抗坏血酸改性Mn_(3)O_(4)活化过硫酸氢盐降解磺胺甲恶唑

采用水热-超声法制备抗坏血酸(AA)改性的Mn_(3)O_(4)(AA-MO),并通过XRD、FTIR、SEM、TEM和XPS等技术手段表征样品的物理化学性质.将AA-MO用于活化过硫酸氢盐(PMS)降解磺胺甲恶唑(SMX),结果表明,AA-MO/PMS体系在2.0~10.0的pH值范围内催化效能先升后降,在中性和偏中性环境中具有最佳降解效果.PMS浓度和催化剂投加量的增大均能有效促进SMX的降解.稳定性实验显示,在3次循环使用后AA-MO相比MO具有更稳定的催化效能.自由基淬灭结果表明硫酸根自由基(SO_(4)^(·-))在降解反应中起主导作用.AA-MO与PMS之间的电子转移反应产生自由基降解SMX,AA的抗氧化性维持了复合催化剂的高催化性.通过高效液相色谱-串联质谱联用(HPLC-MS/MS)测定了降解过程中可能的6种中间产物.SMX通过开环、S-N键断裂、羟基化以及氧化作用等3种路径被降解.通过ECOSAR软件计算物质的毒性阈值并进行毒理分析,需要关注产物P2、P5和P7的毒性.

Thermodynamic equilibrium theory-guided design and synthesis of Mg-doped LiFe_(0.4)Mn_(0.6)PO_(4)/C cathode for lithium-ion batteries

Mn-rich LiFe_(1-x)Mn_(x)PO_(4)(x>0.5),which combines the high operation voltage of LiMnPO_(4)with excellent rate performa nce of LiFePO4,is hindered by its sluggish kinetic properties.Herein,thermodynamic equilibrium analysis of Mn^(2+)-Fe^(2+)-Mg^(2+)-C_(2)O_(4)^(2-)-H_(2)O system is used to guide the design and preparation of insitu Mg-doped(Fe_(0.4)Mn_(0.6))_(1-x)Mg_(x)C_(2)O_(4)intermediate,which is then employed as an innovative precursor to synthesize high-performance Mg-doped LiFe_(0.4)Mn_(0.6)PO_(4).It indicates that the metal ions with a high precipitation efficiency and the stoichiometric precursors with uniform element distribution can be achieved under the optimized thermodynamic conditions.Meanwhile,accelerated Li+diffusivity and reduced charge transfer resistance originating from Mg doping are verified by various kinetic characterizations.Benefiting from the contributions of inherited homogeneous element distribution,small particle size,uniform carbon layer coating,enhanced Li+migration ability and structural stability induced by Mg doping,the Li(Fe_(0.4)Mn_(0.6))_(0.97)Mg_(0.03)PO_(4)/C exhibits splendid electrochemical performance.

纳米级LiNi_(0.05)Mn_(1.95)O_(4)正极材料制备及电化学性能研究

为有效抑制尖晶石锰酸锂的Jahn-Teller效应,改善其在高倍率充放电循环中容量衰减快的问题,采取熔盐燃烧法和不同焙烧温度成功制得LiNi_(0.05)Mn_(1.95)O_(4)样品。实验结果表明,Ni掺杂和不同的焙烧温度没有改变LiMn_(2)O_(4)的晶体结构,随焙烧温度升高,结晶性增加,颗粒尺寸增大,逐渐由纳米级变为亚微米级。在优化焙烧温度650℃下制备的样品电化学性能最优,5C下初始放电比容量及500次循环后容量保持率分别为100.8 mA·h/g和80.0%,更高倍率(10C)下500次循环容量仅衰减7.5%。动力学性能测试结果表明,其具有较大锂离子扩散系数(3.26×10^(-16)cm^(2)/s)和较小表观活化能(25.67 kJ/mol)。Ni掺杂和不同的焙烧温度抑制了LiMn_(2)O_(4)材料的Jahn-Teller效应,提高了材料的倍率性能和循环寿命。

铁酸锶镧对CH_(4)化学循环转化中Mn_(3)O_(4)氧化还原性能的作用机制

通过水热合成法制备了MnO_(2),以其作为锰源通过热分解得到Mn_(3)O_(4),采用溶胶凝胶法制备了Mn_(3)O_(4)/La0.8Sr0.2FeO3,将Mn_(3)O_(4)和Mn_(3)O_(4)/La_(0.8)Sr_(0.2)FeO_(3)在900℃下与体积分数3%的CH_(4)和空气交替接触,模拟化学循环燃烧中的氧化还原过程,研究了Mn_(3)O_(4)和Mn_(3)O_(4)/La_(0.8)Sr_(0.2)FeO_(3)的氧化还原性能和长期稳定性。结果表明:温度的升高会提高Mn_(3)O_(4)/La_(0.8)Sr_(0.2)FeO_(3)的还原失重率;纯Mn_(3)O_(4)在10次氧化还原循环后反应性能降低,不适合作为化学循环燃烧的氧载体,而多次氧化还原循环前后Mn_(3)O_(4)/La_(0.8)Sr_(0.2)FeO_(3)的还原反应活性、稳定性、晶相、元素赋存状态和形貌基本不变。

Na_(2)WO_(4)-Mn_(x)O_(y)/BaTiO_(3)催化剂的制备及其在甲烷氧化偶联反应中的应用

采用浸渍法制备了Na_(2)WO4-Mn_(x)O_(y)/BaTiO_(3)催化剂,研究了Na_(2)WO_(4)-Mn_(x)O_(y)/BaTiO_(3)催化剂对甲烷氧化偶联反应(OCM)的影响,利用SEM,XRD,EDS等分析方法对催化剂进行表征,并与Na_(2)WO_(4)-Mn_(x)O_(y)/SiO_(2)催化剂进行对比。实验结果表明,Na_(2)WO_(4)-Mn_(x)O_(y)/BaTiO_(3)催化剂的活性组分W和Mn在钛酸钡表面分布均匀,且反应过程中催化剂的结构基本保持不变,在反+应温度为800℃、甲烷与氧气摩尔比为1.5时,Na_(2)WO_(4)-Mn_(x)O_(y)/BaTiO_(3)催化剂催化OCM反应的C_(2)收率约为19%,C_(2)^(+)收率约为21%。与Na_(2)WO_(4)-Mn_(x)O_(y)/SiO_(2)催化剂相比,Na_(2)WO_(4)-Mn_(x)O_(y)/BaTiO_(3)催化剂的反应起活温度低60℃,具有更加活泼的活性氧位,能够在更低的温度条件下开始OCM反应。

分子束外延Mn_(4)N单晶薄膜的反常霍尔效应研究

Mn_(4)N是立方相的反钙钛矿型晶体,具有显著的亚铁磁性和反常霍尔效应.该文利用等离子辅助分子束外延在MgO(100)衬底上生长厚度为40 nm的Mn_(4)N(100)单晶薄膜,通过X射线衍射θ扫描和φ扫描,证实外延层的结构符合Mn_(4)N单晶的空间结构特征;化学态测试结果表明Mn_(4)N(100)薄膜内部存在Mn^(0)、Mn^(2+)和Mn^(4+)等几种价态,其实际化学式为Mn_(3.6)N,薄膜中存在富余的N元素;电学测试数据表明Mn_(4)N(100)薄膜具有以电子为载流子的反常霍尔效应(在正磁场中得到负的霍尔电阻率),正常霍尔效应的贡献约占千分之六,其反常霍尔电阻率随着测试温度升高5 K~350 K单调增大,说明温度升高导致电子散射现象加剧.通过对测试数据分析可以推断,在5 K~50 K和50 K~75 K温度范围,反常霍尔效应的来源可分别归结为电子斜散射机制和电子边跳机制.在75 K~350 K这一温度范围内,反常霍尔效应主要来源于与能带结构相关的内禀机制.

超小尺寸碳载Mn_(3)O_(4)纳米催化剂制备及其催化性能

以MnCl_(2)为原料,聚乙烯醇(PVA)为稳定剂,利用PVA介导沉淀法制备Mn_(3)O_(4)纳米粒子(PVA/Mn_(3)O_(4)),进一步将冻干的PVA/Mn_(3)O_(4)复合物炭化制备了超小尺寸的Mn_(3)O_(4)-C催化剂。使用XRD、XPS、TEM、BET表征制备材料的结构和形貌,发现PVA能够有效减小Mn_(3)O_(4)在制备过程中的聚集和长大。无PVA介导沉淀法制备的Mn_(3)O_(4)-P平均粒径为(38.8±9.3)nm。加入PVA后,制备过程中PVA分子链间的Mn_(3)O_(4)纳米粒子平均粒径为(3.2±0.8)nm,经过Ar保护炭化处理后,平均粒径为(4.5±1.2)nm的Mn_(3)O_(4)纳米粒子被均匀固定在碳基底上。制备的Mn_(3)O_(4)-C催化剂具有高效的类芬顿催化降解亚甲基蓝(MB)的能力,在MB质量浓度为40 mg/L的40 mL溶液中,催化剂质量浓度为75 mg/L,H_(2)O_(2)投加量为4 mL,反应时间为40 min,反应温度为80℃的条件下,MB的降解率为94.4%。催化剂经过3次循环使用后,MB的降解率保持在91.1%,且碳基底上的Mn_(3)O_(4)纳米粒子结构和形貌与使用前相似。

氧化还原法制备Mn_(3)O_(4)催化剂及其甲苯催化氧化性能与机理研究

在氧化还原法制备α-MnO_(2)的基础上,通过控制焙烧温度和气氛制备了Mn_(3)O_(4)催化剂,系统考察了其甲苯催化性能。结果显示,Mn_(3)O_(4)催化性能优于MnO_(2),并且在230℃下保持转化率90%以上稳定运行100 h。原位红外等表征结果表明,与MnO_(2)相比,Mn_(3)O_(4)具有适当的氧化还原能力、更高的晶格氧活性、更多的表面吸附氧和更强的甲苯吸附能力,促使催化剂表面苯甲酸物种的快速转化,进而提高其甲苯催化性能。本研究可为锰基催化剂的制备及其甲苯催化氧化性能提升机理研究提供参考。

Diluted low concentration electrolyte for interphase stabilization of high-voltage LiNi_(0.5)Mn_(1.5)O_(4) cathode

The Co-free Li Ni_(0.5)Mn_(1.5)O_(4)(LNMO)is a promising cathode for lithium-ion batteries owing to its high operating voltage and low costs.However,the synthesis of LNMO is generally time and energy consuming,and its practical application is hindered by the lack of a compatible electrolyte.Herein,a spray pyrolysis-based energy-saving synthesis method as well as a diluted low concentration electrolyte(0.5 M LiPF_(6) in a mixture of fluoroethylene carbonate/dimethyl carbonate/1,1,2,2-tetrafluoroethyl-2,2,3,3-tetrafluoropropyl ether(FEC:DMC:TTE,1:4:5 by volume))are proposed to address these challenges.Owing to the unique features of the precursor prepared by spray pyrolysis,well-crystallized LNMO single-crystal can be obtained within 1 h calcination at 900℃.Besides,the fluorinated interphases derived from the diluted low concentration electrolyte not only mitigate the Mn dissolution and Al corrosion at the cathode side,but also suppresses dendritic Li deposition at the anode side,thus enabling stable cycling of both LNMO and Li metal anode.Thus,30μm Li|LNMO(1.75 m A h cm^(-2))cells achieve a high capacity retention(90.9%)after 168 cycles in the diluted low concentration electrolyte.

Facile synthesis of the Mn_(3)O_(4)polyhedron grown on N-doped honeycomb carbon as high-performance negative material for lithium-ion batteries

Because of their large volume variation and inferior electrical conductivity,Mn_(3)O_(4)-based oxide anode materials have short cyclic lives and poor rate capability,which obstructs their development.In this study,we successfully prepared a Mn_(3)O_(4)/N-doped honeycomb carbon composite using a smart and facile synthetic method.The Mn_(3)O_(4)nanopolyhedra are grown on N-doped honeycomb carbon,which evidently mitigates the volume change in the charging and discharging processes but also improves the electrochemical reaction kinetics.More importantly,the Mn-O-C bond in the Mn_(3)O_(4)/N-doped honeycomb carbon composite benefits electrochemical reversibility.These features of the Mn_(3)O_(4)/N-doped honeycomb carbon(NHC)composite are responsible for its superior electrochemical performance.When used for Li-ion batteries,the Mn_(3)O_(4)/N-doped honeycomb carbon anode exhibits a high reversible capacity of 598 mAh·g^(−1)after 350 cycles at 1 A·g^(−1).Even at 2 A·g^(−1),the Mn_(3)O_(4)/NHC anode still delivers a high capacity of 472 mAh·g^(−1).This work provides a new prospect for synthesizing and developing manganese-based oxide materials for energy storage.

用电解锰阳极泥制备高纯Mn_(3)O_(4)

以电解锰阳极泥经还原焙烧—酸浸—深度净化除杂获得的硫酸锰溶液和工业氨水为原料,采用共沉淀法制备高纯Mn_(3)O_(4)。考察了搅拌速度、反应温度、空气流速、反应时间以及Mn^(2+)/NH_(4)^(+)物质的量比对Mn_(3)O_(4)纯度的影响。结果表明,在搅拌速度250 r/min、反应温度60℃、空气流速2.5 L/min、反应时间40 min、Mn^(2+)/NH_(4)^(+)物质的量比1∶2的条件下,可成功制备出球形Mn_(3)O_(4),其锰含量为71.45%,满足高纯Mn_(3)O_(4)的要求。

以Mn_(3)O_(4)为原料制备高性能尖晶石LiMn2O_(4)正极材料

本文实验以Mn_(3)O_(4)为锰源和Li2CO_(3)为锂源,对不同温度制备的尖晶石型LiMn2O_(4)的结构和电化学性能进行了分析研究。XRD分析测试表明在不同温度段制得的尖晶石LiMn2O_(4)均为纯相;SEM分析测试表明不同温度制得的尖晶石LiMn2O_(4)晶粒大小均匀,随着煅烧温度上升LiMn2O_(4)晶粒逐渐长大。尖晶石LiMn2O_(4)的电化学性能测试结果表明,在650~750℃范围煅烧的尖晶石LiMn2O_(4)要优于750℃以上煅烧的样品。

第一性原理研究Al掺杂Mn_(4)Si_(7)的电子结构及光学性质

基于密度泛函理论框架下,利用第一性原理计算方法,对本征Mn_(4)Si_(7)以及不同Al掺杂浓度下Mn_(4)Si_(7)的电子结构及光学性质进行系统计算分析.Mn_(4)Si_(7)晶胞中有16个Mn原子及28个Si原子,建立4种Mn_(16-x)Al_(x)Si_(28)(x=0,2,4,8)的掺杂模型,计算结果表明:本征Mn_(4)Si_(7)的禁带宽度E_(g)=0.775 eV,属于间接带隙半导体,Al的掺入导致了Mn_(4)Si_(7)费米能级附近的电子结构发生改变,导带向低能方向发生偏移,价带向高能方向发生偏移,禁带宽度由0.775 eV降至零,呈现出金属性.计算还表明,在光子能量低能区域,Al的掺入使Mn_(4)Si_(7)的介电函数、折射率、吸收及反射系数等光学性质有所提升,改善了Mn_(4)Si_(7)在红外光区的光电性能.

锂锰摩尔比对水热法制备Li_(1.6)Mn_(1.6)O_(4)的影响

以MnSO_(4)为基础锰源,分别采用3种路径(MnSO_(4)+KMnO_(4)+LiOH一步水热法;自制MnOOH/Mn_(3)O_(4)+LiOH分步水热法)制备出o-LiMnO_(2),然后在400℃下焙烧6 h获得富锂锰氧化物Li_(1.6)Mn_(1.6)O_(4).讨论了锂锰比(Li和Mn的摩尔比,下同)工艺参数对合成o-LiMnO_(2)过程的影响,并使用X射线衍射仪和扫描电镜对3种路径制备的产物进行比较分析.结果表明:自制Mn_(3)O_(4)的分步法在锂锰比为6~12时可制得纯相o-LiMnO_(2),一步法与自制MnOOH锰源的分步法在锂锰比4~20时,制备的LiMnO_(2)均混有杂质相;3种路径制得的o-LiMnO_(2)经焙烧后,均可得到结晶度较好的纳米级Li_(1.6)Mn_(1.6)O_(4)锂离子筛前驱体,由Mn_(3)O_(4)制备的o-LiMnO_(2)呈现特殊棒状形貌,而由MnOOH制备的o-LiMnO_(2)则呈立方状形貌.

回火温度对LiNi_(0.5)Mn_(1.5)O_(4)结构、形貌及电化学性能的影响

以LiNO_(3)、Ni(NO_(3))2·6H_(2)O、Mn(NO_(3))_(2)为主要原料,尿素作燃料,采用低温燃烧法合成了亚微米级、电化学性能良好、单晶形貌的5 V锂离子电池正极材料LiNi_(0.5)Mn_(1.5)O_(4)。考察了不同回火温度对所合成产物的结构、形貌和电化学性能的影响,并通过X射线衍射、扫描电镜和充放电实验对不同回火温度下合成的产物进行了表征。实验结果表明,在不同回火温度得到的样品均具有尖晶石结构。但是在回火温度为800℃和900℃下合成的样品产生了较多的杂质相,随着回火温度的升高,合成产物的结晶度逐渐提高,粒径逐渐增大。在回火温度为850℃得到的样品成清晰的八面体外形,结晶良好,粒径适中,在3.5~4.9 V内0.1 C倍率下首次放电容量最高,30次循环后其容量保持率最好,其电化学性能最好。

HT高电压LiNi_(0.5)Mn_(1.5)O_(4)正极材料的合成与性能分析

采用六水硫酸镍和一水硫酸锰为原料,以Na_(2)CO_(3)为沉淀剂,通过共沉淀法制备镍锰碳酸盐前驱体,并采用碳酸锂为锂源,通过高温固相法合成高电压LiNi_(0.5)Mn_(1.5)O_(4)正极材料。利用X射线衍射(XRD)、扫描电子显微镜(SEM))和X射线能谱(EDS)对前驱体和LiNi_(0.5)Mn_(1.5)O_(4)材料的结构、形貌和组成进行表征。结果表明经高温处理所得的LiNi_(0.5)Mn_(1.5)O_(4)正极材料为尖晶石相且具有微纳结构形貌,颗粒大小约为5μm且镍锰元素分布均匀。电化学测试结果表明,LiNi_(0.5)Mn_(1.5)O_(4)正极材料以0.5 C充放电,初始放电比容量达109 mAh/g,放电平台约4.6 V,1 C循环100次容量保持率约93%。

Enhancing reversibility of LiNi_(0.5)Mn_(1.5)O_(4)by regulating surface oxygen deficiency

Oxygen deficiency has crucial effects on the crystal structure and electrochemical performance of spinel oxide lithium electrode materials such as LiNi_(0.5)Mn_(1.5)O_(4)(LNMO)cathode.In particular,the oxygen stoichiometry on the crystal surface differs from that on the crystal interior in LNMO.The detection of local oxygen loss in LNMO and its correlation with the crystal structure and the cycling stability of LNMO remain challenging.In this study,the effect of oxygen deficiency in LNMO controlled by sintering temperature on the surface crystal structure and electrochemical performance of LNMO is comprehensively investigated.The high concentration of oxygen vacancies segregates at the surface regions of LNMO forming a thin rock‐salt and/or deficient spinel surface layer.The atomic‐level surface structure reconstruction was demonstrated by annular dark‐field and annular brightfield techniques.For the synthesis of LNMO,the higher sintering temperature results in higher crystallinity but the higher oxygen deficiency in LNMO.The high crystallinity of LNMO would increase the thermal stability of LNMO cathodes while the high content of oxygen deficiency would decrease the surface structural stability of LNMO.Therefore,the LNMO sintered at a medium temperature of 850°C achieved the best capacity retention.The results suggest a competitive function mechanism between oxygen stoichiometry and the crystallinity of LNMO on the cycling performance of LNMO.

Dielectric polarization in MgFe_(2)O_(4) coating and bulk doping to enhance high-voltage cycling stability of Na_(2/3)Ni_(1/3)Mn_(2/3)O_(2) cathode material

Charging P2-Na_(2/3)Ni_(1/3)Mn_(2/3)O_(2)to 4.5 V for higher capacity is enticing.However,it leads to severe capacity fading,ascribing to the lattice oxygen evolution and the P2-O2 phase transformation.Here,the Mg Fe_(2)O_(4) coating and Mg,Fe co-doping were constructed simultaneously by Mg,Fe surface treatment to suppress lattice oxygen evolution and P2-O2 phase transformation of P2-Na_(2/3)Ni_(1/3)Mn_(2/3)O_(2)at deep charging.Through ex-situ X-ray diffraction(XRD)tests,we found that the Mg,Fe bulk co-doping could reduce the repulsion between transition metals and Na+/vacancies ordering,thus inhibiting the P2-O2 phase transition and significantly reducing the irreversible volume change of the material.Meanwhile,the internal electric field formed by the dielectric polarization of Mg Fe_(2)O_(4) effectively inhibits the outward migration of oxidized O^(a-)(a<2),thereby suppressing the lattice oxygen evolution at deep charging,confirmed by in situ Raman and ex situ XPS techniques.P2-Na NM@MF-3 shows enhanced high-voltage cycling performance with capacity retentions of 84.8% and 81.3%at 0.1 and 1 C after cycles.This work sheds light on regulating the surface chemistry for Na-layered oxide materials to enhance the high-voltage performance of Na-ion batteries.

LiNi_(1/3)Co_(1/3)Mn_(1/3)O_(2)/Li_(4)Ti_(5)O_(12)全电池的制备及电化学性能测试

为了提高LiNi_(1/3)Co_(1/3)Mn_(1/3)O_(2)/Li_(4)Ti_(5)O_(12)全电池的电化学性能,本文通过对比实验,研究了在不同的N/P比以及充放电电压区间下的全电池性能表现。经对比数据发现,当正极材料LiNi_(1/3)Co_(1/3)Mn_(1/3)O_(2)(NCM111)和负极材料Li_(4)Ti_(5)O_(12)(LTO)的N/P比为1.0:1.0,充放电电压区间为0.5~3.2V时,电池具备较好的比容量、库伦效率和循环稳定性。本文为后续LiNi_(1/3)Co_(1/3)Mn_(1/3)O_(2)/Li_(4)Ti_(5)O_(12)全电池的工业化制造提供了帮助。

基于Au增强的Mn_(3)O_(4)/Au复合纳米酶的高选择性检测特丁基对苯二酚

本研究制备了具有高模拟酶活性的Mn_(3)O_(4)/Au复合纳米酶,该酶可用于催化特丁基对苯二酚(TBHQ)氧化生成红色醌类化合物,基于此原理建立了香精香料中TBHQ的快速比色检测方法。米氏方程动力学模型研究结果表明,Mn_(3)O_(4)/Au复合纳米酶的催化活性远高于Mn_(3)O_(4)和辣根过氧化物酶(HRP)。此外,研究表明金纳米粒子(Au NPs)的加入通过提升电子转移效率,可显著提高复合纳米酶的模拟酶活性。在最优条件下,方法在5~200 mg/kg范围内呈现良好的线性,对TBHQ的检出限为0.6 mg/kg,实际香精样品中TBHQ的加标回收率在93.6%~102.2%范围内,相对标准偏差<5.2%。实际样品中存在的共存物质和其它结构类似的合成酚类抗氧化剂,对所建立的方法几乎无干扰作用,其检测结果也完全可以满足国家标准中对于TBHQ的检测需求。