生物生物量磷显著高于米槠次生林和杉木人工林;冗余分析(RDA)发现,土壤含水量、总氮和无定型铁是影响淋溶层土壤磷的主要因子,而在淀积层,则是酸性磷酸酶、游离型铁和总氮起主要作用;土壤生物化学属性和微生物特性都会影响着不同形态土壤P的积累,其中土壤中的水分和酸性磷酸酶活性是调控土壤磷的关键因子。研究表明,中亚热带地区天然林转换为人促更新林更有利于森林土壤磷的储存和供应,有助于维持本区域森林生态系统的稳定。     

森林转换后土壤因素影响中亚热带土壤磷的积累

磷是植物生长的必需元素之一,是维持亚热带森林生态系统生产力的关键因子。研究森林转换后土壤因素对磷素的影响,对生态系统的稳定和森林经营具有重要意义。本文选取由亚热带常绿阔叶林转换而成的米槠次生林(SF)、米槠人促林(AR)和杉木人工林(CF)为研究对象,测定了土壤理化性质、铁铝氧化物、各形态磷含量以及酸性磷酸酶活性,旨在探究土壤磷对森林转换的响应和驱动土壤磷变化的影响因子。结果显示:米槠人促林土壤的全磷、有机磷和微生物生物量磷显著高于米槠次生林和杉木人工林;冗余分析(RDA)发现,土壤含水量、总氮和无定型铁是影响A层土壤磷的主要因子,而在B层,则是酸性磷酸酶、游离型铁和总氮起主要作用;土壤生物化学属性和微生物特性都会影响着不同形态土壤P的积累,其中土壤中的水分和酸性磷酸酶活性是调控土壤磷的关键因子。研究表明,中亚热带地区天然林转换为人促更新林更有利于森林土壤磷的储存和供应,有助于维持本区域森林生态系统的稳定。本文的研究结果可为中亚热带森林经营提供科学依据。     

中亚热带森林更新方式对土壤团聚体磷组分的影响

土壤团聚体在土壤磷贮存和调节磷有效性中起重要作用,然而森林更新方式如何影响土壤团聚体磷组分仍不清楚。本研究选取米槠天然林经不同强度干扰形成的米槠次生林(轻度干扰)、米槠人促更新林(人促林,中度干扰)及杉木人工林(重度干扰)为对象,通过分析土壤团聚体粒径组成、全土和团聚体磷组分、磷吸附指数(P_SOR)、磷遗留指数(P_LGC)、磷饱和度(DPS_M3)等指标,探究森林更新方式对全土及团聚体磷有效性及供磷潜力的影响。结果表明：森林更新方式显著影响土壤团聚体组成。米槠次生林和人促林土壤粗大团聚体(>2 mm)占比显著高于杉木人工林,而土壤粉黏粒团聚体(<0.053 mm)则表现为相反趋势。土壤团聚体组成显著影响土壤磷组分含量。土壤活性磷组分(可溶性磷P_SOL、速效磷P_M3)含量随团聚体粒径减小而降低;总磷(TP)、有机磷(Po)、中等活性磷组分(无机磷Pi_OH、有机磷Po_OH)、闭蓄态磷(P_OCL)含量、P     

入侵毛竹皆伐对亚热带森林土壤微生物生物量和酶活性的影响

去除入侵植物是恢复入侵地生态系统的首要步骤。本文研究了天目山毛竹纯林(完全入侵)、入侵毛竹皆伐林(皆伐后经过5年自然更新)和常绿阔叶林(未入侵)的土壤微生物生物量及多种土壤酶活性特征。结果表明: 与毛竹纯林相比,入侵毛竹皆伐林土壤有机碳(SOC)、硝态氮、有效磷和速效钾含量显著升高;土壤微生物生物量碳(MBC)和磷(MBP)显著升高,而土壤微生物生物量氮(MBN)显著降低;α-葡萄糖苷酶(AG)、β-葡萄糖苷酶(BG)、亮氨酸氨基肽酶(LAP)和酚氧化酶(POX)活性显著升高,而纤维二糖水解酶(CBH)、β-N-乙酰-氨基葡萄糖苷酶(NAG)、酸性磷酸酶(ACP)和过氧化物酶(PER)活性未发生显著改变。土壤AG、BG和LAP活性与SOC和MBC呈显著正相关;POX活性与硝态氮含量呈显著正相关。此外,入侵毛竹皆伐林土壤MBC、MBN和MBP及AG、BG、NAG、LAP和ACP活性均显著高于常绿阔叶林。综上,入侵毛竹皆伐促进了森林土壤养分含量、微生物生物量和酶活性的提高,是恢复入侵地森林土壤质量的有效措施,研究结果可为亚热带森林毛竹入侵治理提供科学依据。     

杉木采伐迹地营造阔叶树种对土壤微生物生态化学计量特征的影响

研究土壤微生物生物量及其生态化学计量特征对造林树种转换的响应,对深入了解森林生态系统土壤养分循环和有效性具有重要意义。本研究以1993年春在二代杉木采伐迹地上营造的26年生米老排和杉木人工林为对象,采用氯仿熏蒸法测定了0～40 cm土层土壤微生物生物量碳(MBC)、氮(MBN)、磷(MBP)的变化。结果表明: 与杉木人工林相比,米老排人工林0～10 cm土层MBC和0～20 cm土层MBN和MBP均显著提高, 0～20 cm土层MBC/MBP和10～20 cm土层MBN/MBP显著降低。两种人工林所有土层MBC/MBN均无差异。相关分析显示,土壤含水率、总有机碳、总氮、全磷、有效磷与MBC、MBN和MBP呈显著正相关,而与MBC/MBP和MBN/MBP呈显著负相关。逐步线性回归分析表明,MBN和MBP主要受土壤总氮和有效磷的影响,而MBC/MBP和MBN/MBP主要受有机碳和有效磷的驱动。研究表明,造林树种从杉木转换成米老排能够增加表层土壤微生物生物量,加速氮磷养分周转,增加土壤氮磷养分供应能力。米老排人工林土壤MBP的增加可能在一定程度上缓解了树木生长的磷限制。     

中亚热带山区土壤不同形态铁铝氧化物对团聚体稳定性的影响

以福建省三明市本底条件一致的三片林分的土壤作为研究对象,采用湿筛法测定了水稳定性团聚体粒径分布,分析了不同形态铁铝氧化物含量与0.25 mm大团聚体数量及团聚体平均重量直径(MWD)的关系。结果表明:(1)不同形态铁铝氧化物含量呈现出米槠次生林米槠人工林杉木人工林,游离结晶态(Fed、Ald)无定形(Feo、Alo)络合态(Fes、Als)。(2)0.25 mm大团聚体含量呈现米槠次生林米槠人促林杉木人工林,林分之间差异显著,MWD值的趋势与之相似。(3)线性回归分析表明:不同形态铁铝氧化物均与0.25 mm水稳定性大团聚体数量及MWD值达到显著甚至极显著相关,但通过分析相关系数R和显著性P说明氧化铝可能比氧化铁更有助于大团聚体的形成与稳定,无定形及络合态铁铝氧化物比游离态铁铝氧化物更能促进大团聚体的形成与稳定。     

中亚热带4种森林类型土壤活性有机碳的季节动态特征

2011年12月至2012年9月, 在湘中丘陵区杉木(Cunninghamia lanceolata)人工林、马尾松(Pinus massoniana)-石栎(Lithocarpus glaber)针阔混交林、南酸枣(Choerospondias axillaries)落叶阔叶林、石栎(Lithocarpus glaber)-青冈(Cyclobalanopsis glauca)常绿阔叶林1 hm²的长期定位观测样地, 采集0-15 cm、15-30 cm土层土壤样品, 测定土壤微生物生物量碳(MBC)、可矿化有机碳(MOC)、易氧化有机碳(ROC)、水溶性有机碳(DOC)含量, 分析4种森林土壤MBC、MOC、ROC、DOC含量的季节变化特征, 为揭示天然林保护与恢复对土壤有机碳(SOC)库的影响机理过程提供基础数据。结果表明: 森林土壤MBC、MOC、ROC、DOC含量具有明显的季节动态, 且不同森林同一土壤活性有机碳组分的季节变化节律基本一致, MBC、MOC、ROC含量表现为夏、秋季较高, 春、冬季较低; DOC含量表现为春、夏、冬季较高, 秋季最低; 同一森林不同土壤活性有机碳组分含量的季节变化节律不同; 土壤MBC、MOC、ROC、DOC含量与土壤自然含水率、SOC、全N、水解N、全P (除杉木人工林土壤MBC、MOC、ROC外)、速效P含量显著或极显著正相关, 与土壤pH值、全K、速效K含量相关性不显著, 表明不同森林类型外源碳库投入和土壤理化性质的差异是导致不同森林类型土壤活性有机碳含量差异显著的主要原因, 该区域森林土壤活性有机碳各组分含量的季节变化与各森林类型组成树种生长节律及其土壤水分含量和SOC、N、P的可利用性, 以及土壤活性有机碳各组分的来源有关, 森林土壤MBC、MOC、ROC、DOC含量可作为衡量森林土壤C、N、P动态变化的敏感性指标。     

中亚热带4种森林类型土壤活性有机碳的季节动态特征北大核心CSCD

2011年12月至2012年9月,在湘中丘陵区杉木(Cunninghamia lanceolata)人工林、马尾松(Pinus massoniana)-石栎(Lithocarpus glaber)针阔混交林、南酸枣(Choerospondias axillaries)落叶阔叶林、石栎(Lithocarpus glaber)-青冈(Cyclobalanopsis glauca)常绿阔叶林1 hm2的长期定位观测样地,采集0–15 cm、15–30 cm土层土壤样品,测定土壤微生物生物量碳(MBC)、可矿化有机碳(MOC)、易氧化有机碳(ROC)、水溶性有机碳(DOC)含量,分析4种森林土壤MBC、MOC、ROC、DOC含量的季节变化特征,为揭示天然林保护与恢复对土壤有机碳(SOC)库的影响机理过程提供基础数据。结果表明:森林土壤MBC、MOC、ROC、DOC含量具有明显的季节动态,且不同森林同一土壤活性有机碳组分的季节变化节律基本一致,MBC、MOC、ROC含量表现为夏、秋季较高,春、冬季较低;DOC含量表现为春、夏、冬季较高,秋季最低;同一森林不同土壤活性有机碳组分含量的季节变化节律不同;土壤MBC、MOC、ROC、DOC含量与土壤自然含水率、SOC、全N、水解N、全P(除杉木人工林土壤MBC、MOC、ROC外)、速效P含量显著或极显著正相关,与土壤p H值、全K、速效K含量相关性不显著,表明不同森林类型外源碳库投入和土壤理化性质的差异是导致不同森林类型土壤活性有机碳含量差异显著的主要原因,该区域森林土壤活性有机碳各组分含量的季节变化与各森林类型组成树种生长节律及其土壤水分含量和SOC、N、P的可利用性,以及土壤活性有机碳各组分的来源有关,森林土壤MBC、MOC、ROC、DOC含量可作为衡量森林土壤C、N、P动态变化的敏感性指标。     

Response of soil enzyme activities to litter input changes in two secondary Castanopsis carlessii forests in subtropical China

酶在土壤有机质分解中起重要作用。为深入了解全球变化背景下森林凋落物产量的改变对森林生态系统过程的影响, 以亚热带米槠(Castanopsis carlesii)人促更新次生林(米槠人促林)和米槠次生林为研究对象, 设置凋落物加倍(DL)、凋落物去除(NL)和对照(CT) 3种处理, 探讨土壤6种胞外酶活性的变化。研究结果表明: 米槠次生林中土壤纤维素水解酶(CBH)、β-N-乙酰氨基葡萄糖苷酶(NAG)、酚氧化酶(PhOx)和过氧化酶(PerOx)活性高于米槠人促林, 而酸性磷酸酶(AP)和β-葡萄糖苷酶(βG)活性没有差异; NL和DL处理均降低了两种不同更新方式森林土壤的AP、βG和NAG活性, CBH和PerOx活性均无显著变化, 而PhOx活性仅在DL处理后降低; 除NAG活性外, 米槠人促林的AP、βG、PhOx活性在凋落物处理后下降的幅度均高于次生林; Pearson相关分析和冗余分析表明, 土壤酶活性与土壤含水量、碳(C)、氮(N)含量和微生物生物量碳(MBC)、氮(MBN)含量显著相关。因此, 凋落物输入的改变(无论增加和减少), 引起了土壤含水量、C、N以及MBC和MBN含量的下降, 进而可能会导致亚热带米槠次生林和米槠人促林土壤某些胞外酶(如AP、βG和NAG)活性降低。从土壤酶活性角度看, 米槠次生林比米槠人促林更有利于亚热带森林生态系统C、N养分循环。     

Biogeochemical implications of labile phosphorus in forest soils determined by the Hedley fractionation procedure

Forest ecologists and biogeochemists have used a variety of extraction techniques to assess labile vs. non-labile soil P pools in chronosequences, the balance between biological vs. geochemical control of P transformations across a wide range of soil orders, the role of plants with either N-fixing or mycorrhizal symbionts in controlling soil P fractions, and to make inferences about plant-available P. Currently, variants of the sequential extraction procedure developed by M. J. Hedley and co-workers afford the greatest discrimination among labile and non-labile organic and inorganic P pools. Results of recent studies that used this technique to evaluate P fractions in forest soils indicate the following: (1) in intact, highly weathered forest soils of the humid tropics, Hedley-labile P values are several times larger than extractable P values resulting from mildly acidic extracting solutions which were commonly used in the past 2 decades; (2) pools of Hedley-labile P are several times larger than the annual forest P requirement and P required from the soil annually in both temperate and tropical forests; (3) long-term trends in non-labile P pools during pedogenesis are adequately represented by the Walker and Syers' model of changes in P fractionation during soil development. However, to better represent trends in pools that can supply plant-available P across forest soils of different age and weathering status, the paradigm should be modified; and (4) across a wide range of tropical and temperate forest soils, organic matter content is an important determinant of Hedley-labile P.     

Changes in phosphorus fractions caused by increased microbial activity in forest soil in a short-term incubation study

The effects of adding larch (Larix kaempferi) leaf litter and nitrogen (N) on microbial activity and phosphorus (P) fractions in forest soil were examined in a short-term (28-d) laboratory incubation study. The soil was analyzed using a modified Hedley sequential extraction procedure and an acid phosphatase assay. The addition of larch litter and N increased the acid phosphatase activity and decreased the labile P (H₂O-P + NaHCO₃-P) concentration. Compared with addition of larch litter only, addition of both inputs decreased the proportion of inorganic P (Pi) and increased that of organic P (Po) in the NaOH fraction, bound to aluminum and iron oxides. The results of nutrient (carbon, N, or P) addition indicated that acid phosphatase was synthesized to acquire P. This study suggests that, in this forest soil, P in the H₂O-P + NaHCO₃-P and in the NaOH-Pi fractions was available for soil microorganisms to decompose leaf litter and that increase in microbial activity eventually translated in an increase in the proportion of Po found in the NaOH fraction in this forest soil.     

海拔梯度变化对武夷山黄山松林土壤磷组分和有效性的影响

土壤磷（P）是植物生长必需的养分元素,也是亚热带森林生产力的主要限制元素。目前,关于不同海拔土壤P组分和P有效性的变化规律尚无统一定论,其原因主要是忽略了植被类型变化导致的P组分和P有效性对海拔的响应更为复杂。因此,以武夷山不同海拔黄山松林为研究对象,通过测定土壤环境因素、理化性质、微生物生物量（SMB）、酸性磷酸单酯酶（ACP）和磷酸双酯酶（PD）活性以及土壤P组分,探究土壤P组分和P有效性的变化及其影响因素。结果表明,随海拔降低,速效P含量显著增加,而易分解P、中等易分解P、难利用P和总磷含量显著减少。冗余分析结果表明,微生物生物量磷和微生物生物量氮是影响土壤P组分和P有效性变化的关键因素。研究表明,随海拔降低,黄山松林土壤微生物通过提高ACP、PD活性和降低SMB含量的能量分配策略,促进更多较难分解P组分的矿化,从而提高速效P含量,以满足微生物对P的需求。因此,在低海拔地区,微生物通过能量分配策略获取更多有效P,可能有利于提高武夷山黄山松林土壤速效P的供应,但从长期来看,可能使P矿化速率提高和P损耗增加,导致P库的储备不足,不利于土壤P素养分的可持续供应。     

亚热带不同海拔黄山松林土壤磷组分及微生物特征

磷是亚热带地区植物生长必需的养分元素之一,海拔梯度可能会改变土壤-植物-微生物系统并影响土壤磷形态及有效性。了解不同海拔土壤磷组分状况,对维持山地森林生态系统可持续发展具有重要的意义。以戴云山地区不同海拔梯度(1300m和1600 m)黄山松林为研究对象,分析了土壤磷组分、微生物群落特征和磷酸酶活性。结果显示:海拔显著影响黄山松林土壤磷组分,与海拔1300 m相比,海拔1600 m处土壤总磷含量减少了48.4%—49.8%,且各磷组分(易分解态磷、中等易分解态磷和难分解态磷)含量也显著降低,淋溶层(A层)土壤的降低程度分别为45.7%、58.6%和38.7%,淀积层(B层)为82.6%、59.9%和31.1%。海拔对土壤微生物群落特征和酶活性亦有显著影响,各类微生物群落和总微生物磷脂脂肪酸含量(PLFAs),以及磷酸双酯酶(PD)活性均表现为海拔1600 m 1300 m,但酸性磷酸单酯酶(ACP)活性呈相反的趋势。冗余分析(RDA)表明,土壤磷组分主要受有机碳(SOC)调控,且SOC与有机磷组分(Na HCO3-Po和Na OH-Po)呈显著正相关;磷酸酶和外生菌根真菌(EMF)也是影响土壤磷组分变化的重要因素。研究表明,土壤有机质含量和微生物群落结构及功能的变化可能是不同海拔黄山松林土壤磷有效性的关键调控因素。     

Labile Phosphorus in Soils of Forest Fallows and Primary Forest in the Bragantina Region, Brazil

We used the Hedley sequential extraction procedure to measure nine different organic inorganic soil phosphorus fractions in forest soil of the Bragantina region of Para, Brazil. We compared the labile fractions (resin‐extractable P + HCO3‐extractable inorganic and organic P) in Oxisols from three secondary forests (10, 20, and 40 years old) and a primary forest. These stands were located in an area that has supported shifting agriculture for approximately a century. After agricultural use, total P and labile P in soils of young secondary forests are diminished compared to the amounts presents in the primary forest soil. Within each stand, organic carbon content was a good predictor of labile organic and inorganic P, consistent with the large body of research indicating that mineralization of organic matter is important to plant nutrition in tropical ecosystems. During the reorganization of P pools during forest development, the pool of labile organic P (HCO3‐extractable) diminishes more than the other labile fractions, suggesting that it is directly or indirectly an important source of P for the regrowing forest vegetation. Across the four age classes of forest, the soil reservoir of labile P was equal to or greater than the total amount of P in the vegetation. If labile P measured by this method adequately represents P available to plants in the short term (as suggested by the current consensus), we would conclude that plant‐available P is reasonable abundant, and that the effects of agriculture on available P pools are detectable but not sufficient to compromise forest regrowth in this area.     

Wheat, canola and grain legume access to soil phosphorus fractions differs in soils with contrasting phosphorus dynamics

Despite the high phosphorus (P) mobilizing capacity of many legumes, recent studies have found that, at least in calcareous soils, wheat is also able to access insoluble P fractions through yet unknown mechanism(s). We hypothesized that insoluble P fractions may be more available to non-legume plants in alkaline soils due to increased dissolution of the dominant calcium(Ca)-P pool into depleted labile P pools, whereas non-legumes may have limited access to insoluble P fractions in iron(Fe)- and aluminium(Al)-P dominated acid soils. Four crop species (faba bean, chickpea, wheat and canola) were grown on two acid and one alkaline soil under glasshouse conditions to examine rhizosphere processes and soil P fractions accessed. While all species generally depleted the H₂O-soluble inorganic P (water Pi) pool in all soils, there was no net depletion of the labile NaHCO₃-extractable inorganic P fraction (NaHCO₃ Pi) by any species in any soil. The NaOH-extractable P fraction (NaOH Pi) in the alkaline soil was the only non-labile Pi fraction depleted by all crops (particularly canola), possibly due to increases in rhizosphere pH. Chickpea mobilized the insoluble HCl Pi and residual P fractions; however, rhizosphere pH and carboxylate exudation could not fully explain all of the observed Pi depletion in each soil. All organic P fractions appeared highly recalcitrant, with the exception of some depletion of the NaHCO₃ Po fraction by faba bean in the acid soils. Chickpea and faba bean did not show a higher capacity than wheat or canola to mobilize insoluble P pools across all soil types, and the availability of various P fractions to legume and non-legume crops differed in soils with contrasting P dynamics.     

Soil carbon pool and fertility under natural evergreen broadleaved forest and its artificial regeneration forests in southern Sichuan Province, China

The measurement of total soil organic matter (SOM) is not sensitive enough to detect short and medium term changes, and thus meaningful fractions of SOM should be measured. The carbon management index (CMI) was shown to be a useful technique for describing soil fertility. Soil samples were collected from natural evergreen broadleaved forest and its artificial regeneration forests of Sassafras tzumu, Cryptomeria fortunei and Metasequoia glyptostroboides in southern Sichuan Province, China, to determine soil carbon fractions, available nutrients, enzyme activity and CMI. Regression analysis was used to determine the relationship between soil carbon fractions, CMI and fertility. The results showed that the contents of soil organic carbon, water-soluble carbon, microbial biomass carbon, labile carbon, non-labile carbon, hydrolysis-N, available-P and available-K, the activity of invertase, phosphatase and catalase, and CMI were ranked with different seasons and followed the order: natural evergreen broadleaved forest > Sassafras tzumu plantation > Metasequoia glyptostroboides plantation > Cryptomeria fortunei plantation. The soil carbon fractions and CMI were significantly positively (P < 0.05) correlated with available nutrients and enzyme activity. The results indicate that soil carbon fractions and CMI could be used to evaluate the soil fertility for natural evergreen broadleaved forest and its artificial regeneration forests.     

Soil carbon pool and fertility under natural evergreen broadleaved forest and its artificial regeneration forests in southern Sichuan Province, China

The measurement of total soil organic matter (SOM) is not sensitive enough to detect short and medium term changes, and thus meaningful fractions of SOM should be measured. The carbon management index (CMI) was shown to be a useful technique for describing soil fertility. Soil samples were collected from natural evergreen broadleaved forest and its artificial regeneration forests of Sassafras tzumu, Cryptomeria fortunei and Metasequoia glyptostroboides in southern Sichuan Province, China, to determine soil carbon fractions, available nutrients, enzyme activity and CMI. Regression analysis was used to determine the relationship between soil carbon fractions, CMI and fertility. The results showed that the contents of soil organic carbon, water-soluble carbon, microbial biomass carbon, labile carbon, non-labile carbon, hydrolysis-N, available-P and available-K, the activity of invertase, phosphatase and catalase, and CMI were ranked with different seasons and followed the order: natural evergreen broadleaved forest > Sassafras tzumu plantation > Metasequoia glyptostroboides plantation > Cryptomeria fortunei plantation. The soil carbon fractions and CMI were significantly positively (P < 0.05) correlated with available nutrients and enzyme activity. The results indicate that soil carbon fractions and CMI could be used to evaluate the soil fertility for natural evergreen broadleaved forest and its artificial regeneration forests.     

Microbial resource allocation for phosphatase synthesis reflects the availability of inorganic phosphorus across various soils

According to the resource allocation model for extracellular enzyme synthesis, microorganisms should preferentially allocate their resources to phosphorus (P)-acquiring enzyme synthesis when P availability is low in soils. However, the validity of this model across different soil types and soils differing in their microbial community composition has not been well demonstrated. Here we investigated whether the resource allocation model for phosphatase synthesis is applicable across different soil types (Andosols, Acrisols, Cambisols, and Fluvisols) and land uses (arable and forest), and we examined which soil test P and/or P fraction microorganisms responded to when investing their resources in phosphatase synthesis in the soils. The ratio of alkaline phosphatase (ALP) to β-d-glucosidase (BG) activities in the arable soils and the ratio of acid phosphatase (ACP) to BG activities in the forest soils were significantly negatively related with the available inorganic P concentration. We also observed significant effects of available inorganic P, pH, soil types, and land uses on the (ACP + ALP)/BG ratio when the data for the arable and forest soils were combined and used in a stepwise multiple regression analysis. These results suggest that microbial resource allocation for phosphatase synthesis is primarily controlled by available inorganic P concentration and soil pH, but the effects of soil types and land uses are also significant.     

Implications of soil organic carbon and the biogeochemistry of iron and aluminum on soil phosphorus distribution in flooded forests of the lower Orinoco River,Venezuela

Relationships among soil phosphorus distribution, soil organic carbon and biogeochemistry of iron and aluminum were studied along a flooded forest gradient of the Mapire river, Venezuela. Soil samples were collected during the dry season in three zones subjected to different flooding intensity: MAX inundated 8 months per year, MED inundated 5 months per year, and MIN inundated 2 months per year. Total labile phosphorus (resin + bicarbonate extractable fractions) was significantly higher in MIN than in MAX. The longer non-flooding period in MIN probably allowed a higher accumulation of microbial biomass in soils of this zone and consequently a greater release of the bicarbonate organic fraction. The moderately labile phosphorus fraction associated with the chemisorbed phosphorus on amorphous and some crystalline aluminum and iron was significantly lower in MAX than in MIN following the same tendency observed for crystalline iron oxides. This result allowed us to hypothesize that the combined effect of a long flood period and a high soil organic carbon content in the MAX, could be appropriate conditions for microbial reduction of stable forms of iron. The ratio of soil organic carbon to total organic phosphorus decreased from MAX to MIN, indicating higher mineralization of organic phosphorus in MIN. Our results suggests two distinct flood-dependent mechanisms operating for phosphorus release along the gradient. In MAX mineralization process appears to be limited, while microbial mineral dissolution appears to be an important source of phosphorus. In MIN supply of phosphorus is associated with the stability of soil organic matter.