思政元素融入有机化学教学的探索与实践——以醇、酚教学为例

教育的根本任务是立德树人,课程思政是高校落实立德树人根本任务的重要举措。因此,将思政教育有机融入高校课程教学中,传授知识的同时,培养和塑造学生正确的价值观,是高校教师面临的重要课题之一。有机化学教学内容丰富,与人类社会的发展和日常生活密切相关,为开展思政教育提供了大量的思政育人元素。本文以醇、酚教学为例,从醇的结构和性质之间的关系、硝化甘油与诺贝尔及诺贝尔奖的渊源、醇与氯化亚砜的反应、苦味酸的应用及相关的历史事件等四个方面深入挖掘思政育人元素,有机融入有机化学课程教学中。在知识传授的过程中培养学生的家国情怀和科技报国理念、唯物辩证观念、社会责任感、科学素养和绿色化学理念,落实立德树人的根本任务。

RALOX-HAIC联合免疫检查点抑制剂及靶向药物治疗中晚期肝癌的疗效分析

目的:探讨雷替曲塞+奥沙利铂方案肝动脉灌注化疗(RALOX-HAIC)联合免疫及靶向药物三联治疗中晚期肝细胞癌(hepatocellular carcinoma,HCC)的疗效与安全性。方法:回顾性分析2020年6月至2021年12月收治于南方医科大学南方医院39例行RALOX-HAIC联合靶免治疗的中晚期HCC患者,以首次HAIC治疗为起点,以患者疾病进展、死亡、不可耐受不良反应为终点,按照RECIST 1.1标准进行疗效评估,随访时间截至2022年10月。主要研究终点为客观缓解率(objective response rate,ORR),次要研究终点为疾病控制率(disease control rate,DCR)、中位无进展生存期(median progression-free survival,mPFS)、中位总生存期(median overall survival,mOS)及安全性。结果:ORR为41.0%,DCR达87.2%,m PFS为7.3个月(95%CI:5.0~9.6),mOS为14.6个月(95%CI:10.8~18.5),其中1例患者成功转化行手术治疗后完全缓解至今。常见的不良反应有HAIC术后发热、腹痛;化疗药物引起的骨髓抑制;肝功能异常、高血压、手足综合征等,无治疗相关死亡事件发生。结论:RALOX-HAIC联合免疫检查点抑制剂及靶向药物治疗中晚期HCC的DCR高,安全性良好,不良反应可耐受,为后续前瞻性临床研究奠定了基础。

经肝动脉化疗栓塞联合系统治疗对不可切肝细胞癌的疗效分析

目的:探索经肝动脉化疗栓塞(transcatheter arterial chemoembolization,TACE)为基础的不同方案治疗不可切除肝细胞癌(unresectable hepatocellular carcinoma,uHCC)患者的疗效和安全性,以及TACE联合酪氨酸激酶抑制剂(tyrosine kinase inhibitors,TKIs)和免疫检查点抑制剂(immune checkpoint inhibitors,ICIs)的最佳时机。方法:回顾性分析2016年4月至2021年12月期间在南方医科大学南方医院接受基于TACE治疗的555例uHCC患者资料。根据不同治疗方案分为:TACE组(n=317)、TACE+TKIs组(n=66)、TACE+ICIs组(n=33)、TACE+TKIs+ICIs组(n=139)。在亚组分析中,根据不同的联合时间将TACE+TKIs+ICIs组分为“TACE前”和“TACE后”组。采用单因素、多因素Cox回归分析影响OS的预后因素。结果:TACE+TKIs+ICIs组获得最长的OS(21.9个月,95%CI:17.2~26.6,P=0.030)和PFS(8.3个月,95%CI:7.3~9.3,P=0.004)。在亚组分析中,“TACE后”组比“TACE前”组获得更长的OS(26.8个月vs.19.2个月,P=0.011)。TACE组、TACE+TKIs组、TACE+ICIs组、TACE+TKIs+ICIs组的ORR分别为32.8%、41.1%、42.4%、52.5%(P=0.001),DCR分别为59.6%、71.2%、69.7%、82.7%(P<0.001)。不良反应事件与既往研究相似。Cox回归分析提示肿瘤数量、肝外转移及治疗方案是患者OS的独立预后因素(均P<0.05)。结论:TKIs或ICIs可以提高TACE治疗uHCC患者的OS和PFS,TKIs+ICIs联合TACE生存获益更佳。首次TACE术后3个月内联合“TKIs+ICIs”治疗方案的总生存期获益更显著。

从验证到探究的高校有机化学实验教学探讨

以香豆素-3-羧酸的合成为例,改变现有传统实验的实验过程,将验证性实验改变为探究性实验。结果表明,一方面,提高了学生对有机化学理论课的学习兴趣和自主探究理论知识的动力。另一方面,使学生具有较早地参与科学研究的兴趣和基础。

(2R,3R)-1,4-二甲氧基-1,1,4,4-四苯基-2,3-丁二醇合成方法研究进展

(2R,3R)-1,4-二甲氧基-1,1,4,4-四苯基-2,3-丁二醇是一类应用广泛的手性二醇,本文从绿色化学的角度综述了其合成方法的研究进展。本课题组通过(2R,3R)-1,1,4,4-四苯基丁四醇的区域选择性反应设计新的合成方案,缩短了合成路线,用常规试剂如甲醇、氯化亚砜和无机碱液等取代了DDQ(2,3-二氯-5,6-二氰-1,4-苯)、LiAlH4、NaH和MeI等化学试剂,发展出高效、便捷、绿色化程度较高的合成方案。

(2R,3R)-1,4-二甲氧基-1,1,4,4-四苯基-2,3-丁二醇的合成——推荐一个大学有机化学综合实验

“(2R,3R)-1,4-二甲氧基-1,1,4,4-四苯基-2,3-丁二醇的合成与表征”是“化学综合实验”课程的一个创新实验。(2R,3R)-1,4-二甲氧基-1,1,4,4-四苯基-2,3-丁二醇是一种应用广泛的手性二醇,但其合成方案制备成本较高、合成操作繁琐且具有一定的危险性,不适合作为本科教学实验开设。该综合实验以天然酒石酸酯为手性源,与苯基格氏试剂反应制得(2R,3R)-1,1,4,4-四苯基丁四醇;基于其高度区域选择性2,3-环亚硫酸酯化反应,利用甲醇与卤代烃的亲核取代反应引入甲氧基,避开MeI/NaH的羟基醚化方案,制得(2R,3R)-1,4-二甲氧基-1,1,4,4-四苯基-2,3-丁二醇,降低了制备成本,简化了实验操作步骤。该实验涵盖了格氏反应、亲核取代、水解反应等经典反应类型,涉及无水操作、萃取、重结晶及薄层色谱检测等合成操作和熔点、比旋光度测定、核磁共振等表征手段。该综合实验和基础有机化学实验紧密衔接,培养和提高了学生的综合实验能力,加深了学生对有机化学理论知识的理解,让学生深刻认识到高度区域选择性反应的设计在有机合成中的重要性,激发了学生的科研兴趣和创新意识,适合作为大学综合化学实验开设。

2D/2D BiOBr/g-C_(3)N_(4)S型异质结光催化性能

近年来,能源短缺和环境污染严重威胁人类的可持续发展.光催化技术具有绿色环保、成本低等优势,被认为是解决上述问题的最佳途径之一,其实用化的核心是开发高效可见光催化材料.石墨相氮化碳(g-C_(3)N_(4))因其物理化学性质稳定、无毒、廉价及能带适宜等特点,广泛应用于光催化领域.然而,光生载流子易复合、比表面积小等问题不利于其实际应用,构建g-C_(3)N_(4)基2D/2D异质结不仅能促进载流子有效分离,而且能为反应提供更多表面空间环境,是提高g-C_(3)N_(4)催化活性的有效途径.目前,Ⅰ型和Ⅱ型异质结虽能促进电荷分离,但降低了电荷参与表面反应的电势;而S型异质结电荷转移机制遵循热力学和动力学规律,能很好保留高氧化还原能力的电子和空穴,因而备受关注.当前,开发S型g-C_(3)N_(4)基2D/2D异质结有助于发展高效光催化体系.本文首先以三聚氰胺为前驱体,通过二次高温煅烧得到2D g-C_(3)N_(4)纳米片;随后,以Bi(NO3)3·5H2O和KBr为反应物,乙二胺和水为溶剂,借助室温原位自组装法获得一系列不同质量比的BiOBr/g-C_(3)N_(4)异质结.研究表明,BiOBr均匀分布于g-C_(3)N_(4)表面形成具有良好接触界面的2D/2D异质结,而且BiOBr/g-C_(3)N_(4)比表面积可提高至g-C_(3)N_(4)的2.4倍.当BiOBr与g-C_(3)N_(4)质量比为1.5:1时,可见光照射30 min,30 mg复合样品可将浓度为10 mg·L^(-1)的RhB(100 mL)几乎全部降解,降解过程符合一级反应动力学,降解速率是g-C_(3)N_(4)的48.2倍.此外,该体系具有一定的光催化析氢活性及良好的循环稳定性.X射线光电子能谱、紫外光电子能谱、莫特肖特基、电化学阻抗谱分析及活性物种捕获等实验结果表明,由于还原性半导体g-C_(3)N_(4)与氧化型半导体BiOBr费米能级不同,二者接触时,电子从费米能级高的g-C_(3)N_(4)转移至费米能级低的BiOBr,在复合材料界面产生强的内建电场,借助带边弯曲和库仑力共同作用,形成了具有S型电荷转移途径的2D/2D BiOBr/g-C_(3)N_(4)异质结.在光照条件下,g-C_(3)N_(4)价带空穴能与BiOBr导带电子快速复合(一般认为是无用的电荷),从而使具有高反应活性的g-C_(3)N_(4)导带电子与BiOBr价带空穴参与表面反应,有效提高了体系的催化活性.综合本文及其他相关研究可知,在由氧化型和还原型半导体组成的异质结中,S型电荷转移机制具有一定普适性,可指导开发高效光催化体系以解决能源和环境问题.

二维介孔超薄Cd0.5Zn0.5S纳米片:形成机制及光催化分解水制氢性能

太阳光驱动的光催化分解水产氢是一种绿色制氢技术,并以氢为载体可实现太阳能向化学能的转化.目前开发高效、稳定的可见光催化剂仍是本领域的研究热点.在各类光催化材料中,Cd0.5Zn0.5S固溶体比TiO2及g-C3N4具有更优异的光催化产氢活性,但它一般为团聚了的纳米颗粒或纳米微球,表面积小,比表面反应迟缓,从而限制了其实际应用.通常,超薄多孔二维结构光催化剂具有高比表面积,能够为反应物分子与催化剂之间提供大量接触界面并促进传质,此外,特定晶面暴露赋予了其大量不饱和配位表面原子,使反应物分子更容易在催化剂表面吸附活化,提升表面催化反应动力学.本文首先采用乙二胺与水的混合溶液制备了无机有机杂化的硫化锌-乙二胺(记为:ZnS(en)0.5).随后,分别以ZnS(en)0.5为硬模板、以乙二醇为反应介质、氯化镉为镉源,通过溶剂热阳离子交换得到了无机有机杂化的Cd0.5Zn0.5S(en)x中间产物.最后,将Cd0.5Zn0.5S(en)x在纯水中进行水热反应脱除晶格内乙二胺分子得到了2D介孔超薄Cd0.5Zn0.5S纳米片.TEM测试发现,纳米片表面存在大量孔洞,其主要源于Cd0.5Zn0.5S(en)x的相变过程及其晶格内乙二胺分子的逃逸导致的晶格畸变.AFM观察结果表明,最终产物Cd0.5Zn0.5S纳米片厚度约为1.5 nm;其比表面积可达63.5 m2/g,几乎是相应纳米颗粒的两倍.以三乙醇胺(TEOA)为牺牲剂时,Cd0.5Zn0.5S纳米片的产氢速率达到19.1 mmol·h^−1·g^−1,是相应纳米颗粒的两倍多.即使在纯水中,Cd0.5Zn0.5S纳米片产氢速率仍可达到1395μmol·h−^1·g^−1,超过了目前所报道的未加修饰的光催化剂的活性.其优异的活性源于其独特的结构优势,包括载流子迁移距离的缩短、表面不饱合原子及比表面积的增大.但在纯水中其严重的光腐蚀仍然亟待克服.此外,为进一步增强其活性,通过机械复合的方法得到了NiCo2S4/Cd0.5Zn0.5S二元复合光催化剂,其在TEOA为牺牲剂时制氢速率可达62.2 mmol·h^−1·g^−1,在纯水制氢速率达到2436μmol·h^−1·g^−1.电化学、UPS及EPR分析表明,NiCo2S4与Cd0.5Zn0.5S纳米片间形成了肖特基接触,进一步促进了载流子分离能力,提高了复合物的产氢活性.以本工作为基础,还可制备其他高活性的CdZnS-基功能光催化材料用于太阳能转化或其他领域.

双助剂促进g-C_3N_4光解水制氢性能（英文）

氢能是最具应用前景的清洁能源之一,利用太阳能作为驱动力光催化水分解制取氢气已被广泛研究.作为非金属半导体光催化剂, g-C_3N_4具有合适的能带结构(2.71 eV),良好的可见光捕获能力和物理化学稳定性,因而有一定的光催化产氢能力;但是它具有可见光吸收能力(<470 nm)不够、光生电子空穴容易复合等缺点,使其光催化制氢能力受到了极大限制.通过助剂修饰可有效促进载流子分离,增加反应活性位点及加速产氢动力学.因此,本文采用双助剂改性以提高g-C_3N_4的光催化制氢性能.本文首先采用原位煅烧法将银纳米粒子(AgNPs)沉积在g-C_3N_4表面(Ag/g-C_3N_4),随后利用水热法成功地将硫化镍(NiS)负载在Ag/g-C_3N_4复合材料表面.XRD, FT-IR, XPS和TEM结果表明,通过原位煅烧和水热合成法可以成功地将Ag和NiS均匀、稳定沉积在g-C_3N_4表面,并且g-C_3N_4保持原有结构不变.紫外可见吸收光谱(UV-Vis)、瞬态光电流、阻抗(EIS)和光致发光谱(PL)分析表明, AgNPs和NiS的引入不仅改善了体系的光吸收范围和强度,而且显著提高了体系光生电子和空穴的产生、分离性能,有助于提高光子利用效率.其中三元样品的最高光电流可以达到2.94′10–7 A·cm^(–2),是纯g-C_3N_4的3.1倍.对系列光催化剂的分解水制氢性能测试发现(采用300 W氙灯作为光源,三乙醇胺作为牺牲剂), 10wt%-NiS/1.0wt%-Ag/CN样品具有最优异的光催化分解水制氢性能,产氢速率可达9.728 mmol·g–1·h–1,是纯g-C_3N_4的10.82倍,二元10wt%-NiS/CN的3.45倍, 1.0wt%-Ag/CN的2.77倍.三元样品反应前后的XRD特征峰位置没有发生变化,循环四次后样品仍具有83%的催化活性,证明其具有良好的制氢稳定性.10 wt%-NiS/1.0 wt%-Ag/CN样品在可见光下(λ> 420 nm)的制氢量子效率为1.21%.三元体系光催化产氢性能增强的原因在于:(1)Ag纳米颗粒的局域表面等离子体效应使得三元体系的光捕获能力得到提高;(2)Ag NPs和NiS负载在g-C_3N_4上共同促进了光生电子空穴的产生和分离;(3)Ag NPs和Ni S作为优良的析氢助催化剂沉积在g-C_3N_4表面上可以有效地提高产氢动力学.本文构建的NiS/Ag/g-C_3N_4复合体系为g-C_3N_4基复合光催化剂的设计及制备提供了新的思路.

Ni_(2)P-NiS双助剂促进g-C_(3)N_(4)光催化产氢动力学

本文通过简单的一步水热法得到Ni_(2)P-NiS双助催化剂,之后采用溶剂蒸发法将Ni_(2)P-NiS与g-C_(3)N_(4)纳米片结合构建获得无贵金属的Ni_(2)P-NiS/g-C_(3)N_(4)异质结。研究结果表明,优化后的复合材料具有良好的光催化产氢活性,其产氢速率最高可到6892.7μmol·g^(−1)·h^(−1),分别为g-C_(3)N_(4)(150μmol·g^(−1)·h^(−1))、15%NiS/g-C_(3)N_(4)(914.5μmol·g^(−1)·h^(−1))和15%Ni_(2)P/g-C_(3)N_(4)(1565.9μmol·g^(−1)·h^(−1))的46.1、7.5和4.4倍。这主要归因于Ni_(2)P-NiS相比Ni_(2)P和NiS单体具有更好的载流子转移能力,其与g-C_(3)N_(4)形成的肖特基势垒能有效促进光生载流子在二者界面上的分离,同时Ni_(2)P-NiS能进一步降低析氢过电势,进而显著增强了表面析氢反应动力学。本研究为开发稳定、高效的非贵金属产氢助剂提供了实验基础。

等离子体共振协同S-scheme电荷转移促进W_(18)O_(49)/Cd_(0.5)Zn_(0.5)S高效光催化产氢

硫化锌镉(Cd_(1-x)Zn_(x)S,0<x<1)固溶体作为一种可见光响应光催化剂,因能带结构可调和光解水产氢活性优异而备受关注.如何进一步拓展Cd_(1-x)Zn_(x)S太阳光响应范围,提高光生电子与空穴利用效率是当前的研究热点.本文采用溶剂热法分别制备了Cd_(0.5)Zn_(0.5)S纳米棒和W_(18)O_(49)纳米颗粒,然后借助超声辅助静电自组装策略成功获得具有紫外-可见-近红外光响应的W_(18)O_(49)/Cd_(0.5)Zn_(0.5)S异质结.分析表明,W_(18)O_(49)晶格氧空位周围过量自由电荷的集体振荡,引起强烈的局域表面等离子体共振(LSPR)吸收现象,使其对500~800 nm范围的光产生明显吸收,使体系具有紫外至近红外光响应能力;而且W_(18)O_(49)作为一种氧化型半导体材料,可与还原型Cd_(0.5)Zn_(0.5)S半导体之间形成S-scheme异质结,在内建电场、能带弯曲和静电相互作用下有效促进了光生电子和空穴的分离,并能保留强的氧化还原能力.对比实验发现,常温下以Na_(2)S/Na_(2)SO_(3)为牺牲剂,全光谱照射下,20%-W_(18)O_(49)/Cd_(0.5)Zn_(0.5)S的产氢速率可达147.7mmol·g^(-1)·h^(-1),是Cd_(0.5)Zn_(0.5)S纳米棒单体的2.1倍;可见光下,复合样品的产氢活性约为Cd_(0.5)Zn_(0.5)S单体的1.89倍;近红外光下,Cd_(0.5)Zn_(0.5)S单体无产氢活性,而异质结的产氢速率约为0.2 mmol·g^(-1)·h^(-1).进一步对样品波长依赖性研究发现,当365、400、450 nm的入射光仅能引起W18O49和Cd0.5Zn0.5S的带间激发时,它们的复合样品比Cd_(0.5)Zn_(0.5)S表现出更优异的产氢活性;当λ=550、600、650 nm以及>800 nm的入射光仅能引起W_(18)O_(49)的LSPR效应时,Cd_(0.5)Zn_(0.5)S单体无活性,而W_(18)O_(49)/Cd_(0.5)Zn_(0.5)S仍具有较高的催化性能、但随着波长的增大产氢速率逐渐降低,与复合样品瞬态光电流强度的变化趋势吻合良好.以上结果表明,W_(18)O_(49)与Cd_(0.5)Zn_(0.5)S二者形成的S-scheme界面异质结有效抑制了光生载流子的表面复合,且当入射光不足以引起带间激发时,W_(18)O_(49)的LSPR效应产生的"热电子"可有效注入到Cd_(0.5)Zn_(0.5)S,从而引起表面催化反应.进一步研究发现,当将反应温度从25提高到60°C时,20%-W_(18)O_(49)/Cd_(0.5)Zn_(0.5)S在全光谱下的产氢速率可提高到306.1mmol·g^(-1)·h^(-1),表明温度对光催化产氢过程具有不可忽视的影响,可通过增强表面反应速率显著提高产氢活性.总之,本文通过一种简便方法获得了具有紫外-可见-近红外响应的S型W_(18)O_(49)/Cd_(0.5)Zn_(0.5)S异质结光催化剂,详细对比了不同波段下样品的光电特性及催化活性,最终在S-scheme电荷转移机制和LSPR"热电子"注入过程的协同作用下,复合样品活性比Cd_(0.5)Zn_(0.5)S单体有了明显提高.

Identification and characterization of microRNAs in raw milk during different periods of lactation, commercial fluid, and powdered milk products

最近的婴儿的公式奶粉污染事件证明了在牛奶质量控制的经典标记或标准在识别鈥渕a nipulated 鈥 ? 是不够的差质量的牛奶。在现在的学习，我们第一次证明奶牛牛奶包含大量 microRNAs ( miRNAs )并且牛奶特定的 miRNAs 的唯一的表示侧面能为未加工的牛奶和牛奶相关的商业产品的质量控制用作新奇指示物和可能的新标准，例如液体牛奶和粉状的公式牛奶。用定序的 Solexa，首先，我们系统地在未加工的牛奶屏蔽了 miRNA 表示并且在未加工的牛奶识别了 245 miRNAs 的一个总数。不同于层次在哺乳的不同时期是其表达式将近相同的另外的经典 biomarkers，单个 miRNAs 能显著地在哺乳过程期间被改变，含有那 miRNAs 可以是更精确的指示物反映牛奶的优秀改变。第二，使用 TaqMan 基于探查的 miRNA 量的 RT-PCR ，我们进一步识别了七 miRNAs 重要地在整个哺乳过程，和更多有相对一致的表情，这七牛奶特定的 miRNAs 的表示侧面能为区别用作理想的 biomarker 差质量或从纯未加工的牛奶的 鈥渕a nipulated 鈥?牛奶，象为商业乳制品的质量控制一样，例如液体，牛奶和粉状的公式挤。一起，我们的调查结果为为决定未加工的牛奶或牛奶相关的商业产品的质量理解牛奶 miRNAs 和一个新潜在的标准的生理的角色提供一个基础。

Preparation of Nickel‑Cobalt/Carborundum Carbide Composite Coatings by Supergravity Field‑Enhanced Electrodeposition

Nickel-cobalt/silicon carbide(Ni-Co/SiC)composite coatings were fabricated by supergravity field-enhanced electrodeposition.The surface morphology and the distribution of the SiC particles in the coatings were examined by scanning electron microscope and energy dispersive X-ray spectrometry.The preferred orientations of the coatings were measured by X-ray diffractometry.The wear resistance and microhardness were measured by a reciprocating tribometer and a microhardness instrument,respectively.The results revealed that the use of the supergravity field enhanced the smoothness of the as-deposited Ni-Co/SiC coatings,and the SiC nanoparticles were uniformly distributed in comparison with that for conventional electrodeposition.When the rotation speed of the cathode,which provided the supergravity field,was 800 r/min,the SiC content in the coating reached a maximum of 8.1 wt%,which was a much higher content than the 2.2 wt%value obtained under conventional electrodeposition.The highest coating microhardness of 680 HV was also observed at this rotation speed.In addition,the wear resistance of the as-prepared Ni-Co/SiC coatings exhibited improved performance relative to that prepared under normal gravity.A minimum wear weight loss of 1.4 mg together with an average friction coefficient of 0.13 were also realized at a rotation speed of 800 r/min,values which were much lower than those for normal gravity.

Economic Analysis on the Rational Allocation of Agricultural Production Factors in Henan Province

Based on the population floating theory under the Ranis-Fei dual economic structure,this paper designs an econometric model to study the isoquant curve and production factor substitution law. Finally,through the empirical analysis of labor-capital investment in Henan's agricultural production,combined with the principles of isoquant curve model,this paper determines the labor required for a certain scale of investment in agricultural production,and concludes that the fixed assets investment in Henan's agricultural production is not fully utilized,and too much labor is transferred. And this paper makes the corresponding policy recommendations for Henan's macroeconomic development.

羊布鲁菌病合并腹主动脉溃疡1例

布鲁菌病是常见的传染病,主动脉溃疡是其罕见并发症。该文报道1例反复发热、腹痛、纳差的患者,经病原学检查确诊为布鲁菌病,抗菌治疗后腹痛症状仍难以缓解,腹主动脉CT血管成像(CTA)检查结果提示腹主动脉溃疡,行腹主动脉覆膜支架置入术,术后1个月随访CTA结果显示溃疡愈合良好,续予抗感染治疗。

Multiresponsive,easy-reversible,and dual-visual Pt(Ⅱ)salt nanostructures for advanced anti-counterfeiting application

Smart materials that integrate multi-stimuli response,full reversibility,and dual-visual read-out channel are highly desired for anticounterfeiting and information encryption applications.Herein,we developed a multiresponsive perchlorate terpyridyl Pt(Ⅱ)nano complex which could undergo fully reversible conversion between three forms stimulated by water or formaldehyde molecule due to the extent of Pt–Pt interaction.Meanwhile,a dual-visual channel,i.e.,the colorimetric channel changed from yellow to orange or red and the corresponding luminescent channel from orange to orange-red or red,has also been found.The weak and equivalent strength of ion-dipole interaction and hydrogen bond that generated between formaldehyde/water and Pt(II)salt result in the easy-control reversibility between the three forms.Furthermore,by introducing different polymer matrices,1Cl·ClO_(4)@PMMA(1Cl·ClO_(4):[Pt(tpy)Cl]·ClO4,tpy:2,2':6',2''-terpyridine),PMMA:poly(methyl methacrylate))and 1Cl·ClO4@PVA(PVA:polyvinyl alcohol)are successfully constructed,which exhibit different reversible behaviors since the PMMA and PVA matrix exert different influences on the strength of hydrogen-bond.Those smart Pt(II)salt nanostructures present great potential for high-security-level anticounterfeiting application.

Helical wire electrochemical discharge machining on large-thickness Inconel 718 alloy in lowconductivity salt-glycol solution

Wire electrochemical machining(WECM) is a flexible and effective method for machining complex-shaped metal components, but the ability to machine large-thickness workpieces is hampered by the difficulty of transporting electrolytic products in the narrow machining gap. This paper proposes a novel hybrid machining technique that combines the characteristics of WECM and wire electric discharge machining(WEDM), namely, helical wire electrochemical discharge machining. The formation mechanism of electrical discharge in salt-glycol solution was elucidated.Experiments and simulation were conducted to verify the machining mechanism and investigate the performance of the proposed technique. The results show that as the recast layer can be removed by electrochemical action during the proposed process, the surface quality is effectively improved.Minimum surface roughness of the slit sidewall after machining reaches Ra= 0.12 μm. Minimum standard deviation of the slit after machining reaches 5 μm. Moreover, the existence of the discharges significantly improves the transport of the electrolytic products, thus ensuring high machining efficiency. In the experiments, the maximum feed rate of the helical wire electrochemical discharge machining reaches 7 μm/s(12.6 mm^(2)/min). Finally, mortise structures of Inconel 718 with good machining accuracy and surface quality are fabricated with a feed rate of 5 μm/s(9 mm^(2)/min),demonstrating that electrical discharge assisted helical wire ECM is a promising technique for machining large-thickness hard metal materials.

A family of oligo(p-phenylenevinylene)derivative aggregation-induced emission probes:Ultrasensitive,rapid,and anti-interfering fluorescent sensing of perchlorate via precise alkyl chain length modulation

The precise regulation of interactions provided by aggregation-induced emission(AIE)probes is of considerable significance for improving the sensing performance in the field of on-site detection.Here,a highly sensitive perchlorate detection probe was designed by precisely modulating the van der Waals interactions by adjusting the length of the alkyl chain.The optimized AIE probe demonstrated superior perchlorate detection performance owing to its strong van der Waals interactions with perchlorate,including a low detection limit(53.81 nM),rapid response(<5 s),and excellent specificity even in the presence of 16 interfering anions.In addition,a hydrogel-based device loaded with the probe was constructed to achieve ultrasensitive recognition of perchlorate particles with a detection limit as low as 15 fg under a fluorescence microscope.Moreover,the practicality of the probe was further verified by employing a sensing chip in a portable detector,and thus the probe has been proven to be highly promising for trace perchlorate monitoring in real scenarios.We expect the present study to be of great value for the efficient design of high-performance fluorescent probes.

重症医学医师的毕业后教育-中国医师协会重症医学医师分会住培与专培工作

中国医师协会重症医学医师分会在过去三年中致力于重症医学医师的规范化培训,目前已经初步形成了住院医师和专科医师一体化的规范化培训体系。近期的工作重点在于完善已有的培训体系,对基地建设、培训质量和师资建设进行进一步规范化指导。

Electrochemical cutting of mortise-tenon joint structure by rotary tube electrode with helically distributed jet-flow holes

In aero-engines,mortise-tenon joint structures are often used to connect the blades to the turbine disk.The disadvantages associated with conventional manufacturing techniques mean that a low-cost,high-efficiency,and high-quality nickel-based mortise–tenon joint structure is an urgent requirement in the field of aviation engineering.Electrochemical cutting is a potential machining method for manufacturing these parts,as there is no tool degradation in the cutting process and high-quality surfaces can be obtained.To realize the electrochemical cutting of a mortise-tenon joint structure,a method using a tube electrode with helically distributed jet-flow holes on the side-wall is proposed.During feeding,the tube electrode rotates along its central axis.Flow field simulations show that the rotational speed of the tube electrode determines the direct spraying time of the high-speed electrolyte ejected from the jet-flow holes to the machining area,while the electrolyte pressure determines the flow rate of the electrolyte and the velocity of the electrolyte ejected from the jet-flow holes.The machining results using the proposed method are verified experimentally,and the machining parameters are optimized.Finally,mortise and tenon samples are successfully machined using 20 mm thick Inconel 718 alloy with a feeding rate of 5μm/s.