入田泥沙对黄河三角洲地区土壤物理性状的影响——以小开河引黄灌区为例

为研究人田泥沙对小开河灌区自然土壤的影响,用分析化验和工程测试等方法,分析了引黄泥沙和输沙人田后土壤颗粒组成、容重、孔隙状况等物理性状。结果表明：引黄泥沙中0．02～0．002mm的细粉粒比例最高,平均39-31％。小开河自然土壤中0．05-0．02mm的粗粉粒比例最高,为53．41％,泥沙中细粉粒和粘粒含量明显高于当地土壤。输沙人田使灌区土壤中0．02—0．002mm的细粉粒和〈0．002mm的粘粒比例明显增加,〉0．02mm的颗粒比例下降,虽有效避免了因渠首集中沉沙造成的土壤沙化和生态环境恶化,但增加了土壤的粘重程度。农田耕作在一定程度上增加土壤通气孔隙比例、降低土壤容重,但土壤毛管孔隙度依旧稳定在40％左右,毛管作用旺盛,使土壤通气状况不能满足作物需求。在黄河三角洲地区输沙入田的泥沙处理,应结合当地土壤的基本性质和水盐运动规律配置泥沙,以免增强当地土壤紧实、通透性差的性状。     

木薯渣微生物降解及再利用研究进展

木薯渣因其所含粗纤维经有效降解之后可以变废为宝,节省资源又保护环境而受到国内外学者的广泛关注。对木薯渣再利用方面的研究已经成为近年来一大热点,微生物降解是提高木薯渣利用率的一个有效途径。从木薯渣降解再利用角度出发,综述了木薯渣的用途、降解机理以及温度、pH值、含水量等重要影响因素。阐明了在合适的环境条件下,筛选有效降解微生物是提高木薯渣利用率的关键因素。同时展望了调制复合酶系在降解木薯渣纤维素上的应用,以及改造、合成以及重组降解酶以提高和推广木薯渣纤维素分解的必要性。     

冬季淹水稻田CH_4产生、氧化和排放规律及其影响因素研究

采用静态箱/气象色谱法——田间原位观测和室内培养试验连续一年研究了冬季淹水稻田的CH4产生潜力、氧化潜力和排放通量,以探讨冬季淹水稻田CH4产生、氧化和排放的季节变化规律及其影响因素。结果表明：0~251 d（d表示淹水后天数）,CH4产生潜力逐渐增大,到251 d达最大值,之后逐渐减小;0~204 d,CH4氧化潜力变化较小,但到235 d急剧增至最大值,随后逐渐减小;0~169 d,稻田几乎没有CH4排放,192 d才开始有较明显的CH4排放,到230 d达最大值,为80.2 mg.m-2.h-1,随后逐渐减小,331 d出现一个CH4排放高峰。全观测期内CH4排放量为69.9 g.m-2,其中非水稻生长期排放6.7 g.m-2,占总量的9.5%。全观测期内CH4产生潜力与土温及土壤Eh均无显著相关性;全观测期内CH4氧化潜力与土温极显著正相关（P〈0.01）,水稻生长期CH4氧化潜力与土壤中氨氮含量呈极显著正相关（P〈0.01）;全观测期内稻田CH4排放与土温和CH4产生潜力两个因素均显著正相关（P〈0.05）而与土壤Eh呈显著负相关（P〈0.05）。     

外来红树植物无瓣海桑的入侵生态特征

无瓣海桑因其具有速生性的特点而被广泛的用于滩涂海岸造林和控制外来杂草互花米草。但是同样作为外来种,无瓣海桑其自身的入侵性及生态风险已经成为近年来研究的一大热点。依据外来种风险评估的侧重点,分别从定居特性、传播特性及其影响等方面总结了国内外无瓣海桑的入侵生态特征的相关研究,表明无瓣海桑具有速生、高生产力、对低温和土壤具有一定的适应性、已在澳门等地出现扩散入侵现象等利于入侵的特点;但是同时它生态位宽度中等,繁殖率较低,并且它的种植会改善红树林生态系统土壤养分,有利于乡土红树植物的生长。现有对无瓣海桑入侵生态特征的定性研究并不能完全确定其入侵性和生态风险。因此今后需采用风险评估模型等手段对无瓣海桑入侵性进行更为深入地评估。     

河谷型城市城乡结合部景观格局空间尺度效应分析——以兰州市西固区土地利用格局为例

以兰州市西固区土地利用格局为例,利用2005年SPOT5遥感影像和正射航空影像数据,选取14个常用的景观指数,从景观水平和类型水平2个方面分析景观指数随尺度变化的基本规律,采用200m×200m正方形将研究区土地利用数据切分成规则格网,计算每个格网的多样性指数,通过半方差分析研究西固区多样性空间结构特征。结果表明:10m是西固区土地利用景观的本征观测尺度;研究区景观类型和景观格局特征随尺度增大变化显著,体现出一定的尺度依赖性;各乡(镇、街道)的景观指数呈现出城市中心—城乡交错带—乡村的分异特征,梯度变化明显;西固区多样性空间分布属于中等强度空间相关,高值区主要分布于黄河沿岸。     

耕种方式对稻田甲烷排放的影响

通过田间试验研究了稻田2种土壤耕作强度(深翻耕和浅旋耕)和3种水稻栽培方式(直播、抛秧和插秧)下的CH4排放规律,以探讨稻田土壤耕作强度和水稻栽培方式对CH4排放的影响。结果表明,各水稻栽培方式下,深翻耕和浅旋耕稻田CH4排放季节变化趋势一致。土壤耕作强度对稻田CH4季节排放总量的影响受水稻栽培方式的制约:抛秧方式下,浅旋耕与深翻耕处理相比,稻田CH4排放量减少31.37%(P0.05);而直播和插秧方式下,2者CH4季节排放总量相当。水稻栽培方式显著影响稻田CH4排放季节变化规律:直播稻田CH4排放大致呈现"双峰型"模式,且水稻生育前期CH4排放水平较低;而移栽稻田(抛秧和插秧)CH4排放大致呈现"三峰型"模式,且水稻生育前期CH4排放水平较高。与深翻耕抛秧相比,深翻耕直播和深翻耕插秧稻田CH4排放分别减少23.31%和42.51%;而浅旋耕方式下,3种水稻栽培处理CH4季节排放总量相当。降低土壤耕作强度,以浅旋耕代替深翻耕,可以减少耕作对土壤的扰动,在一定程度上减少稻田CH4排放。与水稻移栽相比,水稻直播能够显著降低水稻生育前期CH4排放,具有一定的CH4减排潜力,但仍需加强中后期田间水分管理。     

基于不同土地利用方式的深圳市农用地土壤重金属污染评价（Evaluation of the Heavy Metal Pollution in Different Agricultural Soils of Shenzhen City）

为探讨深圳市农林土壤重金属的污染现状,分菜地、果园、林地和荒地等4种不同的土地利用类型,共采集了52个表层土壤样品,采用原子吸收法测定了其重金属Cu、Pb、Zn、Cd、Cr和Ni全量,单项污染指数法和内梅罗综合指数法评价了6种重金属在土壤中的污染现状.评价结果显示,部分土壤样点存在较为严重的重金属污染,Cd的污染最为严重,Cu的污染最轻;不同用地类型下的污染等级不同,荒地处于尚清洁(警戒限)水平,菜地和林地处于轻度污染水平,果园处于中度污染水平,全市农用地土壤处于轻度污染水平.     

Nitrogen-retaining property of compost in an aerobic thermophilic composting reactor for the sanitary disposal of human feces

Aerobic composting is a method for the sanitary disposal of human feces as is used in bio-toilet systems. As the products of composting can be utilized as a fertilizer, it would be beneficial if the composting conditions could be more precisely controlled for the retention of fecal nitrogen as long as possible in the compost. In this study, batch experiments were conducted using a closed aerobic thermophilic composting reactor with sawdust as the bulk matrix to simulate the condition of a bio-toilet for the sanitary disposal of human feces. Attention was paid to the characteristics of nitrogen transformation. Under the controlled conditions of temperature at 60°C, moisture content at 60%,anda continuous air supply, more than 70% fecal organic removal was obtained, while merely 17% fecal nitrogen loss was observed over a two-week composting period. The nitrogen loss was found to occur mainly in the first 24 h with the rapid depletion of inorganic nitrogen but with an almost unchanged organic nitrogen content. The fecal NH₄-N which was the main component of the inorganic nitrogen ( > 90%) decreased rapidly in the first day, decreased at a slower rate over the following days, and finally disappeared entirely. The depletion of NH₄-N was accompanied by the accumulation of NH₃ gas in the ammonia absorber connected to the reactor. A mass balance between the exhausted NH₃ gas and the fecal NH₄-N content in the first 24 hours indicated that the conversion of ammonium into gaseous ammonia was the main reason for nitrogen loss. Thermophilic composting could be considered as a way to keep a high organic nitrogen content in the compost for better utilization as a fertilizer.     

入田泥沙对黄河三角洲地区土壤物理性状的影响——以小开河引黄灌区为例

为研究入田泥沙对小开河灌区自然土壤的影响,用分析化验和工程测试等方法,分析了引黄泥沙和输沙入田后土壤颗粒组成、容重、孔隙状况等物理性状。结果表明:引黄泥沙中0.02～0.002mm的细粉粒比例最高,平均39.31%。小开河自然土壤中0.05～0.02mm的粗粉粒比例最高,为53.41%,泥沙中细粉粒和粘粒含量明显高于当地土壤。输沙入田使灌区土壤中0.02～0.002mm的细粉粒和﹤0.002mm的粘粒比例明显增加,0.02mm的颗粒比例下降,虽有效避免了因渠首集中沉沙造成的土壤沙化和生态环境恶化,但增加了土壤的粘重程度。农田耕作在一定程度上增加土壤通气孔隙比例、降低土壤容重,但土壤毛管孔隙度依旧稳定在40%左右,毛管作用旺盛,使土壤通气状况不能满足作物需求。在黄河三角洲地区输沙入田的泥沙处理,应结合当地土壤的基本性质和水盐运动规律配置泥沙,以免增强当地土壤紧实、通透性差的性状。     

Enhanced NOx removal from flue gas by an integrated process of chemical absorption coupled with two-stage biological reduction using immobilized microorganisms

An integrated process of metal chelate absorption coupled with two stage bio-reduction using immobilized cultures has been proposed to continuously removal of NO_x, and the effects of SO₂, NO and O₂ concentration, gas/liquid flow rate on NO_x removal efficiency were investigated. Although nitrogen-containing components, such as Fe(II)EDTA-NO, NO₂^? and NO₃^? in the scrubbing solution, inhibited the bio-reduction of Fe(III)EDTA obviously, it was feasible to abate the inhibition effect by using the two stage bio-reduction system, and thus to improve NO_x removal efficiency. The removal efficiency decreased slowly with the increase of SO₂, O₂, NO concentration and gas flow rate, and increased with the increase of liquid flow rate. Continuously operating for 18 days, a high removal efficiency around 95% was reached by using the two-stage bio-reduction system with immobilized microorganisms, while the value decreased to 85% after 5 days of operation by using the suspended microorganisms, at a constant gas flow rate of 60 L/h containing 424–450 mg/m³ NO, 2428–2532 mg/m³ SO₂ and 3% O₂.