Vacancy engineering mediated hollow structured ZnO/ZnS S-scheme heterojunction for highly efficient photocatalytic H_(2) production

Designing a step-scheme(S-scheme)heterojunction photocatalyst with vacancy engineering is a reliable approach to achieve highly efficient photocatalytic H_(2)production activity.Herein,a hollow ZnO/ZnS S-scheme heterojunction with O and Zn vacancies(VO,Zn-ZnO/ZnS)is rationally constructed via ion-exchange and calcination treatments.In such a photocatalytic system,the hollow structure combined with the introduction of dual vacancies endows the adequate light absorption.Moreover,the O and Zn vacancies serve as the trapping sites for photo-induced electrons and holes,respectively,which are beneficial for promoting the photo-induced carrier separation.Meanwhile,the S-scheme charge transfer mechanism can not only improve the separation and transfer efficiencies of photo-induced carrier but also retain the strong redox capacity.As expected,the optimized VO,Zn-ZnO/ZnS heterojunction exhibits a superior photocatalytic H_(2) production rate of 160.91 mmol g^(-1)h^(-1),approximately 643.6 times and 214.5 times with respect to that obtained on pure ZnO and ZnS,respectively.Simultaneously,the experimental results and density functional theory calculations disclose that the photo-induced carrier transfer pathway follows the S-scheme heterojunction mechanism and the introduction of O and Zn vacancies reduces the surface reaction barrier.This work provides an innovative strategy of vacancy engineering in S-scheme heterojunction for solar-to-fuel energy conversion.

Investigating the charge transfer mechanism of ZnSe QD/COF S-scheme photocatalyst for H_(2)O_(2) production by using femtosecond transient absorption spectroscopy

Hydrogen peroxide(H_(2)O_(2))has gained widespread attention as a versatile oxidant and a mild disin-fectant.Here,an electrostatic self-assembly method is applied to couple ZnSe quantum dots(QDs)with a flower-like covalent organic framework(COF)to form a step-scheme(S-scheme)photocata-lyst for H_(2)O_(2)production.The as-prepared S-scheme photocatalyst exhibits a broad light absorption range with an edge at 810 nm owing to the synergistic effect between the ZnSe QDs and COF.The S-scheme charge-carrier transfer mechanism is validated by performing Fermi level calculations and in-situ X-ray photoelectron and femtosecond transient absorption spectroscopies.Photolumi-nescence,time-resolved photoluminescence,photocurrent response,electrochemical impedance spectroscopy,and electron paramagnetic resonance results show that the S-scheme heterojunction not only promotes charge carrier separation but also boosts the redox ability,resulting in enhanced photocatalytic performance.Remarkably,a 10%-ZnSe QD/COF has excellent photocatalytic H_(2)O_(2)-production activity,and the optimal S-scheme composite with ethanol as the hole scavenger yields a H_(2)O_(2)-production rate of 1895 mol g^(-1)h^(-1).This study presents an example of a high-performance organic/inorganic S-scheme photocatalyst for H_(2)O_(2)production.

Self-assembled S-scheme In_(2.77)S_(4)/K^(+)-doped g-C_(3)N_(4)photocatalyst with selective O_(2) reduction pathway for efficient H_(2)O_(2) production using water and air

The development of an efficient artificial H_(2)O_(2) photosynthesis system is a challenging work using H_(2)O and O_(2) as starting materials.Herein,3D In_(2.77)S_(4) nanoflower precursor was in-situ deposited on K^(+)-doped g-C_(3)N_(4)(KCN)nanosheets using a solvothermal method,then In_(2.77)S_(4)/KCN(IS/KCN)het-erojunction with an intimate interface was obtained after a calcination process.The investigation shows that the photocatalytic H_(2)O_(2) production rate of 50IS/KCN can reach up to 1.36 mmol g^(-1)h^(-1)without any sacrificial reagents under visible light irradiation,which is 9.2 times and 4.1 times higher than that of KCN and In_(2.77)S_(4)/respectively.The enhanced activity of the above composite can be mainly attributed to the S-scheme charge transfer route between KCN and In_(2.77)S_(4) according to density functional theory calculations,electron paramagnetic resonance and free radical capture tests,leading to an expanded light response range and rapid charge separation at their interface,as well as preserving the active electrons and holes for H_(2)O_(2) production.Besides,the unique 3D nanostructure and surface hydrophobicity of IS/KCN facilitate the diffusion and transportation of O_(2) around the active centers,the energy barriers of O_(2) protonation and H_(2)O_(2) desorption steps are ef-fectively reduced over the composite.In addition,this system also exhibits excellent light harvesting ability and stability.This work provides a potential strategy to explore a sustainable H_(2)O_(2) photo-synthesis pathway through the design of heterojunctions with intimate interfaces and desired reac-tion thermodynamics and kinetics.

Constructing interfacial electric field and Zn vacancy modulated ohmic junctions ZnS/NiS for photocatalytic H_(2) evolution

Adjusting the interfacial transport efficiency of photogenerated electrons and the free energy of hydrogen adsorption through interface engineering is an effective means of improving the photocatalytic activity of semiconductor photocatalysts.Herein,hollow ZnS/NiS nanocages with ohmic contacts containing Zn vacancy(V_(Zn)-ZnS/NiS)are synthesized using ZIF-8 as templates.An internal electric field is constructed by Fermi level flattening to form ohmic contacts,which increase donor density and accelerate electron transport at the V_(Zn)-ZnS/NiS interface.The experimental and DFT results show that the tight interface and V_(Zn) can rearrange electrons,resulting in a higher charge density at the interface,and optimizing the Gibbs free energy of hydrogen adsorption.The optimal hydrogen production activity of V_(Zn)-ZnS/NiS is 10,636 mmol h^(-1) g^(-1),which is 31.9 times that of V_(Zn)-ZnS.This study provides an idea for constructing sulfide heterojunctions with ohmic contacts and defects to achieve efficient photocatalytic hydrogen production.

Step-scheme ZnO@ZnS hollow microspheres for improved photocatalytic H_(2) production performance

Constructing a step-scheme heterojunction at the interface between two semiconductors is an efficient way to optimize the redox ability and accelerate the charge carrier separation of a photocatalytic system for achieving high photocatalytic performance.In this study,we prepared a hierarchical ZnO@ZnS step-scheme photocatalyst by incorporating ZnS into the outer shell of hollow ZnO microspheres via a simple in situ sulfidation strategy.The ZnO@ZnS step-scheme photocatalysts had a large surface area,high light utilization capacity,and superior separation efficiency for photogenerated charge carriers.In addition,the material simulation revealed that the formation of the step-scheme heterojunction between ZnO and ZnS was due to the presence of the built-in electric field.Our study paves the way for design of high-performance photocatalysts for H_(2) production.

Hydrophilic bi-functional B-doped g-C_(3)N_(4) hierarchical architecture for excellent photocatalytic H_(2)O_(2) production and photoelectrochemical water splitting

Graphitic carbon nitride(g-C_(3)N_(4))has attracted great interest in photocatalysis and photoelectrocatalysis.However,their poor hydrophilicity poses a great challenge for their applications in aqueous environment.Here,we demonstrate synthesis of a hydrophilic bi-functional hierarchical architecture by the assembly of B-doped g-C_(3)N_(4)nanoplatelets.Such hierarchical B-doped g-C_(3)N_(4)material enables full utilization of their highly enhanced visible light absorption and photogenerated carrier separation in aqueous medium,leading to an excellent photocatalytic H_(2)O_(2)production rate of 4240.3μM g^(-1)h^(-1),2.84,2.64 and 2.13 times higher than that of the bulk g-C_(3)N_(4),g-C_(3)N_(4)nanoplatelets and bulk B doped g-C_(3)N_(4),respectively.Photoanodes based on these hierarchical architectures can generate an unprecedented photocurrent density of 1.72 m A cm^(-2)at 1.23 V under AM 1.5 G illumination for photoelectrochemical water splitting.This work makes a fundamental improvement towards large-scale exploitation of highly active,hydrophilic and stable metal-free g-C_(3)N_(4)photocatalysts for various practical applications.

High H_(2) selective performance of Ni-Fe-Ca/H-Al catalysts for steam reforming of biomass and plastic

The development of a selective catalyst for the conversion of biomass and plastics into H2by steam reforming can combat the energy crisis and global warming.In this work,support Ni-Fe-Ca/H-Al bifunctional catalysts were prepared by loading Ni and Fe into pretreatment CaO/Al_(2)O_(3)(Ca/H-Al)carriers and showed high catalytic activity for the steam reforming of biomass and plastic.Moreover,the idea of bidirectional degradation was exploited to strengthen the pyrolysis of plastic with a high H/C and biomass with a high O/C.Interestingly,the products presented high H2selective(1302.10 m L/g)and low CO_(2)yield(120.23 m L/g)in 7Ni-5Fe-Ca/H-Al(2:4)catalyst compared with current reports.Here,the abundant oxygen vacancies(Ov)in the H-Al carrier exhibited an electron-deficient nature,providing active sites for anchoring Ni O.Meanwhile,Ni O interacted with Ca_(2)Fe_(2)O_(5)to produce more defective Ovsites,which stabilized the NiO particles in the 7Ni-5Fe-Ca/H-Al(2:4)catalyst,and the interaction between the catalyst and the carrier was enhanced,leading to the reduction of weakly basic sites,this property promoted the strong adsorption of CO_(2)and H2O by the catalyst,contributing to the enhancement of efficient steam conversion and the promotion of conversion of by-products to H2.Notably,7Ni-5Fe-Ca/H-Al(2:4)catalysts maintained structural integrity after regeneration and exhibited excellent regenerability in H2selection and CO_(2)adsorption.The work provides a new idea for the study of efficient H2production from steam reforming of biomass and plastics.

Science Letters:Culture of Spirulina platensis in human urine for biomass production and O_2 evolution

Attempts were made to culture Spirulina platensis in human urine directly to achieve biomass production and O2 evolution, for potential application to nutrient regeneration and air revitalization in life support system. The culture results showed that Spirulinaplatensis grows successfully in diluted human urine, and yields maximal biomass at urine dilution ratios of 140-240. Accumulation of lipid and decreasing of protein occurred due to N deficiency. O2 release rate of Spirulina platensis in diluted human urine was higher than that in Zarrouk medium.

Dual-functional marigold-like Zn_(x)Cd_(1-x)S homojunction for selective glucose photoreforming with remarkable H_(2)coproduction

The global commitment to pivoting to sustainable energy and products calls for technology development to utilize solar energy for hydrogen(H_(2))and value-added chemicals production by biomass photoreforming.Herein,a novel dual-functional marigold-like Zn_(x)Cd_(1-x)S homojunction has been the production of lactic acid with high-yield and H_(2)with high-efficiency by selective glucose photoreforming.The optimized Zn_(0.3)Cd_(0.7)S exhibits outstanding H_(2)generation(13.64 mmol h^(-1)g^(-1)),glucose conversion(96.40%),and lactic acid yield(76.80%),over 272.80 and 19.21 times higher than that of bare ZnS(0.05 mmol h^(-1)g^(-1))and CdS(0.71 mmol h^(-1)g^(-1))in H_(2)generation,respectively.The marigold-like morphology provides abundant active sites and sufficient substrates accessibility for the photocatalyst,while the specific role of the homojunction formed by hexagonal wurtzite(WZ)and cubic zinc blende(ZB)in photoreforming biomass has been demonstrated by density functional theory(DFT)calculations.Glucose is converted to lactic acid on the WZ surface of Zn_(0.3)Cd_(0.7)S via the photoactive species·O_(2)^(-),while the H_(2)is evolved from protons(H^(+))in H_(2)O on the ZB surface of Zn_(0.3)Cd_(0.7)S.This work paves a promising road for the production of sustainable energy and products by integrating photocatalysis and biorefine.

“H_(2)-free” demethoxylation of guaiacol in subcritical water using Pt supported on N-doped carbon catalysts:A cost-effective strategy for biomass upgrading

"H_(2)-free" HDO is a revolutionary route to circumvent the limitations of H_(2)-fed HDO reactors for biomass upgrading.This work demonstrates the viability of this economically appealing route when an adequate catalyst is implemented.Herein,we have developed a new family of Pt catalysts supported on N-doped activated carbons for the H_(2)-free HDO process of guaiacol.Several N-donors have been used to tune the catalyst’s structural and electronic properties.As a general trend,the N-promoted samples are more selective towards oxygen-depleted products.The best performing material,namely Pt/PANI-AC reached outstanding guaiacol conversion values-ca.75% at 300℃ while displaying reasonable stability for multiple recycling operations.The advanced performance is ascribed to the modified electronic and acid-base properties which favor guaiacol activation and C-O cleavage,as well as the excellent dispersion of the Pt nano particles.

La_(1-x)Ce_(x)MnO_(3)-Ba/Al_(2)O_(3)催化剂对NO选择性生成NH_(3)的影响

为了实现碳中和目标,降低内燃机碳排放,稀薄燃烧技术成为了当前重要的研究方向.该技术不仅能提高发动机燃油热效率,还能有效降低CO_(2)排放.但是稀薄燃烧往往会伴随着大量氮氧化物的产生,为了解决该问题,采用LNT-SCR耦合的NO_(x)净化技术,此时LNT的作用是将排气中部分NO_(x)转化为NH_(3),为下游的SCR提供还原剂.基于此,制备了LNT催化剂,研究催化剂对NO选择性生成NH_(3)的影响.采用溶胶-凝胶法制备了La_(1-x)Ce_(x)MnO_(3)系列钙钛矿氧化物,并通过分步浸渍法得到了La_(1-x)Ce_(x)MnO_(3)-Ba/Al_(2)O_(3)负载型催化剂.利用XRD、H_(2)-TPR、NO-TPD等表征手段研究了钙钛矿氧化物的晶相结构,以及负载型催化剂的还原特性、NO_(x)吸附-脱附性能等物化性质,并且通过H_(2)选择性催化还原NO实验探究了催化剂掺杂Ce对NO转化成NH_(3)的影响.结果表明,Ce掺杂催化剂具有良好的NH_(3)产物选择性,并且显著提高了NO转化率.温度是NO转化和NH_(3)产物选择性生成的决定性因素,而H_(2)和NO体积比是NO转化和NH_(3)产物选择性生成的关键性因素.其中,La_(0.95)Ce_(0.05)MnO_(3)-Ba/Al_(2)O_(3)在低温下催化活性表现最佳,在350℃、H_(2)和NO体积比为5.0时NH_(3)产物选择性为65%,NO转化率为100%.此外,所制备的La_(1-x)Ce_(x)MnO_(3)都形成了钙钛矿型结构,而且Ce掺杂催化剂的大部分Ce离子可以进入到LaMnO_(3)结构中.在催化剂适量掺杂Ce后,H_(2)消耗总面积增大、还原峰的峰值温度降低,表明掺杂Ce改善了催化剂的还原特性;同时NO吸附和脱附面积增大,表明Ce掺杂改变了催化剂的NO_(x)吸附-脱附性能.

HA/H_(2)O_(2)体系对磺胺噻唑降解的机理与效能

以盐酸羟胺/过氧化氢(HA/H_(2)O_(2))作为研究体系,考察其对于磺胺噻唑(STZ)的降解效能。文章考察了HA初始浓度、H_(2)O_(2)初始浓度、STZ初始浓度、pH、天然有机物(NOM)、阴离子(SO_(4)^(2-)、Cl-和NO_(3)^(-))对STZ降解的影响。结果表明:在pH值=3.0的条件下,HA/H_(2)O_(2)体系对STZ具有高效的降解效果,当HA的物质的量浓度由2 mmol/L增加到10 mmol/L时,对STZ的去除率从56.06%增加到85.26%;当H_(2)O_(2)的物质的量浓度从2 mmol/L增加到10 mmol/L时,对STZ的去除率从58.96%增加到85.26%,当STZ的物质的量浓度从2μmol/L增加到10μmol/L时,对STZ的去除率从98.72%降低到71.86%。随着pH的增大,STZ的去除率逐渐降低,在pH值>7的条件下对STZ的去除率可以忽略不计。向反应体系中分别投加5 mmol/L的SO_(4)^(2-)和5 mmol/L的NO_(3)^(-)都可以有效促进STZ的降解,而5 mmol/L的Cl^(-)则会抑制STZ的降解。当向体系中投加小于5 mg/L的NOM则对STZ的降解的影响可以忽略不计。测定了体系中共有17种降解产物,并推测STZ通过取代反应、羟基化反应等方式逐步被降解。通过明亮发光杆菌发光值变化分析降解过程中溶液毒性的变化,测定发现STZ降解过程中急性毒性不高。实际水体试验结果表明,HA/H_(2)O_(2)系统对二级出水中的荧光类物质具有较好的降解效果。

H_(2)O及其中间体在缺电子Mn^((3+δ)+)位的自发增强吸附及其促进光催化产H_(2)O_(2)性能

过渡金属羟基氧化物已被证明是水氧化反应的可靠助催化剂。然而,在水氧化过程中它们对H_(2)O及其中间产物的吸附能力不足,极大制约了水氧化速率的提高。在本研究中,H_(2)O及其中间体在MnOOH助剂的缺电子Mn^((3+δ)+)上的自发增强吸附可以极大地促进水的快速氧化,从而在纯水体系中实现高效的光催化H_(2)O_(2)生成。首先,无定形MnOOH通过定向光诱导氧化方法选择性地沉积在AuPd改性的单晶BiVO_(4)光催化剂的(110)面上,从而制备了AuPd/BiVO_(4)/MnOOH光催化剂。光催化实验表明,所制备的AuPd/BiVO_(4)/MnOOH(0.5%)光催化剂的H_(2)O_(2)产生速率达到214μmol·L^(-1),并表现出良好的稳定性和重现性。密度泛函理论计算和X射线光电子能谱表征表明,MnOOH的自由电子可以有效地转移到BiVO_(4)上,诱导缺电子Mn位(Mn^((3+δ)+))的产生,从而自发地促进H_(2)O及其中间体的吸附,增强四电子WOR反应,导致H_(2)O_(2)的高效生成。本文关于助催化剂与主体催化剂之间强相互作用的工作为其它高效催化材料的合理设计提供了一种新的思路。

A review of recent researches on Bunsen reaction for hydrogen production via S–I water and H2S splitting cycles

The Bunsen reaction is the center reaction for both the sulfur–iodine water splitting cycle for hydrogen production and the novel hydrogen sulfide splitting cycle for hydrogen and sulfuric acid production from the sulfur-containing gases.This paper reviews the research progress of the Bunsen reaction in recent 10–15 years.Researches were initially focused on the optimization of the operating conditions of the conventional Bunsen reaction requiring excessive water and iodine to improve the products separation efficiency and to avoid the side reactions and iodine vapor deposition.Alternative methods including electrochemical methods,precipitation methods,and non-aqueous solvent methods had their respective advantages,but still faced challenges.In development of the technology of H2S splitting cycle,dissolving iodine in toluene solvent could render the Bunsen reaction to occur with the flowable I2 stream at ambient temperature such that the side reactions and iodine vaporization can be avoided and the corrosion hazard lessened.It also prevented the Bunsen reaction from using excessive iodine and water.The products from the Bunsen reaction including HI,H2SO4,H2O,and toluene could be directly electrolyzed.

Oxidation of emerging organic contaminants by in-situ H_(2)O_(2) fenton system

The existence and risk of emerging organic contaminants(EOCs)have been under consideration and paid much effort to degrade these pollutants.Fenton system is one of the most widely used technologies to solve this problem.The original Fenton system relies on the hydroxyl radicals produced by Fe(Ⅱ)/H_(2)O_(2) to oxidize the organic contaminants.However,the application of the Fenton system is limited by its low iron cycling efficiency and the high risks of hydrogen peroxide transportation and storage.The introduction of external energy(including light and electricity etc.)can effectively promote the Fe(Ⅲ)/Fe(Ⅱ)cycle and the reduction of oxygen to produce hydrogen peroxide in situ.This review introduces three in-situ Fenton systems,which are electro-Fenton,Photo-Fenton,and chemical reaction.The mechanism,influencing factors,and catalysts of these three in-situ Fenton systems in degrading EOCs are discussed systematically.This review strengthens the understanding of Fenton and in-situ Fenton systems in degradation,offering further insight into the real application of the in-situ Fenton system in the removal of EOCs.

Ti_(3)C_(2)/In_(4)SnS_(8)肖特基异质结用于高效光催化生成H_(2)O_(2)和Cr(Ⅵ)还原

人工光合成是一种先进的技术,主要利用太阳能作为唯一驱动能源,将水和氧气转化成双氧水(H_(2)O_(2))。然而,目前常用的光催化系统的性能受制于其光吸收能力有限,载流子分离效率低以及表面反应能力弱等问题。在本文研究中,通过采用原位水热法,成功地在少层Ti_(3)C_(2)纳米片表面生长厚度为5-10 nm的立方相In_(4)SnS_(8)纳米片(Eg=2.16 eV),形成了一种具有三明治结构的Ti_(3)C_(2)/In4SnS8纳米复合材料。深入的表征结果显示此2D/2D异质结构具有紧密的界面相互作用并且形成肖特基异质结,有助于载流子快速从In_(4)SnS_(8)转移至Ti_(3)C_(2)表面。其中,7 wt%Ti_(3)C_(2)/In_(4)SnS_(8)复合材料表现出最佳的可见光催化性能,H_(2)O_(2)生成速率为1.998µmol·L^(-1)·min·1,Cr(Ⅵ)的还原速率为19.8×10^(-3)min^(-1)。通过捕获实验、气氛实验和电子顺磁共振分析,证明了H_(2)O_(2)生成的途径包括两种:一种是两步单电子还原路径,另一种是一步两电子水氧化路径。本研究为设计高效、多功能的催化体系提供了一种新的思路。

UV/H_(2)O_(2)和UV/PDS体系对磷霉素降解效果的对比

紫外高级氧化技术降解有机污染物,由于操作简单、成本低、不易产生二次污染等优点被广泛应用。文章以磷霉素钠作为污染物,研究了UV/H_(2)O_(2)和UV/过硫酸盐(PDS)两种高级氧化技术对有机磷的降解特性,并对比了两种体系下有机磷的降解动力学和反应机理。试验结果表明,在UV/H_(2)O_(2)和UV/PDS体系中,UV激活氧化剂产生的活性基团可有效降解有机磷,有机磷降解率分别为97.3%和95.0%,初始pH、氧化剂投加量、反应温度均会对有机磷降解产生影响,相比于UV/H_(2)O_(2)体系,UV/PDS体系在降解有机磷时,具有pH适用范围较宽、反应温度低、氧化剂投加量小、反应速率快的优势。在最优条件下,两种体系都具有环境适应性。通过自由基捕获试验与电子顺磁共振技术(EPR)可知,UV/H_(2)O_(2)体系中存在·OH,UV/PDS体系中存在SO_(4)^(·-)和·OH。通过气-质联用(CG/MS)技术,测得两种体系降解磷霉素钠后均含有乙酸和丙酸。

基于氧同位素示踪技术的H_(2)O对SF_(6)电弧放电分解产物的影响研究

SF_(6)分解产物与SF_(6)开关设备故障放电类型和严重程度存在内在联系,可通过分解产物分析实现对开关设备的故障诊断。H_(2)O对SF_(6)电弧放电分解产物具有显著影响,但其影响规律及相关作用机制目前尚不清楚,严重制约了分解产物分析法的工程应用。为解决这一问题,文中搭建了SF_(6)开关设备电弧放电分解产物实验研究平台,利用H_(2)^(18)O作为示踪剂开展了电弧放电实验,利用气相色谱质谱联用仪分析了放电过程中和放电后含^(18)O同位素物质的变化规律,明确了电弧放电下SF_(6)分解产物的形成途径及H_(2)O对SF_(6)分解产物的影响,阐明了其深层化学反应机理。研究发现,H_(2)O会直接参与SOF_(2)、SO_(2)、SO_(2)F_(2)和CO_(2)的生成反应,化学反应机理的不同导致各物质的形成与演化规律具有显著差异。其中,SOF_(2)和SO_(2)F_(2)的生成主要由放电过程中发生的分解反应和复合反应主导,SO_(2)的生成主要由放电后发生的分子间反应主导,CO_(2)的生成则来自两者的共同作用。

X52钢在含H_(2)S水溶液中的腐蚀规律研究

本试验采用高压反应釜对X52钢在不同条件下(温度、H_(2)S浓度、NaCl浓度、介质流速)的H_(2)S腐蚀行为进行了研究,并对试样腐蚀速率和表面腐蚀产物形貌进行评价分析。试验结果表明:(1)当温度低于60℃时,腐蚀速率随着温度升高而增大;温度高于60℃时,随着温度升高腐蚀速率减小,试样表面转化为保护性好、附着力强、致密的腐蚀产物膜;(2)H_(2)S浓度的增加对腐蚀速率无明显的影响;(3)腐蚀速率随着NaCl浓度升高而下降;(4)腐蚀速率随介质流速增大而增大。

温度对X65管线钢在含CO_(2)/H_(2)S油田模拟环境中腐蚀行为的影响

为了研究在含CO_(2)/H_(2)S环境中温度对X65管线钢腐蚀的影响,采用高温高压模拟集输管线工况环境进行腐蚀试验和电化学试验,并对X65管线钢在不同温度下的腐蚀行为进行分析。结果表明,随着温度的升高,均匀腐蚀速率呈现先增大后减小的趋势,温度达到80℃时,均匀腐蚀速率达到最大值,为0.4345 mm/a,此时试样表面腐蚀产物较为粗糙,生成腐蚀产物FeCO_(3)和FeS;随着温度的升高,X65管线钢腐蚀逐渐以H_(2)S腐蚀为主,腐蚀电流密度先增加后减小,与失重腐蚀试验结果相符,X65管线钢的容抗弧呈现一个时间常数且半径逐渐减小;在试验温度下试样表面都有CaCO_(3)生成,这可能与溶液中的Ca^(2+)含量高相关。