围垦对滨海稻田土壤N2O还原潜力的影响

稻田湿地生态系统的N₂O还原消耗潜力对缓解大气温室气体效应具有重要意义，而滨海自然湿地围垦改造成稻田后耕层土壤的N₂O还原速率及其微生物机制却鲜有报道。选取崇明岛光滩湿地为对照（WK0），比较研究不同围垦年限（19、27、51、86 a）的围垦区稻田耕作层土壤N₂O还原速率演替规律及其微生物数量变异特征。结果表明，土壤总有机碳含量（TOC）随围垦年限增长而显著增加，而土壤pH值、SO₄^2-浓度和EC值则均随围垦年限增长而呈逐渐下降趋势。土壤N₂O还原速率随围垦年限增长而显著增加，其中围垦86 a稻田土壤达到25.5 μg N₂O·g^-1·d^-1，与光滩湿地相比增加了58.4%。定量PCR结果发现，功能基因nosZ Ⅰ和nosZ Ⅱ拷贝数也随着围垦年限增长而显著增加，其中围垦86 a的稻田土壤功能基因分别为1.72×10⁸ copies·g^-1和4.36×10⁸ copies· g^-1，比光滩湿地稻田高出一个数量级。相关性分析发现土壤N₂O还原速率与功能基因nosZ Ⅰ拷贝数呈显著正相关，而功能基因nosZ Ⅱ拷贝数随围垦年限的增加率远高于功能基因nosZ Ⅰ；N₂O还原速率、功能基因nosZ Ⅰ、nosZ Ⅱ拷贝数与3个土壤理化指标（pH、EC、SO₄^2-）均呈负相关。因此，围垦造田促进了滨海湿地土壤N₂O还原过程，而功能基因nosZ Ⅰ数量的大幅增加是N₂O还原速率增加的重要原因。     

不同质地黑土净氮转化速率和温室气体排放规律研究

为探讨黑龙江省半干旱地区不同质地黑土的净氮转化速率和温室气体排放规律,以壤砂土和粉壤土为研究对象开展室内培养试验,对土壤净硝化速率和净矿化速率、N2O和CO2排放速率与累积排放量进行研究。结果表明:7d培养期间壤砂土的平均净矿化速率和CO2平均排放速率分别为0.49mgN kg-1 d-1和0.30mgCO2-C kg-1 h-1,显著低于粉壤土的平均净矿化速率(1.37 mgN kg-1 d-1)和CO2平均排放速率(0.47mgCO2-C kg-1 h-1)。壤砂土的平均净硝化速率和N2O平均排放速率分别为1.65mgN kg-1 d-1和212.6ngN2O-N kg-1 h-1,显著低于粉壤土的5.02mgN kg-1 d-1和521.3ngN2O-N kg-1 h-1。壤砂土和粉壤土的N2O排放比率分别为0.081%~0.301%和0.210%~0.254%。研究表明,土壤质地显著影响土壤净氮转化速率和温室气体排放,壤砂土较低的pH、有机碳和水溶性有机碳含量是导致其净硝化速率、净矿化速率以及N2O、CO2排放速率显著低于粉壤土的主要原因。     

3种遥感产品检测黄土高原森林变化及差异比较

基于Landsat Vegetation Continuous Fields（LVCF）、MODIS Vegetation Continuous Fields（MVCF）和MODIS Land Cover（MODLC）等遥感产品和森林清查数据（NFI）检测2000-2015年黄土高原森林分布及变化。结果表明:1）2000-2015年黄土高原森林覆盖度升高，基于LVCF和MVCF的全区森林覆盖度均值分别由2000年的7.8%和9.6%增加到2015年的9.7%和13.2%。2）遥感产品估算的森林分布空间格局和面积差异较大，基于LVCF、MVCF和MODLC估算的黄土高原森林面积在2000年分别为726.6×10⁴、604.7×10⁴ hm²和325.1×10⁴ hm²，2015年分别为926.2×10⁴、998.3×10⁴ hm²和400.1×10⁴ hm²。3）遥感产品估算的省级尺度上森林面积与NFI的不一致性因省份和年份而异，LVCF与NFI一致性整体略优于MVCF，MODLC与NFI差异最大且估算的森林面积远低于LVCF、MVCF和NFI。4）遥感产品检测的陕西和山西2省的森林面积增加值与NFI一致性高于宁夏；基于遥感产品估算的宁夏森林面积及增加幅度均远低于NFI。     

Yield performance of spring wheat improved by regulated deficit irrigation in an arid area

A field experiment was conducted in 2003 and 2004 growing seasons to evaluate the effects of regulated deficit irrigation on yield performance in spring wheat (Triticum aestivum) in an arid area. Three regulated deficit irrigation treatments designed to subject the crops to various degrees of soil water deficit at different stages of crop development and a no-soil-water-deficit control was established. Soil moisture was measured gravimetrically in the increment of 0–20 cm every five to seven days in the given growth periods, while that in 20 increments to 40, 40–60, 60–80, and 80–100 cm depth measured by neutron probe. Compared to the no-soil-water-deficit treatment, grain yield, biomass, harvest index, water use efficiency (WUE), and water supply use efficiency (WsUE) in spring wheat were all greatly improved by 16.6–25.0, 12.4–19.2, 23.5–27.3, 32.7–39.9, and 44.6–58.8% under regulated deficit irrigation, and better yield components such as thousand-grain weight, grain weight per spike, number of grain, length of spike, and fertile spikelet number were also obtained, but irrigation water was substantially decreased by 14.0–22.9%. The patterns of soil moisture were similar in the regulated deficit treatments, and the soil moisture contents were greatly decreased by regulated deficit irrigation during wheat growing seasons. Significant differences were found between the no-soil-water-deficit treatment and the regulated soil water deficit treatments in grain yield, yield components, biomass, harvest index, WUE, and WsUE, but no significant differences occurred within the regulated soil water deficit treatments. Yield performance proved that regulated deficit irrigation treatment subjected to medium soil water deficit both during the middle vegetative stage (jointing) and the late reproductive stages (filling and maturity or filling) while subjected to no-soil-water-deficit both during the late vegetative stage (booting) and the early reproductive stage (heading) (MNNM) had the highest yield increase of 25.0 and 14.0% of significant water-saving, therefore, the optimum controlled soil water deficit levels in this study should range 50–60% of field water capacity (FWC) at the middle vegetative growth period (jointing), and 65–70% of FWC at both of the late vegetative period (booting) and early reproductive period (heading) followed by 50–60% of FWC at the late reproductive periods (the end of filling or filling and maturity) in treatment MNNM, with the corresponding optimum total irrigation water of 338 mm. In addition, the relationships among grain yield, biomass, and harvest index, the relationship between grain yield and WUE, WsUE, and the relationship between harvest index and WUE, WsUE under regulated deficit irrigation were also estimated through linear or non-linear regression models, which indicate that the highest grain yield was associated with the maximum biomass, harvest index, and water supply use efficiency, but not with the highest water use efficiency, which was reached by appropriate controlling soil moisture content and water consumption. The relations also indicate that the harvest index was associated with the maximum biomass and water supply use efficiency, but not with the highest water use efficiency.     

Agronomic performance of late-season rice under different tillage,straw, and nitrogen management

In double rice-cropping system in China, zero tillage in late-season rice with straw return from early season rice is an emerging technology for saving inputs, shortening the lag time between rice crops, avoiding straw burning, and conserving natural resources. The objective of this 2-year field study was to determine the effects of tillage and straw return on N uptake, grain yield, and N use efficiency of late-season rice. Treatments were arranged in a split-plot design with four combinations of tillage and straw return as main plots and three N management practices as subplots. Tillage was either conventional soil puddling or zero tillage with newly harvested crop residue from early season rice either removed or placed on the soil surface without incorporation. The N treatments were zero-N control, site-specific N management (SSNM), and farmers’ N-fertilizer practice (FFP). Straw return regardless of tillage or N management did not reduce rice yield. In the second year, straw return significantly increased grain yield in the zero-N control. Chlorophyll meter readings at heading and total N uptake at maturity were higher with straw return in the zero-N control, suggesting that straw provides nutrients to rice in the late growing period. Zero tillage did not reduce N uptake, grain yield, and N use efficiency compared with conventional tillage. Despite large differences in timing and rate of N application between FFP and SSNM, these two N treatments resulted in comparable N uptake and grain yield of late-season rice regardless of tillage and straw return. These results suggest that zero tillage after early rice with straw return could replace conventional tillage for late rice in the double rice-cropping system in China.     

Forest floor vegetation plays an important role in photosynthetic production of boreal forests

We estimated gross photosynthetic production (GPP) of the forest floor vegetation in a 40-year-old Scots pine stand in southern Finland with three different methods: measurements of CO₂ exchange of single leaves of field and ground layer species, measurement campaigns of forest floor net CO₂ efflux at different irradiances with a manually operated soil chamber, and continuous measurements of forest floor net CO₂ efflux with an automatic transparent chamber system. We upscaled the measured light response curves from the manual soil chambers using the biomass distribution of the forest floor species, a modelled seasonal pattern of photosynthetic capacity and a model of light extinction down the canopy. Leaf gas exchange measurements as well as measurements of net CO₂ efflux with the manual chamber indicated saturation of photosynthesis at relatively low (50–400 μmol m⁻² s⁻¹) light levels. Leaf and patch level measurements gave similar rates of photosynthetic CO₂ fixation per unit leaf biomass suggesting that reduction in photosynthetic production due to within-patch shading was small. Upscaling of photosynthetic production to the stand level and continuous measurements with the automatic soil chambers indicated that momentary photosynthetic production by the forest floor vegetation in the summer was typically about 2 μmol m⁻² (ground) s⁻¹. Cumulative upscaled GPP over the period of no snow (from 20 April to 20 November) in year 2003 was 131 g C m⁻². Continuous measurements with the automatic soil chamber system were in line with the upscaling, the cumulative GPP being 83 g C m⁻² and the seasonal pattern of photosynthetic rate similar to that of the upscaled photosynthesis.     

Soil-moisture-index spectrum reconstruction improves partial least squares regression of spectral analysis of soil organic carbon

Precision Agriculture - Accurate remote estimation of the soil organic carbon (SOC) content can be useful for site-specific soil management and precision agriculture. However, spectral reflectance...     

秸秆和Eh对稻田土壤溶解性有机质组成及金属释放的影响

为探究秸秆添加对氧化还原条件变化下稻田土壤重金属释放的影响,本文选取典型重金属污染稻田土壤,通过微宇宙试验结合三维荧光光谱等手段,分析了土壤溶液化学性质、溶解性有机质（DOM）、金属释放之间的动态关系。结果表明：添加秸秆增加了厌氧期Fe、Mn、As、Cd等金属的释放,同时影响了DOM组成。土壤DOM中类蛋白（C3）含量在培养期总体降低（P<0.05）;类腐殖质含量呈现厌氧期上升、好氧期下降的趋势。结构方程模型（SEM）分析显示,Eh的变化与Mn和As的溶出显著负相关（路径系数分别为-0.662和-0.528,P<0.01）,同时,Eh还通过影响土壤类腐植酸C2（路径系数-0.816,P<0.01）控制As的释放（路径系数0.244,P<0.05）。因此,稻田土壤干湿交替造成的Eh变化和秸秆还田措施不仅可直接影响重金属的溶出,也可通过DOM含量和组成进一步控制其释放。     

Multi-Temporal Detection of Rice Phenological Stages Using Canopy Spectrum

Information on rice phenology is essential for yield estimation and crop management. To test the ability of remote sensing in detecting multiple phenological stages, paddy rice canopy spectrum was measured by a hand-held radiometer. Normalized difference vegetation index(NDVI) was calculated from spectrum, and the slope of NDVI was obtained as its difference. We evaluated the response of NDVI and its slope to rice growth with a comparison of two late-season rice cultivars. The results showed that NDVI and its slope curves had distinct variation corresponding to rice development and they could be used as cultivar-independent phenological indicators. The dates of flooding and transplanting, tillering, panicle development, heading and flowering, maturity, harvest stages, and even field management practices, could be deduced from these indicators. ‘NDVI ≤ 0' could be used as a single threshold for the detection of flooding and transplanting. The largest spike in the curve of the NDVI slope indicated the duration of tillering stage. The next spike corresponded to panicle development. The heading and flowering stage was characterized by the maximum NDVI and the change of NDVI slope from positive to negative. At the maturity stage, NDVI decreased continuously, and its slope fluctuated just below zero. When rice grains were completely mature and ready for harvest, NDVI decline was accelerated. At harvest, NDVI slope reached its minimum value. The distinction between heading and maturity stages was obscure, most likely due to NDVI saturation at high biomass. The study might provide references for paddy rice phenology determination through remote sensing images.