提升二维材料的电催化析氢和光催化析氢性能的策略

世界能源危机问题和环境问题日益突出,寻找低廉、易得且能够替代化石的清洁能源是目前研究的热点.氢气具有可再生性、安全、高能量密度、环境友好型等优点,因而成为替代化石燃料的首选.在众多途径中,电催化产氢和光催化产氢是目前应用较广且比较成熟的方法,其工艺过程简单、无污染,但由于效率较低或生产成本较高等因素,其大规模应用受到一...     

Layered MoS2@graphene functionalized with nitrogen-doped graphene quantum dots as an enhanced electrochemical hydrogen evolution catalyst

Layered MoS₂@graphene functionalized with nitrogen-doped graphene quantum dots (MoS₂@NGQDs-GR) was obtained by one-pot hydrothermal method, as an enhanced electrochemical hydrogen evolution catalyst.     

Lightweight excellent microwave absorption properties based on sulfur doped graphene

Lightweight and high-efficiency electromagnetic wave (EMW) absorption sulfur doped graphene (S-GS) was fabricated by reducing and doping graphene oxide (GO) using chemical method. The obtained S-GS exhibits an extremely low reflection loss (RL), wide effective absorption frequency bandwidth at a thin coating thickness (d), light weight and low cost. The minimum RL reaches −52.3 dB at 17.5 GHz with a matching thickness of 1.22 mm. More excitedly, the EM absorption properties could be double-adjusted. By changing the amount of dopant and the thickness of S-GS, The minimum RL touches −52.2 dB at 9.4 GHz and −49.3 dB at 8.5 GHz, respectively, even much lower than most kinds of GS based composites which combined with polymers, magnetic nanoparticles and so on. In a word, S-GS can be promised to be an ideal candidate for constructing novel MW absorber with lightweight, strong absorption characteristics, and thin matching thickness.     

Photocatalytic hydrogen evolution over mesoporous TiO2/metal nanocomposites

Na⁺ complex with the dibenzo-18-crown-6 ester was used as a template to synthesize mesoporous titanium dioxide with the specific surface area 130–140 m²/g, pore diameter 5–9 nm and anatase content 70–90%. The mesoporous TiO₂ samples prepared were found to have photocatalytic activity in Cu^II, Ni^II and Ag^I reduction by aliphatic alcohols. The resulting metal–semiconductor nanostructures have remarkable photocatalytic activity in hydrogen evolution from water–alcohol mixtures, their efficiency being 50–60% greater than that of the metal-containing nano-composites based on TiO₂ Degussa P25.The effects of the thermal treatment of mesoporous TiO₂ upon its photocatalytic activity in hydrogen production were studied. The anatase content and pore size were found to be the basic parameters determining the photoreaction rate. The growth of the quantum yield of hydrogen evolution from TiO₂/Ag⁰ to TiO₂/Ni⁰ to TiO₂/Cu⁰ was interpreted in terms of differences in the electronic interaction between metal nanoparticles and the semiconductor surface. It was found that there is an optimal metal concentration range where the quantum yield of hydrogen production is maximal. A decrease in the photoreaction rate at further increment in the metal content was supposed to be connected with the enlargement of metal nanoparticles and deterioration of the intimate electron interaction between the components of the metal–semiconductor nanocomposites.     

Accelerating photocatalytic hydrogen evolution and pollutant degradation by coupling organic co-catalysts with TiO2

Accelerating the separation efficiency of photoexcited electron-hole pairs with the help of highly active co-catalysts has proven to be a promising approach for improving photocatalytic activity. Thus far, the most developed co-catalysts for semiconductor-based photocatalysis are inorganic materials; the employment of a specific organic molecule as a co-catalyst for photocatalytic hydrogen evolution and pollutant photodegradation is rare and still remains a challenging task. Herein, we report on the use of an organic molecule, oxamide (OA), as a novel co-catalyst to enhance electron-hole separation, photocatalytic H₂ evolution, and dye degradation over TiO₂ nanosheets. OA-modified TiO₂ samples were prepared by a wet chemical route and demonstrated improved light absorption in the visible-light region and more efficient charge transport. The photocatalytic performance of H₂ evolution from water splitting and rhodamine B (RhB) degradation for an optimal OA-modified TiO₂ photocatalyst reached 2.37 mmol g^-1 h^-1 and 1.43 × 10^?2 min^?1, respectively, which were 2.4 and 3.8 times higher than those of pristine TiO₂, respectively. A possible mechanism is proposed, in which the specific π-conjugated structure of OA is suggested to play a key role in the enhancement of the charge transfer and catalytic capability of TiO₂. This work may provide advanced insight into the development of a variety of metal-free organic molecules as functional co-catalysts for improved solar-to-fuel conversion and environmental remediation.     

Engineering heterostructure and crystallinity of Ru/RuS2 nanoparticle composited with N-doped graphene as electrocatalysts for alkaline hydrogen evolution

Crystalline engineering and heterostructure have attracted much attention as effective strategies to improve the electrocatalytic activity for hydrogen evolution reaction (HER). In this study, a new heterostructure catalyst (Ru/RuS₂@N-rGO) with low crystallinity was fabricated by a simple and low-temperature method for HER in alkaline solution, applying the Na₂SO₄ as S source and polypyrrole as N source. Optimizing through the controllable crystalline engineering and composition ratio of Ru and RuS₂, the Ru/RuS₂@N-rGO heterocatalyst at the calcining 500 °C revealed highly efficient HER activity with overpotential 18 mV at a current density 10 mA/cm² and remarkable stability for 24 h in 1.0 mol/L KOH. This work provides a facile and effective method in designing advanced electrocatalysts for HER in the alkaline electrolytes by synergistically structural and component modulations.     

高效稳定的Al~(3+)偶联多层Eosin Y敏化TiO_2光催化制氢体系研究

通过Al3+偶联制备了多层EosinY敏化的TiO2催化剂,其光催化制氢性能优于Fe3+偶联的催化剂.在水体系、甲醇-水体系中,以三乙醇胺(TEOA)作电子给体,采用原位载Pt,考察了催化剂在可见光(λ420nm)下的制氢活性与稳定性.结果表明,含水0.5%(体积分数)的体系、载铂量为1.0%时,显示了较高的活性和良好的稳定性,20h的平均量子效率为20.5%,转换数为220.较高的活性和稳定性初步归结于Al3+水解趋势较Fe3+小,且催化剂在甲醇中比在水中更稳定,进一步的研究正在进行中.     

Dispersion of graphene oxide and its flame retardancy effect on epoxy nanocomposites

Graphene oxide was prepared by ultrasonication of completely oxidized graphite and used to improve the flame retardancy of epoxy.The epoxy/graphene oxide nanocomposite was studied in terms of exfoliation/dispersion,thermal stability and flame retardancy.X-ray diffraction and transmission electron microscopy confirmed the exfoliation of the graphene oxide nanosheets in epoxy matrix.Cone calorimeter measurements showed that the time to ignition of the epoxy/graphene oxide nanocomposite was longer than that of neat epoxy.The heat release rate curve of the nanocomposite was broadened compared to that of neat epoxy and the peak heat release rate decreased as well.     

One-step synthesis of monodispersed Pt nanoparticles anchored on 3D graphene foams and its application for electrocatalytic hydrogen evolution

Although platinum-based materials are regarded as the state-of-the-art electro-catalysts for hydrogen evolution reaction(HER),high cost and quantity scarcity hamper their scale-up utilization in industrial deployment.Herein,a one-step strategy was developed to synthesize multi-walled carbon nanotubes and reduced graphene oxide supported Pt nanoparticle hydrogel(PtNP/rGO-MWCNT),in which only ascorbic acid was used as the reductant for one-pot reduction of both GO and chloroplatinic acid.The hydrogel can be directly used as a flexible binder-free catalytic electrode to achieve high performance of HER.Compared to conventional strategies,the current strategy not only significantly reduces the Pt loading to 3.48 wt%,simplifies the synthesis process,but also eliminates the use of any polymer binders,thus decreasing the series resistance and improving catalytic activity.An overpotential of only 11 mV was achieved on as-prepared PtNP/rGO-MWCNT to drive a geometrical current density of 10 mA/cm2 in0.5 mol/L H2 SO4,with its catalytic activity being kept over 15 h.In acidic medium,the HER activity of the PtNP/rGO-MWCNT catalyst exceeds most of the reported Pt-based electro-catalysts and is 3-fold higher than that obtained on commercial Pt/C electrode.     

Pt deposited TiO2 catalyst fabricated by thermal decomposition of titanium complex for solar hydrogen production

C, N codoped TiO₂ catalyst has been synthesized by thermal decomposition of a novel water-soluble titanium complex. The structure, morphology, and optical properties of the synthesized TiO₂ catalyst were characterized by X-ray diffraction, scanning electron microscopy, X-ray photoelectron spectroscopy, and UV–vis diffuse reflectance spectroscopy. The photocatalytic activity of the Pt deposited TiO₂ catalysts synthesized at different temperatures was evaluated by means of hydrogen evolution reaction under both UV–vis and visible light irradiation. The investigation results reveal that the photocatalytic H₂ evolution rate strongly depended on the crystalline grain size as well as specific surface area of the synthesized catalyst. Our studies successfully demonstrate a simple method for the synthesis of visible-light responsive Pt deposited TiO₂ catalyst for solar hydrogen production.     

{111}晶面暴露对介孔金红石TiO2单晶光催化产氢的促进作用

光催化反应发生在半导体材料的表面,材料表面的原子/电子结构直接影响光催化剂的活性或选择性。因此,发展具有特定晶面的半导体光催化剂受到各国学者的普遍关注,被认为是调控光催化材料性能的有效途径之一。自2008年yang等首次合成高表面能{001}晶面占优的锐钛矿TiO2单晶以来,控制合成暴露不同晶面TiO2晶体的研究得到了迅猛的发展,已发展了多种方法合成了具有不同晶面的TiO2晶体。研究表明,选择性地暴露特定的活性晶面能够显著地提高光催化剂的活性或者改变光催化反应的选择性。但是,含有完整晶面构型的TiO2单晶样品的颗粒尺寸一般都较大,通常为几微米,因而显著增加了光生载流子传输与分离的难度,并且导致材料较小的比表面积,限制了对光催化活性的进一步提高。能否在合成含特定晶面单晶的同时增加多孔结构成为有效解决这一问题的关键。最近, Crossland等采用晶种模板法成功合成了介孔的锐钛矿TiO2单晶,并且通过光电器件研究证实了采用该思路可进一步提高材料的光电性能。金红石TiO2在光催化全分解水方面具有独特的优势,然而关于多孔单晶金红石TiO2的研究相对较少,尤其是合成热力学不稳定的高表面能{111}晶面完全暴露的多孔金红石单晶面临较大的技术挑战因而一直未见文献报道。本文利用晶种模板法,以TiCl4溶液为含Ti前驱体、NaF为形貌控制剂、采用水热处理制备出不同比例{111}晶面的介孔金红石单晶。我们前期工作表明, NaF可作为形貌控制剂合成低表面能{110)晶面占优的介孔金红石单晶。本文发现,通过改变NaF的添加量,可有效调变{111}/{110}晶面比例,最终合成完全暴露{111}高表面能的介孔金红石TiO2单晶。扫描电镜结果显示,当添加20 mg NaF时,合成{110}占优的具有高长径比的介孔晶体;当NaF用量增加到40 mg时{110}晶面进一步缩短;至80 mg时则制备出{111})高能面完全暴露的金红石TiO2晶体。值得注意的是,对比研究表明,不采用模板合成了与多孔晶体完全相对应的不同{111}/(110}晶面比例的实心金红石晶体。透射电镜及选区电子衍射以及结合X射线衍射进一步证实,多孔的金红石TiO2晶体与实心金红石单晶均都为单晶结构,孔结构贯穿于样品内部且具有较高的晶面结晶性。氮气吸附实验发现,虽然三个不同晶面比例介孔金红石单晶样品间的形貌具有显著的差异,但比表面积非常相近(分别为24,25,28 m2/g),孔径也都为50 nm左右,该值与所用SiO2模板球的直径以及TEM观察结果相一致。光催化产氢性能结果表明,选择性的暴露活性晶面显著提高了光催化活性,仅含高能面{111}的介孔金红石单晶样品具有最高的产氢速率(约800μmol h–1 g–1),比常规{110}晶面占优的介孔单晶样品速率提高了约一倍。尤其比实心单晶样品的产氢速率提高了至少一个数量级,这应归结于介孔结构特性所导致的表面反应活性位增加、电子传输距离缩短以及光吸收增强协同作用的结果。     

Ultrafine molybdenum carbide nanoparticles supported on nitrogen doped carbon nanosheets for hydrogen evolution reaction

Nitrogen doped carbon nanosheets supported molybdenum carbides nanoparticles (Mo_xC/NCS) have been synthesized by tuning the mass ratio of melamine and ammonia molybdate. The Mo₂C/NCS-10 exhibits superior electrocatalytic performance and stability for HER, which was attributed to N-doped carbon nanosheets, small particle size, mesoporous structure, and large electrochemical active surface area.     

Steering spatially separated dual sites on nano-TiO2 through SMSI and lattice matching for robust photocatalytic hydrogen evolution

Spatial isolation of different functional sites at the nanoscale in multifunctional catalysts for steering reaction sequence and paths remains a major challenge. Herein, we reported the spatial separation of dual-site Au and RuO₂ on the nanosurface of TiO₂ (Au/TiO₂/RuO₂) through the strong metal-support interaction (SMSI) and the lattice matching (LM) for robust photocatalytic hydrogen evolution. The SMSI between Au and TiO₂ induced the encapsulation of Au nanoparticles by an impermeable TiO_x overlayer, which can function as a physical separation barrier to the permeation of the second precursor. The LM between RuO₂ and rutile-TiO₂ can increase the stability of RuO₂/TiO₂ interface and thus prevent the aggregation of dual-site Au and RuO₂ in the calcination process of removing TiO_x overlayer of Au. The photocatalytic hydrogen production is used as a model reaction to evaluate the performance of spatially separated dual-site Au/TiO₂/RuO₂ catalysts. The rate of hydrogen production of the Au/TiO₂/RuO₂ is as high as 84 μmol h⁻¹ g⁻¹ under solar light irradiation without sacrificial agents, which is 2.5 times higher than the reference Au/TiO₂ and non-separated Au/RuO₂/TiO₂ samples. Systematic characterizations verify that the spatially separated dual-site Au and RuO₂ on the nanosurface of TiO₂ can effectively separate the photo-generated carriers and lower the height of the Schottky barrier, respectively, under UV and visible light irradiation. This study provides new inspiration for the precise construction of different sites in multifunctional catalysts.     

一种将三价钛引入锐钛型二氧化钛的新方法:用于有效的光催化产氢（英文）

伴随着科技的日益进步,人们的生活水平有了极大的提升,但是随之而来的环境污染问题也成为当前世界亟待解决的重大问题之一.太阳能是地球上最大的清洁能源来源,有效地利用太阳能将为解决环境污染问题提供巨大的帮助.而光催化技术的一个关键材料就是催化剂,催化剂对太阳能利用的好坏也就决定了光催化技术的应用前景.因此,人们对催化剂的研究也在逐步深入.1972年,Fuiishima和Honda在Nature杂志上首次报道了二氧化钛电极在紫外光照射下分解水产生氢气的现象,自此掀起了半导体光催化的研究热潮.二氧化钛因具有无毒、廉价和耐腐蚀等优点而在光催化领域广受关注.传统白色二氧化钛具有两大劣势(宽的禁带宽度与高的电子/空穴复合率)大大限制了它的应用.人们对于改变二氧化钛性质进行了大量的尝试,例如金属/非金属掺杂、形貌的改变等.黑色二氧化钛(存在大量的氧空位和三价钛)的出现极大地克服了传统白色二氧化钛的缺点,其具有窄的禁带宽度和低的电子/空穴复合速度.目前,黑色二氧化钛的制备方法大致分为以下几种:(1)高压下氢化;(2)高温常压下氢化;(3)铝热还原法;(4)溶液蒸发法;(5)化学氧化法;(6)电化学还原等.由于更简单安全(不涉及氢气使用)和更好的可见光光催化活性,三价钛自掺杂的二氧化钛从这些方法中脱颖而出.迄今为止,诱导三价钛的方法通常是能量密集型的,涉及不稳定的Ti原料(如TiO和TiH_2).研究用于制备三价钛自掺杂二氧化钛的新方法是十分必要的.我们以稳定的钛粉为原料,通过简单的方法将三价钛和氧空位成功地引入锐钛型二氧化钛.通过X射线衍射、场致发射扫描电子显微镜等技术研究了制备样品的物理化学性质,发现H_2O_2和水热反应时间对纳米棒型微观形貌的形成至关重要.通过调整诸如H_2O_2量和水热反应时间的参数,根据实验结果提出了形成这种微观结构的可能机制.更重要的是,可见光区域的光吸收受到样品中氧空位量的控制,存在氧空位的最佳值使光催化产氢活性最高.     

石墨烯修饰三氧化钨/二氧化钛S型异质结增强的光催化产氢活性（英文）

太阳光驱动的光催化分解水产氢是利用太阳能解决当前能源危机和环境问题的理想策略.二氧化钛由于其稳定、环境友好和成本低等优点受到广泛研究,在光催化领域具有不可或缺的作用.然而,纯二氧化钛光催化剂具有光生电子-空穴复合率高、太阳能利用率低等缺点,使其在光催化产氢领域的应用受到限制.迄今为止,人们探索了多种改性策略来提高二氧化钛的光催化活性,如贵金属负载、金属或非金属元素掺杂、构建异质结等.通过复合两个具有合适能带排布的半导体来构建异质结可以大大提高光生载流子的分离,被认为是一种有效的解决方案.最近提出了一种新的S型异质结概念,以解释不同半导体异质界面载流子转移分离的问题.S型异质结是在传统Ⅱ型和Z型(液相Z型、全固态Z型、间接Z型、直接Z型)基础上提出的,但又扬长避短,优于传统Ⅱ型和Z型.通常,S型异质结是由功函数较小、费米能级较高的还原型半导体光催化剂和功函数较大、费米能级较低的氧化型半导体光催化剂构建而成.三氧化钨禁带宽度较小(2.4-2.8 eV),功函数较大,是典型的氧化型光催化剂,也是构建S型异质结的理想半导体光催化剂.根据S型电荷转移机制,三氧化钨/二氧化钛复合物在光辐照下,三氧化钨导带上相对无用的电子与二氧化钛价带上相对无用的空穴复合,二氧化钛导带上还原能力较强的电子和三氧化钨价带上氧化能力较强的空穴得以保留,从而在异质界面上实现了氧化还原能力较强的光生电子-空穴对的分离.同时,石墨烯作为一种蜂窝状碳原子二维材料,是理想的电子受体,在异质结光催化剂中能及时转移电子.而且,石墨烯具有较好的导热性和电子迁移率,光吸收强,比表面积大,可为光催化反应提供丰富的吸附和活性位点,已经被认为是一种重要催化剂载体和光电分解水产氢的有效共催化剂.本文采用简便的一步水热法制备石墨烯修饰的三氧化钨/二氧化钛S型异质结光催化剂.光催化产氢性能测试表明,三氧化钨/二氧化钛/石墨烯复合材料的光催化产氢速率显著提高(245.8μmol g^-1 h^-1),约为纯TiO2的3.5倍.高分辨透射电子显微镜、拉曼光谱和X射线光电子能谱结果证明了TiO2和WO3纳米颗粒的紧密接触,并成功负载在还原氧化石墨烯(rGO)上.X射线光电子能谱中Ti 2p结合能的增加证实TiO2和WO3之间强的相互作用和S型异质结的形成.此外,复合材料中的rGO大大拓展了复合物的光吸收范围(紫外-可见漫反射光谱),增强了光热转换效应,而且rGO与TiO2之间形成肖特基结,促进了TiO2导带电子的转移和分离.总之,WO3和TiO2的S型异质结与TiO2和rGO之间的肖特基异质结的协同效应抑制了相对有用的电子和空穴的复合,有利于氧化还原能力较强的载流子的分离和进一步转移,加速了表面产氢动力学,于是增强了三元复合光催化剂的光催化产氢活性.     

Functional groups to modify g-C_3N_4 for improved photocatalytic activity of hydrogen evolution from water splitting

Rational modification by functional groups was regarded as one of efficient methods to improve the photocatalytic performance of graphitic carbon nitride(g-C_3 N_4).Herein,g-C_3 N_4 with yellow(Y-GCN) and brown(C-GCN) were prepared by using the fresh urea and the urea kept for five years,respectively,for the first time.Experimental results show that the H2 production rate of the C-GCN is 39.06 μmol/h,which is about 5 times of the Y-GCN.Meantime,in terms of apparent quantum efficiency(AQ.E) at 420 nm,C-GCN has a value of 6.3% and nearly 7.3 times higher than that of Y-GCN(0.86%).The results of XRD,IR,DRS,and NMR show,different from Y-GCN,a new kind of functional group of —N=CH— was firstly in-situ introduced into the C-GCN,resulting in good visible light absorption,and then markedly improving the photocatalytic performance.DFT calculation also confirms the effect of the —N=CH— group band structure of g-C_3N_4.Furthermore,XPS results demonstrate that the existence of —N=CH— groups in C-GCN results in tight interaction between C-GCN and Pt nanoparticles,and then improves the charge separation and photocatalytic performance.The present work demonstrates a good example of "defect engineering" to modify the intrinsic molecular structure of g-C_3N_4 and provides a new avenue to enhance the photocatalytic activity of g-C_3N_4 via facile and environmental-friendly method.     

A novel nonenzymatic biosensor for evaluation of oxidative stress based on nanocomposites of graphene blended with CuI

A high-sensitive nonenzymatic hydrogen peroxide (H₂O₂) biosensor based on cuprous iodide and graphene (CuI/Gr) composites has been explored for the detection of H₂O₂ released by living cells and monitoring the oxidative stress of cells under excellular stimulation. The biosensor properties were evaluated by cyclic voltammetry (CV), electrochemical impedance spectroscopy (EIS), amperometric i-t curve, and the redox-competition mode of scanning electrochemical microscopy (SECM). Our observations demonstrate that the CuI/Gr nanocomposites modified glassy carbon electrode (GCE) exhibits excellent catalytic activity for H₂O₂ with relatively low detection limit and a wide linear range from 0.5 μM to 3 mM. Moreover, the redox-competition mode of SECM imaging study further illustrates the improved electrochemical catalytic capability for H₂O₂ reduction with CuI/Gr nanocomposites deposited on graphite electrode. Hence, the as-prepared nonenzymatic H₂O₂ biosensor could be used to detect H₂O₂ release from different kinds of living cells under stimulation while eliminating the interference of ascorbic acid.     

Impact of graphene on the enhancement of electrochemical and photocatalytic performance of Gd2O3 - Graphene nanocomposites

Gadolinium oxide - Graphene (Gd₂O₃-G) nanocomposites were prepared with different weight ratio of graphene using low temperature solution process. The structural, morphological, electrochemical and photocatalytic properties of the composites were investigated by X-ray diffraction, Raman, FE-SEM, HRTEM, Cyclic voltammetric and photo-degradation analysis. The chemical composition of the composites was studied by elemental mapping analysis using EPMA. The binding states of various elements present in the composites were analyzed by XPS. Cyclic voltammetric studies revealed that the nanocomposite with 5% graphene exhibits the specific capacitance of 26 F g⁻¹, which is higher than that of pure Gd₂O₃ (18 F g⁻¹). The presence of graphene has greatly enhanced the photocatalytic performance of Gd₂O₃G composites as the rate of degradation of MB dye is relatively higher in the composites compared to pure Gd₂O₃. The significant increase in the specific capacitance and rate of degradation of dye suggest that the Gd₂O₃G is a promising material for energy storage and environmental applications.     

Cr2O3/C@TiO2核壳型复合材料的设计合成及其光催化产氢性能

随着社会经济的快速发展,能源危机和环境污染问题成为世界各国关注的焦点.通过光催化剂将太阳能用于污染物降解、分解水产氢、CO2还原及有机物合成等领域,是解决上述问题的理想途径.过渡金属氧化物TiO2因其稳定性高、催化活性好、制备简单等优点,被认为是最理想的光催化材料.然而,TiO2带隙较宽、光响应范围窄、光量子效率低等缺点限制了其实际应用.将碳或Cr2O3与TiO2结合形成复合结构已被证明可以有效提升其光催化性能.另一方面,金属离子的掺杂可以有效提高氧化钛的可见光响应.本文利用具有高比表面积的金属有机骨架材料MIL-101(Cr)纳米材料作为模板、镉源和碳源,首先在MIL-101(Cr)表面可控生长TiO2纳米颗粒,获得MIL-101(Cr)@TiO2复合结构;然后在氮气保护下碳化形成Cr2O3/C@TiO2核壳型复合材料.碳化后,制备的复合材料具有模板的八面体形貌和高比表面积,MIL-101(Cr)中的Cr元素一部分会形成Cr2O3,一部分会掺杂到TiO2中,使得TiO2的吸收边红移.此外,Cr2O3/C@TiO2中的C有利于光的吸收和载流子的分离.这种独特的纳米结构赋予Cr2O3/C@TiO2复合材料优异的光催化性能.在300 W氙灯照射下,该复合材料光解水产氢的速率为446μmol h?1 g?1,约为纯TiO2的4倍.在可见光照射下,Cr2O3/C@TiO2分解水产氢的速率为25.5μmol h?1 g?1.将获得的粉体催化剂制备成光电极发现,Cr2O3/C@TiO2在全幅光照射下的光电流密度在0.4 V(vs.Ag/AgCl)下达到2.3 mA/cm2,约为纯TiO2的3.5倍.Cr2O3/C@TiO2光催化产氢活性的提高一方面是由于Cr掺杂到TiO2中使得其具有可见光响应,另一方面MIL-101碳化获得的Cr2O3/C有效促进了光生载流子的分离.