Electrocatalytic reductions of nitrite, nitric oxide, and nitrous oxide by thermophilic cytochrome P450 CYP119 in film-modified electrodes and an analytical comparison of its catalytic activities with myoglobin

Previous investigations of nitrite and nitric oxide reduction by myoglobin in surfactant film modified electrodes characterized several distinct steps in the denitrification pathway, including isolation of a nitroxyl adduct similar to that proposed in the P450nor catalytic cycle. To investigate the effect of the axial ligand on these biomimetic reductions, we report here a comparison of the electrocatalytic activity of myoglobin (Mb) with a thermophilic cytochrome P450 CYP119. Electrocatalytic nitrite reduction by CYP119 is very similar to that by Mb: two catalytic waves at analogous potentials are observed, the first corresponding to the reduction of nitric oxide, the second to the production of ammonia. CYP119 is a much more selective catalyst, giving almost exclusively ammonia during the initial half-hour of reductive electrolysis of nitrite. More careful investigations of specific steps in the catalytic cycle show comparable rates of nitrite dehydration and almost identical potentials and lifetimes for ferrous nitroxyl intermediate (Fe(II)-NO(-)) in CYP119 and Mb. The catalytic efficiency of nitric oxide reduction is reduced for CYP119 as compared to Mb, attributable to both a lower affinity of the protein for NO and a decreased rate of N-N coupling. Isotopic labeling studies show ammonia incorporation into nitrous oxide produced during nitrite reduction, as has been termed co-denitrification for certain bacterial and fungal nitrite reductases. Mb has a much higher co-denitrification activity than CYP119. Conversely, CYP119 is shown to be slightly more efficient at the two-electron reduction of N(2)O to N(2). These results suggest that thiolate ligation does not significantly alter the catalytic reactivity, but the dramatic difference in product distribution may suggest an important role for protein stability in the selectivity of biocatalysts.     

Fe对Pt-Fe/C催化剂电催化氧还原反应活性的影响

制备了用作直接甲醇燃料电池的碳载Pt-Fe(Pt-Fe/C)阴极催化剂, X射线能量色散谱(EDX)、X射线衍射谱和电化学测量的结果表明, 在Pt-Fe/C催化剂中, Fe以3种形式存在. 质量分数大约为20％的Fe进入Pt的晶格, 形成Pt-Fe合金, 质量分数大约为80％的Fe没有进入Pt的晶格而以Fe和Fe2O3的形式单独存在. 该催化剂经酸处理后, 非合金化Fe和Fe2O3被溶解, 而使Pt-Fe/C催化剂的电化学活性比表面积要比未经酸处理前的增加约30％左右, 导致Pt-Fe/C催化剂对氧还原的电催化活性优于未经酸处理前的Pt-Fe/C催化剂. 研究结果表明, Pt-Fe/C催化剂的电化学活性比表面积对氧还原的电催化活性起重要的作用, 另外, 只有与Pt形成合金的Fe能提高Pt对氧还原的电催化活性, 而非合金化的Fe对Pt催化剂对氧还原的电催化活性基本没有影响.     

Fabrication of electroactive layer-by-layer films of myoglobin with gold nanoparticles of different sizes

Alternate adsorption of oppositely charged myoglobin (Mb) and gold nanoparticles with different sizes were used to assemble {Au/Mb}n layer-by-layer films on solid surfaces by electrostatic interaction between them. The direct electrochemistry of Mb was realized in {Au/Mb}n films at pyrolytic graphite (PG) electrodes, showing a pair of well-defined, nearly reversible cyclic voltammetry (CV) peaks for the Mb heme FeIII/FeII redox couple. Quartz crystal microbalance (QCM), electrochemical impedance spectroscopy (EIS), and CV were used to monitor or confirm the growth of the films. Compared with other Mb layer-by-layer films with nonconductive nanoparticles or polyions, {Au/Mb}n films showed much improved properties, such as smaller electron-transfer resistance (Rct) measured by EIS with Fe(CN)3-/4- redox probe, higher maximum surface concentration of electroactive Mb (Gamma*max), and better electrocatalytic activity toward reduction of O2 and H2O2, mainly because of the good conductivity of Au nanoparticles. Because of the high biocompatibility of Au nanoparticles, adsorbed Mb in the films retained its near native structure and biocatalytic activity. The size effect of Au nanoparticles on the electrochemical and electrocatalytic activity of Mb in {Au/Mb}n films was investigated, demonstrating that the {Au/Mb}n films assembled with smaller-sized Au nanoparticles have smaller Rct, higher Gamma*max, and better biocatalytic reactivity than those with larger size.     

Electrocatalytically Activating and Reducing N2 Molecule by Tuning Activity of Local Hydrogen Radical

Decarbonizing N₂ conversion is particularly challenging, but essential for sustainable development of industry and agriculture. Herein, we achieve electrocatalytic activation/reduction of N₂ on X/Fe−N−C (X=Pd, Ir and Pt) dual-atom catalysts under ambient condition. We provide solid experimental evidence that local hydrogen radical (H*) generated on the X site of the X/Fe−N−C catalysts can participate in the activation/reduction of N₂ adsorbed on the Fe site. More importantly, we reveal that the reactivity of X/Fe−N−C catalysts for N₂ activation/reduction can be well adjusted by the activity of H* generated on the X site, i.e., the interaction between the X−H bond. Specifically, X/Fe−N−C catalyst with the weakest X−H bonding exhibits the highest H* activity, which is beneficial to the subsequent cleavage of X−H bond for N₂ hydrogenation. With the most active H*, the Pd/Fe dual-atom site promotes the turnover frequency of N₂ reduction by up to 10 times compared with the pristine Fe site.     

Metal-catalyzed anaerobic disproportionation of hydroxylamine. Role of diazene and nitroxyl intermediates in the formation of N2, N2O, NO+, and NH3

The catalytic disproportionation of NH(2)OH has been studied in anaerobic aqueous solution, pH 6-9.3, at 25.0 degrees C, with Na(3)[Fe(CN)(5)NH(3)].3H(2)O as a precursor of the catalyst, [Fe(II)(CN)(5)H(2)O](3)(-). The oxidation products are N(2), N(2)O, and NO(+) (bound in the nitroprusside ion, NP), and NH(3) is the reduction product. The yields of N(2)/N(2)O increase with pH and with the concentration of NH(2)OH. Fast regime conditions involve a chain process initiated by the NH(2) radical, generated upon coordination of NH(2)OH to [Fe(II)(CN)(5)H(2)O](3)(-). NH(3) and nitroxyl, HNO, are formed in this fast process, and HNO leads to the production of N(2), N(2)O, and NP. An intermediate absorbing at 440 nm is always observed, whose formation and decay depend on the medium conditions. It was identified by UV-vis, RR, and (15)NMR spectroscopies as the diazene-bound [Fe(II)(CN)(5)N(2)H(2)](3)(-) ion and is formed in a competitive process with the radical path, still under the fast regime. At high pH's or NH(2)OH concentrations, an inhibited regime is reached, with slow production of only N(2) and NH(3). The stable red diazene-bridged [(NC)(5)FeHN=NHFe(CN)(5)](6)(-) ion is formed at an advanced degree of NH(2)OH consumption.     

单源MOF衍生具有三维有序大孔结构的氮掺杂碳包覆铁-氮合金复合材料用于高效氧还原

氧还原反应在一些能源转换系统如金属-空气电池中起着至关重要的作用.目前贵金属基材料(Pt/C)被认为是最有效的氧还原电催化剂,然而价格昂贵和储量有限等因素限制了它的商业化应用,因此探索高效的非贵金属氧还原电催化剂具有重要的意义.近年来,负载过渡金属铁的多孔碳催化剂由于独特的结构和优异的氧还原催化活性成为替代铂基催化剂最有潜力的候选者.该类材料的合成通常采用直接煅烧含有氮源、碳源和铁盐的混合前驱体的制备方法,但是热解时材料的多孔结构以及活性位点的均匀分布很难得到有效的控制.近年来,金属有机框架(MOFs)由于其多孔结构和组成可控等优点而经常被用作自牺牲模板来制备负载铁基纳米材料的多孔碳催化剂,并表现出优异的电催化活性.目前以MOF为前驱体制备高活性的载铁氮掺杂碳复合材料通常需要引入额外的氮源或铁源,因此选择氮含量丰富的铁基MOF材料作为单源前驱体制备载铁氮掺杂多孔碳复合材料具有重要的意义.除此之外,具有多级孔隙率的催化剂可以改善反应时的传质过程,同时有序交联的网络结构能够提供连续的电子传输.本文报道了一种简单可控的制备具有三维有序大孔结构的载铁氮掺杂多孔碳复合催化剂的合成方法,该材料表现出优异的电催化氧气还原性能和优异的催化稳定性.首先,以氮含量丰富的双氰胺和吡嗪配体所构筑的Fe-MOF作为前驱体,利用具有均一尺寸的聚苯乙烯微球作为造孔剂,合成得到了具有三维有序大孔结构的Fe-MOF前驱体,然后通过高温煅烧该单源前驱体制备得到具有三维有序大孔结构的氮掺杂多孔碳包覆铁-氮合金的复合型催化剂(3DOM Fe/Fe-NA@NC).扫描电镜和透射电镜结果表明,材料内形成了有序交联的大孔结构;氮气吸附测试表明,刻蚀之后材料的比表面积明显增加,结合分级多孔特性可以共同促进催化反应的传质过程.粉末X射线衍射结果证实了多孔碳材料中铁和铁-氮合金物种的成功合成.电化学测试结果表明,在0.1 M KOH电解液中,3DOM Fe/Fe-NA@NC-800催化剂表现出优于Pt/C的氧还原活性,其半波电位(E_1/2)为0.88 V,大于商业Pt/C的半波电位(E_1/2=0.85 V).同时,3DOM Fe/Fe-NA@NC-800表现出更加优异的稳定性,经过20000 s测试后,其电流保持率为94%,而Pt/C只保持了78%.关于活性位点探究的对比实验证明在所制备的复合材料中,铁物种作为高效的活性位点参与了电催化氧还原反应,与氮掺杂多孔碳之间的协同作用共同主导了3DOM Fe/Fe-NA@NC优异的氧还原活性.得益于其优异的氧还原活性,将其作为阴极活性材料组装为锌-空气电池进一步探究了其在实际应用中的可行性.本结果拓宽了高效的铁基催化剂的类型,同时也为制备封装非贵金属的多孔碳基催化剂提供了实验指导和理论依据.     

Role of adsorbed NO in N2O decomposition over iron-containing ZSM-5 catalysts at low temperatures

Transient response and temperature-programmed desorption/reaction (TPD/TPR) methods were used to study the formation of adsorbed NO(x) from N2O and its effect during N2O decomposition to O2 and N2 over FeZSM-5 catalysts at temperatures below 653 K. The reaction proceeds via the atomic oxygen (O)(Fe) loading from N2O on extraframework active Fe(II) sites followed by its recombination/desorption as the rate-limiting step. The slow formation of surface NO(x,ads) species was observed from N2O catalyzing the N2O decomposition. This autocatalytic effect was assigned to the formation of NO(2,ads) species from NO(ads) and (O)(Fe) leading to facilitation of (O)(Fe) recombination/desorption. Mononitrosyl Fe2+(NO) and nitro (NO(2,ads)) species were found by diffuse reflectance infrared fourier transform spectroscopy (DRIFTS) in situ at 603 K when N2O was introduced into NO-containing flow passing through the catalyst. The presence of NO(x,ads) does not inhibit the surface oxygen loading from N2O at 523 K as observed by transient response. However, the reactivity of (O)(Fe) toward CO oxidation at low temperatures (<523 K) is drastically diminished. Surface NO(x) species probably block the sites necessary for CO activation, which are in the vicinity of the loaded atomic oxygen.     

Fe 含量对 FeAlPO-5 催化剂上甲烷还原 N2O 反应的影响

 采用水热法制备了一系列不同 Fe 含量的 FeAlPO-5 催化剂, 并将其用于 CH4 催化还原 N2O 反应. 结果表明, FeAlPO-5 催化剂在此反应中表现出较高的低温活性. N2 吸附、X 射线衍射和紫外可见光谱等表征结果表明, 水热法制备的 FeAlPO-5 催化剂具有典型的 AlPO-5 分子筛结构. Fe 含量对催化剂的活性及催化剂中 Fe 物种的分布有较大影响, 当 w(Fe) = 2.4% 时, 催化剂除含有可促使 CH4 低温还原 N2O 反应的孤立态的 Fe 物种和低聚态的 Fe 物种外, 还含有相当数量的可使 N2O 直接催化分解的纳米态的 Fe 物种.     

S掺杂促进Fe/N/C催化剂氧还原活性的实验与理论研究

向Fe/N/C非贵金属催化剂中再引入S掺杂是进一步提高其氧还原催化活性的有效方法。为了探究活性提高的原因,本文以三聚氰胺-甲醛树脂为前驱体,氯化钙为模板,氯化铁为铁源,通过添加硫氰化钾(KSCN)来控制热解催化剂的S掺杂量。通过对比分析催化剂的物化性质,结合密度泛函理论(DFT)计算,分析S掺杂促进Fe/N/C催化剂氧还原活性的原因。透射电子显微镜(TEM)和N_2吸脱附等温线测试结果表明,S元素可抑制含铁纳米粒子的形成,促使形成多孔碳结构,提高比表面积。X射线光电子能谱(XPS)结果表明,适量S前驱体可实现较高的S掺杂含量,得到最优的活性,过量的S反而会导致Fe和S的掺杂量同时降低,影响活性。DFT计算结果表明在Fe-N_4大环中引入S掺杂,可增强O_2分子和中间体OOH与Fe-N_4结构中的Fe的相互作用,促进形成Fe―O键,从而导致O―O键的键能显著降低,为后续反应O―O键的断裂提供可能,促进ORR反应的进行。     

FeO+(6Σ+)催化CO还原N2O的理论研究

在B3LYP/6-311+G(2d)//B3LYP/6-31G(d)计算水平下, 考察了FeO+(6Σ+)分子如何催化CO还原N2O微观机理. 计算结果表明, FeO+(6Σ+)是一种有效的催化剂, 其可从N2O中夺取一个O原子, 然后再传递给CO, 完成整个氧转移过程. 结果发现, 反应中可能生成各种过氧[Fe(O2)+]或双端氧(OFeO+)物种, 其中前者比较稳定, 后者更活泼.     

Pd-Fe/C催化剂中Fe的状态对氧还原电催化活性的影响

直接甲醇燃料电池;Pd-Fe/C催化剂;氧还原;合金化     

微量Pt和Pd对Fe_2O_3/ZrO_2催化剂结构与性能的影响

用ＸＲＤ、ＴＰＲ及固定床微反应器技术研究了微量Ｐｔ 和Ｐｄ 对Ｆｅ２Ｏ３／ＺｒＯ２ 催化剂结构及性能的影响。结果表明，活性组分Ｆｅ３ ＋ 与载体ＺｒＯ２ 之间的相互作用会阻止载体从无定形ＺｒＯ２ 到ｔ－ＺｒＯ２ 进而ｍ － ＺｒＯ２ 的转变，同时，促进Ｆｅ２Ｏ３ 在ＺｒＯ２ 表面的分散。微量Ｐｔ 或Ｐｄ 的加入对Ｆｅ２Ｏ３ 在ＺｒＯ２ 上的分散状态无明显影响，但使Ｆｅ２Ｏ３／ＺｒＯ２ 的还原性能发生明显变化，表层Ｆｅ２Ｏ３ 的还原性显著增强，导致Ｍ－ Ｆｅ２Ｏ３／ＺｒＯ２ 催化剂在ＮＯ＋ ＣＯ反应中有更高的催化活性。Ｎ２ 生成的选择性次序为Ｆｅ２Ｏ３／ＺｒＯ２ ＞ Ｐｄ － Ｆｅ２Ｏ３／ＺｒＯ２ ＞ Ｐｔ－ Ｆｅ２Ｏ３／ＺｒＯ２ ＞ Ｐｄ／ＺｒＯ２ ＞ Ｐｔ／ＺｒＯ２ 。     

Myoglobin/sol-gel film modified electrode: direct electrochemistry and electrochemical catalysis

Direct electrochemical and electrocatalytic behavior of myoglobin (Mb) immobilized on carbon paste electrode (CPE) by a silica sol-gel film derived from tetraethyl orthosilicate was investigated for the first time. Mb/sol-gel film modified electrodes show a pair of well-defined and nearly reversible cyclic voltammetric peaks for the Mb Fe(III)/Fe(II) redox couple at about -0.298 V (vs Ag/AgCl) in a pH 7.0 phosphate buffer solution. The formal potential of the Mb heme Fe(III)/Fe(II) couple shifted linearly with pH with a slope of 52.4 mV/pH, denoting that an electron transfer accompanies single-proton transportation. An FTIR and UV-vis spectroscopy study confirms that the secondary structure of Mb immobilized on an electrode by a sol-gel film still maintains the original arrangement. The immobilized Mb displays the features of a peroxidase and acts in an electrocatalytic manner in the reduction of oxygen, trichloroacetic acid (TCA), and nitrite. In comparison to other electrodes, the chemically modified electrodes used in this study for direct electrochemistry and electrocatalysis of Mb are easy to fabricate and fairly inexpensive. Consequently, the Mb/sol-gel film modified electrode provides a convenient way to perform electrochemical research on this kind of protein. It also has potential use in the fabrication of bioreactors and third-generation biosensors.     

Self-sacrificial template synthesis of Fe,N co-doped porous carbon as efficient oxygen reduction electrocatalysts towards Zn-air battery application

Designing highly efficient non-precious based electrocatalysts for oxygen reduction reaction（ORR） is of significance for the rapid development of metal-air batteries.Herein,a hydrothermal-pyrolysis method is employed to fabricate Fe,N co-doped porous carbon materials as effective ORR electrocatalyst through adopting graphitic carbon nitride（g-C₃ N₄） as both the self-sacrificial templates and N sources.The gC₃ N₄ provides a high concentration of unsatur...     

The photochemistry of [Fe(III)N3(cyclam-ac)]PF6 at 266 nm

The photochemistry of iron azido complexes is quite challenging and poorly understood. For example, the photochemical decomposition of [Fe(III)N(3)(cyclam-ac)]PF(6) ([1]PF(6)), where cyclam-ac represents the 1,4,8,11-tetraazacyclotetradecane-1-acetate ligand, has been shown to be wavelength-dependent, leading either to the rare high-valent iron(V) nitrido complex [Fe(V)N(cyclam-ac)]PF(6) ([3]PF(6)) after cleavage of the azide N(α)-N(β) bond, or to a photoreduced Fe(II) species after Fe-N(azide) bond homolysis. The mechanistic details of this intriguing reactivity have never been studied in detail. Here, the photochemistry of 1 in acetonitrile solution at room temperature has been investigated using step-scan and rapid-scan time-resolved Fourier transform infrared (FTIR) spectroscopy following a 266 nm, 10 ns pulsed laser excitation. Using carbon monoxide as a quencher for the primary iron-containing photochemical product, it is shown that 266 nm excitation of 1 results exclusively in the cleavage of the Fe-N(azide) bond, as was suspected from earlier steady-state irradiation studies. In argon-purged solutions of [1]PF(6), the solvent-stabilized complex cation [Fe(II)(CH(3)CN)(cyclam-ac)](+) (2red) together with the azide radical (N(3)(.)) is formed with a relative yield of 80%, as evidenced by the appearance of their characteristic vibrational resonances. Strikingly, step-scan experiments with a higher time resolution reveal the formation of azide anions (N(3)(-)) during the first 500 ns after photolysis, with a yield of 20%. These azide ions can subsequently react thermally with 2red to form [Fe(II)N(3)(cyclam-ac)] (1red) as a secondary product of the photochemical decomposition of 1. Molecular oxygen was further used to quench 1red and 2red to form what seems to be the elusive complex [Fe(O(2))(cyclam-ac)](+) (6).     

Multifunctional nanocomposites constructed from Fe3O4-Au nanoparticle cores and a porous silica shell in the solution phase

This work is directed towards the synthesis of multifunctional nanoparticles composed of Fe(3)O(4)-Au nanocomposite cores and a porous silica shell (Fe(3)O(4)-Au/pSiO(2)), aimed at ensuring the stability, magnetic, and optical properties of magnetic-gold nanocomposite simultaneously. The prepared Fe(3)O(4)-Au/pSiO(2) core/shell nanoparticles are characterized by means of TEM, N(2) adsorption-desorption isotherms, FTIR, XRD, UV-vis, and VSM. Meanwhile, as an example of the applications, catalytic activity of the porous silica shell-encapsulated Fe(3)O(4)-Au nanoparticles is investigated by choosing a model reaction, reduction of o-nitroaniline to benzenediamine by NaBH(4). Due to the existence of porous silica shells, the reaction with Fe(3)O(4)-Au/pSiO(2) core/shell nanoparticles as a catalyst follows second-order kinetics with the rate constant (k) of about 0.0165 l mol(-1) s(-1), remarkably different from the first-order kinetics with the k of about 0.002 s(-1) for the reduction reaction with the core Fe(3)O(4)-Au nanoparticles as a catalyst.     

介孔结构Fe/N/C作为质子交换膜燃料电池氧还原催化剂

燃料电池具有高效、低排放等优势,非常有希望作为未来电动汽车的能源转化装置.目前,燃料电池的商业化受制于昂贵的铂基催化剂,特别是动力学迟缓的阴极氧还原反应(ORR)铂催化剂. Fe/N/C被认为是最有潜力的ORR非贵金属催化剂,但其活性仍远低于Pt催化剂,必须依靠增加载量来弥补其与Pt催化剂的活性差距.然而,较厚的催化层(~100mm)会降低阴极传质速率.因此,改善Fe/N/C阴极的传质是提高电池性能的重要途径.
　　本文选择高N含量的2-氨基苯并咪唑(ABI)为氮源,通过水热聚合包覆在碳黑表面,然后掺入FeCl3,经高温热解/酸洗制备了Fe/N/C-ABI催化剂,并与基于间苯二胺的微孔型Fe/N/C催化剂(Fe/N/C-PmPDA)进行比较. Ar等温吸附-脱附结果表明, Fe/N/C-ABI催化剂具有较高的比表面积(662 m2/g)和丰富的双级孔结构(微孔和介孔);透射电镜表征显示Fe/N/C-ABI催化剂具有中空结构,介孔孔径大约为10–25 nm.而Fe/N/C-PmPDA催化剂具有相当的比表面积(656 m2/g),但以微孔为主,基本不含介孔.旋转环圆盘电极(RRDE)测试表明,在0.1 mol/L H2SO4溶液中, Fe/N/C-ABI催化剂的起始还原电位为0.92 V,在0.8 V电位下质量电流密度可达9.21 A/g;而Fe/N/C-PmPDA催化剂具有相近的起始电位,但具有更高的催化活性,质量电流密度为13.4 A/g.氢氧燃料电池(PEMFC)系统测试结果表明, Fe/N/C-ABI催化剂在1个背压和80oC测试条件下的最大功率密度达710 mW/cm2,高于Fe/N/C-PmPDA催化剂(616 mW/cm2).燃料电池与RRDE测试活性顺序的差异归结于Fe/N/C-ABI的中空球状结构. PEMFC工作时阴极会产生大量的水,很容易堵塞氧气传输通道. Fe/N/C-ABI的介孔结构可以作为水的产生和排除的缓存空间,也有利于提高O2传质,从而提高燃料电池性能.本文为具有高传质速率的Fe/N/C催化剂研制提供了一种新思路.     

Diversity of new structural types in polynuclear iron chemistry with a tridentate N,N,O ligand

The syntheses, crystal structures, and magnetochemical characterization of four new iron clusters [Fe7O4(O2CPh)11(dmem)2] (1), [Fe7O4(O2CMe)11(dmem)2] (2), [Fe6O2(OH)4(O2CBut)8(dmem)2] (3), and [Fe3O(O2CBut)2(N3)3(dmem)2] (4) (dmemH=Me2NCH2CH2N(Me)CH2CH2OH)=2-{[2-(dimethylamino)ethyl]methylamino}ethanol) are reported. The reaction of dmemH with [Fe3O(O2CR)6(H2O)3](NO3) (R=Ph (1), Me (2), and But (3)) gave 1, 2, and 3, respectively, whereas 4 was obtained from the reaction of 3 with sodium azide. The complexes all possess rare or novel core topologies. The core of 1 comprises two [Fe4(mu3-O)2]8+ butterfly units sharing a common body Fe atom. The core of 2 consists of a [Fe3O3] ring with each doubly bridging O2- ion becoming mu3 by also bridging to a third, external Fe atom; a seventh Fe atom is attached on the outside of this core via an additional mu3-O2- ion. The core of 3 consists of a [Fe4(mu3-O)2]8+ butterfly unit with an Fe atom attached above and below this by bridging O atoms. Finally, the core of 4 is an isosceles triangle bridged by a mu3-O2- ion with a rare T-shaped geometry and with the azide groups all bound terminally. Variable-temperature, solid-state dc, and ac magnetization studies were carried out on complexes 1-4 in the 5.0-300 K range. Fitting of the obtained magnetization (M) vs field (H) and temperature (T) data by matrix diagonalization and including only axial anisotropy (zero-field splitting) established that 1, 2, and 4 each possess an S=5/2 ground state spin, whereas 3 has an S=5 ground state. As is usually the case, good fits of the magnetization data could be obtained with both positive and negative D values. To obtain more accurate values and to determine the sign of D, high-frequency EPR studies were carried out on single crystals of representative complexes 1.4MeCN and 3.2MeCN, and these gave D=+0.62 cm-1 and |E|>or=0.067 cm-1 for 1.4MeCN and D=-0.25 cm-1 for 3.2MeCN. The magnetic susceptibility data for 4 were fit to the theoretical chiM vs T expression derived by the use of an isotropic Heisenberg spin Hamiltonian and the Van Vleck equation, and this revealed the pairwise exchange parameters to be antiferromagnetic with values of Ja=-3.6 cm-1 and Jb=-45.9 cm-1. The combined results demonstrate the ligating flexibility of dmem and its usefulness in the synthesis of a variety of Fex molecular species.     

N2O活化的Fe/ZSM-5表面活性氧的表征(英)

Temperature-programmed reduction (H₂-TPR) was employed to quantitatively characterize the active oxygen species generated from a high Fe-loading Fe/ZSM-5 catalyst exposed to N₂O at 250 ℃. [Fe-O-Fe]²⁺ dimer was determined as the active iron complex for N₂O decomposition to produce the active oxygen. Reduction of Fe³⁺ to Fe²⁺ by H₂ in the dimer and removal of OH^- groups from Fe²⁺ dimer by heating Fe/ZSM-5 to 700 ℃ were the prerequisites for the formation of this active Fe complex. A linear correlation with a slope of 1.0 between the amount of [Fe-O-Fe]²⁺ and that of active oxygen species was observed. Maximum amount of active oxygen species can be generated by reducing Fe/ZSM-5 catalyst with H₂ at the temperatures over 500 ℃ and then heating the resulting product in Ar to 700 ℃, followed by N₂O exposure at 250 ℃. The ratio of the total number of oxygen atoms (Ode) deposited by interaction of [Fe-O-Fe]²⁺ with N₂O to the amount of [Fe-O-Fe]²⁺ was 2. However, not all the deposited oxygen atoms were active oxygen (O_a); the ratio of O_a and O_de was 0.5. The iron dimer complex composing active oxygen is a five-atom ion [Fe₂O₃]²⁺; the most probable structure is as follows:     

Iron(II) complexes with bio-inspired N,N,O ligands as oxidation catalysts: olefin epoxidation and cis-dihydroxylation

The Rieske dioxygenases are a group of non-heme iron enzymes, which catalyze the stereospecific cis-dihydroxylation of its substrates. Herein, we report the iron(II) coordination chemistry of the ligands 3,3-bis(1-methylimidazol-2-yl)propionate (L1) and its neutral propyl ester analogue propyl 3,3-bis(1-methylimidazol-2-yl)propionate (PrL1). The molecular structures of two iron(II) complexes with PrL1 were determined and two different coordination modes of the ligand were observed. In [Fe(II)(PrL1)(2)](BPh(4))(2) (3) the ligand is facially coordinated to the metal with an N,N,O donor set, whereas in [Fe(II)(PrL1)(2)(MeOH)(2)](OTf)(2) (4) a bidentate N,N binding mode is found. In 4, the solvent molecules are in a cis arrangement with respect to each other. Complex 4 is a close structural mimic of the crystallographically characterized non-heme iron(II) enzyme apocarotenoid-15-15'-oxygenase (APO). The mechanistic features of APO are thought to be similar to those of the Rieske oxygenases, the original inspiration for this work. The non-heme iron complexes [Fe(II)(PrL1)(2)](OTf)(2) (2) and [Fe(II)(PrL1)(2)](BPh(4))(2) (3) were tested in olefin oxidation reactions with H(2)O(2) as the terminal oxidant. Whereas 2 was an active catalyst and both epoxide and cis-dihydroxylation products were observed, 3 showed negligible activity under the same conditions, illustrating the importance of the anion in the reaction.