创造性思维训练在物理实验教学中的实践

第三次全国教育工作会议以来，创新能力与实践能力的培养越来越成为物理教学的重点与趋势．21世纪对人才的要求，也需要有创造力、协作能力和团队精神等科学素质．物理实验是培养学生科学素质的最有效途径，也是培养学生创造力与创造性思维的最佳途径．在获得诺贝尔物理学奖的物理     

浅谈技能人才的专业教育与人文教育融合的途径

本文试图从校园文化建设的角度来探讨工学院技能人才的专业教育与人文教育的融合问题，文章以工学院校园文化建设现状，初步提出了技能人才的专业教育与人文教育的融合途径。     

Fenton 试剂处理2,4-D废水研究

利用Fenton试剂(Fe2+/H2O2)处理含有除草剂2,4-二氯苯氧乙酸(2,4-D)的模拟废水.结果显示,Fenton试剂对2,4-D有很好的去除效果.Fe2+和H2O2的摩尔比为1:20,在H2O2为1/2Qth理论投加量的条件下处理30mtn,2,4-D去除率达到80.0%.考察了Fe2+投加量、Fe2+和H2O2投加比、2,4-D初始浓度和pH等因素对2,4-D降解的影响.通过GC-MS和HPLC检测到反应中间产物有2,4-二氯苯酚、邻氯苯酚和对氯苯酚,氯离子在这些中间产物上释放.通过离子色谱检测到进一步氧化的产物还有小分子酸,如乙醇酸、乙醛酸、顺丁烯二酸,提出了Fenton降解2,4 -D的可能途径.     

三甲基膦和环氧乙烷的加成产物裂解反应机理的MNDO法研究

文中用ＭＮＤＯ方法研究了三甲基膦和环氧乙烷加成产物裂解反应机理     

降铅冲剂对低水平铅暴露仔鼠血铅及脑铅的影响

目的:研究降铅冲剂对低水平铅暴露仔鼠血铅及脑铅的影响,为评价降铅冲剂的作用提供依据。方法:选用Wister大鼠仔鼠60只,体质量80~100 g,随机分成6组,每组10只,分别为空白组、模型对照组、EDTA对照组、降铅冲剂低剂量组、降铅冲剂中剂量组、降铅冲剂高剂量组;造模后开始给药,EDTA对照组给CaNa2EDTA注射液10(mg/kg)/d腹腔注射,降铅冲剂低、中、高剂量组分别予降铅冲剂5(g/kg)/d、10(g/kg)/d、20(g/kg)/d的剂量灌胃,空白组和模型对照组予等量蒸馏水灌胃,给药共30 d。用石墨炉原子吸收光谱仪测定仔鼠血铅、脑铅。结果:(1)染铅后,各染铅组的血铅水平与空白组比较都显著升高(P<0.001),经过30 d的治疗后,各治疗组的治疗后血铅水平均有不同程度下降,与模型对照组比较均有统计学意义。(2)染铅后,各染铅组的脑铅水平与空白组比较都显著升高(P<0.05),治疗后,各组脑铅与治疗前比较均显著升高,降铅冲剂低、中剂量组的脑铅与模型对照组比较显著下降。结论:降铅冲剂能显著降低低水平铅暴露仔鼠的血铅和脑铅含量,其综合疗效优于CaNa2EDTA。     

化学史教育的实践与思考

分析了目前中学化学史教育中存在的一些问题,对化学史的教育功能作了探讨,认为化学史的教育功能主要在于提高学生的科学素养和人文素养,并结合教学实践,介绍了一些可行的做法。     

全氟烷基磺酸酯C-O键断裂的同面SN2反应

用密度泛函理论研究了CF3SO3CF2CF3 F^-的碳氧键断裂反应的机理。首先，用DFT方法优化了反应物、中间体、过渡态、产物的平衡构型，分析了碳氧键断裂反应的势能面变化，发现在SN2反应机理中，除了S-O断裂SN2反应外，引起C-O键断裂的同面进攻也是一个可能的反应途径。理论计算表明，最终反应的产物是受热力学控制的，S-O键的断裂绝对地优于C-O的断裂。因此，C-O断裂的同面机理虽然是可能的，但却难以被实验观察到，本文还讨论了端基-CF3在同面SN2反应中的邻位效应，以及基组对这个效应的影响。     

铅暴露与出生缺陷

铅是现代工业化国家广泛应用的有毒微量元素,污染环境日趋严重,人体铅负荷随之增加,对孕妇、胎儿及儿童健康的影响已成为公共卫生关注的问题。     

CeO2担载Cu纳米粒子电催化CO2还原产乙烯：CeO2不同暴露晶面对催化性能的影响

Fossil fuels are expected to be the major source of energy for the next few decades. However, combustion of nonrenewable resources leads to the release of large quantities of CO₂, the primary greenhouse gas. Notably, the concentration of CO₂ in the atmosphere is increasing annually at an astounding rate. Electrochemical CO₂ reduction (ECR) to value-added fuels and chemicals using electricity from intermittent renewable energy sources is a carbon-neutral method to alleviate anthropogenic CO₂ emissions. Despite the steady progress in the selective generation of C₁ products (CO and formic acid), the production of multi-carbon species still suffers from low selectivity and efficiency. As an ECR product, ethylene (C₂H₄) has a higher energy density than do C₁ species and is an important industrial feedstock in high demand. However, the conversion of CO₂ to C₂H₄ is plagued by low productivity and large overpotential, in addition to the severe competing hydrogen evolution reaction (HER) during the ECR. To address these issues, the design and development of advanced electrocatalysts are critical. Here, we demonstrate fine-tuning of ECR to C₂H₄ by taking advantage of the prominent interaction of Cu with shape-controlled CeO₂ nanocrystals, that is, cubes, rods, and octahedra predominantly covered with (100), (110), and (111) surfaces, respectively. We found that the selectivity and activity of the ECR depended strongly on the exposed crystal facets of CeO₂. The overall ECR Faradaic efficiency (FE) over Cu/CeO₂(110) (FE ≈ 56.7%) surpassed that of both Cu/CeO₂(100) (FE ≈ 51.5%) and Cu/CeO₂(111) (FE ≈ 48.4%) in 0.1 mol·L^-1 KHCO₃ solutions with an H-type cell. This was in stark contrast to the exclusive occurrence of the HER over pure carbon paper, CeO₂(100), CeO₂(110), and CeO₂(111). In particular, the FE toward C₂H₄ formation and the partial current density increased in the sequence Cu/CeO₂(111) < Cu/CeO₂(100) < Cu/CeO₂(110) within applied bias potentials from -1.00 to -1.15 V (vs. the reversible hydrogen electrode), reaching 39.1% over Cu/CeO₂(110) at a mild overpotential (1.13 V). The corresponding values for Cu/CeO₂(100) and Cu/CeO₂(111) were FE_C2H4 ≈ 31.8% and FE_C2H4 ≈ 29.6%, respectively. The C₂H₄ selectivity was comparable to that of many reported Cu-based electrocatalysts at similar overpotentials. Furthermore, the FE for C₂H₄ remained stable even after 6 h of continuous electrolysis. The superior ECR activity of Cu/CeO₂(110) to yield C₂H₄ was attributed to the metastable (110) surface, which not only promoted the effective adsorption of CO₂ but also remarkably stabilized Cu⁺, thereby boosting the ECR to produce C₂H₄. This work offers an alternative strategy to enhance the ECR efficiency by crystal facet engineering.     

活性位高度暴露的钴/氮/碳电催化剂的构建及氧还原性能研究

金属/氮/碳催化剂（M/N/C，M=Fe、Co等）是最有发展前景的非贵金属电催化剂之一，其性能依赖于催化剂表面的活性物种密度.通过常规的热解含氮前驱物与金属盐的方法制得的催化剂往往存在金属活性物种被包埋而不能有效利用的缺点.考虑到石墨相氮化碳（g-C₃N₄）富含类吡啶氮和亚纳米孔腔结构，将g-C₃N₄包覆在高导电性碳纳米笼（hCNC）表面，进而利用表层g-C₃N₄的配位和限域作用锚定大量Co²⁺离子，获得的Co/g-C₃N₄/hCNC复合物经热解后形成了活性位高度暴露、导电性好、孔结构丰富的Co/N/C催化剂.800℃热解得到的最优化催化剂在碱性介质中展现出优异氧还原活性，其起始电位（0.97 V）与商业Pt/C催化剂相当，且抗甲醇干扰性能和稳定性优异.此项研究提供了一种构建具有高度暴露活性位的M/N/C催化剂的有效策略.