石墨烯负载的氧配位钴单原子稳定金属锂负极

Lithium (Li)-based batteries are the dominant energy source for consumer electronics, grid storage, and electrified transportation. However, the development of batteries based on graphite anodes is hindered by their limited energy density. With its ultrahigh theoretical capacity (3860 mAh∙g⁻¹), low redox potential (−3.04 V), and satisfactorily low density (0.54 g∙cm⁻³), Li metal is the most promising anode for next-generation high-energy-density batteries. Unfortunately, the limited cycling life and safety issues raised by dendrite growth, unstable solid electrolyte interphase, and "dead Li" have inhibited their practical use. An effective strategy is to develop a suitable lithiophilic matrix for regulating initial Li nucleation behavior and controlling subsequent Li growth. Herein, single-atom cobalt coordinated to oxygen sites on graphene (Co-O-G SA) is demonstrated as a Li plating substrate to efficiently regulate Li metal nucleation and growth. Owing to its dense and more uniform lithiophilic sites than single-atom cobalt coordinated to nitrogen sites on graphene (Co-N-G SA), high electronic conductivity, and high specific surface area (519 m²∙g⁻¹), Co-O-G SA could significantly reduce the local current density and promote the reversibility of Li plating and stripping. As a result, the Co-O-G SA based Li anodes exhibited a high Coulombic efficiency of 99.9% at a current density of 1 mA∙cm⁻² with a capacity of 1 mAh∙cm⁻², and excellent rate capability (high current density of 8 mA∙cm⁻²). Even at a high plating capacity of 6 mAh∙cm⁻², the Co-O-G SA electrode could stably cycle for an ultralong lifespan of 1300 h. In the symmetric battery, the Co-O-G SA based Li anode (Co-O-G SA/Li) possessed a stable voltage profile of 18 mV for 780 h at 1 mA∙cm⁻², and even at a high current density of 3 mA∙cm⁻², its overpotential maintained a small hysteresis of approximately 24 mV for > 550 h. Density functional theory calculations showed that the surface of Co-O-G SA had a stronger interaction with Li atoms with a larger binding energy, −3.1 eV, than that of Co-N-G SA (−2.5 eV), leading to a uniform distribution of metallic Li on the Co-O-G SA surface. More importantly, when matched with a sulfur cathode, the resulting Co-O-G SA/lithium sulfur full batteries exhibited a high capacity of 1002 mAh∙g⁻¹, improved kinetics with a small polarization of 191 mV, and an ultralow capacity decay rate of 0.036% per cycle for 1000 cycles at 0.5C (1C = 1675 mA∙g⁻¹) with a steady Coulombic efficiency of nearly 100%. Therefore, this work provides novel insights into the coordination environment of single atoms for the chemistry of Li metal anodes for high-energy-density batteries.     

菱形颗粒冲蚀磨损特性试验及仿真研究

本文中针对单个硬质角形颗粒冲击金属材料表面的过程,设计了弹射试验装置,研究菱形颗粒冲击行为及冲蚀机理.采用高速摄像机,捕捉不同冲击速度v_i、冲击角度α_i和方位角度θ_i下颗粒的运动轨迹.建立了基于拉格朗日法的FEM-SPH耦合数值计算模型,借助于模型进一步分析了角形颗粒的运动学行为和变形凹坑形态.结果表明:冲击角α和方位角θ是决定颗粒旋转的关键因素,在某一固定冲击角αi下存在一个临界方位角θcr_i,当θiθ_(cri)时颗粒冲击后发生前旋旋转,当θ_iθ_(cri)时颗粒冲击后发生后旋旋转;冲击诱导的颗粒旋转对冲蚀机理的影响较大,颗粒前旋旋转对金属材料产生"耕犁"作用,后旋旋转对金属材料产生"撬起剔除"作用.颗粒的动能损失受到冲击角α_i和方位角θ_i的影响较大,临界方位角θ_(cri)下颗粒的动能损失最大,凹坑变形最严重.     

基于电化学发光和阻抗技术研究DNA单碱基错配

单碱基错配的识别和稳定性差异在核酸多态性研究中至关重要。在同一电化学传感器平台上，采用电化学发光（ECL）和电化学阻抗（EIS）2种技术，协同研究DNA链中不同类型和不同位点的单碱基错配识别和稳定性差异。电极表面具有茎环构象的探针DNA与完全互补DNA、不同类型或不同位点单碱基错配DNA杂交前后的ECL和EIS信号强度变化有显著差异。信号强度变化可揭示单碱基错配识别的稳定性。结果表明，DNA链中心位点的C-A单碱基错配稳定性低于链两端的，靠近键合电极表面双链链端的C-A单碱基错配稳定性低于非键合电极表面双链链端的，同一中心位点C-X碱基对的稳定性顺序为C-G?C-T>C-A≥C-C。研究结果可为核酸多态性研究提供参考。     

单原子铂催化剂的制备及其低温催化氧化一氧化碳

以氧化石墨烯为载体，单原子铂（Pt）为活性组分，利用化学还原法制备了单原子Pt/rGO催化剂，用在催化氧化一氧化碳（CO）反应中。通过透射电子显微镜、扫描电子显微镜、球差电镜、傅里叶红外光谱仪对单原子Pt催化剂进行表征。考察了金属负载量、反应温度对催化剂性能的影响，利用气相色谱对CO氧化反应性能进行评价。此次实验包含催化剂的制备、表征和性能测试，实验难度适中，贴近科研前沿，可以让学生体验一个综合的科研过程，激发学生的科研兴趣，培养学生的科研能力。     

单参考态微扰理论发散问题的理论研究

本文对闭壳层和开壳层分子系统由于加入弥散函数导致的单参考态微扰理论的发散问题进行了深入的研究. 发现对开壳层系统，微扰能量的振幅随体系自旋多重度的增加而增加. 本文利用Feenberg变换来处理微扰理论的发散问题. 通过调节Feenberg 变换的参数λ来加速微扰序列的收敛性. 数值计算表明，存在一个λ值，微扰序列收敛最快. 还发现该λ值随着自旋多重度增加而增加.     

正电子冲击下氦电离三重微分截面的理论计算

我们发展了一种正电子碰撞原子电离的畸变波Born近似方法， 在这个方法中，正负电子偶素通道通过一个ab initio的光学势附加到入射粒子和靶的相互作用势上，且通道对电离作用被第一次被考虑在正电子碰撞原子电离的过程中. 应用这个方法计算了在50 eV入射能量范围氦的电离的三重微分截面，计算结果和实验数据很好的符合.