不同耕作条件下豆麦双序列轮作农田土壤温室气体的排放及影响因素研究

为了研究耕作措施对双序列轮作农田土壤温室气体的排放及影响, 采用CO₂分析仪、静态箱 气相色谱法在陇中黄土高原半干旱区对传统耕作不覆盖、免耕不覆盖、免耕秸秆覆盖和传统耕作+秸秆还田4种耕作措施下豆麦双序列轮作农田土壤温室气体(CO₂、N₂O和CH₄)的排放及影响因素进行了连续测定和分析。结果表明: 测定期内4种耕作措施下农田土壤均表现为CO₂源、N₂O源和CH₄净吸收汇; 除传统耕作不覆盖措施, 其他3种耕作措施不同程度地减少了2种轮作序列土壤的N₂O排放通量, 并显著增加了土壤对CH4的吸收。CO₂和N₂O的排放通量分别与地表、地下5 cm处、地下10 cm处的土壤温度呈极显著和显著正相关关系, 相关系数分别为0.92^**和0.89^**、0.95^**和0.91^**、0.77^*和0.62^*; 而CH₄吸收通量与不同地层的温度之间无明显的相关关系; CO₂和CH₄的通量与0~5 cm、5~10 cm的土壤含水量均呈显著正相关关系, 相关系数分别为0.69^*和0.72^*、0.77^*和0.64^*, 而与10~30 cm土壤含水量无明显相关关系; N₂O排放通量与各层次的土壤含水量之间均呈不显著负相关关系。对2种轮作序列各处理下土壤中排放的3种温室气体的增温潜势计算综合得出: 4种耕作措施中, 免耕不覆盖处理可相对减少土壤温室气体的排放量, 进而降低温室效应。     

CaO预处理提高玉米秸秆厌氧消化产沼气性能

为探索CaO预处理方法对玉米秸秆厌氧消化产沼气的影响,采用了3种不同质量百分数的CaO分别在3种不同处理时间下对玉米秸秆进行预处理,并在中温条件下进行了厌氧消化试验。试验结果表明,经过CaO预处理后,玉米秸秆的组分被不同程度破坏,厌氧消化产沼气能力有较大提高,厌氧消化时间有所缩短。综合日产气量、累积产气量、厌氧消化时间等各项参数来看,以5%CaO预处理3d的处理效果最佳,与未经预处理的效果相比,累积产气量提高了136.85%,消化时间缩短了5d,总固体（TS）和挥发性固体（VS）去除率分别提高了21.72%和7.18%,综合效果要优于其他处理组,有效地提高了玉米秸秆厌氧消化的产气量和产气效率。     

面向对象的湖北省土地覆被变化遥感快速监测

为了快速监测湖北省土地覆被变化,以HJ-CCD、TM以及ETM影像为数据源,探索出了集成面向对象技术与"3S"技术的中尺度土地覆被变化遥感流程和方法。该方法首先基于HJ-CCD影像和面向对象技术进行2010年湖北省土地覆被信息的提取,并用野外采样点对结果进行验证。在保证高精度的情况下利用向量相似性函数对湖北省2000－2005年以及2005－2010年进行变化检测,从而获得2个变化时期影像的变化区域,然后利用面向对象技术中的最邻近分类器对变化区进行自动化分类。最后分别将2期的变化结果与未变化结果融合后获得湖北省2000年、2005年和2010年的土地覆被图,在GIS中处理后建成县、市、省3级行政级别的湖北省土地覆被变化本底数据库。试验表明分类结果的总体精度为93.24%,Kappa系数为0.914;2000－2005年与2005－2010年变化检测的总体精度分别为90.88%和90.75%。同时研究发现景观破碎的地区应用面向对象技术有一定的局限性。     

根表功能细菌生物膜及其在土壤有机污染控制与修复中的潜在应用价值

土壤中的有机污染物可从根系进入植物体内,并可进一步通过食物链富集,从而威胁人群健康。植物根际微生物种类繁多、数量巨大,其中很多根际细菌可通过成膜作用在植物根表形成细菌生物膜,协助植物抵抗外界的不良环境或促进植物生长。有机污染物在被植物根系吸收的过程中,多需经过根表细菌生物膜这一特殊界面。综述了根际细菌在植物根表的成膜作用,以及根表功能细菌生物膜对污染物根际环境过程的影响及作用机理,分析了利用根表功能细菌生物膜调控植物吸收有机污染物的可行性,试图为防治土壤有机污染、降低作物污染风险、保障农产品安全等提供理论依据。     

土地利用方式对红枫湖入湖流域土壤团聚体磷含量及其形态的影响

以贵州省安顺市红枫湖入湖口4种典型土地利用方式（玉米地、菜园、林地及撂荒地）为研究对象,分别探讨了土地利用方式对0—15em和15～30cm两个层次土壤团聚体总磷含量及其形态的影响。结果表明,不同土地利用方式下,原状土壤及各粒级团聚体总磷含量均表现为玉米地〉菜园〉撂荒地〉林地。土壤各粒级团聚体磷形态含量以ResidualP、NaOH—P、NaHCO3-P为主,其中ResidualP在各土地利用方式中的含量均最高,变幅分别为玉米地28．3％～45．4％、林地61．1％-72．7％、菜园45．9％～53．0％、撂荒地52．1％-72．4％;玉米地和菜园土壤均表现为有机磷含量约为无机态含量的2倍;随团聚体粒径的减小,土壤对总磷含量的贡献率呈减少趋势,土壤团聚体对总磷含量贡献主要集中在5～2mm和2~0．5mm两个粒级中,贡献率均达77％以上,其中耕作土壤（玉米地、菜园）中5-2mm和2-0．5mm两个粒级团聚体中的磷是湖泊面源污染中磷素的主要贡献载体,也是造成湖泊富营养化的关键因素。     

喀斯特地区植烟土壤有效硼含量分布及其影响因素—— 以湘西州烟区为例

采集湘西州488个植烟土壤样本,采用传统统计学和地统计学方法分析了湘西州植烟土壤有效硼含量分布及其影响因素。结果表明：①湘西州植烟土壤有效硼含量总体上略偏高,平均值为0.728 mg/kg,变幅在0.05?～?2.21 mg/kg,变异系数为53.46%,处于适宜范围内的样本占30.00%。②植烟土壤有效硼含量在空间分布上呈斑块状分布态势,永顺县的西部为一个低值区,东部为一个高值区。③蔬菜和油菜前茬的土壤有效硼含量相对较高;黄棕壤土壤的有效硼含量极显著地高于红灰土和红壤土类型。④有效硼含量有随海拔、pH、土壤有机质含量升高而升高的趋势。     

适量有机肥与氮肥配施方可提高河西绿洲土壤肥力及作物生产效益

【目的】 河西绿洲灌溉农业区是我国主要的商品粮生产及玉米制种基地,结合当地耕作制度进行土壤有效培肥是提高农业生产效益和可持续发展的基础。本研究以河西灌漠土长期定位试验为依托,探讨了长期施用一种或者多种有机肥以及有机无机肥配合对土壤养分、土壤酶活性及产量的影响,为筛选出适于当地农业可持续发展的施肥模式提供理论依据。 【方法】 试验采用随机区组排列,除对照外,在施磷肥 (P₂O₅) 150 kg/hm2 的基础上,再设 12 个处理:单施用农家肥 120 t/hm2 (M);单施绿肥 45 t/hm2 (G);单施秸秆 10.5 t/hm2 (S);单施氮肥 375 kg/hm2 (N);农家肥 60 t/hm2 + 绿肥 22.5 t/hm2 (1/2MG);农家肥 60 t/hm2 + 秸秆 5.25 t/hm2 (1/2MS);农家肥 60 t/hm2 + 氮肥 187.5 kg/hm2 (1/2MN);绿肥 22.5 t/hm2 + 氮肥 187.5 kg/hm2 (1/2GN);秸秆 60 t/hm2 + 氮肥 187.5 kg/hm2 (1/2SN);农家肥 40 t/hm2 + 绿肥 15 t/hm2 + 氮肥 124.5 kg/hm2 (1/3MGN);农家肥 40 t/hm2 + 秸秆 3495 kg/hm2 + 氮肥 124.5 kg/hm2 (1/3MSN);农家肥 30 t/hm2 + 秸秆 2625 kg/hm2 + 绿肥 11.25 t/hm2 + 氮肥 94.5 kg/hm2 (1/4MGSN)。调查了耕层土壤有机质和速效养分含量变化以及几种主要土壤酶活力,采用主成分分析、聚类分析、经济效益分析综合比较了不同施肥方式对土壤质量与经济收益的影响。 【结果】 长期不施肥、单施氮肥(N)、氮肥配施绿肥或者秸秆均会造成土壤钾素匮缺,较 1988 年初测土土壤速效钾含量分别下降了 16.59%、39.37%、25.04%、23.31%;M、G、S 三种有机肥单施或与氮配施均能提高土壤碱解氮、土壤有效磷、土壤有效钾、土壤有机质(SOM)含量,不同施肥方式下,其含量大小总体表现为高量有机肥 > 减量有机肥 + 减量 N > N > CK;M、G、S、N 单施或 1/2MN、1/2GN、1/2SN 处理均能提高蔗糖酶、磷酸酶、脲酶、过氧化氢酶活性,以 G、1/2GN 处理对提高土壤蔗糖酶、脲酶的活性的效果最显著,M、G、MN、GN 处理对提高碱性磷酸酶活性的效果最显著;主成分得分进行聚类分析,不同处理培肥土壤质量效果由高到低分成四类,分别为一类高量有机肥 M、G、1/2MG > 二种有机肥与氮肥减量配施 1/2MN、1/3MSN、1/3MGN、1/2GN、1/2MS、1/4MSGN > 三类氮肥、秸秆、秸秆与氮肥 N、1/2SN、S > 四类不施肥(CK);各施肥方式均能提高作物产量,与不施肥(CK)相比,增产幅度为 12.21%～235.4%,肥料贡献率在 10.89%～70.18% 之间,单施肥增产总趋势为 N > G > M > S,减量配施肥增产总趋势为 1/2GN > 1/2MN>1/2MS,施肥方式以有机肥配施 N 对产量贡献最大;经济效益分析表明施 N 或有机肥与 N 配施对于提高净收益作用较大。 【结论】 通过主成分分析与聚类分析、经济效益与产量综合比较,农家肥、绿肥和秸秆长期单施成本高,产量和经济效益低,维持土壤养分和产量需要的用量大。因此,提倡适量有机肥与氮肥配施,达到提高作物产量,增加经济效益,保证土壤肥力可持续发展。      

Soil nitrogen availability alters rhizodeposition carbon flux into the soil microbial community

Purpose

Soil microorganisms are important in the cycling of plant nutrients. Soil microbial biomass, community structure, and activity are mainly affected by carbon substrate and nutrient availability. The objective was to test if both the overall soil microbial community structure and the community-utilizing plant-derived carbon entering the soil as rhizodeposition were affected by soil carbon (C) and nitrogen (N) availability.

Materials and methods

A ¹³C-CO₂ steady-state labeling experiment was conducted in a ryegrass system. Four soil treatments were established: control, amendment with carboxymethyl cellulose (CMC), amendment with ammonium nitrate (NF), combined CMC and NF. Soil phospholipid fatty acid (PLFA) and ¹³C labeling PLFA were extracted and detected by isotope ratio mass spectrometer.

Results and discussion

The combined CMC and NF treatment with appropriate C/N ratio (20) significantly enhanced soil microbial biomass C and N, but resulted in lower soil inorganic N concentrations. There was no significant difference in soil PLFA profile pattern between different treatments. In contrast, most of the ¹³C was distributed into PLFAs 18:2ω6,9c, 18:1ω7c, and 18:1ω9c, indicative of fungi and gram-negative bacteria. The inorganic-only treatment was distinct in ¹³C PLFA pattern from the other treatments in the first period of labeling. Factor loadings of individual PLFAs confirmed that gram-positive bacteria had relatively greater plant-derived C contents in the inorganic-only treatment, but fungi were more enriched in the other treatments.

Conclusions

Amendments with CMC can improve N transformation processes, and the ryegrass rhizodeposition carbon flux into the soil microbial community is strongly modified by soil N availability.

     

Effect of nutrient solution salinity and ionic concentration on parsley (Petroselinum crispum Mill.) essential oil yield and content

The growth and essential oil (EO) production of parsley were evaluated in response to salinity and nutrient solution concentrations in a soilless culture. Parsley plants that were 60 days old were potted in a coconut fiber and peat moss medium and were treated with four different nutrient solutions, including T1, T2, T3 and T4. The T1 nutrient solution was the standard, the T2 and T3 solutions contained incremental macronutrient concentrations with an electrical conductivity (EC) of up to 2.2 and 3.2 dS m^?1, respectively, and the T4 solution was the same as T2 but with sodium chloride (NaCl) and an incremental macronutrient concentration with an EC of 3.2 dS m^?1. Next, these plants were grown for 90 days in a greenhouse with natural daylight in Nador, Morocco. Shoot and root growth significant decreased with increasing EC. However, the salinity that resulted from the addition of NaCl did not affect plant growth in the nutrient solutions. The optimum obtained growth and EO production were 1.2 and 2.2 dS m^?1, respectively. Consequently, the optimum EC value (based on the EO production) of parsley in the soilless culture was 1.2–2.2 dS m^?1.     

Fertilizer location modifies root zone salinity,root morphology,and water‐stress resistance of tree seedlings according to the watering regime in a dryland reforestation

There is a direct relationship between soil nutrient concentration in localized zones and root proliferation and elongation under well‐watered conditions. However, in field studies under semiarid conditions this relationship can change due to higher salt accumulation and soil dryness that affect root growth, water stress resistance, and seedling survival. We assessed the effect of different locations of fertilizer placement in the soil profile and water availability on root zone salinity, root development and ecophysiological responses of Quillaja saponaria Mol. after outplanting. A single dose (6 g L^?1) of controlled‐release nitrogen fertilizer (CRF_N) was placed at 0 cm (top layer), 15 cm (middle layer), or 30 cm (bottom layer) depth in the containers in a greenhouse, in addition to an unfertilized treatment (control). After 6 months, seedlings were transplanted to the field and subjected to weekly watering regimes (2 L plant^?1 and unwatered). Morphological and ecophysiological parameters were periodically measured on seedlings, as well as soil electrical conductivity (EC). After 1 year, the shoot : root ratio of unwatered seedlings decreased as a function of CRF_N placement depth, which was attributed to lower shoot growth and not to greater root growth. The root morphology of the bottom layer treatment was negatively affected by high EC in unwatered seedlings. Greater total root length and root volume of the middle layer treatment was found only when well‐watered; however, this did not contribute to improve physiological responses against water stress. The lowest EC and the highest photochemical efficiency, net photosynthesis, and stomatal conductance were shown by unfertilized seedlings, independent of water availability. Our findings suggest that varying depth of CRF_N placement does not contribute significantly to improve root growth under water restriction. Water supplements, independently of the CRF_N location in the substrate, contribute to decrease root zone salinity, and consequently, improve root volume growth.