基于RUSBoost算法的地铁盾构施工安全预警模型研究

为应对地铁盾构施工事故频发的问题,构建基于RUSBoost算法的地铁盾构施工安全预警模型,以空间单元为对象提取样本数据集训练模型,训练好的模型可以实时监控施工现场的安全状态,预警潜在的事故。结果表明:该安全预警模型具有良好的泛化能力,预测准确率较高,且运行时间短,具备一定的可推广性。

《中国人手腕骨发育标准—中华05》RUS-CHN法在当代少年运动员中的应用

目的：探讨《中国人手腕骨发育标准-中华05》RUS—CHN法在当代少年运动员中的应用效果。方法：分别采用RUS—CHN法和原骨龄标准CHN法，评价245名8～18岁不同项目少年运动员的左手腕骨骨龄。结果：不同运动项目的少年运动员，RUS—CHN骨龄与生活年龄间的差异无显著性，但原标准CHN法骨龄与生活年龄之间的差值为正数（0．71～0．91岁），且差异显著（P〈0．01）。与原标准CHN方法相比，新标准RUS—CHN法骨龄读数组距更细，频数分布更均匀，并减少了骨龄与生活年龄差值等于或大于2岁的少年运动员的例数。结论：当代少年运动员表现出了生长发育加速的长期趋势，《中国人手腕骨发育标准-中华05》RUS—CHN法更适用于当代少年运动员。

RuSi_n(n=1～6)团簇的结构、稳定性和电子性质的密度泛函研究

运用杂化密度泛函理论方法在（U）B3LYP/Lan L2DZ水平研究了Ru Sin（n=1~6）团簇体系的稳定结构及电子性质.结果发现：Ru Sin（n=1~6）团簇基本保持了纯硅团簇的框架.对原子平均束缚能和分裂能的计算表明,Ru Si6团簇是Ru Sin（n=1~6）团簇中热力学稳定性最强的.对自然电荷分布的研究结果发现,Ru Sin（n=2,4~6）团簇的最低能结构出现电荷反转现象.HOMO-LUMO能隙的研究结果表明掺入钌原子后团簇的化学活性增强了,且Ru Si的化学活性是Ru Sin（n=1~6）团簇最强的.通过对团簇磁矩的研究发现,Ru Si和Ru Si3团簇具有了磁性,其余团簇的总磁矩为零,且Ru Sin（n=1~6）团簇中各原子对团簇总磁矩的贡献不同.

RUS-CHN图谱骨龄评价法用于推侧青少年年龄

目的 探讨RUS—CHN（RC）图谱评价法用于13-18岁青少年年龄推侧的应用价值。方法4424名（男2272，女2152）13—18岁正常城市汉族青少年，以简化RUS—CHN法建立手腕骨发育等级图谱。另以1048名（男530，女518）13～18岁青少年为检验样本，比较不同方法骨龄与生活年龄的差异。结果RUS—CHN图谱法可仅评价桡骨、尺骨远端和第Ⅲ指的4块掌指骨骺。检验样本中男14—17岁、女13～16岁年龄组，RC图谱法骨龄与生活年龄之间的差异均无统计学显著性（Wilcoxon符号秩和检验，P〉0．05），对男18岁、女17岁组出现显著性差异的可能原因进行了讨论。结论RUS—CHN图谱法骨龄适用于男13～18岁、女13～17岁青少年的年龄推测。

拟南芥amiR-RUS4 ms35雄性不育双突变体的构建、鉴定及表型分析

控制雄性育性是研究植物生殖和选择育种的一个重要目标。对雄性不育分子机制的深入理解将为控制雄性育性和杂种繁育提供有效途径。利用人工micro RNA技术对DUF647蛋白家族成员RUS4基因进行特异沉默,结果发现,ami R-RUS4植株败育,药室内壁次生加厚异常,花药不开裂,表明RUS4与药室内壁的木质化有关。MS35/MYB26是木质素生物合成途径上游一个重要的激活因子,为了进一步了解RUS4和MYB26在调控花药药室内壁次生加厚过程中的作用,以ms35为母本、ami R-RUS4为父本进行人工杂交,得到杂交子2代(F2);并对杂交子2代(F2)的基因型、表型和基因表达进行了鉴定,结果获得一个纯合的ami R-RUS4 ms35双突变体,这为进一步分析RUS4和MS35在调控药室内壁次生加厚中的作用提供了宝贵的试验材料。

Geochemical and geochronological characteristics of the Um Rus granite intrusion and associated gold deposit,Eastern Desert,Egypt

The Um Rus tonalite-granodiorite intrusion(~6 km2)occurs at the eastern end of the Neoproterozoic,ENE-trending Wadi Muba rak shear belt in the Central Eastern Desert of Egypt.Gold-bearing quartz veins hosted by the Um Rus intrusion were mined intermittently,and initially by the ancient Egyptians and until the early 1900 s.The relationship between the gold mineralization,host intrusion,and regional structures has always been unclear.We present new geochemical and geochronological data that help to define the tectonic environment and age of the Um Rus intrusion.In addition,field studies are integrated with EPMA and LA-ICP-MS data for gold-associated sulfides to better understand the formation and distribution of gold mineralization.The bulk-rock geochemical data of fresh host rocks indicate a calc-alkaline,metaluminous to mildly peraluminous,I-type granite signature.Their trace element composition reflects a tectonic setting intermediate between subduction-related and within-plate environments,presumably transitional between syn-and post-collisional stages.The crystallization age of the Um Rus intrusion was determined by in situ SHRIMP 206 Pb/238 U and 207Pb/235U measurements on accessory monazite grains.The resultant monazite U-Pb weighted mean age(643±9 Ma;MSWD 1.8)roughly overlaps existing geochronological data for similar granitic intrusions that are confined to major shear systems and are locally associated with gold mineralization in the Central Eastrn Desert(e.g.,Fawakhir and Hangaliya).This age is also consistent with magmatism recognized as concomitant to transpressional tectonics(D2:~650 Ma)during the evolution of the Wadi Mubark belt.Formation of the gold-bearing quartz veins in NNE-SSW and N-S striking fault segments was likely linked to the change from transpressional to transtensional tectonics and terrane exhumation(D3:620-580 Ma).The development of N-S throughgoing fault arrays and dike swarms(~595 Ma)led to heterogeneous deformation and recrystallization of the mineralized quartz veins.Ore minerals in the auriferous quartz veins include ubiquitous pyrite and arsenopyrite,with less abundant pyrrhotite,chalcopyrite,sphalerite,and galena.Uncommon pentlandite,gersdorffite,and cobaltite inclusions hosted in quartz veins with meladiorite slivers are interpreted as pre-ore sulfide phases.The gold-sulfide paragenesis encompasses an early pyrite-arsenopyrite±loellingite assemblage,a transitional pyrite-arsenopyrite assemblage,and a late pyrrhotite-chalcopyrite-sphalerite±galena assemblage.Free-milling gold/electrum grains(10 sμm-long)are scattered in extensively deformed vein quartz and in and adjacent to sulfide grains.Marcasite,malachite,and nodular goethite are authigenic alteration phases after pyrrhotite,chalcopyrite,and pyrite and arsenopyrite,respectively.A combined ore petrography,EPMA,and LA-ICP-MS study distinguishes morphological and compositional differences in the early and transitional pyrites(PyⅠ,PyⅡ)and arsenopyrite(ApyⅠ,ApyⅡ).Py I forms uncommon small euhedral inclusions in later PyⅡand Apy II.PyⅡforms large subhedral crystals with porous inner zones and massive outer zones,separated by narrow As-rich irregular mantles.The Fe and As contents in PyⅡare variable,and the LA-ICP-MS analysis shows erratic concentrations of Au(<1 to 177 ppm)and other trace elements(e.g.,Ag,Te,and Sb)in the porous inner zones,most likely related to discrete sub-microscopic sulfide inclusions.The outer massive zones have a rather homogenous composition,with consistently lower abundances of base metals and Au(mean 1.28 ppm).The early arsenopyrite(Apy I)forms fine-grained euhedral crystals enriched in Au(mean 17.7 ppm)and many other trace elements(i.e.,Ni,Co,Se,Ag,Sb,Te,Hg,and Bi).On the other hand,ApyⅡoccurs as coarsegrained subhedral crystals with lower and less variable concentrations of Au(mean 4 ppm).Elevated concentrations of Au(max.327 ppm)and other trace elements are measured in fragmented and aggregated pyrite and arsenopyrite grains,whereas the undeformed intact zones of the same grains are poor in all trace elements.The occurrence of gold/electrum as secondary inclusions in deformed pyrite and arsenopyrite crystals indicates that gold introduction was relatively late in the paragenesis.The LAICP-MS results are consistent with gold redistribution by the N-S though-going faults/dikes overprinted the earlier NNW-SSE quartz veins in the southeastern part of the intrusion,where the underground mining is concentrated.Formation of the Um Rus intrusion and gold-bearing quartz veins can be related to the evolution of the Wadi Mubarak shear belt,where the granitic intrusion formed during or just subsequent to D2 and provided dilatation spaces for gold-quartz vein deposition when deformed by D3 structures.

Sensitization of Microporous Nanocrystalline TiO_2 Electrode with Quantum Sized RuS2 Particles

The microporous nanocry'sta1line TiO2 electrode with large surface roughness factor hasbeen prepared on a conducting glass support. Modification of the TiO2 electrode by in situ preparingquantum sized RuS2 particles on the surface of TiO2 electrode extends the optical absorptionspectrum and photocurrent action specmim into visible region. In addition, compared with RuS2 bulknlaterials- a blue shifi in both absorption spectrum and photocurrent action speCtrum of RuS2rriO2elcctrode is obserived and explained in terms of quantum sized effect.

RUS3108的临床试验将开始

印度Dr Reddy公司已在北爱尔兰Belfast开始心血管候选药RUS3108的Ⅰ期临床试验，研究其对动脉粥样硬化的疗效。该药是一类新药，通过诱导一种称为perleean的蛋白生成，影响动脉粥样硬化过程中的多个环节，如炎症、增生和血栓形成。为动脉粥样硬化的治疗提供新的手段。

基于fl-TiO_(2)/Pt NPs/RuSi NPs的去氧肾上腺素电化学发光传感器的构建和应用

该文采用溶剂热法制备了高度有序的花状分级二氧化钛微/纳米粒子(fl-TiO_(2)),以(3-氨基丙基)三乙氧基硅烷(APTES)做偶联剂,采用简单的合成后接枝方法制备氨基功能化的fl-TiO_(2)(fl-TiO_(2)-NH_2)。随后,通过静电作用将铂纳米粒子(Pt NPs)组装在fl-TiO_(2)-NH_2表面,制备了一种新型的fl-TiO_(2)/Pt NPs复合材料。最后,将fl-TiO_(2)/Pt NPs与RuSi NPs混合形成均匀的分散溶液,并将其固定在玻碳电极(GCE)表面,制备了一种新型的电化学发光(ECL)传感器(fl-TiO_(2)/Pt NPs/RuSi NPs/GCE)。采用扫描电镜、紫外-可见吸收光谱、X射线衍射和能谱等技术对不同材料的形貌、结构、物理性质和化学组成进行表征,循环伏安法、交流阻抗法和ECL法对所研制ECL传感器的电化学行为和ECL性能进行研究。实验结果表明,Pt NPs优异的电催化活性显著提高了RuSi NPs-三丙胺(TPrA)体系的ECL信号强度。而fl-TiO_(2)的巨大比表面积为Pt NPs和RuSi NPs提供了丰富的结合位点。因此,fl-TiO_(2)/Pt NPs可作为一种新型的共反应剂加速器和ECL信号放大器,用于提高RuSi NPs-TPrA体系的ECL发射效率。在优化实验条件下,fl-TiO_(2)/Pt NPs/RuSi NPs的ECL强度分别为fl-TiO_(2)/RuSi NPs和RuSi NPs的1.5倍和1.8倍。在去氧肾上腺素(PHE)存在下,fl-TiO_(2)/Pt NPs/RuSi NPs-TPrA体系的ECL信号发生猝灭,且ECL猝灭信号与PHE浓度的对数在1.0×10^(-7)~8.0×10^(-5)mol/L范围内呈良好的线性关系(r^(2)=0.998 4),检出限(S/N=3)为2.5×10^(-8)mol/L。该方法用于盐酸去氧肾上腺素注射液中PHE的测定,回收率为99.2%~108%。该传感器具有良好的稳定性和重现性、较高的选择性。该研究为ECL传感平台的构建提供了一种新的ECL信号放大策略,并拓宽了ECL传感器在药物分析中的应用。

RUS家族对植物生长发育的调控作用

叶绿体基因组编码许多参与光合作用和其他代谢过程的关键蛋白质,在叶绿体中合成的代谢物对于植物正常的生长发育至关重要。根对紫外线-B辐射敏感[Root-UVB(ultraviolet radiation B)-sensitive,RUS]蛋白属于叶绿体蛋白,由高度保守的DUF647结构域组成,在参与植物形态发生、物质运输和能量代谢等多种生命活动的调控中发挥作用。本文就近年来关于RUS家族在植物的胚胎发育、光形态建成、维生素B6稳态、生长素转运和花药发育等生长发育过程中的相关研究进行回顾和总结,为深入研究其在植物生长发育中的分子调控机制提供了参考。

基于TW3-C RUS法的骨龄评估方法研究

经典TW3-C RUS(Tanner and Whitehouse 3-Chinese RUS)法将手骨的关键骨骺区域严格划分为9个等级,未充分考虑骨骺发育的连续性,导致骨龄评估存在一定误差。针对该问题,本文提出一种基于TW3-C RUS法的改进骨龄评估方法。采用阈值法的思想,动态选择网络模型输出的前N个等级概率值,并将前N个概率值作为权值计算手骨的加权得分,降低由于手骨单一等级判定引起的误差。针对网络模型冗余问题,采用跨阶段局部网络(cross stage partial network,CSP-Net)轻量化深度残差网络(residual network 50,Resnext50)。实验表明,改进后的方法对男性骨龄评估的平均绝对误差(mean absolute error,MAE)为0.4214岁,女性MAE为0.4128岁,相比于经典TW3-C RUS法,骨龄评估准确率有明显提升。轻量化后的网络模型参数量为46.28 MB,相比Resnext50网络模型有明显降低。

Heterointerface engineering of Ru/RuS_(2) on N/S-doped hollow mesoporous carbon for promoting alkaline hydrogen evolution

Alkaline hydrogen evolution reaction (HER) suffers from a sluggish kinetic,which requires the elaborate catalytic interface and micro-nanoscale architecture engineering of the electrocatalysts to accelerate the water dissociation and hydrogen evolution.Herein,the heterointerface engineering was proposed for promoting the alkaline HER by constructing the highly exposed Ru/RuS_(2) heterostructures homogeneously distributed on hollow N/S-doped carbon microspheres (Ru/RuS_(2)@h-NSC).Benefited from the synergistic effect of heterointerfacial Ru/RuS_(2),the high accessibility of the active sites on both inner and outer surface of mesoporous shells and the efficient mass transport,Ru/RuS_(2)@h-NSC affords a remarkable catalytic performance with an overpotential of 26 mV@10 mA/cm^(2) for alkaline HER,outperforming most of the state-of-the-art catalysts.Further applying Ru/RuS_(2)@h-NSC and its oxidized derivate for the overall alkaline water splitting,the required cell voltage is much lower than that of the commercial Pt/C||RuO_(2)pair to achieve the same current density.Our study may allow us to guide the design of micro-nanoreactors with optimal catalytic interfaces for promising electrocatalytic applications.

Ru、Y对铸造高温合金与陶瓷界面反应的影响

在定向凝固炉中,采用相同的硅基陶瓷型芯,刚玉陶瓷型壳,熔炼工艺和定向凝固工艺制备了四种不同Ru、Y含量的单晶高温合金叶片,研究了组织稳定性提升元素Ru、抗氧化性增强元素Y对合金与陶瓷材料界面反应的影响。研究结果表明,合金中不含Ru、Y时,合金与型壳发生的界面反应主要为物理粘砂作用,未见合金元素与型壳发生明显的化学反应,合金与型芯发生轻微的界面反应,除了物理作用,还发生了Al与SiO2的化学反应。合金中添加Ru,对合金与型壳或型芯的界面反应无影响。合金中添加0.01%Y后,合金与陶瓷型壳或型芯的界面反应稍有增加,但由于其添加量较少,故影响较小。

A Comparative Study between Landmark Based and Real Time Ultrasound Guided Sub Arachnoid Block

Background: Sub arachnoid block (SAB) performed by traditional landmark palpation technique can be inaccurate. This problem is exacerbated by altered patient anatomy due to obesity and age-related changes. A pre-procedural ultrasound scan of the lumbar spine has been shown to be of benefit in guiding lumbar epidural insertion in obstetric patients. Information on the use of real-time ultrasound (RUS) guided SAB, to date, been limited. This study compared RUS guided SAB to traditional landmark guided technique in patients undergoing spinal anesthesia for different surgical procedures. Methods: This was a prospective, single center, comparative observational study conducted in the department of anesthesiology at our center. 560 patients who underwent spinal anesthesia either by landmark based technique or real-time ultrasound-guided methods. The primary outcome was the first attempt success rate of dural puncture when employing the two methods. Results: Baseline characteristics were similar in the two study groups. The first attempt success rate of dural puncture in landmark guided group was 64.3% compared to 72.6% in the ultrasound guided group. This difference was not statistically significant. The procedure performance time was significantly shorter with landmark palpation compared to use of real-time ultrasound guided method. Conclusion: Use of RUS-guided technique does not significantly improve the first attempt success rate of SAB dural puncture during spinal anesthesia compared to the traditional landmark-guided technique.

氨分解催化剂研究进展

氢能作为清洁环保的可再生能源受到全世界的关注。但氢极低的体积能量密度及易燃易爆的特点,给氢气的大规模储运带来困难和危险。氨是一种无碳的氢载体,不仅具有较高的体积和质量能量密度,还有较成熟的储存和运输技术。氨的现场制氢可以解决氢气储存和运输问题,所以氨气储氢正受到人们的广泛关注。氨分解最高效的催化剂是Ru基催化剂,但由于其高昂的价格无法实现大规模应用。在非贵金属基催化剂中,Ni基催化剂的活性最高,且其成本相对较低,被认为十分具有应用潜力。然而,Ru基和Ni基催化体系在活性和稳定性等方面仍存在一些挑战。本文综述了氨分解催化剂的最新研究进展,包括Ru基催化剂、非贵金属Fe基和Ni基催化剂及双金属催化剂等,并对目前文献中的反应机理进行了梳理。

调控等级孔UiO-66(Ce)中Ru纳米团簇的电子态、丰度和微环境用于高效催化双环戊二烯加氢

催化石油加工副产物双环戊二烯(DCPD)加氢得到的四氢双环戊二烯(THDCPD)是一种高能量密度燃料,在航空航天领域具有重要应用价值.传统DCPD加氢催化剂在反应中存在使用寿命短和重复使用性差等问题.金属有机框架(MOFs)作为一种周期有序多孔材料,有望成为用于DCPD加氢的新型高效催化剂.通过引入介孔或大孔来构建等级孔MOFs(HP-MOFs),可以克服微孔对DCPD等大客体分子的扩散限制,促进底物分子向HP-MOFs内部活性位点转移.此外,加入合适的金属组分(如价格相对低廉的Ru)到HP-MOFs,可以使金属的原子利用率最大化,优化活性位点的分散性和稳定性,进一步协同提升催化性能.因此,发展HP-MOFs与金属组分间异质结构的调控方法,建立构效关系至关重要.本文采用软模板法制备了HP-UiO-66(Ce),设计和构建了介孔UiO-66(Ce)负载钌纳米簇(NCs)异质材料,并用于催化DCPD加氢反应.X射线衍射(XRD)、扫描电镜、透射电镜、氮气吸脱附和DCPD加氢结果表明,与微孔和大孔UiO-66(Ce)相比,介孔UiO-66(Ce)独特的结构在催化剂制备和DCPD加氢中显示出独特的优势:(1)具有配体缺失缺陷的Ce-oxo簇促进了Ru^(3+)的有效吸附;(2)微孔框架的约束作用实现了Ru NCs的有效固定和均匀分散,抑制了Ru NCs的团聚和流失,保证了催化剂的稳定性;(3)介孔结构为DCPD和H_(2)底物分子提供了高效的传质通道,也有利于暴露更多的活性中心,促进DCPD与H_(2)底物分子的吸附和活化.此外,通过优化合成条件,可以精确控制Ru NCs活性位点的电子结构、分布和微环境.XRD和X射线光电子能谱结果表明,Ru NCs和Meso-UiO-66(Ce)之间Ru-O-Ce强异质界面的形成导致了晶格畸变,Ru@Meso-UiO-25-200中Ru^(0)和M-O占比最多,主要来源于还原处理得到的Ru NCs和Ru-O-Ce异质界面中Ru‒O键的形成,且样品中Ru0的含量与Ru^(3+)吸附温度呈反相关趋势,与样品还原温度呈正相关趋势.密度泛函理论计算结果表明,金属Ru0作为主要活性位点,极大地促进了DCPD和H2的吸附,并激活了催化剂上吸附的DCPD的C=C键,促进了DCPD两个C=C双键的“共吸附”和连续化加氢过程.因此,介孔UiO-66(Ce)和Ru NCs异质结构的构建,在低温(60℃)下仅用35 min就实现了DCPD催化加氢得到四氢双环戊二烯(THDCPD)(100%转化率和~100%选择性),且循环使用6次后性能基本保持不变,表现出较好的活性和稳定性.综上,本文通过等级孔和异质结构的构筑,证明了介孔结构在大底物分子催化反应中的结构优越性,并进一步揭示了催化剂合成条件、结构和性能之间的关系,为理性设计新型MOFs基功能材料在催化、吸附、储能等方面的应用提供新思路.

载体氧空位提升Sabatier反应钌基催化剂性能研究

通过尿素的掺杂,有效诱导Al_(2)O_(3)载体氧空位的形成,进而通过金属-载体之间的相互作用,提升Al_(2)O_(3)载体表面Ru基活性物种的分散度,调控Ru基活性中心的电子性质,从而达到有效提升Sabatier反应Ru基催化剂性能的目的。在此过程中,借助^(27)Al核磁(^(27)Al-NMR)验证了尿素的掺杂可有效诱导Al_(2)O_(3)载体中氧空位的形成。通过透射电子显微镜(TEM)发现,富含氧空位的Al_(2)O_(3)载体可将负载的Ru颗粒稳定在3.7 nm左右,且粒径分布集中。通过X射线光电子能谱(XPS)和H_(2)程序升温还原(H_(2)-TPR)发现,载体氧空位可有效调控Al_(2)O_(3)载体表面Ru基活性位点的电子性质。经过Sabatier反应性能测试发现,在300℃,n CO_(2)∶n H_(2)=1∶4,空速为6000 mL·g^(-1)·h^(-1)的反应条件下,CO_(2)转化率可达61.25%,CH_(4)选择性可达92.31%,而且,在20 h的反应时间内,催化活性没有明显衰减。

调控五配位Al^(3+)含量制备高性能低温Sabatier反应催化剂

为了制备出高性能低温Sabatier反应Ru基催化剂,通过调控Al_(2)O_(3)载体中五配位Al^(3+)的含量(五配位Al^(3+)占Al物种的比例),实现对Ru基活性位点电子性质的调控。在此过程中,利用~(27)Al固体核磁共振(~(27)Al-NMR)检测Al_(2)O_(3)载体中五配位Al^(3+)的含量,借助X射线光电子能谱仪(XPS)和H_2程序升温还原(H_(2)-TPR)考察Ru基活性位点电子性质的调控效果,利用固定床反应器测试催化剂性能。结果表明,Al_(2)O_(3)载体中的五配位Al^(3+)可有效调控Ru基活性位点的电子性质,进而提升低温Sabatier反应Ru基催化剂性能。其中,以五配位Al^(3+)含量约为28.1%的Al_(2)O_(3)载体制备的Ru基催化剂,在低温区(<300℃)的CO_(2)转化率和CH_4选择性均可达90%以上。而且,在100 h的稳定性测试中,催化性能没有明显降低。

高分散Ru/Si_(3)N_(4)催化剂的制备及其在CO_(2)加氢中的应用

氮化硅是一种良好的载体,具有较高的水热稳定性和机械稳定性,其表面的氨基基团能够较好地锚定金属,显著提高金属分散度。但是,商品氮化硅比表面积较低,对金属分散作用仍然有限。因此,以自制的高比表面积氮化硅(Si_(3)N_(4))为载体,通过浸渍法制备了不同Ru负载量(质量分数分别为0.5%、1.0%和2.0%)的催化剂(分别为0.5%Ru/Si_(3)N_(4)、1.0%Ru/Si_(3)N_(4)和2.0%Ru/Si_(3)N_(4)),并以商品氮化硅(Si_(3)N_(4)-C)为载体制备了2.0%Ru/Si_(3)N_(4)-C催化剂作为对照组。表征了催化剂的理化性质,测试了其在300℃、0.1 MPa下的CO_(2)加氢反应活性。结果显示,与Si_(3)N_(4)-C相比,Si_(3)N_(4)的比表面积较高(502 m^(2)/g),Si_(3)N_(4)作为载体显著提高了金属分散度,降低了金属粒径,催化剂暴露出更多的活性位点。0.5%Ru/Si_(3)N_(4)的金属粒径较小,展现出强的H_(2)吸附能力,H难以解吸,抑制了中间物种CO加氢生成CH_(4)。随着Ru负载量增加,金属粒径增大,催化剂的CH_(4)选择性更好。Ru/Si_(3)N_(4)系列催化剂中,2.0%Ru/Si_(3)N_(4)的CH_(4)选择性较高(98.8%)。空速为10000 m L/(g·h)时,0.5%Ru/Si_(3)N_(4)的CO选择性为88.2%。与2.0%Ru/Si_(3)N_(4)相比,2.0%Ru/Si_(3)N_(4)-C的金属粒径更大,活性位点较少,活性更低。2.0%Ru/Si_(3)N_(4)和2.0%Ru/Si_(3)N_(4)-C的CO_(2)转化率分别为53.1%和9.2%。Si_(3)N_(4)有效提高了金属分散度,提高了催化剂的CO_(2)加氢反应活性;通过调控Ru负载量控制催化剂金属粒径,可实现对产物CO或CH_(4)选择性的调控。

CeO_(2) 微球负载 Ru 催化氧化乙酸乙酯

利用水热法制备了CeO_(2)微球,并采用沉积沉淀法在CeO_(2)微球表面负载Ru,制备Ru/CeO_(2)微球。通过SEM观察了CeO_(2)微球的外观形貌;利用TEM观测了CeO_(2)微球表面Ru颗粒分布情况;XRD对样品的物相进行了分析;用氮气吸附-解吸比较了微球负载Ru前后比表面积和孔隙分布的变化;XPS测试分析了微球负载Ru前后表面化学结构的变化;通过H2-TPR和O2-TPD表征了微球负载Ru前后催化剂还原性和氧活化能力的变化,并进行了样品催化氧化乙酸乙酯性能的测试。结果表明,Ru/CeO_(2)的结构与CeO_(2)相似,均为介孔材料,其中Ru可以离子态进入CeO_(2)晶格,造成CeO_(2)晶格畸变;Ru/CeO_(2)催化剂呈现出贵金属和二氧化铈的强相互作用,活性氧物种较CeO_(2)增加,储氧释氧能力增强,促进了低温催化氧化乙酸乙酯性能的提升;随着Ru负载量的增加,Ru/CeO_(2)催化氧化乙酸乙酯的性能先提高后逐渐趋于平稳,负载量为1.0%时的样品效果最优,其T90与CeO_(2)的相比降低了28.5℃。