Maize straw application as an interlayer improves organic carbon and total nitrogen concentrations in the soil profile: A four-year experiment in a saline soil

Soil salinization is a critical environmental issue restricting agricultural production.Deep return of straw to the soil as an interlayer (at 40 cm depth) has been a popular practice to alleviate salt stress.However,the legacy effects of straw added as an interlayer at different rates on soil organic carbon (SOC) and total nitrogen (TN) in saline soils still remain inconclusive.Therefore,a four-year (2015–2018) field experiment was conducted with four levels (i.e.,0,6,12and 18 Mg ha~(–1)) of straw returned as an interlayer.Compared with no straw interlayer (CK),straw addition increased SOC concentration by 14–32 and 11–57%in the 20–40 and 40–60 cm soil layers,respectively.The increases in soil TN concentration (8–22 and 6–34%in the 20–40 and 40–60 cm soil layers,respectively) were lower than that for SOC concentration,which led to increased soil C:N ratio in the 20–60 cm soil depth.Increases in SOC and TN concentrations in the 20–60 cm soil layer with straw addition led to a decrease in stratification ratios (0–20 cm:20–60 cm),which promoted uniform distributions of SOC and TN in the soil profile.Increases in SOC and TN concentrations were associated with soil salinity and moisture regulation and improved sunflower yield.Generally,compared with other treatments,the application of 12 Mg ha~(–1) straw had higher SOC,TN and C:N ratio,and lower soil stratification ratio in the2015–2017 period.The results highlighted that legacy effects of straw application as an interlayer were maintained for at least four years,and demonstrated that deep soil straw application had a great potential for improving subsoil fertility in salt-affected soils.

Characteristics of soil organic carbon andtotal nitrogen storages for differentland-use types in Central Yunnan Plateau

Two-factor analysis of variance and redundancy analysis were used to analyze the characte-ristics of soil organic carbon total nitrogen storage in garden land,forestland,grassland,farmland,and bare land in the Dachunhe watershed of Jinning District,Kunming City,Yunnan Province,China.The effects of the soil organic carbon,total nitrogen stratification ratio,soil physical and chemical factors on the storage characteristics of organic carbon and total nitrogen of different land-use types were analyzed.The results show that the rates of carbon and nitrogen stratification in soil from 0-20 cm and 40-60 cm of the same land-use types differed are statistically significant(P<0.05).The organic carbon and total nitrogen stratification ratio SR1 of garden land soil are 38.5%and 25.3%,respectively,which are higher than SR^(2).The soil organic carbon and total nitrogen stratification ratio SR^(2) of different land-use types are greater than SR1.There are statistically significant differences in the SR^(2) soil organic carbon and total nitrogen stratification ratios(P<0.05).Soil organic carbon and total nitrogen storage of diffe-rent land-use types gradually decrease with increasing soil depth,with the maximum soil organic carbon and total nitrogen storage in the 0-20 cm soil layer.Soil organic carbon and total nitrogen sto-rage at the same soil depth are significantly different(P<0.05).Soil organic carbon and total nitrogen storage in the garden land are greater than those in the other land-use types.Soil organic carbon and total nitrogen storage in 0-20 cm garden land are 4.96 and 3.19 times than those in bare land,respectively;soil organic carbon and total nitrogen storage are explained by 93.66%and 1.53%in redundancy analysis RDA1 and RDA2,respectively.All physicochemical factors except Available Phosphorus and pH are statistically significance with carbon and nitrogen storage(P<0.05).Soil cationic exchange capacity,Available Phosphorus,C/N ratio,and Moisture Content are positively correlated with organic carbon and total nitrogen storage.In contrast,soil Bulk Density is negatively correlated with organic carbon storage and total nitrogen storage.Available Phosphorus,C/N ratio,and Moisture Content are the main factors promoting soil organic carbon and total nitrogen accumulation.

Characteristics of Soil Organic Carbon, Total Nitrogen, and C/N Ratio in Chinese Apple Orchards

Soil organic carbon and nitrogen are used as indexes of soil quality assessment and sustainable land use management. At the same time, soil C/N ratio is a sensitive indicator of soil quality and for assessing the carbon and nitrogen nutrition balance of soils. We studied the characteristics of soil organic carbon and total nitrogen by investigating a large number of apple orchards in major apple production areas in China. High apple orchard soil organic carbon content was observed in the provinces of Heilongjiang, Xinjiang, and Yunnan, whereas low content was found in the provinces of Shandong, Henan, Hebei, and Shaanxi, with the values ranging between 6.44 and 7.76 g·kg-1. Similar to soil organic carbon, soil total nitrogen content also exhibited obvious differences in the 12 major apple producing provinces. Shandong apple orchard soil had the highest total nitrogen content (1.26 g·kg-1), followed by Beijing (1.23 g·kg-1). No significant difference was noted between these two regions, but their total nitrogen content was significantly higher than the other nine provinces, excluding Yunnan. The soil total nitrogen content for Xinjiang, Heilongjiang, Hebei, Henan, and Gansu was between 0.87 and 1.03 g·kg-1, which was significantly lower than that in Shandong and Beijing, but significantly higher than that in Liaoning, Shanxi, and Shaanxi. Six provinces exhibited apple orchard soil C/N ratio higher than 10, including Heilongjiang (15.42), Xinjiang (13.38), Ningxia (14.45), Liaoning (12.24), Yunnan (11.03), and Gansu (10.63). The soil C/N ratio was below 10 in the remaining six provinces, in which the highest was found in Shaanxi (9.47), followed by Beijing (8.98), Henan (7.99), and Shanxi (7.62), and the lowest was found in Hebei (6.80) and Shandong (6.05). Therefore, the improvement of soil organic carbon should be given more attention to increase the steady growth of soil C/N ratio.

Profile Distribution and Storage of Soil Organic Carbon in an Aquic BrownSoil as Affected by Land Use

Many attempts have been made to estimate the soil organic carbon (SOC) storage under different land uses, especiallyfrom the conversion of forest land or grassland into cultivated field, but limited reports were found on the estimation ofthis storage after cultivated field converted into woodland or grassland, especially in small scales. This study is aimed toinvestigate the dynamics of SOC concentration, its storage and carbon /nitrogen (C/N) ratio in an aquic brown soil at theShenyang Experimental Station of Ecology, Chinese Academy of Sciences under four land use patterns over 14 years. Thefour land use patterns were paddy field (PF), maize field (MF), fallow field (FF) and woodland (WL). In each pedon at 0-150cm depth, soil samples were collected from ten layers. The results showed that the profile distribution of SOC was differentunder different land uses, indicating the effect of land use on SOC. Soil organic carbon was significantly related with soiltotal N, and the correlation was slightly closer in nature ecosystems (with R2=0.990 and P<0.001 in both WL and FF, n=30)than in agroecosystems (with R2=0.976 and P<0.001 in PF, and R2=0.980 and P<0.001 in MF, n=30). The C/N ratio in theprofiles decreased generally with depth under the four land use patterns, and was comparatively higher in WL and lowerin PF. The C/N ratio of the FF was closer to that in the same soil depths of MF than to that of PF. Within 100 cm depth, theannual sequestration of SOC was 4.25, 2.87, and 4.48 t ha-1 more in WL than in PF, MF and FF, the annual SOC increasingrate being 6.15, 3.26, and 5.09 % higher, respectively. As a result, the SOC storage was significantly greater in WL than inany of the other three land use patterns, P=0.001, 0.008, and 0.008 as compared with PF, MF, and FF, respectively, whilethere was no significant difference among the other three land uses. It is suggested that woodland has the potential tomake a significant contribution to C storage and environmental quality.

Assessment of Soil C and N Stocks and Fractions across 11 European Soils under Varying Land Uses

In this study, we measured the stocks and pool sizes of soil organic carbon (SOC) and total soil nitrogen (TN), and their natural 13C and 15N abundance across a wide range of temperate European ecosystems. The objectives were to examine any distinct isotope patterns with land use or climate, and how C and N in these different ecosystems are distributed among soil organic matter (SOM) fractions to better predict soil C and N dynamics and longer term persistence. Soils were sampled to 30 cm depth at 11 sites of the Nitro Europe (NEU) network and included four forests, three grasslands and four croplands. Surface soil samples were fractionated using a combined size-density fractionation protocol separating light (LF) from heavy particulate organic matter (hPOM) by density and silt-from-clay-associated SOM by size. Down-profile natural abundance 15N patterns pointed towards a closed N cycle in the forest sites, while 13C patterns suggested differences in plant water use efficiency across the C3 grassland sites. The forests and grassland sites stored the majority of surface SOC and TN in the LF and hPOM pools. Sustained sequestration of C and N in these rather labile pools will rely on management practices that minimize soil disturbance and increase C input. We also found that the mineral fraction (silt and clay) in the cropland soils stored less C and N per unit of fraction mass compared to the forests and grasslands, which points towards a lower mineral-OM stabilization efficiency of cropland soils. Finally, our study revealed total POM (LF plus hPOM) as a strong predictor of SOC and TN differences, particularly among the non-cropped sites. This study shows that these sites, independent of soil type and climate, store a large fraction of C and N in POM pools that are particularly vulnerable to soil disturbance such as caused by land use change.

Growing Cover Crops to Improve Biomass Accumulation and Carbon Sequestration: A Phytotron Study

Cover crop system has shown a potential approach to improving carbon sequestration and environmental quality. Six of each winter and summer cover crops were subsequently grown in two soils, Krome gravelly loam soil (KGL), and Quincy fine sandy soil (QFS), in phytotrons at 3 temperatures (10/20, 15/25, 25/30oC for winter/summer cover crops) to investigate their contributions for carbon (C) sequestration. Among winter cover crops, the highest and the lowest amounts of C accumulated were by bellbean (Vicia faba L.), 597 g/m2 and white clover (Trifolium repens), 149 g/m2, respectively, in the QFS soil. Among summer cover crops, sunn hemp (Crotalaria juncea L.) accumulated the largest quantity of C (481 g/m2), while that by castorbean (Ricinus communis) was 102 g/m2 at 30oC in the KGL soil. The mean net C remained in the residues following the 127 d decomposition were 187 g/m2 of C (73% of the total) and 91 g/m2 (52% of the total) for the winter and summer cover crops, respectively. Following a whole cycle of winter and summer cover crops grown, the mean soil organic C (SOC) increased by 13.8 and 39.1% in the KGL and QFS soil, respectively, compared to the respective soils before. The results suggest that triticale, ryegrass, and bellbean are the promising winter cover crops in the QFS soil, while sunn hemp, velvetbean (Mucuna pruriens), and sorghum sudangrass (Sorghum bicolor &#215;S. bicolor) are recommended summer cover crops for both soils under favorable temperatures.

Complementary effects of organic and mineral fertilizers on maize production in the smallholder farms of Meru South District, Kenya

Low soil fertility is a major constraint to maize production in the small holder farms of Meru South District. This is mainly attributed to the mining of nutrients due to cropping without external addition of adequate nutrients. Mineral fertilizers are expensive hence un affordable by most small holder farmers. The use of organic matter to increase and maintain soil fertility is being considered as a solution to help the low-income small holder farmers. A study was conducted in Mucwa location, Meru South District to determine the levels of complementarity between organic and mineral N amendments on maize yields and their influence on soil chemical properties. The experiment was set in a complete randomized block design (CRBD) with three replicates. The treatments were compared with the response obtained from control. The general soil fertility parameters changed slightly with Calcium, Magnesium and Potassium increasing in all treatments. The organic Carbon and total Nitrogen was higher in treatments that received sole organic N sources than in sole mineral N and a combination of organic and mineral N sources. The highest maize grain yield of 4.8 t·ha-1 and 4.2 t·ha-1 were realized from sole application of calliandra during the 2005 Short rains and 2006 Long rains cropping seasons. Generally the maize grain yields were lower in treatments with mineral N alone compared to the treatments with organics. Treatments with sole calliandra and sole tithonia had the highest benefit cost ratio (BCR), followed closely by manure treatment. More so, integration of organic and mineral N sources resulted to higher net benefit and BCR than the application of the recommended rate of mineral fertilizers. Results obtained indicated that the use of either organic or combined organic/mineral N soil amendment appear to be superior to using mineral amendment sources alone.

Spatial Distribution of Soil Organic Matter Using Geostatistics: A Key Indicator to Assess Soil Degradation Status in Central Italy

Soil organic matter (SOM) content is one of the main factors to be considered in the evaluation of soil health and fertility. As timing, human and monetary resources often limit the amount of available data, geostatistical techniques provide a valid scientific approach to cope with spatial variability, to interpolate existing data and to predict values at unsampled locations for accurate SOM status survey. Using geostatistical and geographic information system (GIS) approaches, the spatial variability of some physical and chemical soil parameters was investigated under Mediterranean climatic condition in the Abruzzo region of central Italy, where soil erosion processes accelerated by human induced factors are the main causes of soil degradation associated with low SOM content. Experimental semivariograms were established to determine the spatial dependence of the soil variables under investigation. The results of 250 soil sampling point data were interpolated by means of ordinary kriging coupled with a GIS to produce contour maps distribution of soil texture, SOM content related to texture, and C/N ratio. The resulting spatial interpolation of the dataset highlighted a low content of SOM in relation with soil texture in most of the surveyed area (87%) and an optimal C/N ratio for only half of the investigated surface area. Spatial location of degraded area and the assessment of its magnitude can provide decision makers with an accurate support to design appropriate soil conservation strategies and then facilitate a regional planning of agri-environmental measures in the framework of the European Common Agricultural Policy.

土壤C/N比对烤烟碳氮代谢关键酶活性和烟叶品质影响的研究

2009年采用盆栽试验,在河南农业大学科教园区通过添加腐熟的小麦秸秆来调节土壤的碳氮比,进而研究土壤碳氮比对烤烟碳氮代谢关键酶活性和烟叶品质的影响。结果表明：随着土壤碳氮比的增加,硝酸还原酶、转化酶和淀粉酶的活性逐渐增加,烤后烟叶总糖和还原糖的含量、中性香气物质的总量、还原糖/烟碱有不同程度的增加,烟碱、总氮含量以及氮碱比逐渐减少。土壤碳氮比在24~28之间时,有利于促进烤烟碳氮代谢平衡,协调烤后烟叶化学成分。

元素分析仪(Elementar Vario MACRO)测定石灰性土壤C、N时存在问题的探讨

壤全氮、土壤有机质的测定对农业生产和科学研究都有重要意义。因此在许多实验室里,土壤全氮、土壤有机质都被作为一项常规分析项目。土壤全氮量的测定百余年来沿用杜马氏法和凯氏定氮法。测定土壤有机质的方法主要有3种:干烧法、化学氧化法、灼烧法,1989年农业部颁布了国标GB9843-88《土壤有机质测定法》。近年来使用元素分析仪(Elementar Vario MACRO)测定土壤C、N也越来越广泛,元素分析仪是一台用于快速,定量测定元素C、H、N、S的全自动分析仪。用元素分析仪测定C、H、N的方法属于灼烧法,灼烧温度为960摄氏度,对酸性、中性土壤的测定无疑是省时准确的首选。石灰性土壤中由于碳酸盐的存在,在高温灼烧时碳酸盐分解,形成CO2,使土壤有机质的测定结果偏高。降低燃烧管温度测定(630摄氏度),由于样品用锡箔纸包裹,锡箔纸在燃烧管内燃烧生成氧化锡为放热反应,增加燃烧管内的温度高于设定温度,增加碳酸钙的分解测定值偏高,燃烧管温度设定在低于碳酸盐分解点时仪器密封不严实,使测定结果偏低。用盐酸处理土壤中碳酸盐,其后测定有机质时,因土壤中的富里酸溶于酸,使测定结果偏低。因此元素分析仪不适于石灰性土壤有机质的测定。

好气厌气培养下碳源及C／N对土壤供氮特性的影响

研究了添加化学氮肥、稻秸和淀粉的土壤在好气、厌气培养下的供氮特征。（１）单施化学氮肥好气培养，土壤中矿物态氮含量始终高于厌气培养；单施稻秸厌气培养，土壤中矿物态氮含量高于好气培养。（２）培养６０ｄ时，Ｃ／Ｎ为１０的处理好气培养，土壤中矿物态氮含量高于厌气培养；Ｃ／Ｎ＞２０的处理厌气培养，土中矿物态氮含量处于较高水平。（３）添加淀粉使好气培养土壤中矿物态氮含量大幅度减少，厌气培养则变化不大，Ｃ／Ｎ相同的处理，好气培养下添加淀粉的土壤中矿物态氮的减少量为厌气状态下的１．８倍。

影响C_4草本植物C/N比值变化的因素与土壤有机C积累的关系

文章对采自贵州从低海拔的东部到高海拔的西部且大致平行的石灰岩和砂岩两地带均生长的3种C4草本植物,即巴茅(Miscanthus floridulus)、白茅(Imperata cylindrica)和类芦(Neyraudia reynaudiana),以及相对应的土壤表层样品,进行了营养元素和C同位素组成分析;研究营养元素含量随着海拔的不同而出现的变化趋势,以及这些元素之间的相互协变作用,尤其是Ca和N之间的相互协变作用对植物的N含量、C/N比值和δ13C值的影响,以了解植物的C/N比值(指示植物残留物质量的一种标志)与土壤有机C积累的关系。研究结果表明,植物的N含量和δ13C值具有随海拔的上升而显著增大趋势,而植物的C/N比值在砂岩地区虽有减小的趋势,在石灰岩地带则没有。对所研究的C4草本植物来说,在土壤pH值为5.8的中性条件下显示出Ca的最大吸收,因此,Ca与其他营养元素之间的协变模式在两种土壤类型中表现出相反的倾向,并存在土壤交换性Ca的边界浓度:当土壤可交换性Ca的含量为2.24 mg/g,相应土壤的pH值在5.8以下时,随着土壤可交换性Ca浓度的增大,植物的N含量上升,而植物的C/N比值会显著降低;当Ca在边界浓度以上时,随着土壤可交换性Ca浓度的增大,植物的N含量下降,而植物的C/N比值有增加的趋势。由此可见。

增温施肥对农田土壤有机碳和全氮含量及δ^(13)C、δ^(15)N值的影响

农田土壤是重要的碳氮库,对气候变化极其敏感,但土壤碳氮循环对气候变化的响应目前还不清楚。在全球变暖背景下,为了实现我国碳达峰、碳中和目标,研究增温对土壤有机碳、全氮含量及其碳氮同位素的影响具有重要的现实意义。本研究采用红外辐射加热器模拟全球变暖,使5 cm土壤温度增加约2℃。通过测定灌溉前后土壤有机碳和全氮含量及δ^(13)C和δ^(15)N值的变化,研究增温、施氮和灌溉对华北平原小麦田土壤碳氮库的影响。试验共设4个处理:不施氮不增温(N0T0)、不施氮增温(N0T1)、施氮不增温(N1T0)和施氮增温(N1T1)。结果表明:灌溉前,增温降低了土壤有机碳含量,0~10 cm土层N1T1处理与不增温处理(N0T0和N1T0)之间差异显著(P<0.05),10~20 cm土层N1T1处理与其他处理差异均显著(P<0.05);灌溉后,增温虽有降低土壤有机碳含量的趋势,但差异不显著;施氮条件下,增温显著提升了δ^(13)C值(P<0.05)。增温降低了土壤全氮含量,并在灌溉前10~20 cm土层和灌溉后0~10 cm土层达显著水平(P<0.05);增温提升了土壤δ^(15)N值,灌溉前0~10 cm土层N0T0处理与增温处理(N0T1和N1T1)差异显著(P<0.05),灌溉后0~10 cm土层仅N0T1和N1T0处理间差异显著(P<0.05),而10~20 cm土层增温处理(N0T1和N1T1)均与N1T0处理差异显著(P<0.05)。同一处理同一时期,土壤有机碳和全氮的含量随土壤深度的增加而降低,δ^(13)C和δ^(15)N值随深度增加而升高,但土壤有机碳和δ^(13)C值的变化差异不显著,全氮含量和δ^(15)N值的变化差异显著(P<0.05)。土壤有机碳、全氮含量及δ^(13)C和δ^(15)N值在灌溉前后的差异均不显著。连续5年的增温施氮试验表明,未来气候变暖可能会加快土壤有机碳和全氮的分解,造成更多轻组有机碳损失。灌溉在短期内不会显著改变土壤碳氮含量及δ^(13)C和δ^(15)N值,但其长期影响还需进一步探究。此外,未来研究还应该重视多因素交互作用对土壤碳氮循环的影响。

江河源冻土区土壤碳氮空间分布特征及其影响因素

江河源区是我国高寒生态安全屏障的重要区域,冻土的长期存在使其形成低温冻结环境,弱化了土壤微生物活性,抑制了土壤有机质的矿化过程,因而其近地表浅层土壤碳氮含量高。然而,土壤碳氮含量对不同冻土分区和环境因素响应的空间分异规律尚不清楚。为此,针对江河源4个不同冻土区(季节冻土区、岛状多年冻土区、不连续多年冻土区、片状连续多年冻土区)共11个样点进行植被样方调查、土壤分层采样。在分析碳氮含量的基础上,探讨了年均地温(MAGT)、活动层厚度(ALT)、海拔(ASL)、土壤深度(SD)、植被特征及土壤pH对土壤有机碳(SOC)、全氮(TN)、碳氮比(C/N)的影响。结果表明:(1)SOC、TN、C/N在片状连续多年冻土区最高,在季节冻土区最低,且与年均地温负相关,和海拔正相关;(2)江河源区SOC、TN、C/N随土壤深度的增加而降低,自表层至40cm深度整体下降幅度分别为58.45%、36.96%、17.01%;(3)SOC、TN、C/N与植被覆盖度(FVC)显著正相关(P≤0.05),与土壤pH值显著负相关(P≤0.01);(4)冗余分析表明,土壤pH、MAGT、ALT、SD、FVC是影响江河源区SOC、TN、C/N空间分布的关键因素。研究结果可为厘清气候趋暖条件下江河源区土壤碳氮空间分异规律及多年冻土热稳定性对土壤碳氮排放的影响提供科学基础,同时也有助于预测多年冻土区土壤碳氮空间变化。

CO_2浓度升高对三江平原湿地土壤碳氮含量的影响

利用开顶箱薰气室(open-top chamber,OTC),设置正常大气CO2浓度(ambient CO2)和高CO2浓度(elevated CO2,700μmol/mol)2个水平和不施氮(NN,0g/m2),常氮(MN,5g/m2)和高氮(HN,15g/m2)3个氮素水平,研究了CO2浓度升高对三江平原草甸小叶章湿地(Calamagrostis angustifolia)土壤碳氮含量的影响。结果表明,CO2浓度升高连续运行两个生长季后,湿地土壤总有机碳含量没有显著变化,不同N处理增加了0.5%～1.8%。CO2浓度升高,土壤总氮含量总体呈下降趋势。就各生长期平均值而言,CO2浓度升高使土壤NH4+—N的含量分别降低了8.2%(NN),8.9%(MN)和9.7%(HN)。CO2浓度升高使不同N处理的土壤NO3-—N含量也呈降低趋势,其中高氮水平(HN)降低最多,降幅为9.6%。土壤有效态氮是控制植物对高CO2浓度响应的关键因素。

水稻秸秆炭施用对水稻土团聚体稳定性及其碳氮分布的影响

[目的]水稻长期种植过程中大量化肥施用导致土壤结构变差,研究不同用量水稻秸秆生物炭和化肥配施对水稻土结构和碳、氮分布的影响,探索稻田优化施肥管理方式。[方法]水稻田间试验在浙江衢州进行,试验设不施肥对照(CK)、常规施肥处理(NPK)以及常规施肥基础上添加22.5 t/hm^(2)(NPK+1%B)、45 t/hm(NPK+2%B)和90 t/hm^(2)(NPK+4%B)水稻秸秆炭处理,共5个处理。水稻收获后采集0-20 cm土层样品,测定土壤及不同粒级团聚体(>2、0.25~2、0.053~0.25和<0.053 mm)的有机碳和全氮含量,评价团聚体的稳定性。[结果]与NPK处理相比,施用水稻秸秆炭4年后,土壤>0.25 mm粒级团聚体含量提高了2.43%~7.99%,<0.25 mm粒级团聚体含量降低了2.93%~9.63%,土壤有机碳和全氮含量分别提高了16.40%~45.16%和14.67%~36.69%,各指标的变幅均以NPK+4%B处理最大。与NPK处理相比,秸秆炭处理土壤中>2 mm粒级团聚体中的有机碳和全氮含量分别提高了23.96%~70.87%和19.44%~47.56%,0.25~2 mm粒级团聚体中分别提高了21.87%~49.27%和17.18%~37.47%,增幅均以NPK+4%B处理最高,而0.053~0.25和<0.053 mm粒级团聚体中的有机碳和全氮含量无显著差异(P>0.05),说明施用水稻秸秆炭4年后,增加的土壤有机碳和全氮主要积累在>0.25 mm粒级团聚体中。与NPK处理相比,秸秆炭处理水稻土C/N值提高了2.40%~5.69%,但各处理间差异不显著,而4个粒级团聚体的土壤C/N值均显著提升,且均以NPK+4%B处理提高效果最好。此外,施用水稻秸秆炭提高了>2和0.25~2 mm粒级团聚体的碳、氮贡献率6.54%~17.43%、3.67%~7.28%和5.16%~11.55%、0.57%~1.83%,降低了0.053~0.25和<0.053 mm粒级团聚体的碳、氮贡献率7.25%~29.27%、15.93%~33.68%和10.26%~26.80%、12.61%~30.78%(P<0.05)。[结论]施用水稻秸秆炭能够迅速显著提高水稻土有机碳和全氮含量,增加>0.25 mm粒级团聚体质量占比,提高>2 mm粒级团聚体中有机碳的贡献率,降低<0.25 mm粒级团聚体中有机碳和全氮贡献率,且其影响幅度与水稻秸秆炭施用量呈正比。由此可见,施用水稻秸秆炭能在一定程度上改善水稻土结构,提高水稻土碳、氮固持潜力,对保证水稻土结构稳定性和维持水稻持续高产具有重要意义。

长白山区不同海拔森林湿地土壤碳氮磷生态化学计量学特征

以长白山区不同海拔森林湿地为研究对象,研究土壤有机碳、全氮和全磷含量及其生态化学计量比的空间分布特征与海拔和土壤盐度的关系.结果表明:土壤有机碳含量在550~815 m低海拔湿地含量较高,在847~1 280 m高海拔湿地含量较低,土壤全氮含量随海拔的升高呈逐渐下降的趋势,海拔550 m的湿地含量最高;土壤全磷含量呈波动变化,海拔1 280 m含量最高.各海拔湿地土壤有机碳、全氮含量以0~5 cm土层积累较多,且随土层深度的增加而递减.C/N比值随海拔升高呈先增加后降低的趋势,海拔815 m处比值最高.C/P、N/P比值随海拔升高呈先降低后升高再降低波动变化,C/P比值在815 m海拔处最高,N/P比值在550 m海拔处最高,各海拔有机碳、全氮、全磷含量及生态化学计量比空间变异均较大.相关性分析表明:海拔与土壤C、N、N/P具有极显著的相关关系,土壤盐度与C/P、N/P有极显著相关关系、与C、N、P有显著相关关系.说明,海拔和土壤盐度是影响长白山森林湿地土壤C、N、P含量,以及生态化学计量学特征的主要环境因子.

大理典型烟区土壤有机质与全氮时空演变特征

为揭示大理烟区土壤有机质和全氮的时空变异特征,为土壤持续利用和管理提供科学依据,运用地统计学方法对巍山县和永平县烟田1982、2012和2022年3个采样时期土壤有机质(soil organic matter,SOM)、全氮(total nitrogen,TN)及碳氮比(carbon nitrogen ratio,C/N)的空间变异特征进行系统分析。结果表明,1982、2012和2022年3个时期的烟田土壤有机质平均含量分别为30.95、31.40和28.03 g·kg^(-1),总体呈先持平后下降趋势;全氮含量分别为1.52、1.76和1.65 g·kg^(-1),呈先增加后降低的趋势;碳氮比平均值分别为11.54、10.59和9.88,呈下降趋势。空间上,1982—2022年SOM和TN含量呈现东高西低,C/N呈现四周高、中间低的空间分布格局。40年间SOM和C/N空间变异受人为管理因素影响增加,TN的块金效应均在25%~75%,其空间变异受成土母质、地形、气候等自然因素和施肥、耕作等人为管理因素共同影响。植烟土壤有机质和全氮含量表现出显著的线性正相关关系。总体上,目前土壤有机质和全氮的空间分布受自然因素和施肥等人为管理因素共同影响,其含量均处于较高水平,该区域应适当减少氮肥用量,有机肥无机肥配合施用,进一步提高烤烟对肥料的养分利用率。

芦苇湿地土壤有机碳和全氮含量的垂直分布特征

利用元素分析仪,测定了芦苇湿地不同层次土壤有机碳和全N的变化.结果表明,土壤有机碳、全N及C/N随土壤深度的增加呈下降趋势.对不同月份(7、8、9和10月)而言,有机碳、全N及C/N比累积峰位于不同的土层中.土壤温度、水分及芦苇生长状况是引起分异的重要因子.7、8和10月份芦苇湿地不同层次土壤有机碳与全N呈显著相关(R2=0.73、0.73、0.71),而9月份芦苇湿地不同层次土壤有机碳与全N之间的相关性相对较差(R2=0.41).土壤C/N与土壤有机碳、全N均呈负相关,但C/N与全N的相关性强于土壤有机碳,说明C/N的大小主要决定于全N含量.

有机物料输入稻田提高土壤微生物碳氮及可溶性有机碳氮

土壤微生物量碳、氮和可溶性有机碳、氮是土壤碳、氮库中最活跃的组分,是反应土壤被干扰程度的重要灵敏性指标,通过设置相同有机碳施用量下不同有机物料处理的田间试验,研究了有机物料添加下土壤微生物量碳(soil microbial biomass carbon,MBC)、氮(soil microbial biomass nitrogen,MBN)和可溶性有机碳(dissolved organic carbon,DOC)、氮(dissolved organic nitrogen,DON)的变化特征及相互关系。结果表明化肥和生物碳、玉米秸秆、鲜牛粪或松针配施下土壤微生物量碳、氮和可溶性有机碳、氮显著大于不施肥处理(no fertilization,CK)和单施化肥处理,分别比不施肥处理和单施化肥平均高23.52%和12.66%(MBC)、42.68%和24.02%(MBN)、14.70%和9.99%(DOC)、22.32%和21.79%(DON)。化肥和有机物料配施处理中,化肥+鲜牛粪处理的微生物量碳、氮和可溶性有机碳、氮最高,比CK高26.20%(MBC)、49.54%(MBN)、19.29%(DOC)和32.81%(DON),其次是化肥+生物碳或化肥+玉米秸秆处理,而化肥+松针处理最低。土壤可溶性有机碳质量分数(308.87 mg/kg)小于微生物量碳(474.71 mg/kg),而可溶性有机氮质量分数(53.07 mg/kg)要大于微生物量氮(34.79 mg/kg)。与不施肥处理相比,化肥和有机物料配施显著降低MBC/MBN和DOC/DON,降低率分别为24.57%和7.71%。MBC和DOC、MBN和DON随着土壤有机碳(soil organic carbon,SOC)、全氮(total nitrogen,TN)的增加呈显著线性增加。MBC、MBN、DOC、DON、DOC+MBC和DON+MBN之间呈极显著正相关(P<0.01)。从相关程度看,DOC+MBC和DON+MBN较MBC、DOC、MBN、DON更能反映土壤中活性有机碳和氮库的变化,成为评价土壤肥力及质量的更有效指标。结果可为提高洱海流域农田土壤肥力,增强土壤固氮效果,减少土壤中氮素流失,保护洱海水质安全提供科学依据。