Co-doped BaFe_(2)As_(2) Josephson junction fabricated with a focused helium ion beam

Josephson junction plays a key role not only in studying the basic physics of unconventional iron-based superconductors but also in realizing practical application of thin-film based devices,therefore the preparation of high-quality iron pnictide Josephson junctions is of great importance.In this work,we have successfully fabricated Josephson junctions from Co-doped BaFe_(2)As_(2)thin films using a direct junction fabrication technique which utilizes high energy focused helium ion beam(FHIB).The electrical transport properties were investigated for junctions fabricated with various He^(+)irradiation doses.The junctions show sharp superconducting transition around 24 K with a narrow transition width of 2.5 K,and a dose correlated foot-structure resistance which corresponds to the effective tuning of junction properties by He^(+)irradiation.Significant J_c suppression by more than two orders of magnitude can be achieved by increasing the He^(+)irradiation dose,which is advantageous for the realization of low noise ion pnictide thin film devices.Clear Shapiro steps are observed under 10 GHz microwave irradiation.The above results demonstrate the successful fabrication of high quality and controllable Co-doped BaFe_(2)As_(2)Josephson junction with high reproducibility using the FHIB technique,laying the foundation for future investigating the mechanism of iron-based superconductors,and also the further implementation in various superconducting electronic devices.

Memristive feature and mechanism induced by laser-doping in defect-free 2D semiconductor materials

Memristors as non-volatile memory devices have gained numerous attentions owing to their advantages in storage,in-memory computing, synaptic applications, etc. In recent years, two-dimensional(2D) materials with moderate defects have been discovered to exist memristive feature. However, it is very difficult to obtain moderate defect degree in 2D materials, and studied on modulation means and mechanism becomes urgent and essential. In this work, we realized memristive feature with a bipolar switching and a configurable on/off ratio in a two-terminal MoS_(2) device(on/off ratio ~100), for the first time, from absent to present using laser-modulation to few-layer defect-free MoS_(2)(about 10 layers), and its retention time in both high resistance state and low resistance state can reach 2×10^(4) s. The mechanism of the laser-induced memristive feature has been cleared by dynamic Monte Carlo simulations and first-principles calculations. Furthermore, we verified the universality of the laser-modulation by investigating other 2D materials of TMDs. Our work will open a route to modulate and optimize the performance of 2D semiconductor memristive devices.

Selective core-shell doping enabling high performance 4.6 V-LiCoO_(2)

Constructing robust surface and bulk structure is the prerequisite for realizing high performance high voltage LiCoO_(2)(LCO).Herein,we manage to synthesize a surface Mg-doping and bulk Al-doping coreshell structured LCO,which demonstrates excellent cycling performance.Half-cell shows 94.2%capacity retention after 100 cycles at 3.0-4.6 V(vs.Li/Li^(+))cycling,and no capacity decay after 300 cycles for fullcell test(3.0-4.55 V).Based on comprehensive microanalysis and theoretical calculations,the degradation mechanisms and doping effects are systematically revealed.For the undoped LCO,high voltage cycling induces severe interfacial and bulk degradations,where cracks,stripe defects,fatigue H2 phase,and spinel phase are identified in grain bulk.For the doped LCO,Mg-doped surface shell can suppress the interfacial degradations,which not only stabilizes the surface structure by forming a thin rock-salt layer but also significantly improves the electronic conductivity,thus enabling superior rate performance.Bulk Al-doping can suppress the lattice"breathing"effect and the detrimental H3 to H1-3 phase transition,which minimizes the internal strain and defects growth,maintaining the layered structure after prolonged cycling.Combining theoretical calculations,this work deepens our understanding of the doping effects of Mg and Al,which is valuable in guiding the future material design of high voltage LCO.

Unveiling the pressure-driven metal–semiconductor–metal transition in the doped TiS_(2)

Conventional theories expect that materials under pressure exhibit expanded valence and conduction bands,leading to increased electrical conductivity.Here,we report the electrical properties of the doped 1T-TiS_(2) under high pressure by electrical resistance investigations,synchrotron x-ray diffraction,Raman scattering and theoretical calculations.Up to 70 GPa,an unusual metal-semiconductor-metal transition occurs.Our first-principles calculations suggest that the observed anti-Wilson transition from metal to semiconductor at 17 GPa is due to the electron localization induced by the intercalated Ti atoms.This electron localization is attributed to the strengthened coupling between the doped Ti atoms and S atoms,and the Anderson localization arising from the disordered intercalation.At pressures exceeding 30.5 GPa,the doped TiS_(2) undergoes a re-metallization transition initiated by a crystal structure phase transition.We assign the most probable space group as P2_(1)2_(1)2_(1).Our findings suggest that materials probably will eventually undergo the Wilson transition when subjected to sufficient pressure.

Enhanced stability of FA-based perovskite:Rare-earth metal compound EuBr_(2) doping

It is highly desirable to enhance the long-term stability of perovskite solar cells(PSCs)so that this class of photovoltaic cells can be effectively used for the commercialization purposes.In this contribution,attempts have been made to use the two-step sequential method to dope EuBr_(2)into FAMAPbI_(3)perovskite to promote the stability.It is shown that the device durability at 85℃in air with RH of 20%-40%is improved substantially,and simultaneously the champion device efficiency of 23.04%is achieved.The enhancement in stability is attributed to two points:(ⅰ)EuBr_(2)doping effectively inhibits the decomposition andα-δphase transition of perovskite under ambient environment,and(ⅱ)EuBr_(2)aggregates in the oxidized format of Eu(BrO_(3))_(3)at perovskite grain boundaries and surface,hampering humidity erosion and mitigates degradation through coordination with H_(2)O.

Small but mighty:Empowering sodium/potassium-ion battery performance with S-doped SnO_(2) quantum dots embedded in N,S codoped carbon fiber network

SnO_(2) has been extensively investigated as an anode material for sodium-ion batteries(SIBs)and potassium-ion batteries(PIBs)due to its high Na/K storage capacity,high abundance,and low toxicity.However,the sluggish reaction kinetics,low electronic conductivity,and large volume changes during charge and discharge hinder the practical applications of SnO_(2)-based electrodes for SIBs and PIBs.Engineering rational structures with fast charge/ion transfer and robust stability is important to overcoming these challenges.Herein,S-doped SnO_(2)(S-SnO_(2))quantum dots(QDs)(≈3 nm)encapsulated in an N,S codoped carbon fiber networks(S-SnO_(2)-CFN)are rationally fabricated using a sequential freeze-drying,calcination,and S-doping strategy.Experimental analysis and density functional theory calculations reveal that the integration of S-SnO_(2) QDs with N,S codoped carbon fiber network remarkably decreases the adsorption energies of Na/K atoms in the interlayer of SnO_(2)-CFN,and the S doping can increase the conductivity of SnO_(2),thereby enhancing the ion transfer kinetics.The synergistic interaction between S-SnO_(2) QDs and N,S codoped carbon fiber network results in a composite with fast Na+/K+storage and extraordinary long-term cyclability.Specifically,the S-SnO_(2)-CFN delivers high rate capacities of 141.0 mAh g^(−1) at 20 A g^(−1) in SIBs and 102.8 mAh g^(−1) at 10 A g^(−1) in PIBs.Impressively,it delivers ultra-stable sodium storage up to 10,000 cycles at 5 A g^(−1) and potassium storage up to 5000 cycles at 2 A g^(−1).This study provides insights into constructing metal oxide-based carbon fiber network structures for high-performance electrochemical energy storage and conversion devices.

Nitrogen-doping boosts ^(*)CO utilization and H_(2)O activation on copper for improving CO_(2) reduction to C_(2+) products

To improve the electrocatalytic transformation of carbon dioxide (CO_(2)) to multi-carbon (C_(2+)) products is of great importance.Here we developed a nitrogen-doped Cu catalyst,by which the maximum C_(2+) Faradaic efficiency can reach 72.7%in flow-cell system,with the partial current density reaching 0.62 A cm^(-2).The in situ Raman spectra demonstrate that the *CO adsorption can be strengthened on such a N-doped Cu catalyst,thus promoting the *CO utilization in the subsequent C–C coupling step.Simultaneously,the water activation can be well enhanced by N doping on Cu catalyst.Owing to the synergistic effects,the selectivity and activity for C_(2+) products over the N-deoped Cu catalyst are much improved.

Homovalent doping:An efficient strategy of the enhanced TiNb_(2)O_(7)anode for lithium-ion batteries

The low energy density,unsatisfied cycling performance,potential safety issue and slow charging kinetics of the commercial lithium-ion batteries restrained their further application in the fields of fast charging and long-haul electric vehicles.Monoclinic TiNb_(2)O_(7)(TNO)with the theoretical capacity of 387 mAh g^(-1)has been proposed as a high-capacity anode materials to replace Li4Ti5O12.In this work,homovalent doping strategy was used to enhance the electrochemical performance of TiNb_(2)O_(7)(TNO)by employing Zr to partial substitute Ti through solvothermal method.The doping of Zr^(4+)ions can enlarge the lattice structure without changing the chemical valence of the original elements,refine and homogenize the grains,improve the electrical conductivity,and accelerate the ion diffusion kinetics,and finally enhance the cycle and rate performance.Specifically,Z0.05-TNO shows initial discharge capacity of as high as 312.2 mAh g^(-1)at 1 C and 244.8 mAh g^(-1)at 10 C,and still maintains a high specific capacity of 171.3 mAh g^(-1)after 800 cycles at 10 C.This study provides a new strategy for high-performance fast-charging energy storage electrodes.

Defect Engineering in Earth-Abundant Cu_(2)ZnSnSe_(4) Absorber Using Efficient Alkali Doping for Flexible and Tandem Solar Cell Applications

To demonstrate flexible and tandem device applications,a low-temperature Cu_(2)ZnSnSe_(4)(CZTSe)deposition process,combined with efficient alkali doping,was developed.First,high-quality CZTSe films were grown at 480℃by a single co-evaporation,which is applicable to polyimide(PI)substrate.Because of the alkali-free substrate,Na and K alkali doping were systematically studied and optimized to precisely control the alkali distribution in CZTSe.The bulk defect density was significantly reduced by suppression of deep acceptor states after the(NaF+KF)PDTs.Through the low-temperature deposition with(NaF+KF)PDTs,the CZTSe device on glass yields the best efficiency of 8.1%with an improved Voc deficit of 646 mV.The developed deposition technologies have been applied to PI.For the first time,we report the highest efficiency of 6.92%for flexible CZTSe solar cells on PI.Additionally,CZTSe devices were utilized as bottom cells to fabricate four-terminal CZTSe/perovskite tandem cells because of a low bandgap of CZTSe(~1.0 eV)so that the tandem cell yielded an efficiency of 20%.The obtained results show that CZTSe solar cells prepared by a low-temperature process with in-situ alkali doping can be utilized for flexible thin-film solar cells as well as tandem device applications.

Enhancing potassium-ion storage of Bi_(2)S_(3) through external–internal dual synergism: Ti_(3)C_(2)T_(x) compositing and Cu^(2+) doping

Potassium-ion batteries(PIBs)offer a cost-effective and resource-abundant solution for large-scale energy storage.However,the progress of PIBs is impeded by the lack of high-capacity,long-life,and fast-kinetics anode electrode materials.Here,we propose a dual synergic optimization strategy to enhance the K^(+)storage stability and reaction kinetics of Bi_(2)S_(3) through two-dimensional compositing and cation doping.Externally,Bi_(2)S_(3) nanoparticles are loaded onto the surface of three-dimensional interconnected Ti_(3)C_(2)T_(x) nanosheets to stabilize the electrode structure.Internally,Cu^(2+)doping acts as active sites to accelerate K^(+)storage kinetics.Various theoretical simulations and ex situ techniques are used to elucidate the external–internal dual synergism.During discharge,Ti_(3)C_(2)T_(x) and Cu^(2+)collaboratively facilitate K+intercalation.Subsequently,Cu^(2+)doping primarily promotes the fracture of Bi2S3 bonds,facilitating a conversion reaction.Throughout cycling,the Ti_(3)C_(2)T_(x) composite structure and Cu^(2+)doping sustain functionality.The resulting Cu^(2+)-doped Bi2S3 anchored on Ti_(3)C_(2)T_(x)(C-BT)shows excellent rate capability(600 mAh g^(-1) at 0.1 A g^(–1);105 mAh g^(-1) at 5.0 A g^(-1))and cycling performance(91 mAh g^(-1) at 5.0 A g^(-1) after 1000 cycles)in half cells and a high energy density(179 Wh kg–1)in full cells.

A cascade of in situ conversion of bicarbonate to CO_(2) and CO_(2) electroreduction in a flow cell with a Ni-N-S catalyst

Combination of CO_(2) capture using inorganic alkali with subsequently electrochemical conversion of the resultant HCO_(3)^(-)to high-value chemicals is a promising route of low cost and high efficiency.The electrochemical reduction of HCO_(3)^(-)is challenging due to the inaccessible of negatively charged molecular groups to the electrode surface.Herein,we adopt a comprehensive strategy to tackle this challenge,i.e.,cascade of in situ chemical conversion of HCO_(3)^(-)to CO_(2) and CO_(2) electrochemical reduction in a flow cell.With a tailored Ni-N-S single atom catalyst(SACs),where sulfur(S)atoms located in the second shell of Ni center,the CO_(2)electroreduction(CO_(2)ER)to CO is boosted.The experimental results and density functional theory(DFT)calculations reveal that the introduction of S increases the p electron density of N atoms near Ni atom,thereby stabilizing^(*)H over N and boosting the first proton coupled electron transfer process of CO_(2)ER,i.e.,^(*)+e^(-)+^(*)H+^(*)CO_(2)→^(*)COOH.As a result,the obtained catalyst exhibits a high faradaic efficiency(FE_(CO)~98%)and a low overpotential of 425 mV for CO production as well as a superior turnover frequency(TOF)of 47397 h^(-1),outcompeting most of the reported Ni SACs.More importantly,an extremely high FECOof 90%is achieved at 50 mA cm^(-2)in the designed membrane electrode assembly(MEA)cascade electrolyzer fed with liquid bicarbonate.This work not only highlights the significant role of the second coordination on the first coordination shell of the central metal for CO_(2)ER,but also provides an alternative and feasible strategy to realize the electrochemical conversion of HCO_(3)^(-)to high-value chemicals.

Al掺杂对SiO_(2)气凝胶耐高温特性的影响研究

SiO_(2)气凝胶具有成本低、制造工艺简单、化学性质稳定、密度小、超高比表面积等优点,是应用最广泛的高温保温隔热材料。以Si28和Si40为Si源,仲丁醇铝为Al源,乙醇为溶剂,采用酸碱催化、CO_(2)超临界干燥法制备了Al掺杂SiO_(2)气凝胶。结果表明:所得产品高温热处理后均为非晶态无定型结构,无掺杂SiO_(2)气凝胶线收缩率为24.34%,Al掺杂SiO_(2)气凝胶线收缩为14.05%,且在高温热处理后有较大的比表面积和孔体积,说明Al掺杂SiO_(2)气凝胶具有较好的耐高温性能和高温下的绝热性能,这是因为Al元素的掺入使气凝胶在形成过程中产生了很多细小的纳米空洞,热处理过程中Al-Si-O发生化学反应形成双金属氧化物,使气凝胶的氧化物骨架支撑力更强。

掺杂对2H-MoTe_(2)光电特性影响的第一性原理研究

MoTe_(2)是一种非空间反演对称性半导体,由线性偏振光照射,在无偏压条件下可以直接产生光电流,但是非常微弱.掺杂可以改变电子能带结构和降低空间反演对称性,从而有效的增强光电流.本文基于非平衡格林函数-密度泛函理论,采用第一性原理,计算了本征、Nb掺杂、Ti掺杂和W掺杂2H-MoTe_(2)的能带结构、透射谱和光电流.能带结构表明:Nb掺杂使半导体2H-MoTe_(2)能带穿越费米能级,转变为金属特性;Ti和W掺杂减小了2H-MoTe_(2)的带隙,能带没有穿越费米能级,依然为半导体.掺杂都降低2H-MoTe_(2)的反演对称对称性,从本征的D3h转变为Cs.从而在线偏振光的照射下可以有效的提高2H-MoTe_(2)的光电流.同时,发现掺杂可以提高单层2H-MoTe_(2)在低光子能量下的消光比,如Nb和Ti掺杂单层2H-MoTe_(2)分别在光子能量1.1 eV和1.2 eV处取得39.48和28.48的高消光比.这些结果表明掺杂可以有效增强单层2H-MoTe_(2)的光电流和消光比,可以应用于指导2H-MoTe_(2)在光电器件的设计,特别是在红外光探测领域增添了许多可能.

基于N掺杂Ti_(3)C_(2)MXene量子点的荧光探针用于Hg2+和S2-的传感检测

基于N掺杂Ti_(3)C_(2) MXene量子点(N-Ti_(3)C_(2) MQDs)荧光探针和配位相互作用,构建了一种检测Hg^(2+)和S^(2-)的“开-关-开”型荧光传感新方法.研究发现,制备的N-Ti_(3)C_(2) MQDs发射蓝色荧光(λem=440 nm),荧光量子产率为15.7%.Hg^(2+)与N-Ti_(3)C_(2) MQDs表面的—NH2,—COOH,—OH等官能团产生选择性配位作用,导致N-Ti_(3)C_(2) MQDs体系荧光猝灭.当加入S^(2-)后,由于S^(2-)与Hg^(2+)之间强的结合力,形成HgS沉淀,从而使N-Ti_(3)C_(2) MQDs体系荧光恢复.基于该原理,构建了一种“开-关-开”型荧光传感方法,实现了对Hg^(2+)和S^(2-)的定量检测.N-Ti_(3)C_(2) MQDs探针的荧光强度与Hg^(2+)浓度在0.02~200μmol/L范围内呈良好线性关系,检出限为10 nmol/L(S/N=3);与S^(2-)浓度在0.07~150μmol/L范围内呈良好线性关系,检出限为30 nmol/L(S/N=3).该方法具有成本低、操作简单、灵敏度高和选择性好等特点,并可用于水样中Hg^(2+)和S^(2-)的检测.

β-Ga_(2)O_(3)的p型掺杂研究进展

β-Ga_(2)O_(3)具有超宽禁带宽度、高击穿场强、较高的巴利加优值等优点使其成为一种新兴半导体材料,在高功率电子器件、气体传感器、日盲紫外探测器等方面有着极大的应用潜力,但p型掺杂难的问题成为了β-Ga_(2)O_(3)发展的巨大障碍。本文首先简要概述了β-Ga_(2)O_(3)的优点,并介绍了其晶体结构和基本性质。其次,说明了β-Ga_(2)O_(3)的本征缺陷,尤其是氧空位对导电性能的影响。然后,详细讨论了β-Ga_(2)O_(3) p型掺杂的研究现状,包括p型掺杂困难的原因和N掺杂、Mg掺杂、Zn掺杂、其他受主元素掺杂、两种元素共掺杂以及其他方法。最后,总结并对β-Ga_(2)O_(3)未来的发展进行了展望。

P掺杂β-FeSi_(2)材料的制备与热电输运性能

β-FeSi_(2)作为一种绿色环保、高温抗氧化的热电材料,在工业余热回收领域具有潜在的应用价值。虽然磷(P)是一种理想的β-FeSi_(2)硅(Si)位的n型掺杂元素,但是P掺杂β-FeSi_(2)易出现第二相,从而限制了其热电性能的提升。本研究采用感应熔炼法合成了一系列FeSi_(2)-xPx(x=0,0.02,0.04,0.06)样品,极大程度地避免了第二相的产生,并系统研究了P掺杂对β-FeSi_(2)热电输运性能的影响。结果表明,P在β-FeSi_(2)中的掺杂极限约为0.04,与前期的理论缺陷计算结果相符。此外,P掺杂优化了β-FeSi_(2)的热电性能,在850 K时,FeSi1.96P0.04的最高热电优值ZT约为0.12,远高于已有的研究结果(673 K,最高ZT仅为0.03)。然而,与同为n型Co和Ir掺杂的β-FeSi_(2)相比(其载流子浓度可达10^(22)cm^(-3)),P掺杂β-FeSi_(2)的载流子浓度较低,最高仅为10^(20)cm^(-3),这导致其电声散射效应较弱,从而限制了整体热电性能的提升。若能提高其载流子浓度,则热电性能有望得到进一步提升。

纳米Ce_(1-4x)(FeAlCoLa)_(x)O_(2-δ)固溶体微观光谱特征及氧化还原性能研究

采用水热法合成Fe^(3+)、Al^(3+)、Co^(2+)及La^(3+)共掺杂纳米Ce_(1-4x)(FeAlCoLa)_(x)O_(2-δ)(x=0.00~0.05)固溶体,利用X射线衍射(XRD)、透射电子显微镜(TEM)、扫描电子显微镜(SEM)、紫外吸收光谱(UV)、荧光光谱(PL)、拉曼光谱(Raman)以及与H2的程序升温还原反应(TPR)等方法对固溶体的微观结构、形貌、光谱特征和氧化还原活性进行系统表征及分析。XRD结果表明,Ce_(1-4x)(FeAlCoLa)_(x)O_(2-δ)固溶体均呈CeO_(2)立方萤石结构,当掺杂量增加到x=0.04时,在36.6°处出现了微弱的Co_(3)O_(4)杂相,可以确定掺杂离子在CeO_(2)晶格中的固溶度x<0.04。样品的(111)衍射峰位向高角度偏移,表明掺杂离子引起晶格发生畸变。TEM及SEM结果显示样品为球形纳米颗粒,掺杂离子引起晶面间距变小。紫外吸收光谱表明,与纯CeO_(2)相比,掺杂样品的吸收边逐渐红移,在560~780 nm范围观察到掺杂离子的紫外吸收峰。掺杂引起样品能隙降低,从2.84 eV(纯CeO_(2))逐渐降低至2.10 eV(x=0.05)。其原因可归结为掺杂离子在CeO_(2)的价带和导带之间形成新的杂质能级,允许电子从价带跃迁到较低的杂质能级上,继而降低了跃迁能隙。由于掺杂离子引起晶格内部发生畸变以及氧空位比例增大,阻碍了电子的高能跃迁,也可引起能隙减小。荧光光谱证明,掺杂样品的发射峰强度明显降低。Raman光谱表明,掺杂引起F_(2g)峰位发生偏移,峰强减小,峰宽变大。同时,对应于氧空位峰的相对强度逐渐提高。荧光光谱及Raman光谱均证明掺杂离子引起固溶体晶格畸变程度增加,氧空位浓度提高。H_(2)-TPR测试表明,掺杂可以有效降低CeO_(2)的氧化还原反应温度,提高氧化还原活性,当x=0.03的样品表面还原温度最低,还原峰的面积最大,即氧化还原反应活性最佳,表明样品的氧化还原性能与晶粒尺寸、晶格缺陷及氧空位浓度密切相关。通过以上研究证明,四种离子共掺杂CeO_(2)能够有效修饰微观晶体结构,在较低掺杂浓度下即可显著改善样品的催化活性。

Co掺杂诱导Co_(x)P-Ni_(2)P双金属位点与酸协同作用实现高效加氢脱氧

高效加氢脱氧催化剂的开发是生物油提质升级的关键。以介孔SiO_(2)为载体,在Ni_(2)P活性相基础上,通过Co掺杂制备了Co_(x)P-Ni_(2)P双金属位点与酸性位点并存的Co_(x)P-Ni_(2)P/SiO_(2)-y催化剂(y为初始P/(Ni+Co)物质的量比),采用XRD、BET、XPS、H_(2)-TPR、NH3-TPD、Py-FTIR和TEM技术表征了催化剂的结构和化学性质,并以间甲酚为模型化合物,考察了Co掺杂以及P/M物质的量比对Ni2P/SiO_(2)催化剂加氢脱氧性能的影响。结果表明,Co的掺杂不仅新增了活性位点Co_(x)P,还优化了Ni_(2)P的电子结构,进而提高了催化剂的加氢脱氧(HDO)活性。在Co_(x)P-Ni_(2)P/SiO_(2)-y催化剂中,P/M物质的量比为0.5的Co_(x)P-Ni_(2)P/SiO_(2)-0.5催化性能最好,在275℃,2 MPa,1 h的反应条件下,间甲酚转化率达到98.7%,对脱氧产物甲基环己烷(MCH)的选择性达到95.6%,且Co_(x)P-Ni_(2)P/SiO_(2)-y催化剂上的HDO反应过程以先加氢后脱氧(HYD)路径为主。

Mg掺杂In_(2)O_(3)-x催化剂光热催化CO_(2)加氢

为提高光热催化CO_(2)加氢In_(2)O_(3)催化剂的催化活性,采用均相水热法制备Mg(OH)_(2)-In(OH)_(3)前驱体,通过高温煅烧和H2-还原处理得到了富含氧空位的Mg掺杂In_(2)O_(3)-x(Mg-In_(2)O_(3)-x)催化剂。在300℃、常压、可见光照射条件下,CO_(2)加氢转化为CO的CO_(2)转化率可达31.20%,CO产生速率为14.22 mmol·gcat^(-1)·h^(-1),CO选择性为100%。相比于单一In_(2)O_(3)-x催化剂,Mg-In_(2)O_(3)-x催化剂光热催化CO_(2)转化率及CO产生速率明显提高,这归因于Mg成功掺杂到In_(2)O_(3)晶格中,促进In_(2)O_(3)表面氧空位的形成,进而对可见光响应效率大幅提高,并有效减缓光生电子-空穴的复合。

重掺硅片表面APCVD法生长SiO_(2)薄膜的致密性

在硅片加工过程中,金属杂质的存在会增大pn结器件的漏电流,甚至直接导致pn结禁带宽度变窄,为防止出现硅外延过程中造成的自掺杂现象,通常在硅片表面生长一层高致密性的SiO_(2)薄膜。基于常压化学气相沉积(APCVD)法在6英寸(1英寸≈2.54 cm)n型硅片表面生长SiO_(2)薄膜,首先研究不同沉积温度、SiH_(4)和O_(2)的体积流量比对沉积速率和SiO_(2)薄膜致密性的影响,进一步探究了不同退火温度对SiO_(2)薄膜致密性的影响,以期获得致密性较高的SiO_(2)薄膜。采用HF腐蚀速率法表征其致密性,采用扫描电子显微镜(SEM)观察SiO_(2)薄膜的表面形貌,采用F50膜厚测试仪测试SiO_(2)薄膜的厚度。结果表明,沉积温度为400℃,SiH_(4)和O_(2)的体积流量比为1∶10,退火温度为1100℃时,制备的SiO_(2)薄膜的致密性为0.096 nm/s(采用体积分数为1%的HF腐蚀)。