稻麦复种模式下氮肥与稻秸互作对小麦产量和N_(2)O排放影响及推荐施肥研究

优化氮肥施用和秸秆还田技术为途径的农业管理措施被认为是提升农业可持续性的有效手段,然而当前关于氮肥和秸秆还田对小麦产量和N_(2)O排放影响的研究仍十分有限。为此,本研究基于2000—2022年发表的关于长江中下游流域氮肥和秸秆投入下小麦产量和N_(2)O排放变化的文献,运用随机森林建模,定量分析氮肥和秸秆还田对小麦产量和N_(2)O排放的影响,并结合情景设置进行了特定地点的小麦产量和N_(2)O排放模拟,同时评估了碳排放强度(CEE)和净生态系统经济效益(NEEB)。结果表明,建立的区域尺度小麦产量与N_(2)O排放对氮秸互作响应的随机森林模型,验证结果R^(2)分别为0.66和0.65,RMSE分别为0.70和1.11。结果表明施氮量和土壤有机质是影响小麦产量和N_(2)O排放的重要因素。综合来看,达到最大产量所需的氮肥量为208~212 kg hm^(-2),达到最小CEE所需的氮肥量为113~130 kg hm^(-2),达到最高的NEEB所需的氮肥量为202~205 kg hm^(-2),其中在6.75 t hm^(-2)的秸秆投入下施用202 kg hm^(-2)的氮肥可以获得最高的生态收益1.37万元。优化氮肥和秸秆投入具备减少作物碳排放强度并获得最大净生态环境效益的潜力。

基于DNDC模型的红壤旱坡花生地N_(2)O排放模拟研究

为探究DNDC模型在红壤旱坡地N_(2)O排放模拟的适用性,以赣北红壤旱坡花生地为研究对象,设置常规耕作和轻简化免耕2种处理,连续3年(2019—2021年)采用静态箱-气相色谱法开展N_(2)O排放的田间原位观测试验,研究不同耕作处理下N_(2)O排放特征及DNDC模型模拟效果。结果表明:DNDC模型对不同耕作处理下0~10 cm土壤温度(相关系数r为0.86~0.87)和作物产量(r为0.90)的模拟效果较好。该模型能较好地模拟花生季因施肥和降雨引起的N_(2)O排放波动变化,也能较好地模拟常规耕作下土壤N_(2)O排放峰,但会在一定程度上低估轻简化免耕的N_(2)O排放峰和排放总量,且模型对16 mm以下的降雨响应较小。土壤pH值、施肥量对红壤旱坡花生地N_(2)O排放的影响最大,降雨量、土壤有机碳含量和粘粒含量也是影响N_(2)O排放的重要因子。模型模拟2019年不同施肥量下N_(2)O排放总量与花生产量发现,氮肥施用量不能低于76.54 kg/hm^(2),也不宜超过106.78 kg/hm^(2)。研究结果可为红壤坡耕地作物种植优化、农业温室气体减排等提供理论依据。

NaF-Na_(3)PO_(4)-H_(2)O体系相图与热力学模型

NaF–Na_(3)PO_(4)–H_(2)O体系是稀土矿物加工的典型盐水体系,开发氟、磷回收工艺需要该体系的相图和热力学模型支持。利用等温溶解平衡法测定了273.15 K、298.15 K、323.15 K和348.15 K的固液相平衡数据,并基于eNRTL模型框架构建了该体系从最低共熔点到348.15 K的热力学模型。实验结果表明:NaF–Na_(3)PO_(4)–H_(2)O体系存在NaF、Na_(3)PO_(4)·12H_(2)O、Na_(3)PO_(4)·8H_(2)O和复盐NaF·2Na_(3)PO_(4)·19H_(2)O 4个固相物种;其中复盐在各温度均占据三元体系的主要相区,磷酸钠水合物的相区极窄,很难单独成盐,NaF相区相对较大并随温度升高而增大。热力学模型研究较好地表达了NaF–H_(2)O、Na_(3)PO_(4)–H_(2)O体系的多温离子活度系数、溶液渗透系数、二元体系相图,获得了盐水作用参数和6个固相的热力学数据;通过对三元体系多温相图数据的有效表达,获得了盐-盐作用参数和复盐的热力学数据,在此基础上推测了NaF–Na_(3)PO_(4)–H_(2)O体系相图结构,获得了难以实验测定的9个零变量点和9条单变量共饱和线,从而得到了全部固相的平衡相区,并给出了NaF–Na_(3)PO_(4)–H_(2)O体系完整相图,为更复杂体系的热力学表达以及工业应用提供了参考依据。

AlCl_(3)·6H_(2)O在FeCl_(3)、CaCl_(2)、KCl及KCl–FeCl_(3)溶液中溶解度的实验及预测

如何将AlCl_(3)·6H_(2)O从众多组分中选择性地结晶分离是从煤矸石中提Al的关键,而AlCl_(3)·6H_(2)O在煤矸石酸浸体系中的热力学平衡数据对于结晶过程的控制至关重要。在25~85℃的温度范围内,测定了不同温度和溶液浓度下AlCl_(3)·6H_(2)O在FeCl_(3)、CaCl_(2)、KCl及KCl-FeCl_(3)溶液中的溶解度。实验发现温度对AlCl_(3)·6H_(2)O在所有溶液体系中溶解度的影响均不明显,溶解度只随温度的升高略有增加;溶液浓度是影响溶解度的主要因素,AlCl_(3)·6H_(2)O在所有溶液体系中的溶解度均随溶液浓度的升高而明显下降,分析其原因是由于溶液浓度的增大使得Cl^(–)同离子效应增强。为了提高OLI软件预测结果的准确性,对其嵌入Bromley-Zemaitis模型中“Al^(3+)–Cl^(-)”离子对的交互参数进行了修正。随后验证了修正模型的实用性,结果表明它可应用于AlCl_(3)·6H_(2)O在FeCl_(3)、CaCl_(2)及KCl的任意单、混溶液中溶解度的预测。

高压氨氧化中N_(2)O的实验与动力学研究

在流动管平台上进行了接近发动机运行压力的氨气氧化实验,关注N_(2)O的生成和消耗.压力为5.0 MPa,温度从600~1250K,当量比从0.13~1.0.用近年来发表的氨气氧化的动力学模型开展模拟计算和动力学分析,对各模型在高压工况下对N_(2)O的预测能力进行评估和分析.根据最新的计算结果调整NH_(2)和NO_(2)反应的分支比,并在Stagni模型上更新了相关反应的反应速率,添加了N_(2)O缺失的反应路径.模型优化后在不同当量比下对N_(2)O的预测能力均得到了提升.

Thermodynamic modeling and phase diagram prediction of salt lake brine systems.Ⅰ. Aqueous Mg^2+–Ca^2+–Cl^- binary and ternary systems

Salt lake brine is a complex salt-water system under natural environment.Although many models can express the thermodynamic properties and phase equilibrium of electrolyte aqueous solution,the multi-temperature characteristics and predictability are still the goals of model development.In this study,a comprehensive thermodynamic model system is re-established based on the eNRTL model and some improvements:(1) new expression of long-range electrostatic term with symmetrical reference state is proposed to handle the electrolyte solution covering entire concentration range;(2) the temperature dependence of the binary interaction parameters is formulated with a Gibbs Helmholtz expression containing three temperature coefficients,the liquid parameters,which associated with Gibbs energy,enthalpy,and heat capacity contribution;and(3) liquid parameters and solid species data are regressed from properties and solubility data at full temperature range.Together the activity coefficient model,property models and parameters of liquid and solid offer a comprehensive thermodynamic model system for the typical bittern of MgCl2-CaCl2-H2 O binary and ternary systems,and it shows excellent agreement with the literature data for the ternary and binary systems.The successful prediction of complete phase diagram of ternary system shows that the model has the ability to deal with high concentration and high non-idealitv system,and the ability to extrapolate the temperature.

Modeling N_2O Emissions from Agricultural Fields in Southeast China

DNDC, a rainfall-driven and process-oriented model of soil carbon and nitrogenbiogeochemistry, is applied t0 simulate the nitrous oxide emissions from agricultural ecosystem inSoutheast China. We simulated the soil N2O emission during a whole rice-wheat rotation cycle(from Nov. 1, 1996 to Oct. 31, 1997) under three different conditions, which are A) no fertilizer, B)both chemical fertilizer and manure and, C) chemical fertiliser only. The processes ofN2O emission were discussed in detail by comparing the model outputs with the results from fieldmeasurement. The comparison shows that the model is good at simulating most of theNzO emission pulses and trends. Although the simulated N2O emission fluxes are generally lessthan the measured ones, the model outputs during the dryland period, especially during the wheatreviving and maturing stages in spring, are much better than those during the paddy field period.Some sensitive experiments were made by simulating the N2O emissions in spring, when there is asmallest gap between the simulated fluxes and the measured ones. Meanwhile, the effects of someimportant regulating factors, such as the rainfall N deposition by rainfall, temperature, tillage, nitrogen fertilizer and manure application on N2O emission during this period were analyzed. Fromthe analysis, we draw a conclusion that soil moisture and fertilization are the most important regulating factors while the N2O emission is sensitive to some other factors, such as temperature, manure, tillage and the wet deposition of atmospheric nitrate.

A Process-based Model of N_2O Emission from a Rice-Winter Wheat Rotation Agro-Ecosystem:Structure,Validation and Sensitivity

In order to numerically simulate daily nitrous oxide （N2O） emission from a rice-winter wheat rotation cropping system, a process-based site model was developed （referred to as IAP-N-GAS） to track the movement and transformation of several forms of nitrogen in the agro-eeosystem, which is affected by climate, soil, crop growth and management practices. The simulation of daily N2O fluxes, along with key daily environmental variables, was validated with three-year observations conducted in East China. The validation demonstrated that the model simulated well daily solar radiation, soil temperature and moisture, and also captured the dynamics and magnitude of accumulated rice aboveground biomass and mineral nitrogen in the soil. The simulated daily N2O emissions over all three years investigated were generally in good agreement with field observations. Particularly well simulated were the peak N2O emissions induced by fertilizations, rainfall events or mid-season drainages. The model simulation also represented closely the inter-annuM variation in N2O emission. These validations imply that the model has the capability to capture the general characteristics of N2O emission from a typical rice-wheat rotation agro-ecosystem. Sensitivity analyses revealed that the simulated N2O emission is most sensitive to the fertilizer application rate and the soil organic matter content, but it is much less sensitive to variations in soil pH and texture, temperature, precipitation and crop residue incorporation rate under local conditions.

Evaluation of Component Activity in Molten MnO-SiO_(2)-Al_(2)O_(3)-CaO System with Model SELF-SReM4

A sub-regular solution model SELF-SReM4 used to evaluate activity of the components in a homogeneous region of a quaternary system has been developed in Shanghai Enhanced Laboratory of Ferrometallurgy.The application of SELF-SReM4 in C-Mn-Fe-Si system without the SiC formation has been introduced in previous paper.It’s application for molten slag of MnO-SiO2-Al2O3-CaO was introduced in this paper.They provide a basis for the prediction of the metal-slag equilibrium conditions.

A Modified Lattice Model of the Reversible Effect of Axial Strain on the Critical Current of Polycrystalline REBa2Cu3O7-δ Films

The strain effect on the critical current is one of the most important properties for polycrystalline YBa2 Cu3O7-δ （REBCO, RE： rare earth） films, in which the reversible effect is intrinsic in the range of strain 0 and the irreversible strain εirr. By introducing the applied strain, a modified grain boundaries （GBs） in the REBCO film is developed. lattice model combining the strain and misorientation of A good agreement of the calculation on the lattice model with the experimental data shows that the lattice model is able to well describe the reversible effect of axial strain on the critical current of the REBCO film, and provides a good understanding of the mechanism of the reversible effect of the strain. Moreover, the effects of the crystallographic texture of the REBCO film and the residual strain εr on the variation of the critical current with the applied strain are extensively investigated. Furthermore by using the developed lattice model, the irreversible strain εirr of the REBCO film can be theoretically determined by comparing the calculation of the critical current-strain curve with the experimental data.

采用TUD联合模型模拟倒置A^2/O工艺的运行工况

结合北京某大型市政污水处理厂倒置A2/O工艺的运行实践,应用TUD联合模型及其缺省参数对该厂进行了数学模拟,以演示国际通用数学模型对我国污水处理厂模拟的有效性、准确性和简单性,为今后模拟技术在我国的推广应用起到示范作用。在完全使用缺省参数时模拟预测出水COD和TSS与实测值十分吻合,出水TP模拟结果与历史数据亦存在较小误差,而对N的模拟预测效果不甚理想。针对存在的N模拟误差,结合专家法和灵敏度分析法,对模型中有关N的个别组分参数和硝化细菌半饱和动力学参数进行修正(iNSF=6%,iNXS=6%,KNH4=1.5 gN/m3)后,获得了令人满意的模拟预测结果。随后用2组不同季节的运行数据进行模拟验证,也得到了与实测数据十分吻合的模拟结果。

采用TUD模型动态模拟倒置A^2/O工艺运行工况

在进行动态模拟前,首先对3组现场检测的水质、水量数据进行物料平衡检查,目的是校核实测数据的准确度。通过物料平衡分析发现,只有2组数据的物料平衡准确度合格,另外1组为无效数据。利用静态模拟建立并校正过的工艺模型对2组有效数据进行动态水质模拟,发现预测结果与实测值的吻合度至少为80%~90%。在此基础上,对典型水量日变化曲线(24 h)下的动态进水负荷进行模拟以预测出水水质的变化趋势,揭示动态负荷下出水水质的变化规律以及保持良好水质所应采取的运行对策。动态模拟结果具有较高吻合度这一事实表明,数学模拟技术完全可用于我国污水处理厂运行问题诊断以及运行优化方案的制定与实施。

A^2/O工艺污水处理厂运行参数优化的数值模拟

为了确定活性污泥系统A2/O工艺的最佳运行工况,将FCASM2-HYDRO模型应用于德清狮山污水处理厂A2/O工艺污水处理过程的数值模拟中.根据FCASM2-HYDRO模型分别建立了厌氧池、缺氧池、好氧池的数值模拟方程.采用有限元法求解,并使用MATLAB语言建立一套数值模拟程序,利用数值模拟程序分别模拟了工艺参数条件、流量、进水碳氮磷比对德清狮山污水处理厂污水处理效果的影响.由数值模拟结果得到了该厂目前最佳的运行工况:污泥回流比为50%,混合液回流比为100%,泥龄为15d,进水COD∶NH4+-N∶PO43-P比控制为100∶8∶1.

O_2在具有氧和镁缺陷MgO(001)表面的吸附(英文)

在密度泛函理论的框架下,采用嵌入点电荷簇模型研究了O_2在具有氧缺陷和镁缺陷MgO(001)表面上的吸附.用电荷自洽的方法确定了点电荷的值.计算结果表明,O_2倾向吸附在具有氧缺陷的MgO(001)表面上.通过和我们近期研究过的O_2在低配位的边、角上吸附结果相比较,发现具有氧缺陷的MgO(001)表面更加有利于O_2的吸附和解离.Mulliken电荷分析表明,电荷由底物向吸附的O_2反键轨道上转移是导致O_2键强削弱的主要原因.势能曲线表明,O_2在具有氧缺陷的MgO(001)表面上发生解离所需要克服的能垒比在角阳离子端发生解离所需克服的能垒有大幅度降低.

DMF-H_(2)O-CHCl_(3)体系293K液液相平衡数据的测定与关联

为进一步获得制革废水中N,N二甲基甲酰胺(DMF)萃取回收工艺所需的基础数据,采用液液相平衡釜对DMFH2O-CHCl3三元体系在常压、293 K下的液液相平衡进行研究.通过气相色谱对各物质平衡组成进行检测分析,分别采用NRTL和UNIQUAC模型关联了三元液液相平衡数据,并通过单纯形法获取了相关模型参数,同时结合其他各温度的相平衡数据回归获得了相平衡方程.结果表明:NRTL和UNIQUAC模型的计算值与实验值都吻合较好,平均偏差分别为0.0079和0.0076,相平衡方程回归的相关系数为0.98.

污水处理A^(2)/O工艺的数学模型构建

为了扩大污水污染成分的检测范围,增加对于富营养化污泥的分析能力,建立了应用于污水处理的A^(2)/O工艺的数学模型,根据富营养化污泥的水解过程和菌类生长过程建立A^(2)/O工艺耦合模型物料守恒模型,并对该模型的参数灵敏度加以分析。经BioWin软件分析发现,该模块对于化工厂污水成分的分析与实测结果十分接近,检测误差被严格控制在3%以内。

基于DNDC模型不同降水年型下氮肥管理对马铃薯田N_(2)O减排及增产潜力影响研究

农田N_(2)O排放和产量的形成与施肥和水分的关系密切。为了探究不同降水年型下马铃薯(Solanum tuberosum)田不同施肥方式处理下土壤N_(2)O减排增产潜力,进而提出基于减排和稳产增产的优化施肥方式,利用沈阳市1990—2019年共30年降水数据进行降水年型划分,以马铃薯田为研究对象,设置4种施氮梯度,分别为不施氮肥(0 kg·hm^(−2))、低氮(60 kg·hm^(−2))、中氮(120 kg·hm^(−2))、高氮(180 kg·hm^(−2))4种施氮水平,采用静态箱—气相色谱法对土壤N_(2)O气体排放进行田间原位观测,进而运用DeNitrification-DeComposition(DNDC)模型探究在不同降水年型下马铃薯田增产减排的潜力。结果表明,(1)DNDC模型可以较为准确模拟马铃薯田N_(2)O排放通量以及产量情况,模型效率指数分别在0.45—0.88和0.85—0.91之间。(2)运用DNDC模型模拟研究不同降水年型下马铃薯田增产减排的最优施肥量,结果发现随施肥量增加马铃薯产量均呈现出先增加后减少的变化趋势,而N_(2)O排放通量呈现出一直增加的变化趋势。在增产减排的前提下得出干旱年的优化施肥量为45—60 kg·hm^(−2),平水年为75—90 kg·hm^(−2),湿润年为105—120 kg·hm^(−2)。(3)在各年型优化施肥量的前提下,提出了适宜的施肥深度以及施肥比例。在干旱年和平水年,随施肥深度增加产量先增加后减少,N_(2)O排放通量却一直增加,当施肥深度为10—15 cm、基追比例为50%+50%时,模型模拟达到最优产量;而在湿润年,随施肥深度增加产量和N_(2)O排放均增加,当施肥深度为20 cm、基追比例为60%+40%时模型模拟达到最优产量。

长期施用有机肥情景下华北平原旱地土壤固碳及N_(2)O排放的空间格局

【目的】研究施用有机肥对农田土壤固碳及温室气体排放的综合影响,为减缓全球气候变暖提供理论指导。【方法】基于长期定位试验点观测数据,利用验证后的机理过程模型——SPACSYS,结合区域数据库及ArcGIS,模拟2010-2050年华北平原旱地3种施肥情景(等氮量)即单施化肥情景(NPK)、50%化肥配施50%有机肥情景(NPKM(5﹕5))和30%化肥配施70%有机肥情景(NPKM(3﹕7))下,土壤年均固碳速率(SOC_(SR))、土壤N_(2)O年均排放量和年均净全球增温潜势(NGWP)的空间格局。【结果】华北平原旱地SOC_(SR)表现为东部较高、西部较低,较高的地区主要包括江苏省和山东省。相关分析结果表明,SOC_(SR)与初始土壤有机碳含量呈显著负相关,逐步线性回归分析进一步表明,初始土壤有机碳含量、年均温和土壤pH是影响SOC_(SR)的3个重要因子,共解释其变异的24%。土壤N_(2)O年均排放量表现为中部较高、北部和南部较低,较高的地区主要包括山东省部分地区和江苏省。相关分析结果表明,土壤N_(2)O年均排放量与初始土壤有机碳含量呈显著正相关。总体来看,与NPK情景相比,NPKM(5﹕5)和NPKM(3﹕7)两种情景均增加华北平原旱地SOC_(SR)、降低土壤N_(2)O年均排放量,其中SOC_(SR)(233和236 kg C·hm^(-2)·a^(-1))分别增加了79%和82%,土壤N_(2)O年均排放量(15.8和14.4 kg N·hm^(-2)·a^(-1))分别降低了21%和28%,NGWP(6.6和5.9 t CO_(2)-eq·hm^(-2)·a^(-1))分别降低了26%和34%。【结论】长期来看,相比传统的单施化肥模式,化肥配施有机肥有利于华北平原旱地土壤固碳、土壤N_(2)O减排和减缓温室效应。

秸秆还田种类对稻田N_(2)O排放及硝化反硝化微生物的影响

以太湖流域典型单季稻田的原状土柱为研究对象,通过设置温室土柱试验,同步监测3种秸秆(水稻秸秆RS、小麦秸秆WS、玉米秸秆MS)施用下水稻各生长期N_(2)O排放、水稻产量和土壤理化因子,同时定量化分析多个N_(2)O排放相关菌群及功能基因的丰度,以阐明N_(2)O排放对不同种类秸秆施用引发的微生物响应机制,筛选控制单季稻田N_(2)O减排增效最佳的秸秆种类。结果表明:与对照相比,RS、WS和MS处理下水稻生长期N_(2)O排放量分别增加162.32%、107.11%和9.48%,其中RS处理显著高于MS处理。水稻生育期内,土壤氨氧化菌(AOA、AOB)和反硝化菌群落(nirS、nosZ)丰度均呈现先上升后下降的变化趋势。与对照相比,拔节期RS处理显著增加AOA、AOB、nirS和nosZ拷贝数,MS和WS处理对上述功能基因丰度均无显著影响。各生育期土壤NH_(4)^(+)-N含量整体高于NO_(3)^(–)-N含量,二者均在水稻分蘖期达到峰值,而后随水稻生长不断降低,同一时期不同秸秆处理之间二者无显著性差异。相关性分析和结构方程模型(SEM)结果表明,土壤AOB丰度和土壤NH_(4)^(+)-N含量是直接影响稻田土壤N_(2)O排放的主要因素。综合考虑不同类型秸秆还田后土壤理化因子、水稻产量和微生物丰度变化,玉米秸秆是减缓太湖流域单季稻田N_(2)O排放且提高产量的最优秸秆还田种类。

基于DNDC模型的设施菜地N_(2)O减排潜力评估

设施菜地因水肥投入高而导致大量N_(2)O排放已成为当前研究热点。N_(2)O作为主要温室气体之一,探寻N_(2)O减排潜力不仅可为设施菜地碳减排方案的制定提供一定参考,还可为实现我国“双碳”目标提供科学依据。本研究以京郊典型设施黄瓜-番茄系统为研究对象,通过田间试验与DNDC模型相结合的方法,基于田间观测数据对模型进行校验,然后以农民常规种植模式为基线情景,改变田间管理措施(灌溉方式、施氮量、有机肥替代化肥等)和调控土壤理化性质[土壤有机碳(SOC)、pH等]为替代情景,运用DNDC模型通过1250次模拟得到单一情景和多组合情景下N_(2)O排放量,并评估其减排潜力。结果表明,DNDC模型能够较好地模拟设施菜地土壤温湿度、蔬菜产量和N_(2)O排放量。基线情景下N_(2)O排放总量为12.18 kg(N)∙hm^(−2)。单因子情景分析表明,设施菜地N_(2)O减排潜力变幅为12.23%~17.58%。敏感性指数显示N_(2)O排放对土壤pH调控和化肥减施的响应比对其余单因子较为敏感,其中相比于基线情景,1.2倍土壤pH情景和减施30%化肥情景N_(2)O排放量分别降低15.60%和14.86%。多组合因子情景表明,与基线情景相比,同时采用滴灌、减少30%的化肥施氮量和减施30%有机肥组合情景,可降低31.69%的N_(2)O排放。而相同组合在低SOC及高pH的土壤情景中N_(2)O减排潜力可进一步降低,达到55.58%[6.77 kg(N)∙hm^(−2)]。可见,DNDC模型可较好地模拟田间环境,克服田间试验中有限的处理设置和较高的监测成本等局限性,从而为设施菜地N_(2)O排放定量评估和减排评价提供了一个较好的解决方案。DNDC对设施菜地N_(2)O排放的单因子情景和组合情景的模拟结果表明,结合土壤理化性质调控和水肥管理措施优化具有较大的N_(2)O减排潜力。