氮掺杂石墨烯负载单原子Zr催化CO2加氢的密度泛函理论研究

基于密度泛函理论计算,研究了H2和CO2在氮掺杂石墨烯负载单原子Zr催化剂(Zr Nx-Gr)上的吸附和CO2催化加氢反应. H2和CO2在Zr N3-Gr上单独吸附的吸附能分别为-0.49和-2.17 e V,在H2和CO2共吸附状态下,吸附能为-2.24 e V,均高于在Zr N4-Gr表面的吸附能,表明Zr N3-Gr表面更利于CO2加氢反应的发生.在Zr N3-Gr表面, CO2在共吸附后保持了其单独吸附时的特性,削弱了H2分子的吸附. CO2在Zr Nx-Gr表面催化加氢反应起始于H2和CO2的共吸附构型,沿反式HCOOH路径形成甲酸盐(HCOO*)中间体,然后HCOO*基团吸附H原子形成反式甲酸,在Zr N3-Gr和Zr N4-Gr表面该路径的反应能垒分别为1.85和2.48 e V.另一路径为产生CO与H2O的反应,在Zr N3-Gr和Zr N4-Gr表面的反应能垒分别为1.86和1.73 e V,表明Zr N3-Gr更利于CO2加氢生成甲酸反应的发生,而Zr N4-Gr表面更利于CO的产生.     

连续流动条件下含氮Beta分子筛催化甲缩醛-异丁烯Prins反应

采用高温氨气氮化法,制备了一系列含氮Beta分子筛样品,并在连续流动条件下,考察了其催化甲缩醛与异丁烯经Prins缩合制异戊二烯的反应性能.利用XRD、 N₂吸附/脱附、元素分析、 ²⁹SiMAS NMR、 NH₃-TPD、 CO₂-TPD和TG等方法对氮化分子筛的结构、酸碱性和反应后积碳进行了表征,研究了反应条件及样品的酸碱性对反应性能的影响.结果表明,以35%甲缩醛水溶液为反应物,在320℃、 2 MPa、异丁烯与甲缩醛摩尔比为7的适宜条件下,铵型Beta为前驱体制备的催化剂对甲缩醛的转化率达99%,异戊二烯的产率达85%.氮化后少量的酸性位和较多的碱性位有利于维持甲缩醛较高的转化率、较高的异戊二烯产率及较低的反应积碳量.催化剂再生6次后仍保持75%异戊二烯产率,样品中Si―N键削弱导致酸碱性变化是再生后反应性能下降的主要原因.     

GdPO4∶Sm3+荧光粉的焙烧温度和掺杂浓度的优化及发光和磁性能

以GdPO₄为基质,Sm³⁺为激活剂,采用水热法合成了纳米荧光粉前驱体,分别在800、900、1 000、1 100和1 200℃下焙烧,得到一系列GdPO₄∶Sm³⁺荧光粉。首先探究了GdPO₄∶Sm³⁺的最佳焙烧温度;其次研究了Sm³⁺掺杂浓度对GdPO₄∶Sm³⁺荧光性能的影响;最后研究了GdPO₄∶2% Sm³⁺的高温荧光性能和磁性能。使用X射线衍射仪(XRD)、扫描电子显微镜(SEM)、磁强计和荧光分光光度计(FL)对荧光粉的晶体结构、形貌、发光和磁性能进行了表征。结果表明：荧光粉的晶体结构由前驱体六方晶系GdPO₄·H₂O∶Sm³⁺变为单斜晶系的GdPO₄∶Sm³⁺,形貌由纳米棒变为无规则块体。当焙烧温度为1 000℃,Sm³⁺掺杂浓度为2%时,荧光粉的发光强度和荧光寿命达到最大值。GdPO₄∶2% Sm³⁺中Sm³⁺之间能量传递类型为电偶极-电偶极相互作用,能量传递的临界距离为1.646~1.884 nm。最佳样品GdPO₄∶2% Sm³⁺有优异的热稳定性,热猝灭活化能为-0.157 eV,且具有良好的顺磁性,质量磁化率值为1.22×10^-4 emu·g^-1·Oe^-1。     

不同版本高中化学教科书中学生必做实验的分析与启示——基于“科学探究与创新意识”素养

以人教版、苏教版、鲁科版(2019年版)和沪科版(2020年版)高中化学教科书中的学生必做实验文本为研究对象,基于“科学探究与创新意识”素养构建高中化学教科书中学生必做实验文本的分析框架,分析和比较4个版本教科书中学生必做实验文本“科学探究与创新意识”素养的体现及其异同,为学生必做实验教学提供启示和建议。     

论证“是否应该停止使用氮肥”社会性科学议题教学——氮及其化合物的复习

“氮及其化合物”复习教学中,通过社会性科学议题“是否应该停止使用氮肥”,在真实复杂的两难问题情境中,使学生基于物质类别和元素价态视角分析、设计氮肥的制备、使用以及减少其对环境影响中涉及的含氮物质的转化,提高学生自主应用氮元素“价-类”二维图综合分析、解决真实问题的能力,促进证据推理与模型认知、科学探究与创新意识、科学态度与社会责任等多维度化学学科核心素养的融合发展。经过多轮教学改进,结合教学效果抽提出以下教学策略：课上课下统筹安排,合理设置任务,提高学生参与议题的兴趣,促使学生全身心投入对议题的探讨;聚焦真实问题解决,将议题的探讨过程与关键能力持续进阶紧密结合并相互促进;让学生经历“做真事、真做事、真反思、真发展”的完整过程。     

氢键概念的形成和发展

1902年,瑞士化学家维尔纳对氯化铵结构的解释为氢键概念的形成奠定了基础。1920年,美国化学家拉提麦尔和罗德布什首先认识了水中的氢键：2个八隅体所持的氢核构成的“弱键(weak bond)”。1928年,美国化学家鲍林在解释[FHF]^-的结构时首次使用“氢键(hydrogen bond)”一词,但并未对氢键的概念进行明确定义。1939年,鲍林在《化学键的本质》中明确提出了氢键的概念,并解释了氢键的性质,自此,氢键的概念正式形成。近年来,科学家经过深入研究发现了氢键的新类型：π型氢键、双氢键、金属氢键和单电子氢键。随着科学思想和科学技术的发展,关于氢键的认识也会越来越深入。     

Total Synthesis of Metaphanine and Oxoepistephamiersine

Herein, we report a concise and divergent synthesis of the complex hasubanan alkaloids metaphanine and oxoepistephamiersine from commercially available and inexpensive cyclohexanedione monoethylene acetal. Our synthesis features a palladium-catalyzed cascade cyclization reaction to set the tricyclic carbon framework of the desired molecules, a regioselective Baeyer–Villiger oxidation followed by a MeNH₂ triggered skeletal reorganization cascade to construct the benzannulated aza[4.4.3]propellane, and a strategically late-stage regio-/diastereoselective oxidative annulation of sp³ C−H bond to form the challenging THF ring system and hemiketal moiety in a single step. In addition, a highly enantioselective alkylation of cyclohexanedione monoethylene acetal paved the way for the asymmetric synthesis of target molecular.     

Boosting the Proton-coupled Electron Transfer via Fe−P Atomic Pair for Enhanced Electrochemical CO2 Reduction

Single-atom catalysts exhibit superior CO₂-to-CO catalytic activity, but poor kinetics of proton-coupled electron transfer (PCET) steps still limit the overall performance toward the industrial scale. Here, we constructed a Fe−P atom paired catalyst onto nitrogen doped graphitic layer (Fe₁/PNG) to accelerate PCET step. Fe₁/PNG delivers an industrial CO current of 1 A with FE_CO over 90 % at 2.5 V in a membrane-electrode assembly, overperforming the CO current of Fe₁/NG by more than 300 %. We also decrypted the synergistic effects of the P atom in the Fe−P atom pair using operando techniques and density functional theory, revealing that the P atom provides additional adsorption sites for accelerating water dissociation, boosting the hydrogenation of CO₂, and enhancing the activity of CO₂ reduction. This atom-pair catalytic strategy can modulate multiple reactants and intermediates to break through the inherent limitations of single-atom catalysts.     

Palladium and Ruthenium Dual-Single-Atom Sites on Porous Ionic Polymers for Acetylene Dialkoxycarbonylation: Synergetic Effects Stabilize the Active Site and Increase CO Adsorption

Heterogeneous single-metal-site catalysts usually suffer from poor stability, thereby limiting industrial applications. Dual Pd₁−Ru₁ single-atom-sites supported on porous ionic polymers (Pd₁−Ru₁/PIPs) were constructed using a wetness impregnation method. The two isolated metal species in the form of a binuclear complex were immobilized on the cationic framework of PIPs through ionic bonds. Compared to the single Pd- or Ru-site catalyst, the dual single-atom system exhibits higher activity with 98 % acetylene conversion and near 100 % selectivity to dialkoxycarbonylation products, as well as better cycling stability for ten cycles without obvious decay. Based on DFT calculations, it was found that the single-Ru site exhibited a strong CO adsorption energy of −1.6 eV, leading to an increase in the local CO concentration of the catalyst. Notably, the Pd₁−Ru₁/PIPs catalyst had a much lower energy barrier of 2.49 eV compared to 3.87 eV of Pd₁/PIPs for the rate-determining step. The synergetic effect between neighboring single sites Pd₁ and Ru₁ not only enhanced the overall activity, but also stabilized Pd^II active sites. The discovery of synergetic effects between single sites can deepen our understanding of single-site catalysts at the molecular level.     

B(C6F5)3-Catalyzed Aza-Friedel–Crafts Reaction of Indolizines with 2-Aryl-3H-indol-3-ones

A Friedel–Crafts reaction of indolizines with 2-aryl-3H-indol-3-ones catalyzed by B(C₆F₅)₃ is described. This protocol gives access to indolizine derivatives that are valuable building blocks in synthetic and pharmaceutical chemistry. The reaction proceeds under mild conditions, affording various C2-quaternary indolin-3-ones based on indolizine with high yields and regioselectivities. Moreover, the synthetic transformations of the target products were realized by N-methylation and trifluoromethane sulfonation.