Building stabilized Cu_(0.17)Mn_(0.03)V_(2)O_(5−□)·2.16H_(2)O cathode enables an outstanding room‐/low‐temperature aqueous Zn‐ion batteries

Vanadium oxide cathode materials with stable crystal structure and fast Zn^(2+) storage capabilities are extremely important to achieving outstanding electrochemical performance in aqueous zinc‐ion batteries.In this work,a one‐step hydrothermal method was used to manipulate the bimetallic ion intercalation into the interlayer of vanadium oxide.The pre‐intercalated Cu ions act as pillars to pin the vanadium oxide(V‐O)layers,establishing stabilized two‐dimensional channels for fast Zn^(2+) diffusion.The occupation of Mn ions between V‐O interlayer further expands the layer spacing and increases the concentration of oxygen defects(Od),which boosts the Zn^(2+) diffusion kinetics.As a result,as‐prepared Cu_(0.17)Mn_(0.03)V_(2)O_(5−□)·2.16H_(2)O cathode shows outstanding Zn‐storage capabilities under room‐and lowtemperature environments(e.g.,440.3 mAh g^(−1) at room temperature and 294.3 mAh g^(−1)at−60°C).Importantly,it shows a long cycling life and high capacity retention of 93.4%over 2500 cycles at 2 A g^(−1) at−60°C.Furthermore,the reversible intercalation chemistry mechanisms during discharging/charging processes were revealed via operando X‐ray powder diffraction and ex situ Raman characterizations.The strategy of a couple of 3d transition metal doping provides a solution for the development of superior room‐/lowtemperature vanadium‐based cathode materials.

Cu_(3)Mo_(2)O_(9)/Mn_(0.3)Cd_(0.7)S S型异质结的构筑及其光解水产氢性能研究

采用超声辅助研磨煅烧法制备了Cu_(3)Mo_(2)O_(9)/Mn_(0.3)Cd_(0.7)S S型异质结光催化剂,通过X射线粉末衍射仪、扫描电子显微镜、X射线光电子能谱、固体紫外漫反射等测试技术表征了样品的物相、形貌、化学元素组成以及光吸收能力等物理化学性质。在可见光加近红外光照射下进行了光催化析氢性能测试,结果表明,Cu_(3)Mo_(2)O_(9)/Mn_(0.3)Cd_(0.7)S复合材料的光解水产氢性能均优于纯相的Mn_(0.3)Cd_(0.7)S和Cu_(3)Mo_(2)O_(9),其中Cu 3Mo 2O 9的质量分数为1%的Cu_(3)Mo_(2)O_(9)/Mn_(0.3)Cd_(0.7)S显示出最佳的产氢速率(1.554 mmol·h^(-1)·g^(-1)),是Mn 0.3 Cd_(0.7)S的5.5倍。且经过四次循环实验后仍保持较好的光催化活性。此外,根据电化学测试以及红外热成像结果提出了合理的机理,Cu 3Mo 2O 9的光热效应与S型异质结的协同作用是Cu_(3)Mo_(2)O_(9)/Mn_(0.3)Cd_(0.7)S光催化活性提高的关键。

氢气焙烧还原制备全钒液流电池用V_(2)O_(3)

针对氢气焙烧还原偏钒酸铵(AMV)制备全钒液流电池V_(2)O_(3)的试验条件、晶相和微观结构的影响展开研究。结果表明,优选试验条件为:氢气还原温度575℃、氢气还原时间1 h、氢气气流速率100 mL/min、还原后随炉冷却。通过上述试验方案获得的样品基本全部为V_(2)O_(3),主晶相为V_(2)O_(3),微观结构上晶粒饱满且以片状物或块状物的形式紧密堆积在一起。最终可生产电池级V_(2)O_(3),并制备出合格的全钒液流电池电解液。

煅烧气氛对高V_(2)O_(5)含量V_(2)O_(5)-MoO_(3)/TiO_(2)脱硝催化剂性能的影响

采用浸渍—煅烧法制备了高V_(2)O_(5)含量的V_(2)O_(5)-MoO_(3)/TiO_(2)脱硝催化剂,考察了煅烧气氛对催化剂性能的影响。结果表明:煅烧气氛对催化剂的化学组成影响不大;向煅烧气氛中引入O_(2)和H_(2)O可增大催化剂的比表面积和孔体积;N_(2)气氛下煅烧制备的催化剂,活性组分易团聚,导致还原性差,同时酸性和化学吸附氧含量最低,故其脱硝性能最差;催化剂的还原性、酸性、化学吸附氧含量随煅烧气氛中O_(2)含量增加而提高,脱硝性能也随之提高;于5%(φ)H_(2)O-空气气氛下煅烧制得的催化剂,在还原性、酸性和化学吸附氧含量的综合作用下,200~400℃的脱硝效率最高,N_(2)O生成量最少,同时SO_(2)转化为SO_(3)的转化率也最低。

V_(2)CF_(x)MXene衍生2D V_(2)O_(3)@介孔碳纳米片的制备及其电容脱盐特性

采用同源金属V_(2)CF_(x)MXene作为前驱体制备了三氧化二钒@多孔碳(V_(2)O_(3)@porous carbon,V_(2)O_(3)@PC)纳米片作为电容去离子(CDI)阳极,研究其脱盐特性。实验探究了在不同在碳化温度下V_(2)O_(3)@PC的结构、结晶度、润湿性、石墨化程度和电化学特性。研究表明,所制备的V_(2)O_(3)@PC呈现出典型的2D纳米片结构,高结晶度的V_(2)O_(3)纳米颗粒被高石墨化度的PC牢牢束缚。这种结构具有良好的界面润湿性和高导电性,因而可以促进电解质的渗透,加速界面电荷的转移以并促进盐离子的传输和扩散。此外,PC也能较好的抑制V_(2)O_(3)在多次循环后的体积膨胀。电化学结果表明,V的可逆电化学转化在一定程度上提高了Na^(+)的储存。当电压为1.2 V时,NaCl电导率为1000μS·cm^(−1)时,优化后的V_(2)O_(3)@PC电极具有高达2.20 mmol∙g^(−1)的脱盐容量,0.13 mmol∙g^(−1)∙min^(−1)的脱盐速率,62%的水回收率以及24.0 Wh∙m^(−3)的低能耗。

Fe_(3)O_(4)/Cu_(2)O的制备及其类芬顿性能研究

为提高Fe_(3)O_(4)在类芬顿反应体系中对污染物的去除效果,基于类芬顿催化氧化技术,制备了Fe_(3)O_(4)/Cu_(2)O复合材料作为非均相类芬顿催化剂,与H_(2)O_(2)共同构成以亚甲基蓝模拟废水为目标物的类芬顿催化氧化体系。对比分析不同实验条件下Fe_(3)O_(4)/Cu_(2)O复合材料的类芬顿活性,并通过X射线衍射仪、扫描电子显微镜等对材料进行表征。实验结果表明:当Fe_(3)O_(4)与CuCl_(2)·2H_(2)O的复合配比(质量比)为2∶1时制备Fe_(3)O_(4)/Cu_(2)O,且其投加量为40 mg、H_(2)O_(2)用量为0.5 mL时,对浓度为6 mg/L的废水溶液中亚甲基蓝的去除率达到84.27%,类芬顿活性较好;类芬顿反应中起主要活性作用的是·OH。

α-Fe_(2)O_(3)@SiO_(2)@Cu_(2)O核壳结构复合物的合成及其光催化性质的研究

采用水热法,以FeCl_(3)·6H_(2)O和NaH_(2)PO_(4)·2H2O为原料,制备了α-Fe_(2)O_(3)纳米颗粒,然后以TEOS作为硅源,CTAB作为造孔剂,制备α-Fe_(2)O_(3)包覆SiO_(2)的介孔材料,然后对SiO_(2)包覆的α-Fe_(2)O_(3)掺杂过渡金属Cu_(2)O,得到α-Fe_(2)O_(3)@SiO_(2)@Cu_(2)O核壳结构复合物,并且利用XRD对制备的产品进行表征,进行光催化活性的评价。结果表明,以高压汞灯为光源,亚甲基蓝浓度为15 mg/L,当催化剂用量为5 mg,90 min的降解率达到47.3%。

Double enzyme mimetic activities of multifunctional Ag nanoparticle-decorated Co_(3)V_(2)O_(8)hollow hexagonal prismatic pencils for application in colorimetric sensors and disinfection

Since the catalytic activity of most nanozymes is still far lower than the corresponding natural enzymes,there is urgent need to discover novel highly efficient enzyme-like materials.In this work,Co_(3)V_(2)O_(8)with hollow hexagonal prismatic pencil structures were prepared as novel artificial enzyme mimics.They were then decorated by photo-depositing Ag nanoparticles(Ag NPs)on the surface to further improve its catalytic activities.The Ag NPs decorated Co_(3)V_(2)O_(8)(ACVPs)showed both excellent oxidase-and peroxidase-like catalytic activities.They can oxidize the colorless 3,3’,5,5’-tetramethylbenzidine rapidly to induce a blue change.The enhanced enzyme mimetic activities can be attributed to the surface plasma resonance(SPR)effect of Ag NPs as well as the synergistic catalytic effect between Ag NPs and Co_(3)V_(2)O_(8),accelerating electron transfer and promoting the catalytic process.ACVPs were applied in constructing a colorimetric sensor,validating the occurrence of the Fenton reaction,and disinfection,presenting favorable catalytic performance.The enzyme-like catalytic mechanism was studied,indicating the chief role of⋅O_(2)-radicals in the catalytic process.This work not only discovers a novel functional material with double enzyme mimetic activity but also provides a new insight into exploiting artificial enzyme mimics with highly efficient catalytic ability.

固相法制备Bi_(4)V_(2)O_(11)固体电解质在NH_(3)传感器中的应用

通过固相反应法制备了在中低温下具有高离子导电性的固体电解质Bi_(4)V_(2)O_(11),并以CuV_(2)O_(6)为敏感电极组装成混合电位型NH_(3)传感器。通过X射线衍射仪(XRD)、扫描电子显微镜(SEM)和能谱仪(EDS)分析了固体电解质的相组成和传感器的微观形貌。结果表明,在中低温(300℃~600℃)下Bi_(4)V_(2)O_(11)的电导率高于传统氧离子导体YSZ。传感器测试结果表明,基于Bi_(4)V_(2)O_(11)作固体电解质CuV_(2)O_(6)作敏感电极的传感器能在300℃~500℃的温度范围内对10 ppm~300 ppm的NH_(3)进行检测,而以YSZ作固体电解质的传感器在300℃~350℃性能下降明显;传感器在400℃下有着最高的灵敏度(-59.15 mV/decade),优于相同条件下以YSZ作固体电解质的传感器(-42.89 mV/decade)。传感器具有稳定的响应,传感器的响应值和NH_(3)浓度的对数值呈现良好的正比例关系。

黄光发射纯Zn_(3)V_(2)O_(8)荧光粉的制备及光学性能研究

以1%BaF_(2)为助溶剂通过简单的高温固相法成功合成了黄光发射纯Zn_(3)V_(2)O_(8)荧光粉。采用X射线衍射(XRD)测定了Zn_(3)V_(2)O_(8)的纯度,通过激发/发射(PLE/PL)光谱、热猝灭光谱和荧光寿命曲线分析了其光学性质。结果表明:在360 nm激发下,Zn_(3)V_(2)O_(8)荧光粉在400~800 nm表现出较强的宽带发射,该发射归因于^(3)T_(2)→^(1)A_(1)和^(3)T_(1)→^(1)A_(1)的电子跃迁,其最佳发射波长在550 nm,发出明亮的黄光。在550 nm的监测下,Zn_(3)V_(2)O_(8)荧光粉在200~450 nm呈现宽吸收带。Zn_(3)V_(2)O_(8)荧光粉的发射衰减时间为1.67 ms,室温内量子效率高达47.09%。当温度升高到140℃时,该荧光粉的高温发射强度相比于室温发射强度的保持率为25.1%,高于其他石榴石结构的钒酸盐材料。Zn_(3)V_(2)O_(8)荧光粉作为新型白光发光二极管器件的黄光光源在低成本、可大批量生产方面具有潜在的优势。

Polypyride intercalation boosting the kinetics and stability of V_(3)O_(7)·H_(2)O cathodes for aqueous zinc-ion batteries

V_(3)O_(7)·H_(2)O(VO)is a high capacity cathode material in the field of aqueous zinc ion batteries(AZIBs),but it is limited by slow ion migration and low electrical conductivity.In this paper,polypyridine(PPyd)intercalated VO with nanoribbon structure was prepared by a simple in-situ pre-intercalation,which is noted VO-PPyd.The total density of states(TDOS)shows that after the pre-intercalation of PPyd,an intermediate energy level appears between the valence band and conduction band,which provides a step that can effectively reduce the band gap and enhance the electron conductivity.Furthermore,the density functional theory(DFT)results found that Zn^(2+)is more easily de-intercalated from the V-O skeleton,which proves that the embeddedness of PPyd improves the diffusion kinetics of Zn^(2+).Electrochemical studies have shown that VO-PPyd cathode materials exhibit excellent rate performance(high specific capacity of 465 and 192 mA h g^(-1)at 0.2 and 10 A g^(-1),respectively)and long-term cycling performance(92.7%capacity retention rate after 5300 cycles),due to their advantages in structure and composition.More importantly,the energy density of VO-PPyd//Zn at 581 and 5806 W kg^(-1)is 375 and 247 W h kg^(-1),respectively.VO-PPyd exhibits excellent electrochemical properties compared to previously reported vanadium based cathodes,which makes it highly competitive in the field of high-performance cathode materials of AZIBs.

Critical current degradation in an epoxy-impregnated rare-earth Ba_(2)Cu_(3)O_(7-x)coated conductor caused by damage during a quench

High-temperature superconducting(HTS)rare-earth Ba_(2)Cu_(3)O_(7-x)(REBCO)coated conductors(CCs)have significant potential in high-current and high-field applications.However,owing to the weak interface strength of the laminated composite REBCO CCs,the damage induced by the thermal mismatch stress under a combination of epoxy impregnation,cooling,and quenching can cause premature degradation of the critical current.In this study,a three-dimensional(3D)electromagnetic-thermal-mechanical model based on the H-formulation and cohesive zone model(CZM)is developed to study the critical current degradation characteristics in an epoxy-impregnated REBCO CC caused by the damage during a quench.The temperature variation,critical current degradation of the REBCO CC,and its degradation onset temperature calculated by the numerical model are in agreement with the experimental data taken from the literature.The delamination of the REBCO CC predicted by the numerical model is consistent with the experimental result.The numerical results also indicate that the shear stress is the main contributor to the damage propagation inside the REBCO CC.The premature degradation of the critical current during a quench is closely related to the interface shear strength inside the REBCO CC.Finally,the effects of the coefficient of thermal expansion(CTE)of the epoxy resin,thickness of the substrate,and substrate material on the critical current degradation characteristics of the epoxy-impregnated REBCO CC during a quench are also discussed.These results help us understand the relationship between the current-carrying degradation and damage in the HTS applications.

棒状V_(3)O_(7)•H_(2)O电极材料的制备及印刷超级电容器

以V2O5为原料,利用溶剂热法一步制备了V_(3)O_(7)•H_(2)O纳米棒,采用SEM、XRD、EDS、XPS和FTIR对样品进行了测试。以V_(3)O_(7)•H_(2)O纳米棒为电极材料,探究了丝网印刷工艺对电极电化学性能的影响,将此电极组装超级电容器并评价了其电化学性能。结果表明,丝网印刷电极比电容可达268.0 F/g(电流密度为0.3 A/g),经过5000次循环后电容保持率为85.9%,优于涂抹电极的比电容(246.0 F/g)和电容保持率(68.0%),这得益于丝网印刷的油墨规则排列的结构。组装的纽扣超级电容器也表现出优异的电化学性能,比电容和电容保持率为134.2 F/g(0.5 A/g电流密度)和91.2%(5000次充放电循环),且当能量密度为22.0 W·h/kg时,功率密度最高可达4125.0 W/kg。

V_(2)O_(5)-BaTiO_(3)添加对低温烧结NiCuZn材料磁性能的影响

采用固相反应法制备NiCuZn软磁铁氧体材料,探究添加V_(2)O_(5)助熔剂和BaTiO_(3)(BTO)共同作用对铁氧体微观结构和磁性能的影响,以期实现NiCuZn铁氧体的低温烧结。V_(2)O_(5)作为助熔剂可以起到促进晶粒生长和晶界成型的作用,但过量的V_(2)O_(5)的添加会导致出现晶粒异常生长,恶化磁性能。通过对样品高频下的损耗进行分离和分析,明确了致密化的小晶粒尺寸样品可以获得低的功率损耗。添加0.5 wt%的V_(2)O_(5)和0.03 wt%BTO的样品获得了优良的磁性能,室温下起始磁导率μ_(i)为669、饱和磁感应强度B_(s)为373 mT、功率损耗P_(cv)为212 kW/m^(3)(1 MHz,30 mT)。

Cu_(3)Mo_(2)O_(9)/MoO_(3)纳米复合材料制备及三甲胺气敏性能研究

水产品的新鲜度极大地影响着人类的生命及身体健康,水产品在存放过程中会释放出以三甲胺为代表的胺类气体,通过检测这类气体的浓度可以监控水产品的新鲜度.本文以具有优良气体敏感性能的MoO_(3)纳米带作为基体,通过引入Cu_(3)Mo_(2)O_(9)纳米颗粒制备Cu_(3)Mo_(2)O_(9)/MoO_(3)复合材料,具有非常好的三甲胺气体敏感性能、快速响应/恢复时间及长期稳定性.结果表明,采用这种复合材料制备的气敏元件在50-240℃,质量分数为5×10^(-6)时对三甲胺气体的响应可达到Rair/Rgas=13.9,最小检测极限的体积分数为2×10^(-7).分布在MoO_(3)纳米带表面的Cu_(3)Mo_(2)O_(9)颗粒与基体形成异质结界面,利用Cu_(3)Mo_(2)O_(9)的强氧吸附能力与催化效应促进电子与空穴的分离,显著改善了复合材料的电子输运性能和气敏特性,为制备高性能MoO_(3)基气敏材料提供了新的策略.

液相氢还原沉钒制备V_(2)O_(3)及其动力学研究

V_(2)O_(3)是制备氮化钒、氮化钒铁和钒铁重要原料。液相氢还原可直接从富钒液制备出V_(2)O_(3),具有短流程、绿色环保、能耗低的优点。本研究选择低成本的蒽醌和镍粉作为催化剂来替代PdCl_(2),蒽醌沉钒的主要产物为VO_(2)(H_(2)O)_(0.5),无法制备出V_(2)O_(3);镍粉沉钒能获得和PdCl_(2)相同的V_(2)O_(3)产物,沉钒率为99.87%。蒽醌、镍粉与PdCl_(2)催化液相氢还原反应活化能分别为188.83 kJ/mol、140.09 kJ/mol和38.07 kJ/mol。H_(2)分子在Ni或Pd表面发生裂解,同时H原子的s轨道与Pd、Ni的p轨道和d轨道发生了杂化,形成还原性较强的Pd—H或Ni—H键,Pd和Ni对氢气的化学吸附能分别为1.34 eV和2.04 eV;H_(2)在250-300℃发生裂解,其解吸活化能为9.699 4 kJ/mol。本研究采用镍粉可替代PdCl_(2)制备出纯度99.21%的V_(2)O_(3)产品。

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。

射频等离子体改性制备S_(2)O_(2)-8/SnO_(2)-Al_(2)O_(3)固体超强酸催化剂的研究

采用低温陈化法制备S_(2)O_(2)-8/SnO_(2)-Al_(2)O_(3)固体超强酸催化剂,利用射频等离子体技术对其进行改性后催化L-酪氨酸与甲醇的酯化反应。利用Hammett指示剂法、XRD、HRTEM、BET、FT-IR、Py-IR和NH_(3)-TPD等对改性前后的催化剂进行表征。结果表明,经射频等离子体改性后的催化剂颗粒分散性更好、粒径更小(4.32 nm)、比表面积更大(104.4 m^(2)/g)、总酸量更高(142.9μmol/g)。在温度为180℃、压力为1 MPa的条件下,射频等离子体改性后的催化剂催化L-酪氨酸甲酯化反应6 h后L-酪氨酸甲酯产率可达92%。

莫来石晶须增强Al_(2)O_(3)-8YSZ陶瓷涂层的制备和性能

莫来石晶须(3Al_(2)O_(3)·2SiO_(2))由于结晶完美,具有良好的性能,如低的热膨胀和导热性,较高的热稳定性,高的抗蠕变和腐蚀稳定性,以及合适的强度和断裂韧性,使其成为需要耐高温和耐腐蚀性能应用的合适材料.探讨晶须增强Al_(2)O_(3)-8YSZ陶瓷涂层的制备和性能.通过莫来石晶须的增韧作用,提高了陶瓷涂层的硬度,对陶瓷涂层的结构具有明显的改善.

铷掺杂Na_(1.25)V_(3)O_(8)纳米棒作为锌离子电池正极材料的电化学性能

为了探究作为锌离子电池正极的Na_(1.25)V_(3)O_(8)的电化学性能是否还具有进一步提升的空间,文中通过水热-固相法成功合成了纯Na_(1.25)V_(3)O_(8)和铷掺杂Na_(1.25)RbxV_(3)O_(8)纳米棒。根据XRD谱图可以看出,随着铷含量的增加衍射峰向低角度偏移且没有新的衍射峰生成,表明Na_(1.25)RbxV_(3)O_(8)样品为纯相且保持空间群为P21/m的结构对称性。这一结果说明铷离子成功进入了Na_(1.25)RbxV_(3)O_(8)层状化合物的层间。SEM和TEM形貌分析结果显示,随着Rb+掺杂量的增加,纳米棒的形貌变得更大、更厚,会降低材料的比表面积,导致阻抗的增加和Zn2+离子扩散系数的降低,对电化学性能产生不利的影响。EIS和GITT测试结果也证实,Rb+的掺入会使其比容量降低。电化学测试结果显示,虽然未掺杂的Na_(1.25)V_(3)O_(8)纳米棒表现出370 mA·h/g的初始比容量,但随着充放电过程的进行其比容量衰减很快,在电流密度为100 mA/g条件下长循环100圈后的放电比容量衰减了初始容量的50%;而Rb+掺杂的纳米棒尽管比容量有所降低,但其循环稳定性和倍率性能均得到显著提升。其中Rb掺杂量为1%的样品初始比容量为336 mA·h/g,在相同条件下循环100圈后和初始比容量相比只衰减了6%;当Rb掺杂量增加到5%时,尽管初始比容量只有217 mA·h/g,但100圈后放电比容量和初始比容量相比几乎没有衰减。利用XPS能谱和原位XRD技术对其锌离子存储机理进行了深入分析,该水系锌离子电池体系中Na_(1.25)RbxV_(3)O_(8)正极材料的氧化还原反应机理主要以化学转化反应为主,其中只有充电反应过程是可逆的。