Discrimination of marine algal taxonomic groups based on fluorescence excitation emission matrix, parallel factor analysis and CHEMTAX

An in vivo three-dimensional fluorescence method for the determination of algae community structure was developed by parallel factor analysis （PARAFAC） and CHEMTAX. The PARAFAC model was applied to fluo-rescence excitation-emission matrix （EEM） of 60 algae species belonging to five divisions and 11 fluorescent components were identified according to the residual sum of squares and specificity of the composition profiles of fluorescent. By the 11 fluorescent components, the algae species at different growth stages were classified correctly at the division level using Bayesian discriminant analysis （BDA）. Then the reference fluo-rescent component ratio matrix was constructed for CHEMTAX, and the EEM-PARAFAC-CHEMTAX method was developed to differentiate algae taxonomic groups. The correct discrimination ratios （CDRs） when the fluorometric method was used for single-species samples were 100% at the division level, except for Bacil-lariophyta with a CDR of 95.6%. The CDRs for the mixtures were above 94.0% for the dominant algae species and above 87.0% for the subdominant algae species. However, the CDRs of the subdominant algae species were too low to be unreliable when the relative abundance estimated was less than 15.0%. The fluorometric method was tested using the samples from the Jiaozhou Bay and the mesocosm experiments in the Xiaomai Island Bay in August 2007. The discrimination results of the dominant algae groups agreed with microscopy cell counts, as well as the subdominant algae groups of which the estimated relative abundance was above 15.0%. This technique would be of great aid when low-cost and rapid analysis is needed for samples in a large batch. The fluorometric technique has the ability to correctly identify dominant species with proper abundance both in vivo and in situ.

Assessment of phytoplankton class abundance using fluorescence excitation-emission matrix by parallel factor analysis and nonnegative least squares

The feasibility of using fluorescence excitation-emission matrix(EEM) along with parallel factor analysis(PARAFAC) and nonnegative least squares(NNLS) method for the differentiation of phytoplankton taxonomic groups was investigated. Forty-one phytoplankton species belonging to 28 genera of five divisions were studied. First, the PARAFAC model was applied to EEMs, and 15 fluorescence components were generated. Second, 15 fluorescence components were found to have a strong discriminating capability based on Bayesian discriminant analysis(BDA). Third, all spectra of the fluorescence component compositions for the 41 phytoplankton species were spectrographically sorted into 61 reference spectra using hierarchical cluster analysis(HCA), and then, the reference spectra were used to establish a database. Finally, the phytoplankton taxonomic groups was differentiated by the reference spectra database using the NNLS method. The five phytoplankton groups were differentiated with the correct discrimination ratios(CDRs) of 100% for single-species samples at the division level. The CDRs for the mixtures were above 91% for the dominant phytoplankton species and above 73% for the subdominant phytoplankton species. Sixteen of the 85 field samples collected from the Changjiang River estuary were analyzed by both HPLC-CHEMTAX and the fluorometric technique developed. The results of both methods reveal that Bacillariophyta was the dominant algal group in these 16 samples and that the subdominant algal groups comprised Dinophyta, Chlorophyta and Cryptophyta. The differentiation results by the fluorometric technique were in good agreement with those from HPLC-CHEMTAX. The results indicate that the fluorometric technique could differentiate algal taxonomic groups accurately at the division level.

Investigation of seasonal variability of CDOM fluorescence in the southern Changjiang River Estuary by EEM-PARAFAC

The southern Changjiang River Estuary has attracted considerable attention from marine scientists because it is a highly biologically active area and is biogeochemically significant. Moreover, land-ocean interactions strongly impact the estuary, and harmful algal blooms （HABs） frequently occur in the area. In October 2010 and May 2011, water samples of chromophoric dissolved organic matter （CDOM） were collected from the southern Changjiang River Estuary. Parallel factor analysis （PARAFAC） was used to assess the samples＇ CDOM composition using excitation-emission matrix （EEM） spectroscopy. Four components were identified： three were humic-like （C1, C2 and C3） and one was protein-like （C4）. Analysis based on spatial and seasonal distributions, as well as relationships with salinity, Chl a and apparent oxygen utilization （AOU）, revealed that terrestrial inputs had the most significant effect on the three humic-like Components C1, C2 and C3 in autumn. In spring, microbial processes and phytoplankton blooms were also important factors that impacted the three components. The protein-like Component C4 had autochthonous and allochthonous origins and likely represented a biologically labile component. CDOM in the southern Changjiang River Estuary was mostly affected by terrestrial inputs. Microbial processes and phytoplankton blooms were also important sources of CDOM, especially in spring. The fluorescence intensities of the four components were significantly higher in spring than in autumn. On average, C1, C2, C3, C4 and the total fluorescence intensity （TFI） in the surface, middle and bottom layers increased by 123%-242%, 105%-195%, 167%-665%, 483%-567% and 184%-245% in spring than in autumn, respectively. This finding corresponded with a Chl a concentration that was 16-20 times higher in spring than in autumn and an AOU that was two to four times lower in spring than in autumn. The humification index （HIX） was lower in spring that in autumn, and the fluorescence index （FI） was higher in spring than in autumn. This result indicated that the CDOM was labile and the biological activity was intense in spring.

Dissolved organic matter tracers reveal contrasting characteristics across high arsenic aquifers in Cambodia:A fluorescence spectroscopy study

Organic matter in the environment is involved in many biogeochemical processes,including the mobilization of geogenic trace elements,such as arsenic,into groundwater.In this paper we present the use of fluorescence spectroscopy to characterize the dissolved organic matter (DOM) pool in heavily arsenicaffected groundwaters in Kandal Province,Cambodia.The fluorescence DOM (fDOM) characteristics between contrasting field areas of differing dominant lithologies were compared and linked to other hydrogeochemical parameters,including arsenic and dissolved methane as well as selected sedimentary characteristics.Absorbance-corrected fluorescence indices were used to characterize depth profiles and compare field areas.Groundwater fDOM was generally dominated by terrestrial humic and fulvic-like components,with relatively small contributions from microbially-derived,tryptophan-like components.Groundwater fDOM from sand-dominated sequences typically contained lower tryptophan-like,lower fulvic-like and lower humic-like components,was less bioavailable,and had higher humification index than clay-dominated sequences.Methane concentrations were strongly correlated with fDOM bioavailability as well as with tryptophan-like components,suggesting that groundwater methane in these arsenic-prone aquifers is likely of biogenic origin.A comparison of fDOM tracers with sedimentary OM tracers is consistent with the hypothesis that external,surface-derived contributions to the aqueous DOM pool are an important control on groundwater hydrogeochemistry.

Characterization of dissolved organic matter in urban sewage using excitation emission matrix fluorescence spectroscopy and parallel factor analysis

Wastewater dissolved organic matter （DOM） from different processing stages of a sewage treatment plant in Xiamen was characterized using fluorescence and absorption spectroscopy. Parallel factor analysis modeling of excitation-emission matrix spectra revealed five fluorescent components occurring in sewage DOM： one protein-like （C1）, three humic-like （C2, C4 and C5） and one xenobiotic-like （C3） components. During the aerated grit chamber and primary sedimentation tank stage, there was only a slight decrease in fluorescence intensity and the absorption coefficient at 350 nm （a 350 ）. During the second aeration stage, high concentration of protein-like and short-wavelength-excited humic-like components were significantly degraded accompanied by significant loss of DOC （80%） and a 350 （30%）, indicating that C1 and C2 were the dominant constituents of sewage DOM. As a result, long-wavelength- excited C4 and C5 became the dominant humic-like components and the DOM molecular size inferred from the variation of spectral slope S （300–650 nm） and specific absorption （a 280 /DOC） increased. Combination use of F max of C1 and the ratio of C1/C5, or a 350 may provide a quantitative indication for the relative amount of raw or treated sewage in aquatic environment.

Simulated photo-degradation of dissolved organic matter in lakes revealed by three-dimensional excitation-emission matrix with regional integration and parallel factor analysis

Simulated photo-degradation of fluorescent dissolved organic matter(FDOM) in Lake Baihua(BH) and Lake Hongfeng(HF) was investigated with three-dimensional excitationemission matrix(3 DEEM) fluorescence combined with the fluorescence regional integration(FRI),parallel factor(PARAFAC) analysis,and multi-order kinetic models.In the FRI analysis,fulvic-like and humic-like materials were the main constituents for both BH-FDOM and HF-FDOM.Four individual components were identified by use of PARAFAC analysis as humic-like components(C1),fulvic-like components(C2),protein-like components(C3) and unidentified components(C4).The maximum 3 DEEM fluorescence intensity of PARAFAC components C1-C3 decreased by about 60%,70% and 90%,respectively after photo-degradation.The multi-order kinetic model was acceptable to represent the photo-degradation of FDOM with correlation coefficient(Radj2)(0.963-0.998).The photo-degradation rate constants(kn) showed differences of three orders of magnitude,from 1.09 × 10-6 to 4.02 × 10-4 min-1,and half-life of multi-order model(T1/2n)ranged from 5.26 to 64.01 min.The decreased values of fluorescence index(FI) and biogenic index(BI),the fact that of percent fluorescence response parameter of Region I(PⅠ,n) showed the greatest change ratio,followed by percent fluorescence response parameter of Region II(PⅡ,n,while the largest decrease ratio was found for C3 components,and the lowest T1/2n was observed for C3,indicated preferential degradation of protein-like materials/components derived from biological sources during photodegradation.This research on the degradation of FDOM by 3 DEEM/FRI-PARAFAC would be beneficial to understanding the photo-degradation of FD OM in natural environments and accurately predicting the environmental behaviors of contaminants in the presence of FDOM.

西安PM_(2.5)碳组成及水溶性有机物分子特性和来源季节差异

利用平行因子分析和后向轨迹模型,采用紫外光谱法、三维荧光光谱法,分析西安市PM_(2.5)碳组成及水溶性有机物(Water-Soluble Organic Matters,WSOM)的荧光组分、分子特性和来源。结果显示,西安市各季节PM_(2.5)及其有机碳(Organic Carbon,OC)和元素碳(Elemental Carbon,EC)的质量浓度由高到低依次为:冬、秋、春、夏,且南北郊差异不显著。PM_(2.5)中水溶性有机碳(Water-Soluble Organic Carbon,WSOC)质量浓度为3.50~17.29μg/m^(3),冬季WSOC质量浓度最高。四季的WSOM中均含有紫外光类腐殖质和可见光类腐殖质。秋、冬和夏季类富里酸的荧光强度占比最大。WSOM的E_(2)/E_(3)、E_(3)/E_(4)和AAE值由高到低依次是:冬、春、夏、秋。SUVA 254和MAE_(3)65值均在冬季最高,夏季最低。冬季WSOM的相对分子质量和腐殖化程度较小,分子苯环取代程度最大,光吸收能力对光吸收的波长依赖性较强;秋季WSOM的相对分子质量较大,腐殖化程度较强,光吸收的波长依赖性较弱;夏季WSOM的芳香化程度和光吸收能力及春季WSOM分子苯环取代程度最弱。碳组分质量浓度、UV 254、α350和荧光强度两两呈显著正相关(p<0.01)。WSOM的荧光指数(Fluorescence Index,FI)、生物源指数(Biogenic Index,BIX)和腐殖化指数(Humification Index,HIX)值分别为1.51~2.15、0.88~1.46、1.18~3.19。冬季WSOM的自生来源最高,夏季WSOM的陆源来源比例相对较大。西安市污染气团主要来自于陕西省区域气团传输。西安市四季PM_(2.5)碳组成及WSOM的荧光组分、分子特性和来源存在季节差异,但北郊和南郊的紫外荧光光谱特性和来源差异不显著。

不同碳源对污泥堆肥过程腐殖质电子转移能力的影响

以污水处理厂污泥为主要原料,葡萄糖、蔗糖分别作为外加碳源进行高温堆肥,探讨不同碳源对污泥好氧堆肥过程中腐殖质(HS)的电子转移能力(ETC)的影响。通过电化学方法测定了堆肥不同阶段的HS中胡敏酸(HA)和富里酸(FA)的电子供给能力(EDC)和电子接受能力(EAC),以三维荧光光谱、紫外-可见光谱、傅里叶变换红外光谱等分析方法表征HS的结构和组成变化。结果表明:两个处理HS的EDC、EAC和RER(电子循环率)在堆肥过程中都呈现不断增强的趋势;相比葡萄糖组试验,蔗糖组试验增强了HA和FA的ETC和RER,对HA的EDC和FA的EAC提升效果较好;光谱学分析发现,蔗糖组试验促进了蛋白类物质的降解和类胡敏酸、类富里酸物质的形成,且腐殖化程度、芳香化程度和含氧活性基团含量高于葡萄糖组试验。相关性分析表明,类胡敏酸物质和芳香族物质的增加促进了HA的ETC和RER的增加,而分子量的增大,蛋白质的下降,腐殖化程度的提高,类富里酸和芳香族物质的形成有利于FA中ETC和RER的增强。因此,在选择污泥堆肥的外加碳源时,可通过蔗糖的投加来强化堆肥腐殖质电子转移能力。

北京市温榆河-北运河水系水质空间分布特征研究

采用水体三维荧光光谱(3D-EEMs)结合平行因子分析(PARAFAC)方法,研究了温榆河-北运河水系溶解性有机物(DOM)的荧光组分及其空间分布特征,并对沿岸污水处理厂、支流、干流的水质参数及其DOM组分之间的相互作用进行了分析。结果表明:温榆河-北运河水系干流溶解性有机碳(DOC)浓度与各支流接近,总磷浓度从上游到下游逐渐降低,氨氮和总磷污染严重。水体DOM共存在2类(4种)荧光组分,包括类腐殖质组分(类腐殖酸,C1;类富里酸,C2)和类蛋白组分(类色氨酸,C3;微生物代谢产物,C4)。污水处理厂出水汇入各支流后,水体DOM中的类腐殖质组分的比例上升。荧光比例显示,各河流DOM以C3组分为主,占比为24.76%~40.27%。水体荧光指数(1.58~1.72)、自生源指数(0.96~1.17)及腐殖化指数(0.74~0.81)计算结果指明,该水体的DOM组成具有内源和外源的双重特性,整体腐殖化程度低且自生源特性强。DOC与C1、C2和C4组分呈现极显著正相关,表明荧光组分可用于动态跟踪河流有机物;总氮与C1、C2组分呈极显著正相关,说明类腐殖质组分会对氮污染物浓度产生重要影响;总磷与自生源指数呈显著负相关(P<0.05),表现为DOM腐殖化程度越高,总磷浓度越低。

海拉尔河典型傍河型地下水源砷的富集机制与溶解性有机物三维荧光特性解析

傍河型地下水是我国北方地区较为普遍的一种饮用水水源地类型,其水质水量受临近河道和地下径流补充双重影响.海拉尔河沿线傍河型地下水源中砷浓度较高,备受关注.溶解性有机质(dissolved organic matter,DOM)是影响地下水中砷释放的主要因素,为此,本研究对海拉尔河和沿线地下水水源中砷(As)的含量和DOM进行调查监测,展开三维荧光光谱分析,利用平行因子法确定水体的有机物组分,对探究砷的富集机理具有重要意义.结果表明,满洲里水体中DOM包括含陆源类腐殖质(C1)、类醌化合物(C2)和微生物来源的腐殖质(C3)的3种组分.傍河地下水源的腐殖化程度高于地表河流,且浅水井多为陆源和微生物源混合来源有机物.有机质通过多种方式影响地下水中砷的浓度,主要为C1通过络合方式促进溶解性砷浓度升高,C2则穿梭于易分解的DOM、Fe和As之间,对微生物的氧化还原作用起传递作用.综上,在陆源类有机物和微生物利用内源有机碳的共同作用下,使As在地下水中的浓度逐年升高.

混凝-臭氧氧化对渗滤液生化出水有机微污染物的去除效果

为了探究混凝-臭氧氧化技术对渗滤液生化出水中有机微污染物的去除效能,以青岛某渗滤液生化出水为实验对象,分析了混凝剂种类、投加量及pH等因素对有机物的去除效果,研究了O_(3)、GAC/O_(3)、UV/O_(3)臭氧氧化体系对混凝出水去除效果的提升作用,进一步系统评估了混凝-臭氧氧化技术对渗滤液生化出水中抗生素类有机微污染物的去除效能。结果表明,当聚合硫酸铁(PFS)投加量为4g/L、pH=7、臭氧流量为80mg/min、反应30min时,PFS-UV/O_(3)对COD和色度(CN)的去除率分别为86.27%和99.06%,显著优于PFS-O_(3)和PFS-GAC/O_(3);在最优条件下,混凝-臭氧氧化抗生素具有良好的去除效果,PFS-UV/O_(3)对氧氟沙星、恩诺沙星、磺胺胍、金霉素的去除率分别为100%、95.06%、100%和100%;三维荧光-平行因子分析可知,经PFS-UV/O_(3)处理后渗滤液生化出水中腐殖类荧光物质特征峰消失,得以有效分解;技术经济分析可知,PFS-UV/O_(3)处理技术的能源消耗和成本分别为75.34kW·h/kg COD和53.00CNY/kg COD。整体而言,PFS-UV/O_(3)处理技术经济可行,具有潜在的应用前景。

基于三维荧光光谱的原酒品质评价模型建立

酒厂的生产主要采用传统的“看花摘酒”工艺,依靠工人的主观经验进行评价。实际生产中受到诸多因素的影响,导致接酒过程的不确定性,原酒品质的稳定性难以得到保证。通过采集原酒样本并配制掺加不同浓度酒尾(0.0%~2.0%)的复合原酒,进行荧光扫描得到三维荧光光谱,建立物质变化与荧光数据变化之间的联系:采取切除散射、拉曼归一化、Savitzky-Golay平滑、去除异常值等方法进行光谱预处理,通过平行因子分析将其分解为四个互不相关的组分,结合单物质荧光光谱特点进行综合相似度分析,对各组分进行了初步鉴别。结果表明,大部分酸类和酯类物质的荧光光谱与组分二相关性更大,组分二的荧光特性受酸类和酯类物质影响更大;数据集大小由781×61×164简化为4×164,达到了数据降维的效果。建立了支持向量机模型(SVM)对原酒品质进行评价,采取遗传寻优算法(GA)对支持向量机模型优化。GA-SVM模型较原始SVM模型性能有所提升,优化后的模型准确率由88.64%提升至95.45%,模型精确率由0.94提升至1.00。三维荧光结合化学计量学可以作为一种快速检测的有效手段对原酒质量进行评价,为酒厂摘酒过程实现在线检测提供支持。

基于荧光指纹的土门西沟小流域农业面源溯源研究

于2022—2023年采集密云水库的典型农业小流域土门西沟小流域内源样品构建指纹库,采集7、8月河道6个重点断面水样进行三维荧光光谱测定,通过平行因子分析解析小流域氮素来源。结果表明:研究区氮平均质量浓度为7.92 mg/L,主要形态为硝态氮;通过结合荧光激发发射矩阵与平行因子分析共解析出4种荧光组分,主要包括两种类腐殖质组分(C1、C2)及类蛋白组分(C3、C4),C1与农业有机肥施用有关,C2与堆肥有关,C3、C4主要来自农村生活污水或未分解的尿素化肥;研究区农村生活污水荧光指数平均值约为2.16,土壤浸提液荧光指数平均值约为1.83,农村生活污水在8月对农业面源约贡献35%;小流域丰水期水质波动主要与类腐殖质C1、C2组分相关,应对研究区有机肥带来的农业面源给予关注并加强管控。

基于三维荧光光谱与平行因子的混合有机农药检测分析

荧光光谱法作为一种快速、准确和非破坏性的检测方法,已广泛应用于农药残留的检测分析中。应用三维荧光光谱方法结合平行因子算法(PARAFAC)对混合有机农药进行定性定量分析。首先配制不同浓度的多杀菌素-高效氟氯氰菊酯、多杀菌素-宁南霉素混合体系,采用LS55荧光分光光度计扫描三维荧光光谱,发射波长范围设置为200~600 nm,激发波长范围分别为250~322和260~370 nm;应用平行因子算法对预处理后的光谱数据建模分析,通过三线性分解获得混合物中各组分的预测光谱及得分值,将预测光谱与实际光谱进行可视化匹配可识别出农药类别;最后将得分值与对应组分浓度值进行线性拟合分析,并计算均方误差、决定系数和回收率参数。结果表明,两种混合体系对应的各组分预测光谱与真实光谱在荧光特征峰处的重合度较高。多杀菌素-高效氟氯氰菊酯混合体系中各组分对应的预测均方误差分别为1.9856×10^(-8)和4.4800×10^(-7);多杀菌素-宁南霉素对应的预测均方误差分别为2.1552×10^(-7)和5.5722×10^(-5),模型决定系数均超过0.99,平均回收率接近100%,测试结果表明三维荧光光谱结合平行因子可实现对农药混合物的分析,具有较高的分析精度。该研究内容为混合有机农药的定性定量分析提供了一定的方法依据,可推广用于其他种类混合样品的检测分析。

基于EEM-PARAFAC的荧光示踪剂检测方法的研究

在油田的注水开发中,利用化学示踪剂进行井间连通性测试是了解出水优势通道特征、制定提高采收率方案的必要前提。但常见的荧光示踪剂在现场应用中易受原油中荧光物质的干扰导致识别率和检测精度较低,严重影响测试结果的准确性。采用三维荧光光谱法与平行因子分析法相结合的分析方法,对在多种荧光物质干扰下的模拟采出液中的荧光示踪剂进行定性分析与定量分析,成功得出模拟采出液中荧光示踪剂浓度,经计算平均相对误差约为12.75%。该方法用三维荧光光谱的数据处理代替传统的荧光背景测试,去除模拟采出液中不同荧光物质对待检测示踪剂的干扰,具有操作简单、准确性高、成本低、检测速度快的特点,可广泛应用于复杂背景条件下荧光示踪剂的快速检测。

水化学离子对溶解有机物三维荧光光谱影响及分类预处理方法

三维荧光光谱在水环境原位监测领域具有广阔的应用前景。但由于其预处理方法简单,不能完全排除水环境中水化学离子的干扰,会降低水质识别结果的准确性。目前尚无相关研究对这种干扰情况进行分类。为定量解释天然水环境中水化学离子对溶解性有机质(DOM)荧光特性的干扰,本研究以腐殖酸为研究对象,设置不投加离子为对照,其他样品中分别投加3种离子浓度(1-100mg·L^(-1))的9种水化学离子(Na^(+)、 Cl^(-)、 NO_(3)^(-)、 Ca^(2+)、 Mg^(2+)、 K^(+)、 CO_(3)^(2-)、 HCO_(3)^(-)、 SO_(4)^(2-))。通过平行因子法和区域积分法对不同离子浓度下DOM荧光光谱数据进行解析,得到水化学离子对DOM荧光特性(荧光区域积分、组分最大荧光强度、荧光参数)的影响。根据对荧光特性的影响程度,采用系统聚类分类方法,将水化学离子的干扰作用分为三类:第一类(10、 100 mg·L^(-1)CO_(3)^(2-)),增强;第二类(10、 100 mg·L^(-1)SO_(4)^(2-)和100 mg·L^(-1)NO_(3)^(-)),减弱;第三类(1、 10 mg·L^(-1)NO-3、未添加离子、 1 mg·L^(-1)CO_(3)^(2-)、SO_(4)^(2-)和1、 10、 100 mg·L^(-1)Ca^(2+)、 Mg^(2+)、 K^(+)、 HCO_(3)^(-)、 Na^(+)、 Cl^(-)),无显著影响。结果表明,当天然水环境中的水化学离子属于第三类离子时,可采用三维荧光光谱进行水环境监测。在其他情况下,应优先考虑在预处理过程中去除水化学离子干扰的方法,例如离子回旋共振质谱法等;或者加强三维荧光光谱技术与其他技术的联合,在减少单一技术局限性的同时,获得更全面的信息。该研究为还原真实荧光光谱提供了数据基础,为三维荧光与其他技术的联合应用提供科学依据。

9-羟基菲对α-葡萄糖苷酶的活性影响及相互作用研究

α-葡萄糖苷酶(GAA)作为一类重要的糖苷水解酶,是维持人体血糖平衡的重要功能性蛋白质。长期以来,为实现高血糖人群的降糖,研究人员多关注于探寻具有GAA活性抑制作用的食品、药品,但鲜有研究关注于人体非主动摄取的外源物质对GAA正常生理功能可能产生的影响。该研究选取典型多环芳烃类物质—菲的羟基代谢产物9-羟基菲(9-OHPhe),探究其对GAA活性功能的影响及潜在机制。为获得9-OHPhe与GAA的结合作用信息,PARAFAC法被应用于光谱重叠的9-OHPhe和GAA的三维荧光光谱(EEM)数据的解析,同时分子对接法被运用于分析分子层面两者结合的微观信息。9-OHPhe对GAA的活性有抑制作用,相应的IC50值为(7.59±1.91)μmol L^(-1);PARAFAC可有效应用于荧光光谱重叠的GAA和9-OHPhe反应体系的荧光数据解析;9-OHPhe可引起GAA内源荧光的静态猝灭,两者能形成1∶1复合物,在298 K下其结合常数为(8.91±0.68)×10^(3) L·mol^(-1);9-OHPhe与GAA的GLN281、LEU305、ASN319、LEU321、TYR322、LEU323和TYR352之间产生了疏水作用力,与GLN309和ASN319分别形成了键长为2.71和3.05Å的氢键;低浓度的9-OHPhe可使GAA的二级结构变得稳定,但过高浓度的9-OHPhe则会破坏GAA的结构稳定性。9-OHPhe对GAA活性有明显抑制效应,提示相关外源污染物进入健康人体后经这一途径所可能引起的血糖平衡紊乱值得关注和深入研究。

CW-MFC系统启动过程中溶解有机物的荧光光谱解析

为判断CW-MFC反应器运行状态提供一种简单且快速的监测方法,利用三维荧光光谱法研究人工湿地-微生物燃料电池耦合系统(CW-MFC)启动过程中溶解性有机物(DOM)的光谱特征。结果显示CW-MFC反应器启动阶段的循环进水周期内类蛋白质峰荧光逐渐变弱,说明反应器内部微生物有较好的活性,而类腐殖质和类富里酸峰荧光呈现逐渐增强的趋势。同时,随着驯化时间的推移,在连续流进水周期内系统的输出电压基本维持在300 mV左右,COD、NH_(4)^(+)-N、TP的平均去除率也逐渐趋于稳定,分别为82.66%±4.47%、73.52%±6.95%和55.42%±8.59%。并通过比较反应器的出水中DOM组分荧光强度得分值,发现从启动到稳定运行的过程中反应器内部微生物的活性和代谢逐渐稳定,说明利用三维荧光光谱技术判断反应器是否运行稳定具有可行性。

冬季沱江(成都段)水体中溶解性有机质(DOM)的组成、分布及来源分析

以冬季沱江流域成都段为研究对象,通过紫外-可见吸收光谱、平行因子模型(EEMs-PARAFAC)及主成分分析(PCA)方法,探讨其水体中溶解性有机质(DOM)的组份特征及来源.结果表明,冬季沱江流域成都段水体中共解析出3种荧光组分,分别为分子量较高的UVA类腐殖质C1、内源类蛋白中的类酪氨酸组分C2和分子量较大的芳香氨基酸腐殖物质组分C3,其中C2主要为外源输入,C2、C3的则是以内源为主的混合型输入,3种组分分别占总荧光强度的22.9%、51.3%和25.8%.通过对比分析水体中DOC、SUVA254和SR,发现研究区整体DOM腐殖化程度和DOM分子量大小依次为下游>中游>上游;利用主成分分析法(PCA)确定研究区水体DOM的来源,其中内源输入贡献率为77.64%,外源输入贡献率为10.13%,累计方差贡献率为87.77%。基于上述分析结果,能从一定程度上反映冬季沱江流域成都段的水质状况。

不同有机肥对生菜生育期土壤剖面DOM分布的影响

施用有机肥是农作物生产过程中提质增效的有效途径,研究不同来源有机肥施加下土壤剖面溶解性有机质(DOM)的分布规律有助于优化有机肥利用及进一步了解DOM环境行为。采用二维相关光谱(2DCOS)等方法,研究施加不同来源有机肥(猪粪、鸡粪、羊粪、牛粪和沼渣)对土壤剖面DOM分布规律的影响。结果显示:有机肥还田主要影响土壤DOM的相对含量及组分构成。施加不同来源有机肥后,土壤中DOM相对含量始终大于对照(CK)处理,其中0~10cm土层DOM相对含量影响最大,平均增加14.67g·kg-1。不同类型有机肥对增加剖面DOM有一定差异,其中鸡粪有机肥对剖面DOM增加影响最大,增加了21.42%。有机肥的施加主要提高了类酪氨酸组分(C4)的相对含量,对10~20cm土层C4相对含量的影响最大,平均增加4.12%,其中羊粪和沼渣有机肥影响最大,分别增加了7.80%、7.89%。2D-COS分析显示,不同来源有机肥施用对溶解性微生物代谢产物、类蛋白质组分(295nm、315nm)影响最大,CK、鸡粪有机肥处理主要影响的是溶解性微生物代谢产物组分,其他处理最先响应的是类蛋白质组分;不同来源有机肥施用下,腐殖化指数HIX和Fn(330)、Fn(280)均随土层深度的增加而减小,但HIX和Fn(330)、Fn(280)的变化随有机肥种类不同而有所差异,其中牛粪有机肥对HIX和Fn(330)影响最大,羊粪有机肥对Fn(280)影响最大。生物指数BIX和新鲜度指数β∶α随着土层深度增加而增加,其中沼渣的影响最显著,但荧光指数FI并无显著变化。