马尾松低产林套种木荷的林地与根际土壤养分特性的研究

马尾松低产林套种木荷的混交林林地与根际土壤养分特性研究表明，木荷根际对土壤养分的活化能力大于马尾松，这利于混交林中马尾松的生长．套种后所形成的混交林根际微区对土壤养分活化程度的提高改善了两树种的养分利用状况，这可能是低产林改造后林地土壤养分高于纯林地且林分生产力提高的主要原因之一．     

滨海4种盐生植物根际土壤酶活性特征与主要养分的关系

植物可直接或间接地影响土壤酶的活性,根际土壤酶的种类和活性对土壤养分的速效化产生影响,从而影响植物的吸收利用。以滨海盐土和轻度盐化潮土为材料,利用根袋法研究滨海盐生植物对根际与非根际土壤养分含量以及酶活性的影响,为盐生植物在滨海盐渍土壤中的修复利用提供理论依据。结果表明：在两种土壤中,植物根际过氧化氢酶,脲酶和蛋白酶的活性表现出相反的变化,滨海盐土中,根际土3种酶的活性均高于非根际土;而轻度盐化潮土中的根际土3种酶活性均低于非根际土。在两种土壤中,根际土全氮质量分数比非根际土高,但全磷却比非根际土低。根际土速效态养分的变化则与全态养分的变化相反,4种植物的根际土速效氮质量分数均显著低于非根际土。除芦苇外,根际土速效磷质量分数均高于非根际土。滨海盐土中碱性磷酸酶、过氧化氢酶和转化酶和土壤中几种主要养分的相关性最紧密,较好地体现了4种滨海盐生植物根际的养分状况,也说明盐生植物对滨海盐土酶活性有较大的影响。对比4种植物根际土壤中的酶活性,在高盐质量分数的滨海盐土中,盐地碱蓬对根际土壤酶活性的影响最大     

不同退化程度喀斯特生态系统根际土壤的养分分布特征

以贵州中部喀斯特地区由乔木林、灌木林和灌草丛等不同退化程度生态系统中的优势物种根际土壤为研究对象,测定其C、N、P全量及有效态质量分数,分析各优势物种根际土壤的养分变化。结果表明：3个生态系统中不同优势物种根际各类土壤养分质量分数变化较大,其中,土壤C、N、P养分为乔木林中园果化香根际土壤质量分数最高,白枥根际养分质量分数最低。可溶性有机碳质量分数为乔木林中最低,其平均水平不超过10 mg·kg-1。土壤磷素的供给能力为乔木林的园果化香和刺秋相对较强,其中园果化香中达到1.5%。而且优势树种间根际土壤有效态养分质量分数的差异明显高于全量养分,说明喀斯特地区根际土壤养分差异性主要受植被因素的影响,土壤有效态养分较全量养分对植被群落演替的响应更为灵敏,而且根际土壤养分质量分数和形态的变化与土壤有机碳质量分数有显著的正相关关系,这进一步说明喀斯特地区植被类型的变化对土壤养分的循环利用具有重要的影响作用。     

南亚热带不同植被根际微生物数量与根际土壤养分状况

研究了包括尾叶桉、广东凤丫蕨、柳叶竹、大叶相思、青皮、木荷、湿地松在内的7种南亚热带不同植物植被下土壤根际微生物与根际养分状况及其相关关系。结果表明,根际环境对细菌有明显的正效应,对放线菌和真菌有正、负两方面的影响,但对根际微生物总量具有根际效应明显;在南亚热带森林生态系统中.在植物的某些生长季节,微生物的根际效应与土壤养分的根际效应一致     

杨树人工林土壤养分有效性变化及其与土壤细菌群落演变的相关性

为揭示连作人工林衰退机制,基于离子交换树脂膜埋置和PCR-DGGE技术,对杨树人工林土壤养分库与流特征、土壤细菌群落结构的代际差异进行了对比分析.结果表明,随连作代数增加,杨树人工林土壤养分含量总体呈现逐渐下降的趋势;根际和非根际土壤中速效氮和钾的含量在代际间呈现显著降低(P0.05),说明连作人工林极易出现养分亏缺.养分离子流在非根际土壤中并没有显著差异,但根际土壤中NH4+和K+在单位时间内的提取量呈现显著增加,NO3-则显著减少(P0.05),说明连作杨树人工林土壤硝化作用存在障碍.对土壤细菌群落结构的研究表明,根际土壤细菌丰富度和Shannon-wiener多样性显著低于非根际土,但氨化细菌、好气性固氮菌和纤维素分解菌的数量显著高于非根际土;而且呈现出氨化细菌数量在代际间显著增加,亚硝化细菌和好气性固氮菌显著减少的趋势(P0.05).典型相关分析表明,杨树人工林土壤养分有效性变化与细菌群落演变具有极显著相关性(P0.01).因此,细菌群落演变可能是影响土壤硝化作用和氮素有效性变化的重要机制.     

丛枝菌根化大青杨苗木根际微域环境的研究

对接种AM菌根真菌的大青杨苗木根际微区进行系统研究，发现AM菌根真菌对宿主根际微域环境产生了重要影响：试验中选用的Glomus mosseae、G.intraradices、G.sinuosa、G.versifopme等4种AM菌根真菌都与盆栽大青杨苗木形成了菌根复合体。其中G.mosseae、G.intraradices侵染效果最好，侵染率分别是64．4％、67．4％。受两种菌侵染的苗木的生物量分别是对照处理的2．59、2．13倍。AM菌根对根际土壤微生物种群数量没有产生影响，但使根面、根系上的细菌、放线菌、固氮菌的数量显著增加。AM菌根增加了根际土壤磷酸酶、脲酶、蛋白酶的活性，各种酶活性增加量与苗木菌根侵染率呈显著相关。AM菌根使根际pH值降低，与菌根侵染率呈显著负相关。接种苗木的根际土壤中，可直接被植物吸收利用的N、P元素出现富集现象，与菌根侵染率呈极显著相关。     

有机酸对根际土壤中铅形态及其生物毒性的影响

采用根袋盆栽试验和连续浸提方法研究外源柠檬酸、EDTA对根际土壤中Pb形态转化及其生物毒性的影响。结果表明，有机酸能明显活化根际土壤中的Pb，高浓度(3mmol／L)比低浓度(0．5mmol／L)的柠檬酸对Pb的活化能力强；EDTA在低浓度(0．5mmol／L)时对Pb的活化能力就很强。柠檬酸、EDTA能增强土壤Pb的毒性，提高小麦根部对Pb的吸收，并促进Pb由根部向地上部转移。     

凤庆县不同古茶园根际与非根际土壤酶活性及其化学计量特征

研究不同古茶园土壤养分状况间的差异影响,可为古茶园的土壤养分管理提供理论依据,实现茶园的提质增效.以凤庆县郭大寨乡3个典型古茶园的根际与非根际土壤为研究对象,探究其根际与非根际土壤理化性质、土壤酶活性及其化学计量比之间的关系.结果显示：（1）茶园根际与非根际土壤养分含量及酶活性差异显著（P <0.05）,且表现出不同的土壤营养条件.（2）不同茶园的根际土壤含水量、全碳、全氮、全磷含量差异显著（P <0.05）,均表现为大箐>龙潭>琼英;同时,龙潭茶园土壤pH=4.5为茶树生长最适值.（3）不同茶园非根际土壤胞外酶活性的高低表现为大箐>龙潭>琼英,其活性与土壤含水量、全碳、全氮、全磷含量正相关,其中土壤含水量解释了97.2%变异,与pH值负相关.而在植物根系的作用下,根际土壤酶活性呈现出不同变化趋势;其活性与土壤含水量、pH值、全碳、全氮、全磷含量均正相关,土壤含水量解释了93.9%的变异,全碳解释了5.2%的变异.（4）根据土壤酶化学计量比矢量分析,3个茶园土壤微生物受碳源限制程度不同,限制程度为琼英>龙潭>大箐,大箐茶园土壤微生物受到一...     

根系分泌物及其在植物营养中的作用

论述了根系分泌物的种类和影响因素，根系分泌物在植物营养中的调节作用、异种克生作用，根系分泌物与根际微生物的相互作用。在铁胁迫条件下，许多高等植物都能产生一系列生理和形态方面的适应性反应，禾本科植物通过根际特定分泌物——麦根酸类物质来自动调节其体内的铁营养状况；在磷胁迫条件下，根系分泌的低分子有机酸种类主要有柠檬酸、草酸、酒石酸和苹果酸，它们在植物根际的富集能明显促进土壤中磷的释放，提高作物对磷的吸收，缓解植物的磷胁迫；在锌胁迫条件下，双子叶植物的根系分泌物对锌的活化作用不明显，而禾本科植物的根系分泌物可以活化石灰性土壤中难溶性锌。     

植物根系分泌物与根际营养关系评述

根系分泌物（ｒｏｏｔ ｅｘｕｄａｔｅｓ, ＲＥ）主要有粘胶、外酶、有机酸、糖、酚及各种氨基酸。不同营养基因型的植物, ＲＥ组分明显不同。存在养分和环境胁迫时,植物通过增加粘胶、酶及某些有机酸的分泌量以适应变化的环境。ＲＥ也是植物改善根际营养环境的重要手段。ＲＥ可改善土壤物理结构,促进矿物风化,提高土壤ＣＥＣ,影响土壤ｐＨ、土壤矿物表面吸附性能及土壤生物学性质。ＲＥ还在活化根际土壤养分,促进植物对养分吸收起主要作用。今后ＲＥ的研究应注重ＲＥ研究方法的完善,拓展研究领域,并加强与各学科的联合。     

A numerical model of wave- and current-driven nutrient uptake by coral reef communities

We developed a numerical model capable of simulating the spatial zonation of nutrient uptake in coral reef systems driven by hydrodynamic forcing (both from waves and currents). Relationships between nutrient uptake and bed stress derived from flume and field studies were added to a four-component biogeochemical model embedded within a three-dimensional (3-D) hydrodynamic ocean model coupled to a numerical wave model. The performance of the resulting coupled physical-biogeochemical model was first evaluated in an idealized one-dimensional (1-D) channel for both a pure current and a combined wave-current flow. Waves in the channel were represented by an oscillatory flow with constant amplitude and frequency. The simulated nutrient concentrations were in good agreement with the analytical solution for nutrient depletion along a uniform channel, as well as with existing observations of phosphate uptake across a real reef flat. We then applied this integrated model to investigate more complex two-dimensional (2-D) nutrient dynamics, firstly to an idealized coral reef-lagoon morphology, and secondly to a realistic section of Ningaloo Reef in Western Australia, where nutrients were advected into the domain via alongshore coastal currents. Both the idealized reef and Ningaloo Reef simulations showed similar patterns of maximum uptake rates on the shallow forereef and reef crest, and with nutrient concentration decreasing as water flowed over the reef flat. As a result of the cumulative outflow of nutrient-depleted water exiting the reef channels and then being advected down the coast by alongshore currents, both reef simulations exhibited substantial alongshore variation in nutrient concentrations. The coupled models successfully reproduced the observed spatial-variability in nitrate concentration across the Ningaloo Reef system.     

Unintended nutrient imbalance induced by wastewater effluent inputs to receiving water and its ecological consequences

Eutrophication is the most widespread water quality issue globally. To date, most efforts to control eutrophication have focused on reductions of external nutrient inputs, yet importance of nutrient stoichiometry and subsequent shift in plankton composition in aquatic ecosystem has been largely neglected. To address eutrophication, improved sanitation is one of the United Nations Sustainable Development Goals, spurring the constructions of wastewater treatment facilities that have improved water quality in many lakes and rivers. However, control measures are often targeted at and effective in removing a single nutrient from sewage and thus are less effective in removing the others, resulting in the changes of nutrient stoichiometry. In general, more effective phosphorus removal relative to nitrogen has occurred in wastewater treatment leading to substantial increases in N/P ratios in effluent relative to the influent. Unfortunately, high N/P ratios in receiving waters can impose negative influences on ecosystems. Thus, long-term strategies for domestic wastewater management should not merely focus on the total reduction of nutrient discharge but also consider their stoichiometric balances in receiving waters.     

Modeling compensated root water and nutrient uptake

Plant root water and nutrient uptake is one of the most important processes in subsurface unsaturated flow and transport modeling, as root uptake controls actual plant evapotranspiration, water recharge and nutrient leaching to the groundwater, and exerts a major influence on predictions of global climate models. In general, unsaturated models describe root uptake relatively simple. For example, root water uptake is mostly uncompensated and nutrient uptake is simulated assuming that all uptake is passive, through the water uptake pathway only. We present a new compensated root water and nutrient uptake model, implemented in HYDRUS. The so-called root adaptability factor represents a threshold value above which reduced root water or nutrient uptake in water- or nutrient-stressed parts of the root zone is fully compensated for by increased uptake in other soil regions that are less stressed. Using a critical value of the water stress index, water uptake compensation is proportional to the water stress response function. Total root nutrient uptake is determined from the total of active and passive nutrient uptake. The partitioning between passive and active uptake is controlled by the a priori defined concentration value c_max. Passive nutrient uptake is simulated by multiplying root water uptake with the dissolved nutrient concentration, for soil solution concentration values below c_max. Passive nutrient uptake is thus zero when c_max is equal to zero. As the active nutrient uptake is obtained from the difference between plant nutrient demand and passive nutrient uptake (using Michaelis–Menten kinetics), the presented model thus implies that reduced passive nutrient uptake is compensated for by active nutrient uptake. In addition, the proposed root uptake model includes compensation for active nutrient uptake, in a similar way as used for root water uptake. The proposed root water and nutrient uptake model is demonstrated by several hypothetical examples, for plants supplied by water due to capillary rise from groundwater and surface drip irrigation.     

Insights into the changes of amino acids,microbial community,and enzymatic activities related with the nutrient quality of product during the composting of food waste

● The highest seed germination index was achieved at 0.3 g/g total solids of food waste. ● Proline was identified as the key amino acid related with the composting process. ● Amino acid metabolism sequences predominated during the whole composting process. This study systematically investigated the changes of amino acids as the composting process of food waste proceeded. It is found that the addition of 0.3 g/g total solids of food waste achieved the highest seed germination index of the product (268 %). The microbial community results indicated that the abundance of amino acid metabolism sequences remained at high levels during the whole composting process. Proline was identified as the key amino acid related with the nutrient quality of product during the composting of food waste. Further plant germination and hydroponic experiments found, that compared with those without the addition of proline, the addition of 50 mg/L proline increased seed germination rate by 20 %, increased shoot length by 3 %, increased root biomass of seedlings by 82 %, and increased leaf biomass of seedlings by 76 %, respectively. Firmicutes, γ-Pseudomonadota, Chloroflexi and Planctomycetes were the key identified bacteria related with the increase of proline during the composting of food waste. Meanwhile, the enzymatic tests of the activities of superoxide dismutase, peroxidase and malondialdehyde indicated that proline did not cause oxidative damage on the growth of plants. This study provided novel insights into the changes of amino acids, microbial community, and enzymatic activities related with the nutrient quality of product during the composting of food waste.     

Nutrient-limited toxin production and the dynamics of two phytoplankton in culture media: A mathematical model

In this paper we have proposed and analyzed a simple mathematical model consisting of four variables, viz., nutrient concentration, toxin producing phytoplankton (TPP), non-toxic phytoplankton (NTP), and toxin concentration. Limitation in the concentration of the extracellular nutrient has been incorporated as an environmental stress condition for the plankton population, and the liberation of toxic chemicals has been described by a monotonic function of extracellular nutrient. The model is analyzed and simulated to reproduce the experimental findings of Graneli and Johansson [Graneli, E., Johansson, N., 2003. Increase in the production of allelopathic Prymnesium parvum cells grown under N- or P-deficient conditions. Harmful Algae 2, 135–145]. The robustness of the numerical experiments are tested by a formal parameter sensitivity analysis. As the first theoretical model consistent with the experiment of Graneli and Johansson (2003), our results demonstrate that, when nutrient-deficient conditions are favorable for the TPP population to release toxic chemicals, the TPP species control the bloom of other phytoplankton species which are non-toxic. Consistent with the observations made by Graneli and Johansson (2003), our model overcomes the limitation of not incorporating the effect of nutrient-limited toxic production in several other models developed on plankton dynamics.     

An ecosystem model for estimating potential shellfish culture production in sheltered coastal waters

A generic ecosystem model has been developed for estimating the potential production of shellfish culture and the effect of that cultivation on the pelagic ecosystem in sheltered coastal waters. The model describes the dynamics of a simple food web, nutrient cycling and growth of shellfish. The design of the model is closely tied to the temporal and spatial scales that are important in determining the sustainable production level for a particular embayment. The pelagic ecosystem, mussel energetics, population dynamics and hydrodynamics are coupled to allow fully dynamic predictions of the effect of the shellfish density. When applied to Beatrix Bay, an intensive culture embayment in the Pelorus Sound of New Zealand, the model successfully captured main features of the observed system behaviour. The hydrodynamic regime of the bay controls mussel growth and production. Although high fluxes of water into the bay suppress nutrient and carbon cycling signals in the system, the model simulations demonstrated that the mussel cultivation can have considerable effects on the ecosystem of the bay including food depletion and nutrient cycling. One of the most obvious effects is nutrient enhancement through mussel excretion at low cultivation densities, which promotes primary production particularly during the N-limitation period in summer. The sensitivity analysis identified uncertainty in some parameters and indicated areas for which experimental studies could lead to model improvement. The modelling exercise has established a primary predictive tool for managing mussel aquaculture of a coastal embayment to estimate relationships between the stock level and the growth rate of mussels, and the potentially achievable harvest and stocking density.     

Nitrogen versus phosphorus limitation in a subtropical coastal embayment (Moreton Bay; Australia): Implications for management

An approach combining nutrient budgets, dynamic modelling, and field observations of phytoplankton and nitrogen (N₂)-fixing Lyngbya majuscula following changes in wastewater N loads, was used to demonstrate that Moreton Bay is potentially phosphorus (P) limited. Modelling and nutrient budgeting shows that benthic N-fixation loads are high, allowing the system to overcome any potential N-limitation. Phytoplankton biomass has shown little change from 1991 to 2006 in the sections of Moreton Bay most impacted by wastewater effluents, despite a large reduction in wastewater N loads from 2000 to 2002. This is consistent with modelling that also showed no reduction in primary productivity associated with reduced N loads. Most importantly, there have been rapid increases in the occurrence of N-fixing L. majuscula in Moreton Bay as wastewater P loads have increased relative to wastewater N loads. This is also consistent with modelling. This work supports the premise that there may be fundamental differences in nutrient limitation of primary production between subtropical and temperate coastal systems due to differences in the importance of internal nitrogen sources and sinks (N-fixation and denitrification). These differences need to be recognised for optimum management of coastal systems.     

Integrating wetlands and riparian zones in river basin modelling

Wetlands, and in particular riparian wetlands, represent an interface between the catchment area and the aquatic environment. They control the exchange of water and related chemical fluxes from the upper catchment area to surface waters like streams and lakes. Their influence on water and nutrient balances has been investigated mainly at the patch scale. In this study an attempt was made (a) to integrate riparian zones and wetlands into eco-hydrological river basin modelling, and (b) to quantify the impacts of riparian wetland processes on water and nutrient fluxes in a meso-scale catchment located in the northeastern German lowland. The investigation was performed by analysing hydro-chemical field data and applying the eco-hydrological model SWIM (Soil and Water Integrated Model), which was extended to reproduce the relevant water and nutrient flows and retention processes at the catchment scale in general, and in riparian zones and wetlands in particular. The main extensions introduced in the model were: (1) implementation of daily groundwater table dynamics at the hydrotope level, (2) implementation of water and nutrient uptake by plants from groundwater in riparian zones and wetlands, and (3) assessment of nutrient retention in groundwater and interflow. The simulation results indicate that wetlands, though they represent relatively small parts of the total catchment area, may have a significant impact on the overall water and nutrient balances of the catchment. The uncertainty of the simulation results is considerably high, with the main sources of uncertainty being the model parameters representing the geo-hydrology and the input data for land use management.     

Nutrient fluxes at the landscape level and the R* rule

Nutrient cycling in terrestrial ecosystems involves not only the vertical recycling of nutrients at specific locations in space, but also biologically driven horizontal fluxes between different areas of the landscape. This latter process can result in net accumulation of nutrients in some places and net losses in others. We examined the effects of such nutrient-concentrating fluxes on the R* rule, which predicts that the species that can survive in steady state at the lowest level of limiting resource, R*, can exclude all competing species. To study the R* rule in this context, we used a literature model of plant growth and nutrient cycling in which both nutrients and light may limit growth, with plants allocating carbon and nutrients between foliage and roots according to different strategies. We incorporated the assumption that biological processes may concentrate nutrients in some parts of the landscape. We assumed further that these processes draw nutrients from outside the zone of local recycling at a rate proportional to the local biomass density. Analysis showed that at sites where there is a sufficient biomass-dependent accumulation of nutrients, the plant species with the highest biomass production rates (roughly corresponding to the best competitors) do not reduce locally available nutrients to a minimum concentration level (that is, minimum R*), as expected from the R* rule, but instead maximize local nutrient concentration. These new results require broadening of our understanding of the relationships between nutrients and vegetation competition on the landscape level. The R* rule is replaced by a more complex criterion that varies across a landscape and reduces to the R* rule only under certain limiting conditions.     

新垦赤红壤不同轮作的养分变化

五年的研究结果是:赤红壤耕垦之后只要采取合理的轮作和结合适当的秸秆返回措施,它的肥力就可以得到保持,而且还可以获得显著提高。在四种轮作形式中,效果最明显的为1:1,它的土壤有机质、全量N、P、K含量比轮作前分别提高了L 22、1.84、2.27和0.06倍1:2和2:1的效果较差,分别提高了0.57、0.83、2.08、0.39倍和1.02、0.91、1.46、-0.07倍,0:1的由于没有轮作,加上每年把长好的草皮铲走,导致了土壤有机质、全氮量反而比轮作前下降了6.5％和25.0％。随着轮作土壤养分的提高,土壤物理和微生物状况也获得了改善。