物理新课程中现代技术素养探源

现代技术在当今时代迅猛发展,提高学生现代技术素养应该成为基础教育阶段的目标.界定基础教育阶段现代技术素养的构成要素,对高中物理新课程标准和教材进行文本分析,归纳高中物理课程中体现现代技术素养的内容特点,探讨物理新课程中现代技术素养的教学策略,为发展学生现代技术素养提供新的思路.     

Cu纳米针上电场促进C-C耦合增强CO2电还原生成C2产物

电催化CO₂减排技术利用电能将过量的CO₂转化为有附加值的化学品,是解决能源危机、实现碳中和的有效途径之一.电催化CO₂还原反应(CO₂RR)中的多碳产物(C₂),如乙烯和乙醇,因其比C1产物具有更高的能量密度和更广泛的应用而受到较大关注.目前为止,Cu基催化剂被认为是获得C₂产物的独特材料.研究者在提高Cu基催化剂C₂产物的活性和选择性方面做了大量的工作,如催化剂形貌工程、活性位点设计和中间吸附性能调控等.许多理论和实验研究已经证明,Cu基催化剂上的C-C偶联过程是C₂产物生成的速率决定步骤.优化C-C偶联过程的能垒是提高C₂产物活性和选择性的重要而直接的策略.CO₂RR在Cu上是由CO₂还原吸附CO(*CO)并二聚生成C₂产物引起的.C-C偶联过程与*CO的吸附性能密切相关.众所周知,CO是一种典型的极性分子,因此其在催化剂表面的吸附性能可能会受到活性位点周围的局部电场的影响.构建合适的局部电场是调节CO吸附性能和C-C偶联过程的潜在手段之一.前期工作(Nature,2016,537,382-386)证明了高曲率金纳米针可以在尖端产生高的局部电场.高局域电场诱导K+聚集,使活性位点周围CO₂浓度升高,大大促进了Au纳米针上的CO生成.基于Au纳米针的局域电场促进了CO₂RR的CO生成.本文利用Cu纳米针促进并优化C-C偶联反应来提高C₂产物活性和选择性.结果表明,局部电场可以促进C-C偶联过程,进而增强CO₂电还原生成C₂产物.有限元模拟结果表明,高曲率铜纳米针处存在较强的局部电场;密度泛函理论计算结果表明,强电场能促进C-C耦合过程.在此基础上,制备了一系列不同曲率的Cu催化剂,其中,Cu纳米针(CuNNs)的曲率最高,Cu纳米棒(CuNRs)和Cu纳米颗粒(CuNPs)曲率次之.实验测得CuNNs上吸附的K+浓度最高,证明了纳米针上的局部电场最强.同时,CO吸附传感器测试表明,CuNNs对CO的吸附能力最强,原位傅里叶变换红外光谱显示,CuNNs的*COCO和*CO信号最强.由此可见,高曲率铜纳米针可以诱导高局部电场,从而促进C-C耦合过程.催化性能测试结果表明,在低电位(-0.6 V vs.RHE)下,Cu NNs对CO₂RR的生成C₂产物的法拉第效率值为44%,约为Cu NPs的2.2倍.综上,本文为CO₂RR过程中提高多碳产物提供了新的思路.     

鱼雷豚跳运动及初始转动角速度选取

鱼雷依靠惯性以一定姿态跃出水面并再次落入水中的过程称之为鱼雷的豚跳运动. 针对鱼雷的豚跳运动需要以零攻角入水, 而鱼雷在空中运动过程中无法控制的问题, 提出了通过构建鱼雷豚跳运动模型并以此为基础控制初始出水转动角速度的解决方法. 附加质量、浮力、浮心、浸湿面积、浸水体积等变量随鱼雷出水姿态、出水过程不同而不同. 在构建鱼雷豚跳运动模型过程中, 充分考虑了各个变化物理量的导数项, 分析了鱼雷水动阻力系数与攻角的关系, 构建了运动模型, 得出鱼雷豚跳运动的规律. 利用优化搜索算法计算出使鱼雷豚跳以零攻角条件入水的初始转动角速度. 仿真结果表明了所建模型及控制初始转动角速度方法的有效性.     

Graphitic carbon nitride based single-atom photocatalysts

Single-atom photocatalysts, due to their high catalysis activity, selectivity and stability, become a hotspot in the field of photocatalysis. Graphitic carbon nitride (g-C₃N₄) is known as both a good support for single atoms and a star photocatalyst. Developing g-C₃N₄-based single-atom photocatalysts exhibits great potential in improving the photocatalytic performance. In this review, we summarize the recent progress in g-C₃N₄-based single-atom photocatalysts, mainly including preparation strategies, characterizations, and their photocatalytic applications. The significant roles of single atoms and catalysis mechanism in g-C₃N₄-based single-atom photocatalysts are analyzed. At last, the challenges and perspectives for exploring high-efficient g-C₃N₄-based single-atom photocatalysts are presented.     

CuPd催化剂调节中间反应能垒提高电催化CO2生成二碳产物的选择性

过度的碳排放已造成了严重的全球环境问题,电催化CO2还原是一种利用间歇性过剩电能将CO2转化为有价值的化学物质的有效策略.在多种CO2还原产物中,二碳(C2)产物(如乙烯、乙醇)因其比一碳产物(如甲酸、甲烷、甲醇)具有更高的能量密度而备受关注.Cu是唯一能用电化学方法将CO2转化为多碳产物的单金属催化剂.如何提高Cu基催化剂上CO2还原为C2产物的效率已引起了极大关注.电催化还原CO2生成C2产物有两个重要步骤:一是参与碳碳偶联反应的CO*中间体的量(*代表中间体吸附在基底表面),二是碳碳偶联步骤的能垒.对于Cu单金属催化剂,虽然其表面碳碳偶联步骤的能垒相对较低,但是Cu对CO2的吸附能力和CO2*加氢能力并不高,导致在Cu表面不能生成足量的CO*中间体参与碳碳偶联反应,因而对C2产物的选择性和活性并不理想.与Cu单金属催化剂相反,在Pd单金属催化剂表面,CO*中间体的形成具有超快的反应动力学,但是CO*易在Pd表面中毒且后续碳碳偶联步骤的能垒极高,使其表面不能生成C2产物.为了充分发挥Cu(碳碳偶联步骤能垒较低)和Pd(CO*形成具有超快反应动力学)的双重优势,本文构建了一种紧密的CuPd(100)界面,以调节中间反应能垒,从而提高C2产率.密度泛函理论(DFT)计算表明,CuPd(100)界面增强了CO2的吸附,且降低了CO2*加氢步骤的能垒,从而能够催化生成更多的CO*中间体参与碳碳偶联反应.且CuPd(100)界面上CO2还原为C2产物的电位决定步骤能垒为0.61 eV,低于Cu(100)表面的(0.72 eV).本文采用了一种简便的湿化学法制备了CuPd(100)界面催化剂.X射线衍射和X射线光电子能谱测试以及扩展X射线吸收精细结构光谱结果表明,合成的是相分离的CuPd双金属催化剂,而非CuPd合金催化剂.同时高分辨透射电镜可以观察到清晰的CuPd(100)界面.由此可见,本文成功合成了CuPd(100)界面催化剂.程序升温脱附实验结果表明,CuPd(100)界面对CO2和CO*的吸附比Cu强,结果与理论预测一致.气体传感实验结果表明,CuPd(100)界面CO2*加氢能力比Cu强.为评估CuPd(100)界面催化剂的催化活性,进行了CO2电化学还原实验.结果表明,在0.1 mol/L的KHCO3电解液中,CuPd(100)界面催化剂在–1.4 VRHE下,C2产物的法拉第效率为50.3％ ±1.2％,是同电位下Cu催化剂的(23.6％ ±1.5％)的2.1倍,C2产物的选择性是Cu催化剂的2.4倍,且具有更高的电流密度和更大的电化学活性面积.本文通过调控中间反应能垒以合理设计铜基CO2还原电催化剂提供了参考.     

Novel closed-cycle reaction mode for totally green production of Cu1.8Se nanoparticles based on laser-generated Se colloidal solution

Non-stoichiometric copper selenide (Cu_2-xSe, x=0.18～0.25) nanomaterials have attracted extensive attentions due to their excellent thermoelectric, optoelectronic and photocatalytic performances. However, efficient production of Cu_2-xSe nanoparticles (NPs) through a green and convenient way is still hindered by the inevitable non-environmentally friendly operations in common chemical synthesis. Herein, we initially reveal the coexistence of seleninic acid content and elemental selenium (Se) NPs in pulsed laser-generated Se colloidal solution. Consequently, we put forward firstly a closed-cycle reaction mode for totally green production of Cu_1.8Se NPs to exclude traditional requirements of high temperature and toxic precursors by using Se colloidal solution. In such closed-cycle reaction, seleninic acid works as the initiator to oxidize copper sheet to release cuprous ions which can catalyze the disproportion of Se NPs to form SeO₃^2- and Se^2- ions and further produce Cu_2-xSe NPs, and the by-product SeO₃^2- ions promote subsequent formation of cuprous from the excessive Cu sheet. In experiments, the adequate copper (Cu) sheet was simply dipped into such Se colloidal solution at 70 ℃, and then the stream of Cu_1.8Se NPs could be produced until the exhaustion of selenium source. The conversion rate of Se element reaches to more than 75% when the size of Se NPs in weakly acidic colloidal solution is limited between 1 nm and 50 nm. The laser irradiation duration shows negative correlation with the size of Se NPs and unobvious impact to the pH of the solution which both are essential to the high yield of Cu_1.8Se NPs. Before Cu sheet is exhausted, Se colloidal solution can be successively added without influences to the product quality and the Se conversion rate. Such green methodology positively showcases a brand-new and potential strategy for mass production of Cu_2-xSe nanomaterials.     

单原子Co位点的CO2还原反应路径:局部配位环境的影响

在CO2还原反应(CO2RR)应中,单原子催化剂被认为是很有前途的电催化剂.Co-N4活性位点因其优异的CO选择性和活性而受到广泛关注.然而,Co位点的局部配位环境与CO2RR途径之间的相关性尚不明确.本文采用密度泛函理论(DFT)计算,研究了含1,10-菲咯啉基底的N4-大环配体(Co-N4-CPY)负载的CoN4位...