Combustion synthesis of mesoporous CoAl2O4 for peroxymonosulfate activation to degrade organic pollutants

A mesoporous cobalt aluminate (CoAl₂O₄) spinel is synthesized through a combustion method and adopted for the activation of peroxymonosulfate (PMS) to degrade organic pollutants. Multiple characterization procedures are conducted to investigate the morphology and physicochemical properties of the CoAl₂O₄ spinel. Due to its mesoporous structure, large surface area, and high electrical conductivity, the obtained CoAl₂O₄ exhibits remarkable catalytic activity for Rhodamine B (RhB) degradation. Its RhB degradation rate is 89.0 and 10.5 times greater than those of Co₃O₄ and CoAl₂O₄ spinel prepared by a precipitation method, respectively. Moreover, the mesoporous CoAl₂O₄ spinel demonstrates a broad operating pH range and excellent recyclability. The influence of several parameters (catalyst amount, PMS concentration, initial pH, and coexisting inorganic anions) on the oxidation of RhB is evaluated. Through quenching tests and electron paramagnetic resonance experiments, sulfate radicals are identified as the predominant reactive species in RhB degradation. This paper provides new insights for the development of efficient, stable, and reusable cobalt-based heterogeneous catalysts and promotes the application of persulfate activation technology for the treatment of refractory organic wastewater.     

铁基金属-有机骨架及其复合物高级氧化降解水中新兴有机污染物

新兴有机污染物(Emerging organic contaminants,EOCs)是对人体健康及生态环境具有潜在或实质威胁的新型化学污染物。由于其被频繁使用且能在水生生态系统中持久性存在而对水生生物健康和安全造成严重威胁,故引起大众越来越多的关注。以活性污泥法为代表的传统水处理工艺通常不足以消除这些新兴有机污染物。为高效去除新兴有机污染物,基于新材料的高级氧化技术是最主要的深度处理技术之一。铁基金属-有机骨架(Fe-MOFs)及其复合物在诸多领域得到了广泛的应用,特别是在催化氧化去除水中有机污染物方面展现出良好的应用前景。通过合成方法改进、合成后改性以及与特定功能材料复合等方法可有效提升Fe-MOFs及其相关材料的吸附性能、增强其光吸收特性和促进载流子有效分离等。本文重点综述了Fe-MOFs及其复合物高级氧化(光催化、类芬顿和硫酸根自由基($SO_{4}^{-·}$)介导的氧化)去除水中新兴有机污染物的研究进展,并探讨了未来研究所面临的机遇和挑战。     

碳化硅块状气凝胶的制备及应用

碳化硅气凝胶具有高温稳定性、低热膨胀系数、良好的抗热震性以及抗氧化和耐腐蚀等优异的性质,在高温和高腐蚀性环境下的隔热、电磁吸波、过滤和吸附等领域具有较大的应用潜力。然而,块状碳化硅气凝胶的可控制备一直是一项较大的挑战。本文综述了块状碳化硅气凝胶在制备工艺和应用两个方面的研究进展,首先分析总结了各种制备工艺及其优缺点,包括有机/SiO₂复合气凝胶碳热还原法、预陶瓷化聚合物裂解法、化学气相沉积法、高温气相渗硅法和碳化硅纳米线组装法;然后,详细介绍了碳化硅气凝胶在高温隔热和电磁吸波两个领域的应用研究进展;最后,展望了碳化硅气凝胶未来的若干发展方向。     

多相催化过硫酸盐工艺处理水环境中有机污染物的非自由基过程

20世纪80年代至今,水处理技术中的高级氧化过程(AOP)已被广泛研究及应用。然而水体中的有机污染物仍因种类繁多和降解难易不同困扰着研究者们,因此对于AOP的机理过程需要更深入的分析认识,以利于技术的进一步发展及应用。AOP中的过硫酸盐氧化工艺近年来得到大量关注,其自由基机理的关键活性物种是·OH 和·SO₄^-。非自由基机理分为¹O₂氧化和PS直接氧化(也称电子转移),某些体系中高价态金属也直接或间接地参与氧化过程。但非自由基过程的发生机理及优势特点仍存在争议。本文综述了基于多相催化过硫酸盐高级氧化过程处理水中有机污染物的最新研究,阐述反应机理及其分析手段,并指出当前研究可能存在的问题。对于过硫酸盐高级氧化工艺中非自由基过程的未来研究方向及应用前景提出展望。     

碳辅助金属配合物热解法制备高含量Fe-N4单原子催化剂用于氧还原反应

单原子催化剂凭借其超高的原子利用率及在某些反应中表现出的出色催化效果,被认为是最有前途的电催化剂之一,引起了研究人员的极大热情和兴趣.制备高金属含量的单原子催化剂是基础研究和实际应用的前提和关键.然而,由于原子表面自由能随着尺寸的减小而急剧增加,在制备和催化过程中,单原子催化剂的金属原子很容易聚集成团簇甚至颗粒,因此如何制备高负载量的单原子催化剂仍然是一个不小的挑战.在众多单原子催化剂中,非贵金属中铁基单原子被认为是燃料电池中的Pt催化剂的有效替代品.在燃料电池的核心反应–电化学氧还原反应中,Fe-N_x被证明是铁单原子催化剂中的主要活性中心.因此,为了获得更好的氧还原性能,提高铁单原子催化剂中Fe-N_x的含量就显得非常关键.前期已报道了一些关于制备高Fe含量的铁单原子催化剂材料的策略,例如空间限域策略和配位合成策略.其中卟啉和葡萄糖作为配位剂,双氰胺和三聚氰胺可热解成氮掺杂碳材料以捕获金属原子,形成M-N_x.同时,具有高比表面积的富氧碳载体可以通过掺杂氮来作为固定金属原子的位点.我们开发了一种简单直接的方法,通过碳辅助金属配合物热解法制备高金属含量的Fe-N4单原子催化剂,即在最佳碳化温度800℃、三聚氰胺存在下对氮掺杂多孔碳辅助分散铁邻苯二胺配合物进行热解.在该方法中,氮掺杂多孔碳是一种具有丰富氮缺陷,高表面积(1267 m²?g^–1)和良好分散性的多孔生物质碳材料.邻苯二胺作为含两个氨基的二齿配体,可以很容易地与过渡金属配位,形成稳定的平面四配位络合物.此外,由于在高温条件下过渡金属的催化作用,邻苯二胺也被用作氮掺杂碳的前体.因此,氮掺杂多孔碳和邻苯二胺是合成高金属含量铁单原子催化剂的关键前驱体.通过X射线光电子能谱,大角度环形暗场扫描透射电子显微镜和X射线吸收精细结构光谱表征,发现所制备的铁单原子催化剂中铁原子以单个原子的形式锚固在碳载体上,并与碳基质的四个掺杂氮原子配位,得到Fe-N₄的构型.通过调节Fe前驱体量,铁单原子催化剂中Fe的最高负载量达到7.5 wt%,在目前已经报道的铁单原子催化剂中排第四.电化学氧还原测试表明,在0.10 M KOH溶液中,随着铁含量的增加,铁单原子催化剂的氧还原性能逐渐提高.其中250Fe-SA/NPC-800样品表现出最高起始电位0.97 V和最正的半波电位0.85 V,可与市售的40%Pt/C催化剂相媲美.和已报道的铁单原子催化剂相比,由于我们制得的催化剂的比表面积较低,只有247 m²?g^–1,所以制约了催化剂的性能.在混合动力学势域中,根据Koutecky-Levich方程计算得出的电子转移数约为3.6,表明250Fe-SA/NPC-800主要催化四电子转移过程,这可以归因于以Fe-N₄活性中心降低了四电子过程中关键中间体的形成能垒及过程的自由能变化.此外,250Fe-SA/NPC-800展现了较高的电化学稳定性.连续工作6 h后,250Fe-SA/NPC-800保留了超过87%的电流密度,而Pt/C表现出明显的衰减,仅保留了49%.     

Effect of Interfacial Adsorption on the Stability of Thin Polymer Films in a Solvent-induced Process

The stability of ultrathin polymer films plays a crucial role in their technological applications. Here, we systematically investigated the influence of interfacial adsorption in physical aging and the stability of thin polymer films in the solvent-induced process. We further identify the stability mechanism from the theory of thin film stability. Our results show that the aging temperature and film thickness can strongly influence the stability of thin PS films in acetone vapor. Physical aging can greatly improve the stability of thin polymer films when the aging temperature T_(aging1)T_g. A thinner PS film more quickly reaches a stable state via physical aging. At short aging time, the formation of the adsorbed layer can reduce the polar interaction; however, it slightly influences the stability of thin polymer films in the solvent-induced process. At later aging stage,the conformational rearrangement of the polymer chains induced by the interfacial effect at the aging temperature T_(aging1) plays an important role in stabilizing the thin polymer films. However, at T_(aging2)T_g, the process of physical aging slightly influences the stability of the thin polymer films.The formation of the adsorbed layer at T_(aging2) can reduce the short-range polar interaction of the thin film system and cannot suppress the instability of thin polymer films in the solvent-induced process. These results provide further insight into the stable mechanism of thin polymer films in the solvent-induced process.     

Microwave-Assisted One-Pot Lipid Extraction and Glycolipid Production from Oleaginous Yeast Saitozyma podzolica in Sugar Alcohol-Based Media

Glycolipids are non-ionic surfactants occurring in numerous products of daily life. Due to their surface-activity, emulsifying properties, and foaming abilities, they can be applied in food, cosmetics, and pharmaceuticals. Enzymatic synthesis of glycolipids based on carbohydrates and free fatty acids or esters is often catalyzed using certain acyltransferases in reaction media of low water activity, e.g., organic solvents or notably Deep Eutectic Systems (DESs). Existing reports describing integrated processes for glycolipid production from renewables use many reaction steps, therefore this study aims at simplifying the procedure. By using microwave dielectric heating, DESs preparation was first accelerated considerably. A comparative study revealed a preparation time on average 16-fold faster than the conventional heating method in an incubator. Furthermore, lipids from robust oleaginous yeast biomass were successfully extracted up to 70% without using the pre-treatment method for cell disruption, limiting logically the energy input necessary for such process. Acidified DESs consisting of either xylitol or sorbitol and choline chloride mediated the one-pot process, allowing subsequent conversion of the lipids into mono-acylated palmitate, oleate, linoleate, and stearate sugar alcohol esters. Thus, we show strong evidence that addition of immobilized Candida antarctica Lipase B (Novozym 435^®), in acidified DES mixture, enables a simplified and fast glycolipid synthesis using directly oleaginous yeast biomass.     

Ni-Al layered double hydroxides electrodeposition from a chloride solution

Ni-Al LDHs was electrodeposited from a NiCl₂-AlCl₃ solution. In order to analyze the electrodeposition process, electrolytes with initial Al content range of 0–20% were used. With increasing Al content in the sample, the preferred orientations of (0 0 3) and (0 0 6), increased crystallinity, and decreased interlayer spacing were observed from the XRD results. A dissolution–recrystallization of (0 0 3) plane was detected among the Ni-Al LDHs from the strongly alkaline solution soaking results, which was found to be conducted easily in high Al-containing samples. The pH of the Al-containing electrolyte was much lower than that of pure NiCl₂ solution because lower pH was needed to start a precipitation reaction in the AlCl₃-NiCl₂ solution. The electrodeposition yield and current efficiency were found to decrease obviously in the electrolytes with initial Al content higher than 10%, which was attributed to the increasing Al content in the sample and diffusion of the complex ions. The electrodeposition pattern was in-situ in the electrolyte initially containing 10% Al, then, it developed toward and off in-situ in electrolytes initially containing 0–10% and 10–20% Al.     

Development of Magnesium Anode-Based Transient Primary Batteries

Biodegradable primary batteries, also known as transient batteries, are essential to realize autonomous biodegradable electronic devices with high performance and advanced functionality. In this work, magnesium, copper, iron, and zinc – metals that exist as trace elements in the human body – were tested as materials for biomedical transient electronic devices. Different full cell combinations of Mg and X (where X = Cu, Fe, and Zn and the anodized form of the metals) with phosphate buffered saline (PBS) as electrolyte were studied. To form the cathodes, metal foils were anodized galvanostatically at a current density of 2.0 mA cm⁻² for 30 mins. Electrochemical measurements were then conducted for each electrode combination to evaluate full cell battery performance. Results showed that the Mg−Cu_anodized chemistry has the highest power density at 0.99 mW/cm². Nominal operating voltages of 1.26 V for the first 0.50 h and 0.63 V for the next 3.7 h were observed for Mg−Cu_anodized which was discharged at a current density of 0.70 mA cm⁻². Among the materials tested, Mg−Cu_anodized exhibited the best discharge performance with an average specific capacity of 2.94 mAh cm⁻², which is comparable to previous reports on transient batteries.     

Multiphase Flow Regime Characterization and Liquid Flow Measurement Using Low-Field Magnetic Resonance Imaging

Multiphase flow metering with operationally robust, low-cost real-time systems that provide accuracy across a broad range of produced volumes and fluid properties, is a requirement across a range of process industries, particularly those concerning petroleum. Especially the wide variety of multiphase flow profiles that can be encountered in the field provides challenges in terms of metering accuracy. Recently, low-field magnetic resonance (MR) measurement technology has been introduced as a feasible solution for the petroleum industry. In this work, we study two phase air-water horizontal flows using MR technology. We show that low-field MR technology applied to multiphase flow has the capability to measure the instantaneous liquid holdup and liquid flow velocity using a constant gradient low flip angle CPMG (LFA-CPMG) pulse sequence. LFA-CPMG allows representative sampling of the correlations between liquid holdup and liquid flow velocity, which allows multiphase flow profiles to be characterized. Flow measurements based on this method allow liquid flow rate determination with an accuracy that is independent of the multiphase flow profile observed in horizontal pipe flow for a wide dynamic range in terms of the average gas and liquid flow rates.