Effects of Chlorine and Chlorine Monoxide on Stratospheric Ozone Depletion

This paper presents a system approach of mass balance calculations of ozone and other species under diffusion-convection-reaction processes to study the impacts of major ozone-depleting chemicals, chlorine (Cl) and chlorine monoxide (ClO), and the effect of photolysis on ozone concentrations, ozone depletion, total ozone abundance, and ozone layer along the altitude in the stratosphere. The calculated ozone concentrations and profile of the layer followed a similar trend and were generally in good agreement with the measurements above the tropical area. The calculated peak of the layer was at the same mid-stratosphere at Z = 30 km with a peak concentration and total ozone abundance about 20% higher than the measured peak concentration of 8.0 ppm and total abundance of 399 DU. In the presence of Cl and ClO, the calculated ozone concentrations and total abundance were substantially reduced. Cl generally depleted more uniformly of ozone across the altitude, while ClO reduced substantially the ozone in the upper stratosphere and thus shifted the peak of the layer to a much lower elevation at Z = 14 km. Although both ClO and Cl are active ozone-depleting chemicals, ClO was found to have a more pronounced impact on ozone depletion and distribution than Cl. The possible explanations of these interesting phenomena were discussed and elaborated. The approach and calculations in this paper were shown to be useful in providing an initial insight into the structure and behavior of the complex ozone layer.

Unveiling the geometric site dependent activity of spinel Co_(3)O_(4)for electrocatalytic chlorine evolution reaction

Spinel cobalt oxide(Co_(3)O_(4)),consisting of tetrahedral Co^(2+)(CoTd)and octahedral Co^(3+)(CoOh),is considered as promising earth-abundant electrocatalyst for chlorine evolution reaction(CER).Identifying the catalytic contribution of geometric Co site in the electrocatalytic CER plays a pivotal role to precisely modulate electronic configuration of active Co sites to boost CER.Herein,combining density functional theory calculations and experiment results assisted with operando analysis,we found that the Co_(Oh) site acts as the main active site for CER in spinel Co_(3)O_(4),which shows better Cl^(-)adsorption and more moderate intermediate adsorption toward CER than CoTd site,and does not undergo redox transition under CER condition at applied potentials.Guided by above findings,the oxygen vacancies were further introduced into the Co_(3)O_(4) to precisely manipulate the electronic configuration of Co_(Oh) to boost Cl^(-)adsorption and optimize the reaction path of CER and thus to enhance the intrinsic CER activity significantly.Our work figures out the importance of geometric configuration dependent CER activity,shedding light on the rational design of advanced electrocatalysts from geometric configuration optimization at the atomic level.

One-Step Scalable Fabrication of Nitrogen and Chlorine Co-doped Graphene by Electrochemical Exfoliation for High-Performance Supercapacitors

The stacking and aggregation of graphene nanosheets have been obstacles to their application as electrode materials for microelectronic devices.This study deploys a one-step,scalable,facile electrochemical exfoliation technique to fabricate nitrogen(N)and chlorine(Cl)co-doped graphene nanosheets(i.e.,N-Cl-G)via the application of constant voltage on graphite in a mixture of 0.1 mol/L H_(2)SO_(4)and 0.1 mol/L NH_(4)Cl without using dangerous and exhaustive operation.The introduction of Cl(with its large radius)and N,both with high electrical negativity,facilitates the modulation of the electronic structure of graphene and creation of rich structural defects in it.Consequently,in the as-constructed supercapacitors,N-Cl-G exhibits a high specific capacitance of 77 F/g at 0.2 A/g and remarkable cycling stability with 91.7%retention of initial capacitance after 20,000 cycles at 10 A/g.Furthermore,a symmetrical supercapacitor assembled with N-Cl-G as the positive and negative electrodes(denoted as N-Cl-G//N-Cl-G)exhibits an energy density of 3.38 Wh/kg at a power density of 600 W/kg and superior cycling stability with almost no capacitance loss after 5000 cycles at 5 A/g.This study provides a scalable protocol for the facile fabrication of high-performance co-doped graphene as an electrode material candidate for supercapacitors.

Detection of Oxidants Such as Hydroxyl Radicals and Chlorine Electrogenerated on a BDD Electrode by Simple Methods

The aim of this work is to detect electrogenerated hydroxyl radicals and chlorine by simple and less expensive methods. Preparative electrolyses of perchloric acid (HClO4) and sodium chloride (NaCl) were performed on a boron-doped diamond (BDD) electrode. The hydroxyl radicals were quantified indirectly by assaying the samples from the HClO4 (0.1 M) electrolysis with a 10−4 M potassium permanganate solution. The investigations showed that the amount of hydroxyl radicals depends on the concentration of HClO4 and the current density. As for chlorine, a qualitative determination was carried out. A mixture of the electrolyte solution of HClO4 (0.1 M) + NaI (0.2 M) + 2 mL of hexane, taken in this order, leads to a purplish-pink coloration attesting to the presence of Cl2. The same test was carried out with NaBr and NaI giving pale and very pale pink colourations, respectively, showing that the intensity of the colouration depends on the strength of the oxidant present. In addition, oxidants were detected during the electrooxidation of metronidazole (MNZ). The results showed the participation of electrogenerated hydroxyl radicals. The generation of chlorine has also been proven. Furthermore, the degradation leads to a chemical oxygen demand (COD) removal rate of 83.48% and the process is diffusion-controlled.

Chlorine-Substituent Regulation in Dopant-Free Small-Molecule Hole-Transport Materials Improves the Effi ciency and Stability of Inverted Perovskite Solar Cells

Although doped hole-transport materials(HTMs)off er an effi ciency benefi t for perovskite solar cells(PSCs),they inevi-tably diminish the stability.Here,we describe the use of various chlorinated small molecules,specifi cally fl uorenone-triphenylamine(FO-TPA)-x-Cl[x=para,meta,and ortho(p,m,and o)],with diff erent chlorine-substituent positions,as dopant-free HTMs for PSCs.These chlorinated molecules feature a symmetrical donor-acceptor-donor structure and ideal intramolecular charge transfer properties,allowing for self-doping and the establishment of built-in potentials for improving charge extraction.Highly effi cient hole-transfer interfaces are constructed between perovskites and these HTMs by strategi-cally modifying the chlorine substitution.Thus,the chlorinated HTM-derived inverted PSCs exhibited superior effi ciencies and air stabilities.Importantly,the dopant-free HTM FO-TPA-o-Cl not only attains a power conversion effi ciency of 20.82% but also demonstrates exceptional stability,retaining 93.8%of its initial effi ciency even after a 30-day aging test conducted under ambient air conditions in PSCs without encapsulation.These fi ndings underscore the critical role of chlorine-substituent regulation in HTMs in ensuring the formation and maintenance of effi cient and stable PSCs.

Effects of surface chlorine atoms on charge distribution and reaction barriers for photocatalytic CO_(2)reduction

Photocatalytic CO_(2)reduction to produce high value-added carbon-based fuel has been proposed as a promising approach to mitigate global warming issues.However,the conversion efficiency and product selectivity are still low due to the sluggish dynamics of transfer processes involved in proton-assisted multi-electron reactions.Lowering the formation energy barriers of intermediate products is an effective method to enhance the selectivity and productivity of final products.In this study,we aim to regulate the surface electronic structure of Bi_(2)WO_(6)by doping surface chlorine atoms to achieve effective photocatalytic CO_(2)reduction.Surface Cl atoms can enhance the absorption ability of light,affect its energy band structure and promote charge separation.Combined with DFT calculations,it is revealed that surface Cl atoms can not only change the surface charge distribution which affects the competitive adsorption of H_(2)O and CO_(2),but also lower the formation energy barrier of intermediate products to generate more intermediate*COOH,thus facilitating CO production.Overall,this study demonstrates a promising surface halogenation strategy to enhance the photocatalytic CO_(2)reduction activity of a layered structure Bi-based catalyst.

Calculations and Sensitivity Analysis of Chlorine-,NO_(x)-,and Bromine-Depleting Cycles of Stratospheric Ozone

This paper presents an engineering system approach using a 2D model of conservation of mass to study the dynamics of ozone and concerned chemical species in the stratosphere.By considering all fourteen photolysis,ozone-generating,and-depleting chemical reactions,the model calculated the transient,spatial changes of ozone under different physical-chemical-radiative conditions.Validation against the measured data demonstrated good accuracy,close match of our model with the observed ozone concentrations at both 20°S and 90°N locations.The deviation in the average concentration was less than 1% and in ozone profiles less than 17%.The impacts of various chlorine-(Cl),nitrogen oxides-(NO_(x)),and bromine-(Br)depleting cycles on ozone concentrations and distribution were investigated.The chlorine catalytic depleting cycle was found to exhibit the most significant impact on ozone dynamics,confirming the key role of chlorine in the problem of ozone depletion.Sensitivity analysis was conducted with levels of 25%,50%,100%,200%,and 400% of the baseline value.The combined cycles(Cl+NO_(x)+Br)showed the most significant influence on ozone behavior.The total ozone abundance above the South Pole could decrease by a small 3%,from 281 DU(Dubson Units)to 273 DU for the 25% level,or by a huge thinning of 60%to 114 DU for the 400% concentration level.When the level of chlorine gases increased beyond 200%,it would cause ozone depletion to a level of ozone hole(below 220 DU).The 2D Ozone Model presented in this paper demonstrates robustness,convenience,efficiency,and executability for analyzing complex ozone phenomena in the stratosphere.

装饰用UV延迟固化环保型胶粘剂制备及性能分析

针对传统热固化技术中效率低、材料强度低等问题,制备一种UV延迟固化胶粘剂,并对其工艺进行优化,研究其强度、热稳定性、耐化学性等。试验结果表明,选择25%EP3作为活性稀释剂,1%TR-PAG-20101作为阳离子光引发剂,光固化时间为10 s;试验制备的25%EP3UV延迟固化胶粘剂的粘接强度为(3.52±0.16)MPa,拉伸剪切强度为3.6 MPa,固化反应时间在5 min之内,热分解温度在300℃以上;材料在沸水和酸性溶液(pH=2)环境下,强度依然较好,其中,酸性溶液浸泡后强度为(3.36±0.40)MPa。因此,试验制备的UV延迟固化胶粘剂具备良好的力学性能。

超声耦合TiO_(2)/UV光催化处理对玉米秸秆组分影响研究

本文采用超声耦合Ti O_(2)/UV光催化处理玉米秸秆,探究处理条件对玉米秸秆组分及结构的影响。研究结果表明,在Ti O_(2)投加量为0.25g·L^(-1)、pH值为8.25、超声强度为0.625W·m L^(-1)、处理1h的条件下,玉米秸秆中木质素和半纤维素含量分别由未处理前的26.06%、20.58%降低到22.85%、18.39%,纤维素含量由37.67%增加到40.39%。超声耦合Ti O_(2)/UV光催化处理可以破坏玉米秸秆的结构,玉米秸秆断裂破碎成细小碎片,表面粗糙有褶皱。本研究可为超声耦合Ti O_(2)/UV光催化技术在玉米秸秆预处理中的应用提供技术参考。

UV-C照射对鲜切豇豆的保鲜效果研究

为探究短波紫外线(UV-C)照射对鲜切豇豆的保鲜效果,在预试验结果的基础上,分别采用0、0.5 kJ/m^(2)的UV-C处理豇豆,然后将其置于4℃条件下贮藏,定期测定相关指标。结果表明:采用0.5 kJ/m^(2)UV-C照射可以维持鲜切豇豆较高的VC、可溶性固形物、可溶性蛋白和叶绿素含量,减少鲜切豇豆丙二醛(MDA)的积累,同时还能保持鲜切豇豆较高的总酚、类黄酮含量,并提高抗氧化酶的活性,包括过氧化物酶(POD)、过氧化氢酶(CAT)、抗坏血酸过氧化物酶(APX),一定程度上稳定多酚氧化酶(PPO)的活性。综合来说,0.5 kJ/m^(2)UV-C处理可用于鲜切豇豆的贮藏保鲜。

UV-B照射时长对酿酒葡萄果实品质及类黄酮代谢产物的影响

为探明UV-B照射时长对赤霞珠酿酒葡萄果实品质及类黄酮物质的影响,试验设立UV-B每天分别照射2、4、6、8 h共4个梯度,以不进行UV-B照射为对照(CK),对不同UV-B照射时长葡萄果实品质及类黄酮物质进行检测分析。结果表明,短时间的UV-B照射会增加果实中可溶性糖含量,UV-B不同照射时长处理的总酚、单宁、总类黄酮、黄烷-3-醇和总花色苷含量均增加;UV-B不同照射时长对酿酒葡萄果皮中的类黄酮代谢产物影响显著,筛选出差异代谢物13个,其中5种物质显著上调、8种物质显著下调;在类黄酮和次生代谢产物合成通路上分别富集了7个差异代谢物,占代谢物总数的77.78%。利用主成分对果实品质和果皮类黄酮产物测定值进行综合评价,得分从高到低依次为UV-B照射2 h>UV-B照射8 h>UV-B照射4 h>UV-B照射6 h>CK。UV-B照射酿酒葡萄赤霞珠2 h时,果实品质和类黄酮代谢产物表现最佳。

HPLC-UV法同时测定赤血康脉胶囊中五种成分

本研究旨在建立HPLC-UV法同时测定赤血康脉胶囊中芍药苷、毛蕊异黄酮葡萄糖苷、β-蜕皮甾酮、阿魏酸和党参炔苷的含量。采用DiamonsilR C_(18)(250 mm×4.6 mm,5μm)色谱柱;流动相为乙腈-0.1%磷酸(梯度洗脱);流速为1.0 mL/min;柱温为35℃;检测波长为268 nm,进行分析。结果显示,5种化学成分在各自范围内线性关系良好(r>0.9995);精密度、稳定性、重复性试验结果的RSD均小于2.0%,平均加样回收率99.35%~101.59%,RSD 0.95%~2.69%。该含量测定方法简单可靠、重复性好,操作便捷,适用于同时测定赤血康脉胶囊中五种成分的含量。

UV接枝聚硅氧烷-TiO_(2)复合棉织物的制备及性能

通过紫外辐射3-(异丁烯酰氧)丙基三甲氧基硅烷对棉织物进行接枝聚合改性,然后与钛酸四丁酯共水解,形成Si—O—Ti化学键,通过化学键合的形式引入TiO_(2)层。由于Si元素位于棉织物和二氧化钛之间,阻断TiO_(2)光催化降解棉织物。化学键合TiO_(2)与棉织物的结合强度高,提高了耐久性。TiO_(2)对棉织物的整体结构未造成改变,但棉织物的抗紫外线能力显著提升,禁带宽度变小,光催化自清洁能力增强。

基于HPLC-UV-QDa检测不同剂型中噻唑膦和吡虫啉

建立了高效液相色谱-紫外检测器-质谱(HPLC-UV-QDa)测定5种不同剂型产品中噻唑膦和吡虫啉含量的分析方法。样品以乙腈+水(0.05%甲酸)为流动相,采用C18色谱柱进行梯度洗脱,结合紫外和质谱串联检测器进行定性和定量分析。研究结果显示,在质量浓度0.05~50 mg/L,噻唑膦、吡虫啉的线性关系良好,R2分别为0.9992~0.9999和0.9991~0.9996。在0.5、50、500 mg/kg等3个添加水平下,噻唑膦、吡虫啉的平均回收率分别为90.2%~103.9%和94.7%~104.1%,相对标准偏差(RSD)分别为1.04%~6.69%和1.27%~5.88%。噻唑膦和吡虫啉在5种基质中无明显基质效应,检出限分别为0.005和0.01 mg/L,定量限分别为0.02和0.04 mg/kg。方法灵敏度高、稳定性好、准确度高,适用于不同剂型产品中噻唑膦和吡虫啉的分析。

UV-LED表面消毒辐射场的数学模拟体系的建立及试验验证

为了实现紫外发光二极管(Ultraviolet Light-Emitting Diodes,UV-LED)表面消毒器设计的优化、高效、智能化目的,研究建立了UV-LED表面消毒辐射场的数学模型,并进行了试验验证。根据该数学模型,编写了VBA(Visual Basic for Applications)程序,对辐射场进行了模拟和分析。结果显示,辐射模型的计算值与实测值接近,试验验证了辐射模型的可行性。试验进行了应用举例,当照射距离与灯间距的比值为0.4时,选择最大发光角90°的UV-LED可使辐射场最优化;当照射距离与灯间距的比值为0.8和1.6时,对应的最优选择分别是45°和30°的UV-LED。数学模型和相关计算方法为优化设计紫外线表面消毒设施提供了模拟、优化的有效工具。

UV及潮气双重固化硅树脂的制备及性能研究

以含氢MQ硅树脂(HMQ)和1,2-环氧-4-乙烯基环己烷(VCHO)为原料,2,6-二叔丁基-4-甲氧基苯酚(BHT)为抗氧化剂,无水甲苯为溶剂,在铂的乙烯基络合物催化作用下通过硅氢加成反应制备得到含有脂环族环氧官能团和硅羟基的有机硅树脂,通过核磁共振波谱(NMR)、傅里叶红外光谱(FT-IR)以及凝胶渗透色谱(GPC)等手段对树脂结构进行了表征。对合成的脂环族环氧官能化硅树脂进行UV及潮气双重固化实验,探究了UV光照时间、脂环族环氧基含量以及Si-OH含量等因素对硅树脂材料性能的影响。结果表明:当UV光照时间为20s时,制备得到的双固化树脂材料的综合性能良好,凝胶率大于80%、吸水率小于2.4%、水接触角大于111.2°、氮气中5%失重温度大于370℃、空气中5%失重温度大于340℃、玻璃化转变温度(T_(g))大于17℃、铅笔硬度大于4H(3d)。

氟硅协同增强的UV固化透明高硬度双疏涂层的制备及性能

以全氟辛基乙基丙烯酸酯(17F)和四(3-巯基丙酸)季戊四醇酯(PETMP)为原料,通过迈克尔加成反应合成了氟改性多巯基交联剂(FPETMP)。红外光谱和核磁共振氢谱表征证实17F成功改性了多巯基交联剂,且合成的FPETMP中仍有未反应的巯基。将FPETMP与PETMP、(丙烯酰氧基丙基)甲基硅氧烷均聚物(APMS)混合,经紫外光引发巯基-烯点击反应制得透明双疏涂层。研究了FPETMP用量对涂层疏水疏油性、透明性和力学性能的影响。结果表明,随着FPETMP含量的增加,涂层的疏水疏油性增强。但是FPETMP用量太高时,体系相容性下降,涂层的透明度和铅笔硬度也随之变差。当FPETMP的质量分数为20%时,涂层对水和十六烷的接触角分别为116.5°和75.6°,且涂层的硬度较高,铅笔硬度为7H。涂层呈现出良好的光学透明性,综合性能最佳。

UV滴胶模拟水立体形态的工艺及其在设计中的应用

目的 从材料创新角度出发,利用UV滴胶与水质感的相似性,模拟水的立体形态和色彩,探索UV滴胶模拟水形态的工艺技巧和设计应用。方法 复习文献并借助实验熟悉UV滴胶的材料特性,采用滴胶自由造型的方式,分别加入色精、粉末与织物对水的形态进行实验模拟,根据实验效果,探讨UV滴胶在设计中的应用途径和方式。结果 实验采用的UV滴胶自由造型方式能够模拟水的形态;在滴胶造型过程中加入色精与粉末,可模拟水的色彩;在UV滴胶模拟水的形态(如波浪和冰柱)、肌理(如水泡和水波)和色彩的基础上,获得滴胶与织物结合的5种方式,滴胶定型褶裥面料或镂空面料、条状面料、片状面料、碎屑状面料填入滴胶。结论 UV滴胶在以水为主题的设计中呈现出立体、新颖的视觉效果,拓展了新型材料在设计中的应用,可为相关设计提供创新思路和工艺参考。

VUV/UV/NaClO及UV/NaClO去除百里香酚:降解机制及水质影响因素

采用VUV/UV/NaClO及UV/NaClO工艺去除百里香酚(Tml),对比考察pH、CO_(3)^(2-)、NO_(3)^(-)和腐殖酸(HA)等因素对Tml去除的影响,鉴定识别Tml的降解产物并推测了降解途径,探究VUV/UV/NaClO工艺中反应溶液的急性毒性变化,通过反应溶液组分毒性鉴定评估结合ECOSAR软件模拟识别了毒性较大的产物。结果表明,UV/NaClO和VUV/UV/NaClO工艺中Tml的去除拟一级反应动力学常数kobs均随着pH的增大先减少后增加,且均在pH为7时达到最小,分别为0.183 6 min-1和0.554 7 min-1;CO_(3)^(2-)的存在有利于Tml的去除,在VUV/UV/NaClO工艺中,低浓度NO_(3)^(-)对Tml的去除有轻微抑制作用,高浓度则反之;而在UV/NaClO工艺中,NO_(3)^(-)的存在有利于Tml的去除;HA对Tml的去除有抑制作用。相同条件下不同水质因素对VUV/UV/NaClO工艺的促进或抑制更为显著,约为UV/NaClO工艺的1.05~3.57倍。VUV/UV/NaClO工艺中Tml主要发生了自由基的取代、加成和氧化分解反应,生成了氯代、醌和醛类中间产物。VUV/UV/NaClO处理后的溶液毒性呈先上升后下降再上升的趋势,生成的丙酸乙烯基酯和戊醛类等小分子有机物导致了反应后期反应溶液急性毒性增加。

UV固化超支化聚氨酯木器涂料的制备及性能研究

传统UV固化聚氨酯树脂以端双键封端,极性基团少,降低了涂层在木材表面的附着力。采用两步法将一种多羟基的超支化结构引入由不同异氰酸酯制备的聚氨酯体系中并封端,合成了含有多羟基超支化结构的紫外光固化聚氨酯木器涂料。采用凝胶渗透色谱仪(GPC)、核磁共振波谱仪(NMR)、傅立叶变换红外光谱仪(FT-IR)、热重分析仪(TG)、动态热机械分析仪(DMA)等测试表征方法,研究了紫外光固化聚氨酯树脂及木器涂料的各项性能。结果表明:—NCO与—OH物质的量比为1∶8的多羟基超支化异氰酸酯制备成功并引入到聚氨酯中,其中以六甲撑基二异氰酸酯为主体聚氨酯的拉伸强度达到34.69 MPa,弹性模量达到10.64 MPa,玻璃化转变温度为102.02℃,漆膜附着力为0级。此方法为具有高强度、高附着力的UV固化型聚氨酯木器涂料提供了创新解决方案。