Multi‐walled carbon nanotube modified dummy‐template magnetic molecularly imprinted microspheres as solid‐phase extraction material for the determination of polychlorinated biphenyls in fish

Novel multi‐walled carbon nanotube modified dummy‐template molecularly imprinted microspheres (MWCNTs@DMMIPs) were successfully synthesized as adsorbents for six kinds of polychlorinated biphenyls (PCBs). MWCNTs@DMMIPs were prepared by a surface molecular imprinting technique. Core–shell Fe₃O₄@SiO₂ nanoparticles were employed as magnetic support. 3,4‐Dichlorobenzene acetic acid was used as a dummy template instead of PCBs, methacrylic acid was used as functional monomer and ethylene glycol dimethacrylate was used as the cross‐linker. The resulting absorbent was characterized by various methods. The adsorbent was employed for extracting PCBs and exhibited good selectivity and high adsorption efficiency. Furthermore, it was reusable and capable of magnetic separation. Adsorption kinetics fit well with a pseudo‐second‐order kinetic equation and also exhibited a three‐stage intra‐particle diffusion model. The Freundlich model was used to describe the adsorption isotherms. The materials were successfully applied to the magnetic dispersive solid‐phase extraction of six kinds of PCBs followed by gas chromatography with mass spectrometry determination in fish samples, the limit of detection of six kinds of PCBs were 0.0028–0.0068 μg/L and spiked recoveries ranged between 73.41 and 114.21%. The prepared adsorbent was expected to be a new material for the removal and recovery of PCBs from contaminated foods.     

Fitting formula for the injection volume of a gas chromatograph for radio‐xenon sampling in the lower troposphere

GC is usually used for xenon concentration and radon removal in the International Monitoring System of the Comprehensive Nuclear‐Test‐Ban Treaty. In a gas chromatograph, the injection volume is defined to calculate the column capacity. In this paper, the injection volume was investigated and a fitting formula for the injection volume was derived and discussed subsequently. As a consequence, the xenon injection volume exponentially decreased with the column temperature increased, but exponentially increased as the flow rate increased.     

聚合物材料表面化学镀铜的前处理研究进展

聚合物材料表面金属化在通讯、电子、航空航天领域具有重要应用. 化学镀铜是聚合物材料表面金属化的主要技术之一. 聚合物材料表面的前处理直接影响化学镀铜层的结合力及镀层平整度. 本综述详细介绍非导电聚合物材料的种类、组成以及性能, 并概述其表面化学镀铜前处理的研究进展.     

磁性三维氮掺杂碳纳米材料对6种双酚类化合物的吸附性能及其在泡腾分散微萃取中的应用

采用简单高温煅烧法成功制备了磁性钴镍基氮掺杂三维碳纳米管与石墨烯复合材料(CoNi@NGC),将其作为吸附剂用于水体中6种双酚类化合物(BPs)的吸附性能和机理研究。将CoNi@NGC复合纳米材料用作萃取介质,运用酸碱泡腾片的CO₂强力分散作用,开发了泡腾反应强化的分散固相微萃取前处理方法,结合高效液相色谱-荧光检测(HPLC-FLD)快速定量饮料中痕量BPs。采用扫描电镜、透射电镜、傅里叶红外光谱、氮气吸脱附、X射线光电子能谱和磁滞回线等技术手段对材料形貌结构进行表征,结果显示:该吸附剂成功实现氮元素的掺杂,且具有较大的比表面积(109.42 m²/g)、丰富的孔径及较强的磁性(17.98 emu/g)。吸附剂投加量、pH、温度、时间等因子优化试验表明:当pH=7,在初始质量浓度为5 mg/L的BPs混合溶液中投加5 mg CoNi@NGC, 298 K反应5 min,对双酚M(BPM)、双酚A(BPA)的吸附率分别高达99.01%和98.21%。作用90 min时对双酚Z(BPZ)、BPA、BPM的吸附率近100%。在吸附过程中,BPs与CoNi@NGC之间的整个吸附过程主要受氢键、静电作用和π-π共轭作用共同控制。整个吸附过程符合Freundlich吸附等温线模型和准二级动力学方程,吸附自发进行。进一步将CoNi@NGC作为萃取介质制备成磁性泡腾片,利用泡腾分散微萃取技术高效富集和提取6种盒装饮料中的BPs,优化了影响富集效果的泡腾片的存在与否、洗脱剂种类、洗脱时间、洗脱体积等关键因子,在最佳萃取条件下(pH=7,投加5 mg CoNi@NGC, 2 mL丙酮洗脱6 min),结合HPLC-FLD,新开发的泡腾分散微萃取方法提供的检出限为0.06~0.20 μg/L,定量限为0.20~0.66 μg/L,日内和日间精密度分别为1.44%~4.76%和1.69%~5.36%,在实际样品中不同水平下的加标回收率为82.4%~103.7%,在桃汁中检测到BPA和双酚B(BPB)分别为2.09 μg/L和1.37 μg/L。再生试验表明该吸附材料至少可以重复使用5次以上,显著降低了分析的试验成本。与其他方法相比,该方法具有灵敏度高、萃取速度快、环境友好等优点,在常规食品污染监测中具有较强的应用价值。     

High-throughput screening against $$\sim $$6.1 million structurally diverse,lead-like compounds to discover novel ROCK inhibitors for cerebral injury recovery

Rho-associated protein kinase (ROCK) has been recognized as an attractive therapeutic target to promote neurogenesis, neuroregeneration, and neurorecovery after cerebral injury. Here, a high-throughput screening protocol was described to discover novel ROCK inhibitors from a large chemical library containing \(\sim \)6.1 million structurally diverse, lead-like compounds. The protocol employed empirical rules such as ADMET evaluation and chemical similarity analysis to exclude those of drug-unlike candidates, and then molecular docking and binding affinity predictions were performed to suggest few promising candidates with high scores. Consequently, five compounds were successfully identified to have satisfactory activity profile with \(\hbox {IC}_{50}\) values at nanomolar level. In order to elucidate the molecular mechanism of inhibitor binding to target, the complex structures of ROCK kinase domain with the five identified compounds were modeled and examined in detail. A number of polar chemical forces such as hydrogen bonds and cation-\(\pi \) interactions as well as nonpolar contacts such as \(\pi \)–\(\pi \) stacking and hydrophobic forces were revealed at the complex interface, conferring high affinity and strong specificity to inhibitor binding. In addition, several key residues around the kinase active site, including Val90, Lys105, Asn203, and Phe368, were found to play an important role in binding.     

Critical behavior of a passively mode-locked laser: rational harmonic mode locking

The critical behavior of passive mode locking has been demonstrated in a figure-eight fiber laser that performs rational harmonic mode locking (RHML). On both the repetition rate and the pulse amplitude distribution, the observed pulse trains near the threshold exhibit the same regulations as the rational harmonic mode-locked ones. The theory also shows that there should be a middle status of RHML before achieving normal mode locking. It is important to note that the results provide what we believe to be the first confirmed attempt to address a fundamental question: how does a laser become mode locking with an increase of pump power?     

可控表面磷原子修饰提升超细W2C纳米颗粒电解水析氢反应性能

研究高活性和稳定性的非贵金属基析氢催化剂对解决当前能源危机和环境污染问题具有重要意义.碳化钨具有与贵金属Pt类似的d带电子结构,因而成为一类新兴的非贵金属析氢催化剂,受到广泛关注.磷掺杂是提高催化剂析氢活性的有效方法之一,然而目前最常见的构筑磷掺杂方法是使用多金属氧酸盐(POMs,如H3PW12O40),其固定的W/P原子比导致W2C中的掺杂浓度难以调控,并且磷掺杂主要是进入碳载体而不是碳化物本身,从而导致无法明确杂原子对其电催化析氢活性的贡献.本文采用植酸(PA)为磷源设计合成了可控磷掺杂W2C纳米颗粒,并探讨了催化剂组分、杂原子掺杂位置与析氢性能之间的关系.深入研究了磷掺杂碳化钨(WCP)的化学结构和析氢活性.与原始的W2C催化剂相比,WCP具有更高的本征活性、更快的电子转移速率和更多的活性位数量,并且在酸性和碱性条件下均表现出较好的析氢性能.特别是过电位为-200 mV时,WCP催化剂的本征活性在酸性和碱性条件下分别为0.07和0.56 H2 s-1,高出纯W2C(0.01和0.05 H2 S-1)数倍.同时,在电流密度为-10 mA cm-2时,优化后的WCP催化剂在酸性和碱性条件下的析氢过电位分别降低了96和88 mV.XPS及EDS元素分析结果表明,随磷源添加量增加,磷掺杂从碳化钨表面逐渐向内部扩散,进一步说明磷取代位置与析氢活性之间的构效关系,高浓度的表面磷取代可以加速质子捕获过程,从而显著提高其析氢活性,而过量的内部磷取代会破坏W2C结构,降低电子转移速率,从而导致析氢性能下降.利用密度泛函理论计算深入研究了WCP具有较好析氢性能的原因,与内部磷取代相比,表面磷取代会使碳化钨表现出更合适的氢吸附自由能,并且更加有效地降低了氢释放势垒,从而优化了析氢反应动力学.综上,本文为元素掺杂工艺提供了新的思路,同时研究了表面异质原子对析氢活性的关键作用,为该类催化材料的构效关系研究提供了新思路.     

锂金属电池用高浓度电解液体系研究进展

锂金属二次电池具有极高的能量密度,是下一代储能电池的研究热点。然而,金属锂负极在传统碳酸酯电解液1 mol·L^?1 LiPF6-EC/DEC(ethylene carbonate/diethyl carbonate)中充放电时,存在严重的枝晶生长和循环效率低下等问题,阻碍了其商业化应用。因此,开发与锂负极兼容的新型电解液体系是目前重要的研究任务。与传统稀溶液相比,高浓度电解液体系具有独有的物化性质和优异的界面相容性,并且能有效抑制锂枝晶生长、显著提升锂负极的循环可逆性,因而格外受到关注。本文综述了高浓度电解液及局部高浓电解液体系的最新研究进展,分析了其溶液化学结构和物化性质,对其与锂负极的界面相容性、枝晶抑制效果、效率提升能力及界面稳定性机制进行了探讨;文章着重介绍了高浓与局部高浓电解液体系在锂金属二次电池中的应用,同时从基础科学研究和应用研究两个层面对高浓电解液和局部高浓电解液存在的主要问题进行了简要分析,并对其未来发展方向进行了展望。