广州城郊森林公园常绿阔叶林土壤有机碳及组分特征

为探讨森林公园土壤有机碳的分布特征,以广州城郊的石门国家森林公园和云髻山森林公园为研究对象,采用分层采样方法 (0—5、5—10、10—20、20—40和40—60 cm) 对天然常绿阔叶林的土壤总有机碳、惰性有机碳、易氧化有机碳、水溶性有机碳、微生物生物量碳含量进行了研究。结果表明：土壤惰性有机碳、活性有机碳及总有机碳含量随土层加深均表现下降趋势。不同组分的活性有机碳含量及其所占总有机碳比例在土壤剖面分布存在差异,均表现为易氧化有机碳>微生物生物量碳>水溶性有机碳。土壤惰性有机碳占总有机碳的比例显著高于活性有机碳,随土层加深呈先下降后增加趋势,深层土壤有利于维护有机碳的稳定性。土壤惰性有机碳、易氧化有机碳、水溶性有机碳及微生物生物量碳含量与总有机碳、微生物生物量氮含量均呈显著正相关,土壤各组分碳间转化依赖于总有机碳量的变化,同时受微生物生物量氮的支配。     

土地利用变化对川西米亚罗林土壤活性碳库的影响

为了揭示土地利用变化对土壤活性有机碳库的影响,在四川省亚高山米亚罗林区,以原始冷杉林(M-Y)和由原始林转化成的45年龄云杉人工林(M-60)、25年龄云杉人工林(M-80)和菜地(M-C)等4种土地利用类型为研究对象,进行了土壤的微生物量碳(MBC)、水溶性有机碳(WDOC)和易氧化有机碳(LOC)的含量和季节变化研究.结果表明,土地利用变化明显影响土壤活性有机碳组分的含量,其中微生物量碳和水溶性有机碳的变化趋势为M-Y>M-60>M-80>M-C,易氧化有机碳的变化趋势则为M-60>M-Y.土地利用变化没有改变活性有机碳各组分的垂直分布,各组分均随着土层深度的增加而降低,季节变化幅度较小,但枯落物层和表层土壤的变化幅度明显高于深层土壤,而各组分的分配比例变化幅度明显小于活性有机碳含量的变化.     

秦岭典型林分土壤活性有机碳及碳储量垂直分布特征

采用野外调查结合室内分析的方法,2013年8月分析了秦岭典型林分锐齿栎(马头滩林区,Ⅰ)、油松(Ⅱ)、华山松(Ⅲ)、松栎混交林(Ⅳ)、云杉(Ⅴ)、锐齿栎(辛家山林区,Ⅵ)土壤剖面上活性有机碳及碳储量的分布规律.结果表明: 研究区各林分土壤的有机碳、微生物生物量碳、水溶性碳、易氧化态碳含量均随着土层深度的增加而不断减小;在整个土壤剖面(0～60 cm)上,云杉和松栎混交林的土壤有机碳和水溶性碳含量明显高于其余林分,不同林分的土壤有机碳和水溶性碳含量的平均值大小均为Ⅴ＞Ⅳ＞Ⅰ＞Ⅱ＞Ⅲ＞Ⅵ;各林分不同土层的微生物生物量碳在71.25～710.05 mg·kg^-1,不同林分的土壤微生物生物量碳大小依次为Ⅰ＞Ⅴ＞Ⅳ＞Ⅲ＞Ⅱ＞Ⅵ;整个土壤剖面上,松栎混交林的土壤易氧化态碳含量降幅最大,不同林分土壤易氧化态碳含量的平均值大小为Ⅳ＞Ⅴ＞Ⅰ＞Ⅱ＞Ⅲ＞Ⅵ.3种活性有机碳占有机碳的比例在不同林分类型中没有表现出一致的规律性.各林分0～60 cm土层的有机碳储量大小为Ⅴ＞Ⅰ＞Ⅳ＞Ⅲ＞Ⅵ＞Ⅱ.各林分的土壤微生物生物量碳、水溶性碳、易氧化态碳两两之间均表现为极显著相关,各林分的土壤微生物生物量碳、水溶性碳、易氧化态碳与土壤有机碳、全氮之间的相关性均表现为显著或极显著水平,与碳氮比、pH、土壤水分、土壤容重的相关关系不显著.     

江西官山常绿阔叶林土壤有机碳组分沿海拔的变化

对江西官山国家级自然保护区不同海拔(400、600、800、1000、1200 m)常绿阔叶林土壤总有机碳、惰性有机碳和活性有机碳进行分析,研究土壤有机碳的海拔分布特征。结果表明: 土壤总有机碳、惰性有机碳及活性有机碳含量在土壤表层最高,随土层加深而逐渐下降。随海拔升高,土壤总有机碳、惰性有机碳、易氧化有机碳、微生物生物量碳及0～20 cm土层土壤颗粒有机碳含量均出现先增后降的趋势, 且在海拔1000 m达到峰值,而土壤水溶性有机碳及20～40 cm土层土壤颗粒有机碳含量无明显变化。在0～10 cm土层,土壤惰性有机碳占总有机碳的比例在海拔800和1200 m显著高于海拔400和1000 m,而土壤活性有机碳占总有机碳的比例在海拔400 m最高;土壤惰性有机碳和活性有机碳占总有机碳的比例在10～40 cm土层随海拔的增加均呈先增加后降低的趋势,峰值分别在1000和600 m处。各组分有机碳与土壤湿度、微生物生物量氮、可溶性有机氮均呈显著正相关,而且活性有机碳与铵态氮呈显著正相关。海拔显著影响常绿阔叶林土壤有机碳组分的分布,惰性有机碳、易氧化有机碳和微生物生物量碳对海拔变化的响应更敏感。高海拔土壤惰性有机碳和活性有机碳在水分和氮素充足条件下易发生分解与转化,降低土壤碳库的稳定性。在全球气温持续升高背景下,要加强高海拔地区森林土壤有机碳的动态变化研究。     

林冠氮添加和林下植被去除对杉木林土壤有机碳组分的影响

为探讨氮添加和林下植被管理对杉木人工林土壤有机碳组分的影响,以福建沙县官庄国有林场杉木人工林为对象,设置对照（CK）、林冠氮添加（CN）、林下植被去除（UR）、林冠氮添加和林下植被去除（CNUR）4个处理的野外控制实验,研究林冠氮添加和林下植被去除对土壤总有机碳、惰性有机碳、易氧化有机碳、颗粒有机碳、微生物生物量碳和水溶性有机碳的影响。结果表明：5年CN添加处理显著降低易氧化有机碳（10—20 cm）和微生物生物量碳（20—40 cm）含量,增加表层土壤颗粒有机碳占总有机碳的比例。UR处理对土壤有机碳组分的作用不显著,而CNUR处理显著降低表层土壤水溶性有机碳含量及其比例。土壤各有机碳组分均与土壤含水量、可溶性有机氮、微生物生物量氮和铵态氮呈显著正相关。研究表明,土壤活性有机碳比惰性有机碳对林冠氮添加（5年）的响应更敏感,且表现为中下层土壤响应大于表层土壤,短期氮添加能促进土壤活性有机碳的分解,而林下植被去除在短时间内可能通过改变土壤含水量和可利用氮减缓有机碳的分解与转化,从而补偿由于氮添加引起的土壤活性有机碳下降,未来需要通过长期氮添加实验进一步研究土壤有机碳动态变化的响应机制。     

红壤侵蚀地不同人工恢复林对土壤总有机碳和活性有机碳的影响

土壤有机碳尤其是活性有机碳可快速反映土壤肥力和土壤质量的恢复程度。研究了南方红壤侵蚀地3种典型人工恢复林(马尾松与阔叶复层林(Pinus massoniana-broadleaved multiple layer forest(PB))、木荷与马尾松混交林(Schima superba-Pinus massoniana mixed forest(SP))、阔叶混交林(broad-leaved mixed forest(BF)))土壤(0—60 cm)总有机碳和不同活性有机碳的垂直分布特征及其差异。结果表明:不同恢复林分土壤总有机碳(SOC)含量和有机碳储量均表现为PBSPBF,均随土层深度的增加而逐渐降低;土壤表层有机碳富集系数为0.49—0.55,表明表层土壤具有较高的有机碳恢复水平和保持强度。不同林分土壤易氧化有机碳(ROC)、水溶性有机碳(DOC)和微生物量碳(MBC)含量变化范围为0.92—9.17 g/kg、535.89—800.46 mg/kg和27.24—261.31 mg/kg,且均随土层深度的增加而降低,土壤活性有机碳含量总体以BF较高。土壤活性有机碳分配比例以ROC/SOC最高,DOC/SOC次之,MBC/SOC最低,且随土层深度的增加,ROC/SOC的值呈逐渐降低趋势,DOC/SOC的值却呈逐渐升高趋势,MBC/SOC(微生物熵)则变化规律不明显;不同林分间土壤活性有机碳分配比例以BF最高,表明阔叶混交林更有利于活性碳的积累。因此,对于红壤侵蚀地森林恢复初期,可适当密植和立体种植,以提高土壤碳储量和土壤肥力,并在马尾松等先锋树种林分中补植阔叶树种,以增加土壤活性有机碳含量,从而有利于退化生态系统土壤速效养分和土壤功能的快速恢复。     

喀斯特森林自然恢复中土壤微生物生物量碳与水溶性有机碳特征

2011年9月,采用空间代替时间方法,研究了贵州茂兰国家级自然保护区退化喀斯特森林自然恢复中土壤微生物生物量碳和水溶性有机碳特征.结果表明:研究期间,土壤微生物生物量碳含量、基础呼吸随土壤深度增加而减少,随自然恢复的进程而增加;微生物熵随土壤深度增加和恢复的进程增加;水溶性有机碳含量随土壤深度增加而减少,随自然恢复的进程表层土增加,下层先增加后减少;水溶性有机碳与有机碳的比值随土壤深度增加而增加,随自然恢复的进程而减少;土壤质量、有机碳的质与量随自然恢复的进程而提高,其中微生物量碳变化最大,而水溶性有机碳变化不显著.     

不同土壤耕作措施与秸秆还田对稻麦两熟制农田土壤活性有机碳组分的短期影响

通过2年（2009-2011年）大田试验,研究不同耕作措施和秸秆还田及其交互效应对稻麦两熟制农田0～7、7～14和14～21 cm 3个土层土壤总有机碳和活性有机碳组分（易氧化有机碳、水溶性有机碳和微生物生物量碳）的影响.结果表明： 秸秆还田处理各土层土壤总有机碳和活性有机碳含量均显著高于无秸秆还田处理;0～7 cm土层,翻耕处理土壤微生物生物量碳含量显著高于旋耕处理,旋耕处理易氧化有机碳含量高于翻耕处理;7～14 cm土层,旋耕处理土壤总有机碳含量显著高于翻耕处理;14～21 cm土层,翻耕处理土壤总有机碳、水溶性有机碳和微生物生物量碳含量均显著高于旋耕处理;翻耕加稻麦两季秸秆均还田处理的总有机碳含量均高于其他各处理.     

猪粪堆肥化处理过程中的氮素转变及腐熟度研究

经过63d堆肥化处理后,猪粪与木屑混合堆肥及猪粪,木屑与树叶混合堆肥的T－N分别从开始的1．57％和1．78％增加到2．0％和2．11％;水溶性NO3－N／水溶性T－N均从接近于0的水平增加到3％左右;水溶性有机N／水溶性T－N分别增加到70％和76％;水溶性NH4－N／水溶性T－N则分别从开始52％和61％下降至堆肥结束时的30％和24％。种子发芽系数的测定结果表明,加入树叶有利于猪粪的腐熟化,可使猪粪堆肥化处理所城的时间从42d缩短至35d。化学指标与种子发芽系数的相关分析结果表明,水溶性NH4－N／水溶性T－N,水溶性NO3－N／水溶性T－N和水溶性有机N／水溶性T－N均与种子发芽系数呈显著相关,可作为堆肥的腐熟度评价指标。     

红壤稻田生态系统有机物料循环对土壤有机碳转化的影响

通过对12年田间定位试验数据的分析,研究了红壤稻田生态系统有机物料循环再利用对土壤有机碳积累的贡献及其对转化的影响。结果表明,红壤稻田生态系统有机物料循环再利用可促进土壤有机碳的积累、改善腐殖质组分和改良有机质品质。红壤稻田生态系统内有机物料循环再利用,土壤有机碳的年增速率最大可达到0.37 g.kg-1;12年间易氧化有机碳最大增量达到3.8 g.kg-1,胡敏酸和富里酸最大增量分别达到3.06和1.63 g.kg-1。预测结果显示,有机物料循环再利用红壤稻田生态系统土壤有机碳50年内可提高8.3~18.9 g.kg-1,增长率达到62.0%~140.7%。     

Optimizing composting parameters for nitrogen conservation in composting

A central composite experimental design was used to investigate the influence of environmental composting parameters (moisture, aeration, particle size and time) for legume trimming residues, used on soil restoration, on the properties of products obtained (organic matter, Kjeldahl-N, C/N ratio and nitrogen losses (N-losses)) in order to determine the best composting conditions. A second-order polynomial model consisting of four independent process variables was found to accurately describe (the differences between the experimental values and those estimated by using the equations never exceeded 10% of the former) the composting process. Results of the experiment showed that compost with acceptably chemical properties (OM, 85%; Kjeldahl-N, 3.2%), high degradation and minimum N-losses entails operating at high operation time (78 days), low particle size (1cm), medium moisture content (40%) and medium to low aeration level (0.2-0.4 l air/min kg).     

八角下脚料、甘蔗滤泥、桐麸联合堆肥的腐熟度指标研究

测定八角下脚料与甘蔗滤泥、桐麸联合堆肥过程中温度、C/N比、种子发芽指数(GI)等腐熟度指标,研究各项指标在堆肥进程中的变化情况。结果表明:GI可作为八角下脚料与甘蔗滤泥、桐麸联合堆肥评价堆肥腐熟度的主要评价指标。在起始C/N比为31.45条件下进行八角提油下脚料、甘蔗滤泥、桐麸的联合高温好氧堆肥,堆制21 d和26 d时,三种腐熟度指标未全部显示堆肥腐熟;堆制31 d时,C/N比为18.55,T值为0.59(小于0.6),发芽指数GI为93.7%(大于80%)。从温度、发芽指数和C/N比三个指标均可认为堆肥已达到腐熟。     

Thermophilic composting of food waste

A laboratory reactor was designed to study the effects of operating parameters (air suction rate, seeding and agitation) on the composting process of a synthetic food waste made of dog food. Experimental results showed that the synthetic food waste could be composted within 4 days and the final compost passed the maturity tests. In most cases except those with 32% of seeding, the process involved two major stages of composting. The two peak temperatures between 50 and 60 degrees C occurred at 8-12th hour and 50-65th hour, respectively. Operating parameters that converted the most volatile solids and carbons in the feedstock were as follows: 1.6 l air/kg dry solid-min of air suction rate, 32% of seeding and 50% of agitation time.     

堆肥过程中的微生物种群结构

堆肥化是有机固体废物无害化、减量化、资源化的根本途径。有机固体废弃物的堆肥化研究一直是环境科学领域研究的热点之一。产品中含有有机质、P、K等多种植物所需的养分,可以提高农林等产品的产量,改善土壤结构,提高土壤肥力。微生物是堆肥过程的工作主体,早期对堆肥中微生物的研究主要采用分     

Accelerated coffee pulp composting

The effect of two abundant, easily available and very low-cost agro-industrial organic residues, i.e., filter cake from the sugar industry and poultry litter, on the composting stabilization time of coffee pulp and on the quality of the produced compost, was evaluated. Piles of one cubic meter were built and monitored within the facilities of a coffee processing plant in the Coatepec region of the State of Veracruz, Mexico. Manual aeration was carried out once a week. A longer thermophilic period (28 days) and a much lower C/N ratio (in the range of 6.9–9.1) were observed in the piles containing the amendments, as compared to the control pile containing only coffee pulp (14 days and a C/N ratio of 14.4, respectively). The maximum assimilation rate of the reducing sugars was 1.6 g kg-1 d-1 (from 7.5 to 5.3%) during the first two weeks when accelerators were present in the proportion of 20% filter cake plus 20% poultry litter, while they accumulated at a rate of 1.2 g kg-1 d-1 (from 7.4 to 9.13%) during the same period in the control pile. The best combination of amendments was 30% filter cake with 20% poultry litter, resulting in a final nitrogen content as high as 4.81%. The second best combination was 20% filter cake with 10% poultry litter, resulting in a compost which also contained a high level of total nitrogen (4.54%). It was concluded that the use of these two residues enhanced the composting process of coffee pulp, promoting a shorter stabilization period and yielding a higher quality of compost.     

Accelerated food waste composting

Experiments on food waste composting under the temperate and dry conditions of Mexico City showed that the waste stabilized faster (within 2 months) if an accelerator (chopped orange peel and carrot bagasse) was used. The relatively cool and humid conditions prevailing during similar experiments in Xalapa City inhibited decomposition, and stabilization of waste, with or without accelerator, was generally slower than in Mexico City. However, addition of wood chips as a bulking agent greatly improved composting in Xalapa, leading to stabilization in just 35 days.Use of the accelerator increases the initial C/N ratio in the waste. This permits rapid utilization of any easily degradable sugars, which in turn supports rapid multiplication of mesophilic microorganisms.     

Fertilizers from composting of olive-mill wastewaters

The aerobic bioremediation of olive-mill wastewaters produces a high quality compost, characterized by a considerable presence of nutrients, mainly organically-bound nitrogen (1.5-3%), a good level of humification (degree of HUMIFICATION=78%; humification INDEX=0.28), and by the absence of phytotoxicity. The agronomic value of a compost thus obtained was assayed both by the ‘crop test’ and following the plant-soil system as influenced by compost supply. Field experiments performed on maize showed that compost, when supplied before sowing in amounts of 60–90 Mg ha⁻¹ (equivalent to a manuring on the basis of organic matter) is able to reduce the need for chemical fertilization. The same quantity supported the nutritional need of rye grass and horticultural plants. A good rest-effect was also recorded. Compost supply enhanced both soil oxygen consumption and nitrogen fixation in the open field. An improvement of activities in the plant-soil system was made evident by pot trials.     

The biosecurity of on-farm mortality composting

Composting is a natural biological decomposition process that takes place under aerobic and thermophilic conditions. It can be used for the day-to-day management of mortalities on farms and for carcass disposal in emergency animal disease (EAD) outbreaks. In mortality composting, carcasses are placed in piles or bins together with supplemental carbon sources such as sawdust, litter, straw or wood shavings. Composting is particularly suitable for broiler-farm mortalities and litter. In the case of emergency disease outbreaks, composting can be conducted either inside or outside the poultry house following killing. Composting has been successfully employed for emergency disposal of carcasses in a few cases in North America, but research is lacking on the biosecurity of the process. Composting is a well-established pathogen reduction technology, but process management and heterogenous pile conditions pose particular challenges for validating the microbiological safety of mortality composting. This paper reviews the available information on the biosecurity of mortality composting, identifies potential sources of risk, and highlights emerging research needs. Reports to date of the use of composting in EAD outbreaks are also discussed.     

Study of composting of cotton residues

A study on the composting of residues of cotton gin previously crushed or uncrushed is presented in this work. A multifactor analysis of correlation for each one of the treatments revealed that the final results obtained during the composting process of cotton residuals were very different according to whether the residues were crushed or uncrushed. Generally, the highest final values of macronutrients and micronutrients obtained were found when the composting process was carried out with the crushed residuals.     

Bioreclamation of chlorophenol-contaminated soil by composting

Summary Microbiological decontamination of technical chlorophenol-containing soil by composting was studied. In two 50 m³ windrows the concentration of chlorophenols went down from 212 mg kg^-1 to 30 mg kg^-1 in 4 summer months and after the second summer of composting it was only 15 mg kg^-1. All chlorophenol congeners present in the technical chlorophenol were degraded, but the main dimeric impurities, polychlorinated phenoxyphenols were recalcitrant. The contaminated soil was found to contain chlorophenol-degrading microbes, 5x10⁶ cfu g^-1 of dry windrow soil. Laboratory experiments with samples from the windrow compost showed that chlorophenols were truly degraded and that chlorophenol loss by evaporation was less than 1.5% under the circumstances studied. Laboratory experiments also showed that degradation of chlorophenols (120 mg kg^-1) was accelerated when sterilized contaminated soil was inoculated with Rhodococcus chlorophenolicus (mineralizer of several chlorophenols) or naturally occurring microbes of the field composts. Biomethylation of chlorophenols in the composts was insignificant compared to biodegradation.