Environmental assessment and nano-mineralogical characterization of coal,overburden and sediment from Indian coal mining acid drainage

The deterioration of environmental conditions is the major contributory factor to poor health and quality of life that hinders sustainable development in any region.Coal mining is one of the major industries that contribute to the economy of a country but it also impacts the environment.The chemical parameters of the coal,overburden,soil and sediments along with the coal mine drainage(CMD)were investigated in order to understand the overall environmental impact from high sulphur coal mining at northeastern coalfield(India).It was found that the total sulphur content of the coal is noticeably high compared to the overburden(OB)and soil.The volatile matter of the coal is sufficiently high against the high ash content of the soil and overburden.The water samples have a High Electrical Conductivity(EC)and high Total Dissolve Solid(TDS).Lower values of pH,indicate the dissolution of minerals present in the coal as well as other minerals in the mine rejects/overburden.The chemical and nano-mineralogical composition of coal,soil and overburden samples was studied using a High Resolution-Transmission Electron Microscopy(HR-TEM),Energy Dispersive Spectroscopy(EDS),Selected-Area Diffraction(SAED),Field Emission-Scanning Electron Microscopy(FE-SEM)/EDS,X-ray diffraction(XRD),Fourier Transform Infrared Spectroscopy(FTIR),Raman and Ion-Chromatographic analysis,and Mossbauer spectroscopy.From different geochemical analysis it has been found that the mine water sample from Ledo colliery has the lowest pH value of 3.30,Tirap colliery samples have the highest electrical conductivity value of5.40 ms cm^(-1)Both Ledo and Tirap coals have total sulphur contents within the range 3-3.50%.The coal mine water from Tirap colliery(TW-15 B)has high values of Mg^(2+)(450 ppm),and Br^-(227.17 ppm).XRD analysis revealed the presence of minerals including quartz and hematite in the coals.Mineral analysis of coal mine overburden(OB)indicates the presence both of pyrite and marcasite which was also confirmed in XRD and Mossbauer spectral analysis.The presented data of the minerals and ultra/nano-particles present shows their ability to control the mobility of hazardous elements,suggesting possible use in environmental management technology,including restoration of the delicate Indian coal mine areas.

Synthesis of a Green Nano-Silica Material Using Beneficiated Waste Dunites and Its Application in Concrete

Nano-silica, one of the substances boosting the field of nanomaterials, can be produced by dissolving olivine in acid. The dissolution of olivine is a convenient alternative route to the existing methods of nano-silica production (neutralization of sodium silicate and flame hydrolysis) because the olivine dissolution is a low temperature process making this method cheaper and greener. Furthermore, this process can use waste olivine materials for the production of nano-silica. The produced nano-silica has a specific surface area between 100 and 400 m2/g;a primary particle size between 10 and 25 nm, which is agglomerated in clusters;and an impurity content below 5 wt.%. In addition, olivine nano-silica can be classified as a pozzolanic material with an activity index of 101%. The optimum replacement level of olivine nano-silica in conventional vibrated concrete is around 5% by volume resulting in: 1) a compressive strength increase of 20%;2) a CO2 emission reduction of 3%. Therefore, the use of the olivine nano-silica in CVC does not only improve the compressive strength but also reduce the CO2 emissions.

A Review of Research Progress in the Genesis of Colloform Pyrite and Its Environmental Indications

Colloform pyrite is a special form of nano-micro polycrystalline aggregation growth, for which a suitable term is ＂aggregates of nano-micro crystals＂. This kind of colloform texture is observed in various geological bodies, such as ancient sedimentary rocks, modern marine and lake sediments, various types of ore deposits, and modern seafloor hydrothermal vents. This paper summarizes the latest developments and research into the definition, formation mechanisms, and environmental indications of colloform pyrite. There appears to be three main formation mechanisms of colloform pyrite： pseudomorphic replacement; biogenic precipitation; and inorganic precipitation. The morphology, particle size, trace element content and preferential growth orientations of coUoform pyrite microcrystals can be important indicators for sedimentary environments, hydrothermal activity, and ore-forming processes. We suggest that the microscopic features of nano-micro crystals in colloform pyrite and their aggregation growth patterns need further investigation. The relationships between formation mechanisms of colioform pyrite, organic activity and depositional environments require further exploration. To reveal the nature of nano-micro grain aggregation growth in colloform pyrite and analyse its growth environment and evolutionary history, it is supposed to apply nanoscientific and nanotechnological methods, further integrate consideration of macroscopic geological backgrounds and microscopic mineral growth phenomena, combine high-resolution imaging systems and in situ quantitative microanalysis methods and constitute a mergence of earth science, thermodynamics and kinetics, life science, material science, and chemistry in the study.

Microplastics and Nano-Plastics: From Initiation to Termination

Following the advent of the Industrial Revolution, plastic pollution has been a serious environmental issue while micro- and nano-plastics have been a cynosure of researchers’ attention in the twenty-first century. This is due to the improved knowledge of its ecotoxicological effects and the global pushforward towards sustainability. There is a growing concern that the increasing presence of microplastics and nanoplastics (MNPs) in aquatic habitats poses a threat to marine life, and it is predicted that nanoplastics will be just as ubiquitous as macro- and micro-plastics, but far more destructive to living organisms due to their ability to infiltrate cells. Recent research has shown that marine and freshwater biota become entangled with plastic litter, which disrupts the ecosystem. Aquatic creatures are known to absorb and deposit these new pollutants in their digestive systems, as has been documented in several studies. More recent research has also examined their co-occurrence and toxicity with other emerging contaminants, including their prevalence and effects in food, air, and soil. Using articles extracted from a six-year period from Scopus, ACS Publications and Google Scholar, this review explores the origins, fates, occurrence in the food chain, exposure routes, cellular interactions of microplastics and nano-plastics, in addition to the ecotoxicological impacts, analytical methods, and the potential remedies for combating pollution and toxicity. Ultimately, this review is a comprehensive, updated addendum to available reviews on micro- and nano-plastics.

低成本小批量微纳卫星控制系统的研制实践

针对微纳卫星的研制特点,结合控制系统研制过程中的具体实践,从单机产品设计、系统方案设计、测试和环境试验,以及软件开发方面,给出了微纳卫星降低成本、提高可靠性与研制效率的措施和建议.通过采用控制系统内部的冗余备份设计,以及系统级可靠性措施,简化了系统配置,并提高了系统可靠性.通过进行系统级的热循环试验可降低研制成本,并达到可靠性试验筛选的目的.通过开展平台化和通用化设计,完善和改进软件开发流程,提高了研制效率.所述方法和措施在卫星研制中取得了较好的效果.

机器学习辅助光谱分析技术在环境微/纳塑料研究中的应用

微/纳塑料在环境中广泛存在,威胁着全球生态系统的平衡和稳定,因此有必要确定和评估微/纳塑料的环境赋存特征、环境行为和效应以及生态毒性效应。然而微/纳塑料具有的低浓度、小尺寸及容易吸附其他物质等特点,为其在复杂环境基质中的分析带来了巨大挑战。大多数分析方法在提供环境样本中微/纳塑料的定性定量信息方面存在成本高、准确性差、时间效率低等问题,而具有无损、高效、操作方便等优点的光谱分析技术可以弥补这些方法的不足。但采集的微/纳塑料光谱信号可能会受到环境样本中复杂成分的背景噪声干扰,亟需采用智能化手段提高分析的准确性和效率。机器学习具有强大的数据处理和自动化分析能力,准确性高、应用性广,适用于复杂光谱数据的分类和解析,将机器学习与光谱分析技术相结合有望成为微/纳塑料分析的可靠方法。首先对常用的机器学习辅助光谱分析技术进行综述,然后系统性地讨论了机器学习辅助光谱分析技术在微/纳塑料的环境赋存特征、环境行为和效应、生态毒理效应等研究中的应用,最后对该技术的发展前景进行了总结和展望。机器学习辅助光谱分析技术有望为环境中微/纳塑料的生态环境健康风险评估和污染防治提供重要数据支持。

地表水环境中微(纳米)塑料污染防控面临的挑战

微(纳米)塑料因其可在水体、沉积物、土壤等环境介质中长期存在并危害生态环境,且在环境中难降解的特性已成为一种新污染物。根据国内地表水环境中微(纳米)塑料的分布、来源和生态毒性效应的相关研究发现,地表水环境中微(纳米)塑料的来源繁杂,直接来源主要包括个人护理品、工农业制备、各类垃圾不当处置等;间接来源为污水处理厂的污水排放、地表径流、原始塑料的风化降解等。微(纳米)塑料的生态毒性组成复杂,除其本身对于生物体的生化胁迫外,还易与其他污染物形成复合污染,对水生生物产生交互效应。因此,研究治理地表水环境微(纳米)塑料污染已刻不容缓,本文可为地表水环境中微(纳米)塑料污染防控和生态风险研究提供理论参考。

胡敏酸对纳米二氧化钛光催化降解土霉素的影响

胡敏酸普遍存在于土壤中,可与环境中的纳米二氧化钛结合,从而改变纳米二氧化钛的性质及其与共存污染物的相互作用机制。研究以土霉素作为代表性环境污染物,通过模拟太阳日照探究胡敏酸对纳米二氧化钛光催化降解土霉素的影响。结果显示:土霉素在溶液中易光解,碱性条件更易于光解,猝灭试验表明羟基自由基与超氧自由基参与了光解;土霉素的降解率与纳米二氧化钛投加量、溶液初始pH值正相关,与溶液土霉素初始质量浓度负相关;胡敏酸对纳米二氧化钛光催化降解土霉素兼具促进与抑制作用,胡敏酸初始质量浓度为100 mg/L、250 mg/L时,可促进土霉素的光催化降解,而胡敏酸初始质量浓度为500 mg/L、1000 mg/L时,形成的复合物会抑制土霉素的光催化降解。

纳米零价铁的制备及其可持续性评估

纳米零价铁(nZVI)是一种广受关注的环境修复材料,其兼具纳米材料的反应活性和零价铁的还原特性,扩展了铁基材料在场地修复和污染物去除中的应用范围,尽管纳米级的零价铁会带来更优异的使用效果,但更加复杂的制备过程也导致了更多的环境足迹和生产成本,制备方式正逐渐成为限制nZVI发展的关键。介绍了nZVI的发展历程,综述了制备方式的研究进展,从可持续发展的角度梳理了nZVI的主要制备方法,在总结优势特点的同时分析了制备过程可能造成的环境影响。以此为基础,研究了对nZVI典型制备方法的可持续性评估,定量分析了潜在的不可持续因素,着重说明了制备过程对电力能源的依赖。根据已有研究成果,对液相激光烧蚀等有潜力大规模制备nZVI的生产方式进行了展望,并进一步阐述了合理选择制备方式的重要性,强调了可持续性评估在nZVI未来发展中不可或缺的地位,希望能对研究者和决策者在选择和改良nZVI制备方法时提供参考。

MoS_(2)/Ti-WC纳米多层薄膜结构设计及其宽温域摩擦性能研究

目的探究环境温度对MoS_(2)/Ti-WC纳米多层薄膜摩擦磨损性能的影响,探讨并揭示薄膜在高温环境下的损伤机理。方法采用非平衡磁控溅射技术制备MoS_(2)/Ti-WC纳米多层薄膜,评价Ti、WC双功能组元以及纳米多层结构设计对薄膜表面形貌和微观结构的影响。利用X射线衍射仪(XRD)、扫描电镜(SEM)、扫描探针显微镜(SPM)等表征手段对薄膜的晶体结构、表截面形貌以及表面粗糙度进行分析,利用原位纳米压痕仪对薄膜的力学性能进行评估,利用高温摩擦磨损试验机评价薄膜在不同温度环境(25~300℃)下的摩擦磨损性能,进一步通过激光共聚焦对磨痕和磨斑进行光学形貌分析,并利用能谱仪(EDS)和共聚焦显微拉曼光谱(Micro-Raman)对钢配副表面的摩擦转移膜进行成分分析。最终揭示MoS_(2)/Ti-WC纳米多层薄膜在不同温度下的磨损机理。结果MoS_(2)/Ti-WC纳米多层的结构设计可以诱导MoS_(2)(002)晶面的择优生长,获得表面平整光滑、结构致密的薄膜。相比于MoS_(2)/Ti薄膜,WC纳米层的引入,赋予薄膜更高的硬度和硬/弹比。MoS_(2)/Ti-WC纳米多层薄膜在潮湿空气中的平均摩擦因数为0.07,平均磨损率为6.14×10^(-7)mm^(3)/(N·m)。结论MoS_(2)/Ti-WC纳米多层薄膜在宽温域(100~300℃)内保持稳定的摩擦性能,这得益于薄膜纳米多层的结构设计、高的硬/弹比以及优异的抗氧化性能,同时在钢配副表面形成了连续且致密的转移膜。

纳米MnO_(2)炭基复合材料的制备及吸附去除水中La(Ⅲ)离子性能研究

稀土是一种珍贵的战略资源,但其开发冶炼过程会产生大量废水并造成严重的环境污染,因此如何高效吸附去除废水中稀土离子被大量研究。通过共沉淀法将纳米MnO_(2)负载至生物炭(Biochar, BC)表面,得到纳米MnO_(2)炭基复合材料(Nano-MnO_(2)Carbon Matrix Composites, MBC),并用于吸附去除废水中的La(Ⅲ)离子。研究通过表征分析材料的物理和化学结构变化,考察了应用环境条件对MBC吸附La(Ⅲ)离子性能的影响,在308 K、pH=6.0条件下,0.55 g/L MBC对20 mg/L La(Ⅲ)离子模拟废水进行吸附处理,24 h后吸附效率达到95.65%。吸附动力学、等温线和热力学研究显示,MBC对La(Ⅲ)离子的吸附过程符合拟一级动力学模型和Langmuir模型,为单分子层吸附,最大吸附质量比可达43.49 mg/g;通过D-R模型计算的Es为23.12 kJ/mol,表明吸附过程偏向于化学吸附,且是自发的吸热过程。MBC经5次循环后,吸附性能仍达到初始吸附质量比的79.18%,MBC作为炭基吸附剂用于吸附水中的La(Ⅲ)离子,展现出一定的应用前景。

磁性纳米铁对土壤理化性质及微生物群落和代谢的影响研究进展

近年来,磁性纳米铁因其独特性能在生物医学、农业、工业、生命科学及环境保护领域广泛应用.随着磁性纳米铁的大范围应用,其对环境和人体健康将带来的潜在影响,已经引起科学界的广泛关注.本文系统总结了近年来磁性纳米铁的相关文献资料,探讨了磁性纳米铁的合成方法、表征及环境应用;我们重点强调了磁性纳米铁对土壤理化性质及微生物群落和代谢的潜在影响.最后展望了磁性纳米铁在未来的环境应用、发展及纳米毒理学亟待研究的重要问题.本文旨在更加全面地揭示磁性纳米铁的环境可持续性,为其安全使用和环境功能化应用提供一定的参考.

纳米零价铁合成、改性及对重金属的修复机制研究进展

土壤和水体中日益严重的重金属污染引起了极大关注。纳米零价铁(nZVI)及其改性材料由于具有优越的比表面积、还原能力、吸附性能和流动性被广泛报道。该文首先介绍了目前nZVI的主要合成方法(包括球磨法、液相还原法、碳热还原法、电化学法、绿色合成法),讨论了nZVI的常见改性方式(包括表面改性nZVI、硫化nZVI和负载nZVI)。其次,探讨了nZVI去除重金属(Pb(II)、Cu(II)、Cr(VI))的机理和作用。最后,对nZVI颗粒在工业水平上的应用前景以及它在实际应用中的挑战进行了总结,并提出了未来该领域研究发展的展望,以期待为nZVI的研究提供新的思路。

纳米氧化锌溶解性及共存镉离子的影响

纳米ZnO是应用最为广泛但具有一定生物毒性的金属型纳米颗粒之一,其致毒机制之一可能来自其溶解释放的锌离子。共存重金属离子可能会影响纳米ZnO的溶解,反之,纳米ZnO可能吸附去除重金属离子,但是其相关作用尚不清楚。文章通过批试验探讨了不同纳米ZnO投加量(200、400、1000和2000 mg/L)在不同震荡时间(12、24和36 h)时纳米ZnO的溶解性及共存镉离子的影响。结果表明,去离子水中纳米ZnO投加量1000 mg/L时锌的溶出量最大(3.71 mg/L),但不受震荡时间的影响。添加1 mg/mL的镉离子显著增加了纳米ZnO的溶解,在纳米ZnO投加量为200 mg/L时,锌离子的溶出量和溶出率高达95 mg/L和55%;增加纳米ZnO投加量降低锌离子含量和溶出率,但增加震荡时间没有增加其溶解性。同时,纳米ZnO能够降低镉离子浓度,说明纳米ZnO可以吸附水中的镉离子。总之,共存镉离子能够改变纳米ZnO的环境行为,并可能因而影响其生物毒性。

中药渣综合利用研究现状及展望

随着中医药行业的发展和中医药制取技术的进步,中药渣的产生量也与日俱增,现年产量已超过3 500万t。利用好中药渣资源不仅能保护环境,降低企业支出,还能创造巨大的经济效益。本文从活性成分再提取、环境治理、作为饲料或饲料添加剂、作为有机肥料与栽培基质、作为轻工业生产原料等方面综述了中药渣传统生态经济化利用现状,从开发能源物质、膳食纤维产品、纳米纤维素类产品及复合材料等方面分析了中药渣高值化利用现状,并对中药渣综合利用进行了展望,以期为中医药产业高质量发展提供参考。

基于纳米TiO_(2)气敏性传感器的研究进展

纳米TiO_(2)材料由于具有较宽的能带及光反应性强的半导体特性,有望成为新一代气敏传感技术的首选基体材料。文中综述了当前国内外基于TiO_(2)气敏性传感器的技术现状,重点介绍了不同空间结构的TiO_(2)气敏性传感器,探讨了TiO_(2)与不同材料复合后的传感特性并揭示就其传感机理,并展望了TiO_(2)气敏性传感器未来的发展趋势。

环境友好超疏水材料的制备及应用研究进展

随着科技的进步,超疏水材料的制备技术得到了快速发展,其优越的性能在表面自清洁、废弃污水的分离处理、低温下防覆冰、特殊环境的耐腐蚀等方面有广阔的应用前景,但制备技术存在过程复杂、成本高、难以大面积制备和对环境不友好等缺点及对性能的评价体系不完善、与实际应用所处环境不符合等问题。基于上述问题,本文从构筑材料的选用、评价体系的分析等方面进行综述,希望为该方向未来的发展提供新的思路。

废建材再生环保复合砂浆配比优化改性及性能测试

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