N-doped graphene quantum dot-decorated N-TiO2/P-doped porous hollow g-C_(3)N_(4) nanotube composite photocatalysts for antibiotic photodegradation and H2 production

Exclusive responsiveness to ultraviolet light (~3.2 eV) and high photogenerated charge recombination rate are the two primary drawbacks of pure TiO_(2). We combined N-doped graphene quantum dots (N-GQDs), morphology regulation, and heterojunction construction strategies to synthesize N-GQD/N-doped TiO_(2)/P-doped porous hollow g-C_(3)N_(4) nanotube (PCN) composite photocatalysts (denoted as G-TPCN). The optimal sample (G-TPCN doped with 0.1wt% N-GQD, denoted as 0.1% G-TPCN) exhibits significantly enhanced photoabsorption, which is attributed to the change in bandgap caused by elemental doping (P and N), the improved light-harvesting resulting from the tube structure, and the upconversion effect of N-GQDs. In addition, the internal charge separation and transfer capability of0.1% G-TPCN are dramatically boosted, and its carrier concentration is 3.7, 2.3, and 1.9 times that of N-TiO_(2), PCN, and N-TiO_(2)/PCN(TPCN-1), respectively. This phenomenon is attributed to the formation of Z-scheme heterojunction between N-TiO_(2) and PCNs, the excellent electron conduction ability of N-GQDs, and the short transfer distance caused by the porous nanotube structure. Compared with those of N-TiO_(2), PCNs, and TPCN-1, the H2 production activity of 0.1%G-TPCN under visible light is enhanced by 12.4, 2.3, and 1.4times, respectively, and its ciprofloxacin (CIP) degradation rate is increased by 7.9, 5.7, and 2.9 times, respectively. The optimized performance benefits from excellent photoresponsiveness and improved carrier separation and migration efficiencies. Finally, the photocatalytic mechanism of 0.1% G-TPCN and five possible degradation pathways of CIP are proposed. This study clarifies the mechanism of multiple modification strategies to synergistically improve the photocatalytic performance of 0.1% G-TPCN and provides a potential strategy for rationally designing novel photocatalysts for environmental remediation and solar energy conversion.

Advanced oxidation via the synergy of C-defective/C-O band modified ultrathin porous g-C_(3)N_(4)and PMS for efficient photothermal degradation of bisphenol pollutants and lignin derivatives

This work uses thermal polymerization of urea nitrate,oxyacetic acid and urea as the raw material to prepare ultra-thin porous carbon nitride with carbon defects and C-O band(OA-UN-CN).Density functional theory(DFT)calculations showed OA-UN-CN had narrower band gap,faster electron transport and a new internal construction electric field.Additionally,the prepared OA-UN-CN significantly enhanced photocatalytic activation of peroxymonosulfate(PMS)due to enhanced light absorption performance and faster electron overflow.As the result,the OA-UN-CN/PMS could entirely degrade bisphenol A(BPA)within 30 min,where the photodegradation rate was 81.8 and 7.9 times higher than that of g-C_(3)N_(4)and OA-UN-CN,respectively.Beyond,the OA-UN-CN/PMS could likewise degrade other bisphenol pollutants and sodium lignosulfonate efficiently.We suggested possible photocatalytic degradation pathways accordingly and explored the toxicity of its degradation products.This work provides a new idea on the development of advanced photocatalytic oxidation processes for the treatment of bisphenol pollutants and lignin derivatives,via a metal-free photothermal-catalyst.

Pt nanoclusters modified porous g-C_(3)N_(4)nanosheets to significantly enhance hydrogen production by photocatalytic water reforming of methanol

For the use of green hydrogen energy,it is crucial to have efficient photocatalytic activity for hydrogen generation by water reforming of methanol under mild conditions.Much attention has been paid to gC_(3)N_(4)as a promising photocatalyst for the generation of hydrogen.To improve the separation of photogenerated charge,porous nanosheet g-C_(3)N_(4)was modified with Pt nanoclusters(Pt/g-C_(3)N_(4))through impregnation and following photo-induced reduction.This catalyst showed excellent photocatalytic activity of water reforming of methanol fo r hydrogen production with a 17.12 mmol·g^(-1)·h^(-1)rate at room temperature,which was 311 times higher than that of the unmodified g-C_(3)N_(4).The strong interactions of Pt-N in Pt/g-C_(3)N_(4)constructed effective electron transfer channels to promote the separation of photogenerated electrons and holes effectively.In addition,in-situ infrared spectroscopy was used to investigate the intermediates of the hydrogen production reaction,which proved that methanol and water eventually turn into H_(2)and CO_(2)via formaldehyde and formate.This study provides insights for understanding the photocatalytic hydrogen production in the water reforming of methanol.

CdS/In_(2)O_(3)/g-C_(3)N_(4)复合材料的制备及光催化性能研究

采用溶剂热法成功合成了一种新型的Z型CdS/In_(2)O_(3)/g-C_(3)N_(4)三元复合光催化材料。通过XRD、SEM、TEM、XPS和紫外-可见漫反射光谱仪对光催化材料的相结构、形貌、原子价态和光响应性能等进行表征,通过可见光降解苯酚评价其光催化活性。结果表明,具有零维结构的CdS、一维结构的In_(2)O_(3)和三维结构的g-C_(3)N_(4)形成了0D/1D/3D三元复合材料,该材料在180 min可有效降解90%的苯酚,降解速率是CdS的2.9倍、g-C_(3)N_(4)的6倍,且具有较高的稳定性。复合材料光催化能力的增强主要归因于三维多孔g-C_(3)N_(4)与CdS和In_(2)O_(3)形成的三维空间电场。三维多孔结构不仅有利于污染物的高效吸附,而且为光催化反应提供活性位点,三维空间和网络互连结构有利于光生电荷的定向迁移,增加载流子寿命。

B、Cu共掺杂单层g-C_(3)N_(4)电子结构及光学性质的第一性原理研究

g-C_(3)N_(4)是一种极具潜力的绿色半导体光催化剂,但其带隙较宽,对可见光利用率有限。通过元素掺杂可以有效提高g-C_(3)N_(4)的光催化性能,采用第一性原理方法研究了非金属元素B和金属元素Cu共掺杂对g-C_(3)N_(4)电子结构于光学性质的影响机理,结果表明,B、Cu共掺杂g-C_(3)N_(4)(001)表面的最稳定位点为B占据H位点,而Cu占据N2位点。B、Cu共掺杂相比单一B元素掺杂可以使g-C_(3)N_(4)(001)表面的能隙和功函数进一步下降,Cu元素的加入主要改善了B掺杂的g-C_(3)N_(4)(001)表面的电子导通能力以及对光的捕捉能力,从而提高了光催化活性。

金属有机骨架和g-C_(3)N_(4)共掺杂改性TiO_(2)光催化性能

以钛酸四丁酯、三聚氰胺、二甲基咪唑和Co(NO_(3))_(2)•6H_(2)O为原料,采用溶胶-凝胶法、高温煅烧法,将类石墨相氮化碳(g-C_(3)N_(4))和二甲基咪唑钴(ZIF-67)与TiO_(2)共掺杂,制备了TiO_(2)-g-C_(3)N_(4)-ZIF-67光催化剂。采用XRD、XPS、SEM和紫外-可见漫反射光谱(UV-Vis DRS)对TiO_(2)-g-C_(3)N_(4)-ZIF-67进行了表征,对TiO_(2)-g-C_(3)N_(4)-ZIF-67光催化降解甲基橙的催化活性进行了评价,并对其催化机理进行了推测。结果表明,TiO_(2)-g-C_(3)N_(4)-ZIF-67同时包含锐钛矿及少量金红石相TiO_(2)、g-C_(3)N_(4)及ZIF-67;g-C_(3)N_(4)的加入使TiO_(2)的带隙降至2.45 eV,ZIF-67将带隙进一步降至1.91 eV;g-C_(3)N_(4)和ZIF-67的共掺杂降低了带隙,显著提高了TiO_(2)可见光吸收范围(492~649 nm);TiO_(2)-g-C_(3)N_(4)-ZIF-67形成了Ⅱ型异质结,TiO_(2)-g-C_(3)N_(4)与金属有机骨架的结合增强了TiO_(2)光催化降解甲基橙的能力。Co质量分数21.5%的TiO_(2)-g-C_(3)N_(4)-ZIF-67-2具有最佳的光催化降解甲基橙活性,在可见光照射40 min时,甲基橙降解率可达79.92%,3次循环后甲基橙降解率为58.86%(90 min),光催化反应对ZIF-67的结晶度有所影响,进而影响了循环时的光催化活性。

B掺杂对单层g-C_(3)N_(4)光催化性能调控机制的第一性原理研究

光催化技术以太阳能为驱动,在环境治理、氢能制备等领域具有十分广阔的应用前景。g-C_(3)N_(4)是一种极具潜力的绿色光催化剂,但其有限的可见光响应范围以及较宽的能隙限制了其光催化性能的进一步提高。非金属元素掺杂是一种有效提升g-C_(3)N_(4)光催化活性的方法,采用第一性原理计算的方法研究了B元素掺杂对g-C_(3)N_(4)光催化活性的影响机理,考察了掺杂前后的电子结构以及光学性能。结果表明,g-C_(3)N_(4)(001)表面的H位点是B原子掺杂的最稳定位点,掺杂能为-7.81 eV,B元素的加入使g-C_(3)N_(4)(001)表面的能隙从未掺杂的1.468 eV降低到了0.732 eV,功函数从4.055 eV降低到3.108 eV,并提高了表面C原子的反应活性,从而使得g-C_(3)N_(4)(001)表面的光催化活性得到了有效地提高。光学性质研究表明,B元素的加入使得g-C_(3)N_(4)(001)表面发生了明显的“红移”现象,使表面的光响应能力得到了提高,从而获得了更高的光催化能力。

基于Bi_(2)O_(3)/g-C_(3)N_(4)复合材料的自供能紫外探测器的制备及性能研究

为了获得高性能的自供能紫外探测器,结合热聚法和溶液法成功制备了Bi_(2)O_(3)/g-C_(3)N_(4)复合材料,并对其微观形貌、晶体结构、元素组成及价态进行了表征。结果表明,Bi_(2)O_(3)呈蜂窝状结构的块体,其附着在具有层状结构的g-C_(3)N_(4)纳米片上。基于该异质结制备了无需外加偏压即能工作的紫外探测器。在紫外光照射下,Bi_(2)O_(3)/g-C_(3)N_(4)光电探测器能够立即产生光电流并达到最大稳定值约0.43μA,相比于Bi_(2)O_(3)纳米块紫外探测器,其光电流提升了约1.05倍。值得注意的是,Bi_(2)O_(3)/g-C_(3)N_(4)紫外探测器还展现出了快的响应速度(约181.7 ms),并且其光电流与入射光强也具有良好的线性关系,表明该器件对不同强度的紫外光均能实现快速且稳定的探测。

Ag/质子化g-C_(3)N_(4)纳米棒材料的制备及其光催化降解性能

制备了Ag负载于质子化g-C_(3)N_(4)(pCN)的纳米棒材料(Ag/pCN),对比了g-C_(3)N_(4)(CN)、表面负载Ag的CN(Ag/CN)、pCN和Ag/pCN在可见光条件下光催化降解亚甲蓝(MB)溶液的效果。结果表明,Ag/pCN光催化效率最高(92.63%),并且具有良好的稳定性;通过光电流-时间(I-t)曲线、Nyquist曲线、Mott-Schokkty曲线和捕获实验探究了Ag/pCN光催化降解MB的机理:虽然pCN的π共轭体系较CN发生变化,但由于形成了纳米棒,其比表面积的增加以及Ag负载的协同效应致使Ag/pCN具有优异的光催化性能。光催化过程中羟基自由基(·OH)是起主要作用的活性物质,其由光生电子(e^(-))与表面吸附的O_(2)反应产生以及光生空穴(h^(+))与H_(2)O或OH^(-)反应产生。

光激性ZnO@g-C_(3)N_(4)异质结的制备与可见光降解亚甲基蓝

以尿素和三聚氰胺为原材料,通过热聚合制备层状多孔g-C_(3)N_(4)材料。以醋酸锌为锌源,g-C_(3)N_(4)为基体材料,水热法制备异质结构ZnO@g-C_(3)N_(4)材料。利用X射线衍射、扫描电镜、透射电镜、荧光光谱和紫外/可见光漫反射光谱等手段对ZnO@g-C_(3)N_(4)材料进行表征。结果表明,g-C_(3)N_(4)和ZnO@g-C_(3)N_(4)具有多孔片层结构,并且ZnO均匀分布于片层g-C_(3)N_(4)表面,形成异质结构。荧光光谱说明ZnO@g-C_(3)N_(4)异质结构加快了电子和空穴的迁移,降低了电子和空穴的复合率。紫外/可见光漫反射光谱监测亚甲基蓝的特征峰变化,证明了ZnO@g-C_(3)N_(4)异质催化剂可有效降解亚甲基蓝染料。ZnO@g-C_(3)N_(4)催化后离心回收循环利用,多次循环后降解效率未明显降低,说明ZnO@g-C_(3)N_(4)可以重复利用。

CoS_(x)/g-C_(3)N_(4)纳米复合材料的合成及其光催化降解四环素性能

采用简便的低温(120℃)水热法成功合成出非晶相硫化钴/石墨相氮化碳(CoS_(x)/g-C_(3)N_(4))复合材料,利用自组装的方式,让CoS_(x)能够均匀地生长在g-C_(3)N_(4)纳米片上。通过XRD,SEM,FTIR,UV-Vis DRS,BET等测试方法对纳米复合材料的结构和性能进行表征,并在可见光(λ≥420 nm)光照条件下探究其光催化降解四环素的活性。结果表明:特殊的结构设计能够提高复合材料的光催化性能。其中1%CoS_(x)/g-C_(3)N_(4)在可见光照射40 min,四环素的降解率可以达到88.3%,CoS_(x)/g-C_(3)N_(4)复合材料的光催化能力和催化活性大大提高,表现出良好的可见光光催化降解四环素的性能和稳定性。

不同形貌g-C_(3)N_(4)光催化剂的制备及性能

本工作制备了四种形貌的g-C_(3)N_(4)光催化剂,分别为不规则疏松片状g-C_(3)N_(4)-4、不均匀致密颗粒状g-C_(3)N_(4)-8、管状g-C_(3)N_(4)-24以及不规则管状g-C_(3)N_(4)-32。XRD和XPS测试结果证明四种g-C_(3)N_(4)光催化剂的成功制备。光电性能测试结果表明,中空管状g-C_(3)N_(4)-24具有良好的可见光响应、最小的阻抗及最佳的光电流响应,光生电子和空穴的分离效果最好。以碱性品红(Fuchsin basic)为模拟污染物,考察g-C_(3)N_(4)-24光催化剂的光催化降解性能,结果表明,在可见光的条件下,90 min内其对碱性品红的降解效果能达到86.7%。最后根据活性物种捕获实验对g-C_(3)N_(4)-24光催化剂的光催化机理进行研究,发现·O_(2)^(-)、h^(+)和·OH均为碱性品红降解过程中的活性物质,其中·O_(2)^(-)为最主要的活性物种。

Fe/g-C_(3)N_(4)表面改性及其对CO加氢产物分布的影响

采用尿素热缩合法制备了氮化碳(g-C_(3)N_(4)),经H_(2)O_(2)、NH_(3)·H_(2)O处理、浸渍法负载Fe制得改性Fe/g-C_(3)N_(4),对比研究了改性前后催化剂的CO加氢性能。结合XRD、SEM、FT-IR、CO_(2)-TPD、CO-TPD、H_(2)-TPR、接触角测试和N_(2)物理吸附-脱附等系列表征,探究了表面预处理对Fe/g-C3N4催化剂织构性质以及CO加氢产物分布的影响。结果表明,不同改性方法对催化剂的织构性质和CO加氢性能影响显著。尿素热缩合法制备的g-C_(3)N_(4)具有典型蜂窝状结构,Fe与g-C_(3)N_(4)相互作用较强,且高度分散;改性前后样品均呈亲水性,且H_(2)O_(2)、 NH_(3)·H_(2)O处理后亲水性增强,H_(2)O_(2)处理增强了表面羟基,NH_(3)·H_(2)O处理增加了表面氨基,促进了CO吸附,促使Fe(NCN)物相生成;预处理后的催化剂表面碱性增强。在CO加氢反应中,两步改性后的Fe/AM-g-C3N4催化剂,CO_(2)选择性降至11.61%;Fe/AM-g-C_(3)N_(4)表面碱性增强,抑制了烯烃二次加氢,烯烃选择性较高,C_(2)^(=)-C_(4)^(=)达32.37%,O/P值3.23。

新型供体-受体g-C_(3)N_(4)有机半导体光催化铀分离技术

从核废水中光催化提取铀是避免环境破坏和回收铀资源的一种可行方法,但设计具有快速迁移光生电荷和表面反应动力学的高效光催化剂用于去除含铀废水中的U(Ⅵ)仍然是一个重大挑战。采用无模板的自组装技术,成功构建了空心管状g-C_(3)N_(4)(TCN),并通过将间苯二酚引入TCN的骨架结构中,制备了管状供体-受体(D-A)有机半导体光催化剂B-TCN_(x),用于空气气氛下光催化去除U(Ⅵ)。分子内D-A体系的构建,使得电子和空穴分别聚集在受体和供体部分,这降低了电子-空穴对的复合。此外,电子和空穴在受体和供体部分的积累导致了内置电场的形成,从而促进了载流子的迁移。结果表明,B-TCN_(60)在120 min内对U(Ⅵ)的去除率达到96.8%,其动力学常数(0.031 14 min^(-1))是TCN (0.012 15 min^(-1))的2.58倍。并且在连续5次循环后变化不大,具有稳定性和可重复性。因此,D-A光催化剂具有很高的光催化铀分离效率。这项研究为深入了解光催化铀分离提供了启示和指导。

Bi_(2)WO_(6)/g-C_(3)N_(4)复合光催化剂的制备及其光催化性能研究

以尿素、硝酸铋、钨酸钠等为主要原料,在热缩聚法制备g-C_(3)N_(4)的基础上,通过水热法制备Bi_(2)WO_(6)/g-C_(3)N_(4)复合光催化剂。在模拟太阳光照射下,研究Bi_(2)WO_(6)/g-C_(3)N_(4)复合光催化剂对甲基橙的光催化降解性能。结果表明,复合光催化剂相比于单体光催化剂的性能有显著提高。在Bi_(2)WO_(6)与g-C_(3)N_(4)质量比为2∶1、水热温度为180℃、水热时间为12 h条件下,复合光催化剂的性能最好。光照时间210 min时,甲基橙降解率达到了98.15%,相比于单体Bi_(2)WO_(6)和g-C_(3)N_(4)光催化剂的效率分别提高了25.1%和37.7%,且光催化降解过程符合一级动力学方程。复合光催化剂具有优异的稳定性,经过4次重复性实验,甲基橙降解率仍达到95.17%。

g-C_(3)N_(4)基S型异质结的构建及其光催化性能研究

为了解决日益严重的环境污染和能源短缺等问题,基于半导体的光催化技术利用太阳能为环境修复和能源储存提供了一种“绿色”可持续的方案。首先介绍了g-C_(3)N_(4)的优点和局限性,以及S型半导体的优势与不足,接着介绍了g-C_(3)N_(4)基S型异质结的电子结构和光催化性质,综述了基于不同类型g-C_(3)N_(4)的S型异质结光催化材料构建和光催化性能的提升策略,并梳理了其部分应用。最后,综述了基于g-C_(3)N_(4)的S型异质结面临的挑战和未来发展趋势,有望为g-C_(3)N_(4)基S型异质结光催化材料的开发和实际应用提供重要的参考。

CQDs/g-C_(3)N_(4)复合材料合成及其光催化性能的研究进展

石墨氮化碳(g-C_(3)N_(4))在新能源开发和环境修复方面具有巨大的应用潜力,但纯g-C_(3)N_(4)存在的光吸收范围小、结晶度高、光生载流子复合率高和活性位点偏少等缺点限制了其应用范围。引入碳量子点(CQDs)构建复合相,可以增加g-C_(3)N_(4)的反应活性位点,加快其表面电荷的转移,抑制载流子的复合,从而提升其光催化活性。对CQDs的制备方法和原料来源,以及CQDs/g-C_(3)N_(4)复合材料的合成方法(溶剂热法、煅烧法、自组装法)和光催化性能的提升策略等方面的研究进展进行了综述,介绍了近年来CQDs/g-C_(3)N_(4)复合材料在氢气制取、污染物降解、抗菌方面的应用,最后对CQDs/g-C_(3)N_(4)复合材料的未来发展方向进行了展望。

g-C_(3)N_(4)/MXene@Ag多功能膜制备及其水净化性能研究

通过真空辅助组装构建g-C_(3)N_(4)/MXene@Ag(CNMA)分离膜。研究表明,银纳米粒子的引入可以增强表面润湿性并优化传质通道,复合膜最高分离通量(对水包1,2-二氯乙烷乳液)为(6812.7±106)L m^(-2)h^(-1)bar^(-1),最大效率可达99.7%。值得注意的是,CNMA复合膜具有显著的抗污能力,在连续使用10次后仍保持稳定的分离性能。此外,MXene@Ag材料能够优化复合膜体系的能带结构,促进电子-空穴(e^(-)-h^(+))的有效空间分离,从而改善光电性能,实现对有机污染物(染料、抗生素)的高效去除,其中对亚甲基蓝染料的降解效率为98%。CNMA分离膜适用于有机污染物场景下的水环境修复,满足实际污水处理要求,具有十足的发展前景。

g-C_(3)N_(4)/生物炭/nZVI还原水中硝酸盐的性能

通过在g-C_(3)N_(4)/生物炭(BC)材料表面还原沉积纳米零价铁(nZVI)制备了g-C_(3)N_(4)/BC/nZVI复合催化剂.利用SEM、TEM、XPS、XRD、UV-Vis DRS、光电流等对所制备的催化剂进行了物化性质和光电性能的表征,考察了g-C_(3)N_(4)/BC/nZVI在可见光照下对水中硝酸盐(NO_(3)^(-))的还原性能.结果表明,中性水体的最佳反应条件为g-C_(3)N_(4)/BC与nZVI的质量比为1:0.6,g-C_(3)N_(4)/BC/nZVI的投加量为2g/L,NO_(3)^(-)的初始浓度为20mg/L.与nZVI,BC/nZVI,g-C_(3)N_(4)/nZVI相比,g-C_(3)N_(4)/BC/nZVI表现出最快的NO_(3)^(-)还原速率(k=10.6×10^(-2)min^(-1))以及较高的脱氮性能(71.6%).实验进一步考察了g-C_(3)N_(4)/BC/nZVI还原NO_(3)^(-)过程中氮的变化规律.推测还原机理为:可见光照下,光生电子通过BC转移到n ZVI表面,提高了nZVI的反应活性和稳定性,同时,BC材料抑制光生空穴对nZVI的氧化作用;nZVI表面的活性电子将NO_(3)^(-)还原为N2和NH4+,而光生空穴则进一步将部分NH4+氧化为N2和其他气态产物.

Decade Milestone Advancement of Defect-Engineered g-C_(3)N_(4) for Solar Catalytic Applications

Over the past decade, graphitic carbon nitride(g-C_(3)N_(4)) has emerged as a universal photocatalyst toward various sustainable carbo-neutral technologies. Despite solar applications discrepancy, g-C_(3)N_(4) is still confronted with a general fatal issue of insufficient supply of thermodynamically active photocarriers due to its inferior solar harvesting ability and sluggish charge transfer dynamics. Fortunately, this could be significantly alleviated by the “all-in-one” defect engineering strategy, which enables a simultaneous amelioration of both textural uniqueness and intrinsic electronic band structures. To this end, we have summarized an unprecedently comprehensive discussion on defect controls including the vacancy/non-metallic dopant creation with optimized electronic band structure and electronic density, metallic doping with ultraactive coordinated environment(M–N_(x), M–C_(2)N_(2), M–O bonding), functional group grafting with optimized band structure, and promoted crystallinity with extended conjugation π system with weakened interlayered van der Waals interaction. Among them, the defect states induced by various defect types such as N vacancy, P/S/halogen dopants, and cyano group in boosting solar harvesting and accelerating photocarrier transfer have also been emphasized. More importantly, the shallow defect traps identified by femtosecond transient absorption spectra(fs-TAS) have also been highlighted. It is believed that this review would pave the way for future readers with a unique insight into a more precise defective g-C_(3)N_(4) “customization”, motivating more profound thinking and flourishing research outputs on g-C_(3)N_(4)-based photocatalysis.