基于方向图的天线分类模型的分析与研究

文章重点考察不同天线在远区场同一接收阵列处的场强大小之间的不同关系特征,并利用神经网络对不同天线的这种非线性特征进行模拟,从而实现基于天线方向图对不同天线的分类,并对不同分类模型进行对比。     

国际马拉松赛期间厦门同期气温诊断分析

利用厦门市长年代气温观测资料(1973-2021年),用趋势分析方法分析了国际马拉松赛期间厦门同期气温变化特征,发现1月多年平均气温呈现缓慢线性增温趋势,而逐日气温呈现明显的小幅波动下降趋势.利用小波分析方法研究了高、低温的多时间尺度变化特征.结果表明,高、低温均具高低频两个振荡周期,且从闭合中心的发展趋势来看,预计2...     

聚己内酯复合固体碳源的制备及其深度脱氮性能研究

以聚己内酯（PCL）为骨架结合不同低成本碳源制备得到PCL复合碳源,静态释放试验筛选出适用于污水深度脱氮的复合碳源,批式试验研究其脱氮性能.并通过比较碳源表面特征、反硝化功能基因丰度与微生物群落结构特征分析其脱氮机理.结果表明,PCL/玉米淀粉连续30 d释碳性能稳定,氮、磷释放量均低于1.0 mg·L^-1,对水质影响较小,可用于生活污水深度脱氮.批式脱氮试验结果显示,PCL/玉米淀粉反硝化系统脱氮效果好,反硝化功能基因nirS、nirK拷贝数高,能够有效富集反硝化菌.此外,PCL/玉米淀粉系统中群落丰富度与多样性更高,系统抗逆性更强.因此,PCL/玉米淀粉能够实现生活污水长效稳定深度脱氮.     

有机紫外吸收剂BP-3的厌氧污泥降解特性

2-羟基-4-甲氧基二苯甲酮（BP-3）作为化学品添加剂广泛应用于防晒霜、化妆品和染色剂等个人护理品以及塑料制品,用于吸收紫外线防止皮肤晒伤、材料老化和腐蚀.经使用后BP-3随污水排放或者人类涉水活动直接或间接排放到受纳水环境.因BP-3属于疏水性化合物,进入水环境后更易于分配至污泥和沉积物等缺氧和厌氧环境,厌氧微生物降解是BP-3重要的自然消减过程.然而,目前BP-3在不同厌氧条件下的降解转化机制仍不清楚.本研究以城市污水处理厂厌氧污泥为接种体,对比分析了不同厌氧还原条件和碳源共代谢对BP-3厌氧降解转化的差异.研究结果表明,硝酸盐、硫酸盐还原条件抑制BP-3的厌氧降解,而额外添加混合碳源可促进BP-3的降解（最短降解半衰期为1.285 d）.通过对混合碳源体系厌氧菌群驯化培养,BP-3降解能力显著提高,降解半衰期缩短至0.734 d （10 mg·L^-1）.利用UPLC-QTOF-MS鉴定主要降解中间产物为2,4-二羟基二苯甲酮（BP-1）,推测其厌氧降解转化主要途径为去甲基化.筛查获得了一株BP-3高效厌氧降解单菌,通过16S rDNA测序比对确定为柠檬酸杆菌属兼性厌氧菌.     

近20年重庆市主城区碳储量对土地利用/覆被变化的响应及脆弱性分析

土地利用/覆被变化（LUCC）是影响区域生态系统碳储量变化的重要驱动因素,探明碳储量对LUCC的响应及脆弱性,对区域实现“双碳”战略目标具有重要意义。以重庆市主城九区为例,运用InVEST模型研究了近20年主城区碳储量对土地利用转移的响应,采用潜在影响指数（PI）评估了该区域生态系统碳储量服务的脆弱性。结果表明：（1）2000—2020年间,主城区耕地面积减少743.29 km²,建设用地面积急剧增加773.48 km²。前10年土地转移面积6.05%,后10年转移13.98%,耕地转为建设用地是主要的土地转移类型。（2）近20年主城区碳储量累计减少5.78 Tg,其中建设用地侵占耕地是碳储量急速下降的主导因素。碳储量分布呈现“中部低—四周高”的空间格局。（3）近20年主城区均表现为碳源,土地利用程度指数提高14.73,PI指数为-2.50~ -2.59 Tg,均表现负面潜在影响,且2000—2015年间脆弱性不断恶化,2015—2020年间脆弱性有所缓解。研究结果可为区域生态可持续发展和未来土地利用管理政策制定提供参考,并为西部其他同类型山地城市提供借鉴。     

Pickering乳化强化地下水三氯乙烯NAPL修复

合成了4种不同长径比的SiO₂颗粒调控水/NAPL界面,考察所形成的Pickering乳化效果和稳定性,结果表明：长径比（L/D）为2.3的SiO₂颗粒分散的Pickering乳液液滴尺寸均匀,直径约10 μm,且10d内保持稳定,乳化指数高达63%.流变测试进一步证实所形成的Pickering乳化具有低剪切应变下乳液稳定的特性,利于地下水的原位修复技术的实施.同时考察胶体颗粒浓度,水中离子强度以及水/NAPL比例对Pickering乳化效果和稳定性的影响,为Pickering乳化技术在实际地下水修复应用提供理论基础.通过对比Pickering乳化和未乳化条件下NAPL溶解和氧化降解动力学过程,发现Pickering乳化通过增大两相间界面积显著提高NAPL的溶解速率,进而实现NAPL相污染物降解速率的提高.     

Robust optimization approach to two-echelon agricultural cold chain logistics considering carbon emission and stochastic demand

Environment, Development and Sustainability - Cold chain logistics has become one of the main sources of carbon emissions. Meanwhile, the implementation of low-carbon economy has become an...     

PFAS Experts Symposium: Statements on regulatory policy,chemistry and analytics,toxicology, transport/fate,and remediation for per‐ and polyfluoroalkyl substances (PFAS) contamination issues

Sixty leading members of the scientific, engineering, regulatory, and legal communities assembled for the PFAS Experts Symposium in Arlington, Virginia on May 20 and 21, 2019 to discuss issues related to per‐ and polyfluoroalkyl substances (PFAS) based on the quickly evolving developments of PFAS regulations, chemistry and analytics, transport and fate concepts, toxicology, and remediation technologies.  The Symposium created a venue for experts with various specialized skills to provide opinions and trade perspectives on existing and new approaches to PFAS assessment and remediation in light of lessons learned managing other contaminants encountered over the past four decades. The following summarizes several consensus points developed as an outcome of the Symposium:

• Regulatory and policy issues: The response by many states and the US Environmental Protection Agency (USEPA) to media exposure and public pressure related to PFAS contamination is to relatively quickly initiate programs to regulate PFAS sites. This includes the USEPA establishing relatively low lifetime health advisory levels for PFAS in drinking water and even more stringent guidance and standards in several states. In addition, if PFAS are designated as hazardous substances at the federal level, as proposed by several Congressional bills, there could be wide‐reaching effects including listing of new Superfund sites solely for PFAS, application of stringent state standards, additional characterization and remediation at existing sites, reopening of closed sites, and cost renegotiation among PRPs.
• Chemistry and analytics: PFAS analysis is confounded by the lack of regulatory‐approved methods for most PFAS in water and all PFAS in solid media and air, interference with current water‐based analytical methods if samples contain high levels of suspended solids, and sample collection and analytical interference due to the presence of PFAS in common consumer products, sampling equipment, and laboratory materials.
• Toxicology and risk: Uncertainties remain related to human health and ecological effects for most PFAS; however, regulatory standards and guidance are being established incorporating safety factors that result in part per trillion (ppt) cleanup objectives. Given the thousands of PFAS that may be present in the environment, a more appropriate paradigm may be to develop toxicity criteria for groups of PFAS rather than individual PFAS.
• Transport and fate: The recalcitrance of many perfluoroalkyl compounds and the capability of some fluorotelomers to transform into perfluoroalkyl compounds complicate conceptual site models at many PFAS sites, particularly those involving complex mixtures, such as firefighting foams. Research is warranted to better understand the physicochemical properties and corresponding transport and fate of most PFAS, of branched and linear isomers of the same compounds, and of the interactions of PFAS with other co‐contaminants such as nonaqueous phase liquids. Many PFAS exhibit complex transport mechanisms, particularly at the air/water interface, and it is uncertain whether traditional transport principles apply to the ppt levels important to PFAS projects. Existing analytical methods are sufficient when combined with the many advances in site characterization techniques to move rapidly forward at selected sites to develop and test process‐based conceptual site models.
• Existing remediation technologies and research: Current technologies largely focus on separation (sorption, ion exchange, or sequestration). Due to diversity in PFAS properties, effective treatment will likely require treatment trains. Monitored natural attenuation will not likely involve destructive reactions, but be driven by processes such as matrix diffusion, sorption, dispersion, and dilution.

The consensus message from the Symposium participants is that PFAS present far more complex challenges to the environmental community than prior contaminants. This is because, in contrast to chlorinated solvents, PFAS are severely complicated by their mobility, persistence, toxicological uncertainties, and technical obstacles to remediation—all under the backdrop of stringent regulatory and policy developments that vary by state and will be further driven by USEPA. Concern was expressed about the time, expense, and complexity required to remediate PFAS sites and whether the challenges of PFAS warrant alternative approaches to site cleanups, including the notion that adaptive management and technical impracticability waivers may be warranted at sites with expansive PFAS plumes. A paradigm shift towards receptor protection rather than broad scale groundwater/aquifer remediation may be appropriate.     

The effectiveness of travel restriction measures in alleviating the COVID-19 epidemic: evidence from Shenzhen,China

Environmental Geochemistry and Health - With the expansion of the global novel coronavirus disease (COVID-19) pandemic, unprecedented interventions have been widely implemented in many countries,...     

Quantifying PM<Subscript>2.5</Subscript> capture capability of greening trees based on leaf factors analyzing

As PM_2.5 affect human health, it is important to target tree planting in the role of reducing air pollution concentrations. PM_2.5 capture capability of greening trees is associated with leaf morphology, while quantitative research is scanty. In this paper, the PM_2.5 capture capability of 25 species in Beijing and Chongqing were examined by a chamber device. Groove proportion, leaf hair, stomatal density, and stomata size were selected as indexes of leaf morphology. Results showed that groove proportion and stomata size significantly relate to PM_2.5 capture quantity, while no significantly positive correlations were found for leaf hairs and stomatal density. Broadleaf species are conducive to PM_2.5 capture for their rich leaf morphology and have an edge over coniferous in PM_2.5 capture per leaf area. However, coniferous had a larger PM_2.5 capture capability per tree due to the advantage of a large leaf area. Significant difference existed between the species in Beijing and Chongqing due to the different leaf morphology. Urban greening trees are diverse and the structures are complicated. Complex ecological environment may lead to different morphology characteristics. Climate and pollution conditions should be considered when greening.