含萘酰亚胺和烷基疏水基的新型表面活性剂合成及性能

为获得高效多功能表面活性剂,设计并合成了一系列萘酰亚胺和长链烷基为疏水基的新型季铵盐阳离子表面活性剂(C_(n)NDA,n=10,12,14,16代表长链烷基链长),并利用红外光谱(FT-IR)、核磁氢谱(^(1)H NMR)、核磁碳谱(^(13)C NMR)和质谱(HRMS)对其结构进行了表征。研究了C_(n)NDA的表面活性、胶束性质、泡沫及抗菌性能。结果表明,C_(n)NDA具有优异的表面活性和泡沫性能。当疏水烷基链长碳数从10增加到16,其cmc值从1.01降至0.026 mmol/L;0.10 g/L的C14NDA水溶液的泡沫半衰期可达16 h。同时C_(n)NDA具有良好的抗菌活性,C_(16)NDA对大肠杆菌和金黄色葡萄球菌的最低杀菌质量浓度分别为3.0和1.2μg/mL。另外,^(1)H NMR和荧光光谱研究表明,C_(n)NDA能够形成分子间氢键,且萘酰亚胺基团间形成了π-π堆积。C_(n)NDA的优异性能与上述分子间的相互作用密切相关。该类表面活性剂在杀菌和泡沫等领域具有潜在的应用前景。

2D ZnMOF/BiVO_(4)S型异质结的构建及其可见光催化还原CO_(2)性能

利用光催化技术将CO_(2)转换为燃料或高附加值的化学品,既实现了碳的循环利用,同时也缓解了能源危机和环境污染问题.一个完整的光催化还原CO_(2)反应包含空穴氧化水和电子还原CO_(2)两个半反应,这要求半导体的导带底能级和价带顶能级同时满足CO_(2)还原和水氧化的热力学反应电位.而单一的半导体很难在充分吸收可见光的同时满足上述两个半反应的热力学电势.S型异质结由一个具有较深价带的氧化型半导体和一个具有较负导带的还原型半导体组成,在光照条件下,氧化型半导体的电子和还原型半导体的空穴相复合,氧化型半导体的空穴和还原型半导体的电子实现空间分离.因此,选择能级位置匹配的两个窄带隙半导体构筑S型异质结,既可以充分吸收、利用可见光,又保留了强氧化还原能力的空穴和电子以分别高效诱发水氧化和还原CO_(2)两个半反应.钒酸铋(BiVO_(4))的价带位置较正,具有良好的析氧性能,是理想的窄带隙氧化型半导体材料.其中,二维结构的BiVO_(4)纳米片可有效缩短光生电荷扩散到表面的距离,具有较大的接触面积且表面含有丰富的羟基,非常利于与还原型半导体形成紧密的界面.g-C_(3)N_(4)由于其导带能级较负,光生电子还原能力强,是经典的还原型半导体光催化材料.但其吸光范围与BiVO4大部分重叠且缺少表面催化活性位点.金属有机骨架(MOFs)是一类由金属团簇和有机配体联结而成的晶态多孔材料,具有比表面积大、孔隙率高、能带结构可调等特点.二维MOFs材料的电子易于扩散到表面且含有丰富的表面金属位点,因而在光催化领域受到广泛关注.二维卟啉锌金属有机骨架(Zn-MOF)以卟啉锌为配体,不仅具有MOFs的结构优势,同时保留了金属卟啉宽可见光响应的特点.更为重要的是,Zn-MOF具有较高的LUMO能级,特别是二维结构暴露了丰富的金属节点,将更有利于CO_(2)的吸附与活化.因此,以Zn-MOF作为还原型半导体,有望与二维BiVO_(4)纳米片构建维度匹配的、宽光谱响应的且富含表面催化活性中心的高效S型异质结光催化剂.本文利用羟基诱导组装的方法制备了2D/2D Zn-MOF/BiVO4 S型异质结光催化剂.最佳样品的光催化还原CO_(2)至CO的产率分别为BiVO4纳米片(厚度约5 nm)和BiVO_(4)纳米盘(厚度约15 nm)的6倍和22倍,为传统g-C_(3)N_(4)/BiVO_(4)异质结的2倍.电化学还原测试、电子顺磁共振波谱及原位傅里叶变换红外光谱等研究表明,BiVO_(4)和Zn-MOF之间增强的S型电荷转移、均匀分散在Zn-MOF中的金属节点Zn_(2)(COO)_(4)对CO_(2)的有效活化以及体系的宽可见光响应是光催化还原CO_(2)性能提高的关键.本文为构筑宽光谱响应的含有卟啉基MOFs的高效S型异质结光催化体系提供了新思路.

Stability Control of Gob-Side Entry Retaining in Fully Mechanized Caving Face Based on a Compatible Deformation Model

The stability control of gob-side entry retaining in fully mechanized caving face is a typical challenge in many coal mines in China.The rotation and subsidence of the lateral cantilever play a critical role in a coal mine,possibly leading to instability in a coal seam wall or a gob-side wall due to its excessive rotation subsidence.Hence,the presplitting blasting measures in the roof was implemented to cut down the lower main roof and convert it to caved immediate roof strata,which can significantly reduce the rotation space for the lateral cantilever and effectively control its rotation.Firstly,the compatible deformation model was established to investigate the quantitative relationship between the deformation of the coal seam wall and the gob-side wall and the subsidence of the lateral cantilever.Then,the instability judgments for the coal seam wall and gob-side wall were revealed,and the determination method for the optimal roof cutting height were obtained.Furthermore,The Universal Distinct Element Code numerical simulation was adopted to investigate the effect of roof-cutting height on the stability of the retained entry.The numerical simulation results indicated that the deformation of the roadway could be effectively controlled when the roofcutting height reached to 18 m,which verified the theoretical deduction well.Finally,a field application was performed at the No.3307 haulage gateway in the Tangan coal mine,Ltd.,Shanxi Province,China.The field monitoring results showed that the blasting roof cutting method could effectively control the large deformation of surrounding rocks,which provided helpful references for coal mine safety production under similar conditions.