电子束照射法脱硫脱氮技术工艺

在阐明电子束照射法脱硫脱氮技术的机理、流程、特点的基础上 ,探讨了该工艺在应用过程中存在的主要经济、技术问题。     

Insights into the electron transfer mechanisms of permanganate activation by carbon nanotube membrane for enhanced micropollutants degradation

● A CNT filter enabled effective KMnO₄ activation via facilitated electron transfer. ● Ultra-fast degradation of micropollutants were achieved in KMnO₄/CNT system. ● CNT mediated electron transfer process from electron-rich molecules to KMnO₄. ● Electron transfer dominated organic degradation. Numerous reagents have been proposed as electron sacrificers to induce the decomposition of permanganate (KMnO₄) by producing highly reactive Mn species for micropollutants degradation. However, this strategy can lead to low KMnO₄ utilization efficiency due to limitations associated with poor mass transport and high energy consumption. In the present study, we rationally designed a catalytic carbon nanotube (CNT) membrane for KMnO₄ activation toward enhanced degradation of micropollutants. The proposed flow-through system outperformed conventional batch reactor owing to the improved mass transfer via convection. Under optimal conditionals, a > 70% removal (equivalent to an oxidation flux of 2.43 mmol/(h·m²)) of 80 μmol/L sulfamethoxazole (SMX) solution can be achieved at single-pass mode. The experimental analysis and DFT studies verified that CNT could mediate direct electron transfer from organic molecules to KMnO₄, resulting in a high utilization efficiency of KMnO₄. Furthermore, the KMnO₄/CNT system had outstanding reusability and CNT could maintain a long-lasting reactivity, which served as a green strategy for the remediation of micropollutants in a sustainable manner. This study provides new insights into the electron transfer mechanisms and unveils the advantages of effective KMnO₄ utilization in the KMnO₄/CNT system for environmental remediation.     

The relevance of James Lovelock’s research and philosophy to environmental science and academia

James E. Lovelock, famed for his Gaia hypothesis, which views the Earth as a living integrated and interconnected self-regulating system whose equilibrium comes about from complex energy-based interactions and feedback loops, ultimately sustaining life, passed away at the end of July, 2022 at the age of 103. Not only are the adaptive mechanisms of Gaia central to the conversation of environmental homeostasis, they lie at the heart of climate change and global warming. Lovelock is also remembered as the co-inventor of the electron capture detector that eventually allowed for the sensitive detection of chlorofluorocarbons and pesticides. Finally, Lovelock’s free-spirited nature and research independence allow academia to rethink current research’s modus operandi.     

纳米硫化镉对A549细胞的损伤研究

研究纳米硫化镉(Nano-Cd S)材料对肺癌细胞系A549的毒性及氧化损伤作用。培养A549细胞,经传代后接种于6孔板中,每孔2 m L完全培养基,接种次日进行染毒。用直径20~30 nm、长度80~100 nm的Nano-Cd S进行染毒,染毒浓度分别为0、5、10、20、40和80 mg·L~(-1)。染毒24 h后用MTT检测细胞存活率,以存活率在80%左右的浓度为后续实验染毒浓度。应用流式细胞技术,用荧光探针法检测A549细胞的活性氧(reactive oxygen species,ROS)含量,PI-Annexin-V法检测细胞凋亡情况;用试剂盒检测细胞中超氧化物岐化酶(superoxide dismutase,SOD)和过氧化氢酶(catalase,CAT)活性以及丙二醛(malondialdehyde,MDA)含量,判断细胞氧化损伤情况。不同浓度Nano-Cd S处理细胞24 h之后,细胞存活率随剂量的增加而下降,浓度为10、20、40和80μg·L~(-1)时,存活率分别为(88.71%±0.80%)、(81.93%±3.06%)、(75.23%±1.13%)和(70.66%±5.63%),且各组间差异均具有统计学意义(P0.05)。以浓度为10和20 mg·L~(-1)的Nano-Cd S染毒24 h后,胞内ROS含量和细胞凋亡率随染毒剂量的增加而增加(P0.05);浓度为10 mg·L~(-1)时,细胞凋亡率为(6.26%±0.44%)。与对照相比,各染毒组SOD和CAT活性和MDA含量升高,20 mg·L~(-1)染毒组SOD和CAT活性和MDA含量高于10 mg·L~(-1)染毒组(P0.05)。研究表明,纳米硫化镉能引起A549细胞的氧化损伤和细胞凋亡,具有明显的细胞毒性。     

预处理方法对香蒲厌氧发酵联产H2-CH4效能的影响

通过厌氧发酵动力学分析、还原糖及其他代谢产物变化情况,结合香蒲微观结构解析,系统研究酸(HCl)、碱(NaOH)、酶(纤维素酶R-10)3种预处理对水生植物厌氧发酵联产H₂-CH₄的影响. 结果表明:香蒲分别经酸、碱、酶3种预处理后,厌氧发酵联产累积H₂、CH₄产量及含量均显著提高,c(HCl)、c(NaOH)均为1.0mol/L, w(纤维素酶R-10)(以底物计)为10mg/g时,预处理最佳. 其中1.0mol/L NaOH预处理香蒲效果最佳,φ(H₂)(H₂含量)达30.09%,累积产H₂量(以香蒲干质量计)达11.39mL/g;φ(CH₄)(CH₄含量)最高达67.48%,累积产CH₄量(以香蒲干质量计)达41.87mL/g;还原糖利用率达50.87%,sCOD(溶解性化学需氧量)利用率达66.17%. 纤维素酶预处理后香蒲产CH₄能力显著提高,产CH₄阶段φ(CH₄)最高为71.39%,累积产CH₄量达46.32mL/g,还原糖利用率达72.10%. 扫描电镜微观结构分析表明,碱预处理对香蒲纤维素结构破坏程度最大,可有效增加香蒲与微生物接触面积,有利于厌氧发酵联产H₂-CH₄工艺的快速启动和稳定运行.      

Electron microscopy documenting the cellular metabolic fate of Zn IONS∗

In vertebrates and invertebrates Zn exist as complexed compounds with metallothioneins. However, its cellular level effects and metabolic fates are scantly documented. In the elucidation of this fact, EM results on hepatic cellular alterations in fish under lethal dose exposure at 4.0 ppm over a week is illustrated.

A large number of lysosomes in hepatic cells prevailed on exposure to Zn in its sulfate form. Evidently, due to metal compound stress and cellular damage lysosomal activity is augmented. The lysosomes harboured digestible material, presumably the aforementioned substrates. Contrary to it, fat droplets prevailed while glycogen depletion is noticeable. Unlike the effects of Hg, the nuclei were normal with granular chromatin and prominent nucleoli. However, the mitochondria contained some small intramitochondrial bodies. Similar to the effects of Hg, the cell membrane remained intact.

In vivo enzymatic studies indicated augmentation in catalase, acid‐ and alkaline‐phosphatases, while glucose‐6‐phosphatase is inhibited. However, only alkaline‐ and glucose‐6‐phosphatases are inhibited under in vitro conditions.

Thus, it is evident that Zn enhances cellular bioenergetic requirements culminating in glycogen depletion owing to stress, concomitantly envisaging inhibition of oxidative phosphorylation in the electron transport system.     

薇甘菊浸提液对福寿螺主要器官组织损伤的扫描电镜观察

采用薇甘菊（Mikania micrantha H.B.K.）的乙酸乙酯浸提液对福寿螺（Pomacea canaliculata）进行浸杀,通过扫描电镜观察福寿螺头足部、外套膜及肝脏组织的损伤状况,探讨薇甘菊化感物质对福寿螺器官组织结构的影响。经过薇甘菊质量浓度为100mg·L^-1提取液浸杀2d后,福寿螺主要器官出现了明显的组织损伤。头足部肌肉组织出现明显的杂乱丝条状并有断裂,部分有侵蚀剥落,表现为较大的组织缺损;外套膜有大量的细胞被浸润,呈疏松不整齐的结构;肝脏表面粗糙,凹凸相间的皱褶形成起伏不平的组织,其间有深浅不一的裂痕,并有侵蚀孔状损伤。扫描电镜的观察结果可为探讨薇甘菊浸提液对福寿螺的毒杀机理提供一定的依据。     

Developing “precise-acting” strategies for improving anaerobic methanogenesis of organic waste: Insights from the electron transfer system of syntrophic partners

Methanogenesis is the last step in anaerobic digestion, which is usually a rate-limiting step in the biological treatment of organic waste. The low methanogenesis efficiency (low methane production rate, low methane yield, low methane content) substantially limits the development of anaerobic digestion technology. Traditional pretreatment methods and bio-stimulation strategies have impacts on the entire anaerobic system and cannot directly enhance methanogenesis in a targeted manner, which was defined as “broad-acting” strategies in this perspective. Further, we discussed our opinion of methanogenesis process with insights from the electron transfer system of syntrophic partners and provided potential targeted enhancing strategy for high-efficiency electron transfer system. These “precise-acting” strategies are expected to achieve an efficient methanogenesis process and enhance the bio-energy recovery of organic waste.     

Reaction pathways of dimethyl phthalate degradation in TiO2-UV-O2 and TiO2-UV-Fe(VI) systems

The photocatalytic degradation of dimethyl phthalate (DMP) in aqueous TiO₂ suspension under UV illumination has been investigated using oxygen (O₂) and ferrate (Fe(VI)) as electron acceptors. The experiments demonstrated that Fe(VI) was a more effective electron acceptor than O₂ for scavenging the conduction band electrons from the surface of the catalyst. Some major intermediate products from DMP degradation were identified by HPLC and GC/MS analyses. The analytical results identified dimethyl 3-hydroxyphthalate and dimethyl 2-hydroxyphthalate as the two main intermediate products from the DMP degradation in the TiO₂–UV–O₂ system, while in contrast phthalic acid was found to be the main intermediate product in the TiO₂–UV–Fe(VI) system. These findings indicate that DMP degradation in the TiO₂–UV–O₂ and TiO₂–UV–Fe(VI) systems followed different reaction pathways. An electron spin resonance analysis confirmed that hydroxyl radicals existed in the TiO₂–UV–O₂ reaction system and an unknown radical species (most likely an iron–oxo species) is suspected to exist in the TiO₂–UV–Fe(VI) reaction system. Two pathway schemes of DMP degradation in the TiO₂–UV–O₂ and TiO₂–UV–Fe(VI) reaction systems are proposed. It is believed that the radicals formed in the TiO₂–UV–O₂ reaction system preferably attack the aromatic ring of the DMP, while in contrast the radicals formed in the TiO₂–UV–Fe(VI) reaction systems attack the alkyl chain of DMP.     

厦门近海沉积物中高分子有机质的来源初探

采用多步连续-湿法-化学方法,分离提纯了于2010年7月和12月在厦门近海采集的沉积物样品,获得3类高分子有机质,即腐殖酸（HA）、干酪根和碳黑（KB）和碳黑（BC）。以扫描电镜（SEM）作为有效的辅助手段,观察沉积物原样及高分子有机质的形貌特征,结合稳定碳同位素（δ13C）的分析,初步探讨了厦门近海沉积物中高分子有机质的来源。扫描电镜观察发现,在原样沉积物中存在多种海源物质（如钙质硅藻和圆筛藻/冠盘藻）;而在KB样品中同时发现类似于陆地植物的木质碎片以及来自海洋的藻胶鞘,暗示了其来源是海源与陆源共同作用的结果。稳定碳同位素研究表明厦门湾近海海域沉积物中有机质以陆源影响占优势,其比例在58.32%至84.45%之间;δ13C值整体上显示为夏季的贫于冬季的,这与研究区域的生态系统中陆源C3植被和海源水生植物的繁殖生长有关,同时还有排海污水及化石燃料煤燃烧后或者运煤船只洒落的碎屑的贡献。