Hydrothermal Synthesis and Properties of Y-zeolite-containing Composite Material with Micro/mesoporous Structure

A Y-zeolite-containing composite material with micro/mesoporous structure had been synthesized from kaolin by means of the in-situ crystallization method. The obtained samples were investigated by XRD and BET methods. Evaluation of catalytic activity of both the commercial Y-zeolite and the novel Y-zeolite-containing composite material was carried out in the pulse micro-chromatography platform with two probe molecules of different molecular sizes： VGO feedstock and 1,3,5 tri-isopropyl benzene. It was found that the Y-zeolite-containing composite material was richer in external surface and meso-/macro-pores; the Y-zeolite-containing composite material demonstrated a smaller rate of deactivation compared to the commercial Y-zeolite.

Synthesis and Characterization of Worm-shaped Tubular Lanthanum Aluminum Composite Mesoporous Materials

The lanthanum aluminum mesoporous materials were synthesized using sodium dodecyl sulfate as a template agent by ultrasonic hydrothermal method.The resulting samples were characterized by low angle X-ray diffraction（XRD）,N2 adsorption-desorption studies,transmission electron microscopy（TEM）and surface morphology analysis（SEM）,surface acid（NH3-TPD）,reducibility properties（TPR）,X-ray energy dispersive spectrometer（EDS）and thermogravimetric analysis（TG/DTG）.A l/La composite mesoporous material were synthesized with n（Al）︰n（La）=70︰1.0,80°C of reaction temperature,20 h of reaction time,12 h of crystallization time,650°C of calcination temperature.The specific surface area of the sample is 273.90 m 2 ·g ？1 ,with the average diameter 5.642 nm and pore volume 0.2354 cm 3 ·g ？1 .The samples have mesoporous structure and its particles are similar to a worm-shaped tubular structure.The influence of calcination temperature on the surface physical and chemical properties of Al/La composited mesoporous materials was examined,and the results showed that the acid strength was increased but the amount of acidic sites is decreased as the calcination temperature increased.It was found that the sample calcined at 650°C had appropriate acid content,acid strength and better reducibility.

基于量子点@有序介孔复合材料的Micro⁃LED色转换特性

量子点(Quantum dots)由于具有优异的光电特性,广泛应用于发光与显示、太阳能电池、光催化等领域,它的发现和合成获得了2023年诺贝尔化学奖。采用量子点色转换的Micro-LED全彩化显示技术无需巨量转移,有望实现大规模量产,然而,量子点在高强度Micro-LED出光激发下的性能和寿命仍存在局限。基于此,本文研究了基于量子点@有序介孔(QDs@SBA-15)复合材料的Micro-LED色转换技术及其特性,有序介孔分子筛载体独特的孔道结构不仅能够有效提升Micro-LED色转换和光提取效率,且致密的有序介孔材料也一定程度上保障了量子点的稳定性。首先,通过时域有限差分方法(FDTD)建立了Micro-LED仿真模型,探究量子点粒径和有序介孔材料的孔径对光提取效率的影响;基于仿真结果指导,进一步采用物理共混法制备了QDs@SBA-15复合材料,通过透射光谱、荧光激发光谱、紫外-可见光吸收谱等手段对其进行表征并确定浓度配比;最后,将该复合材料与聚二甲基硅氧烷(PDMS)混合固化成膜,并研究了其光致发光性能。实验结果发现,量子点粒径和介孔材料孔径的匹配度以及量子点和有序介孔材料的比例浓度是影响QDs@SBA-15复合材料发光效率及Micro-LED色转换性能的关键因素;通过优化,所得复合材料可获得优异的发光性能以及良好的环境稳定性,相比于纯量子点色转换层,复合材料的光提取效率提升了81.73%,复合材料的环境稳定性提升了14.33%,以Micro-LED作为蓝光光源组成的三基色发光器件工作色域达到了104.52%NTSC。本研究为量子点色转换Micro-LED显示技术提供了理论指导,为实现Micro-LED全彩化开辟了新路径。

Preparation, characterization and electrochemical properties of mesoporous LiFe_(0.99)Mo_(0.01)PO_4/C

A mesoporous LiFe0.99Mo0.01PO4/C composite was synthesized by the sol-gel method using （NH4）2MoO4 as a doping starting material. The formation of conductive carbon, metal doping and mesopores was achieved simultaneously in the prepared material. The characterizations of crystal structures and microstructures were investigated using X-ray diffraction （XRD）, scanning electron microscopy （SEM）, transmission electron microscopy （TEM）, extended X-ray-absorption fine-structure （EXAFS） and X-ray-absorption near-structure spectroscopy （XANES） while the surface area was determined using N2 adsorption techniques. Cyclic voltammetry （CV） and charge-discharge cycling performance were used to characterize its electrochemical properties. The sample possessed uniformly distributed mesopores with an average pore size of 4 nm, and the specific surface area was about 69.368 m^2/g. The results show that the reversible capacity of mesoporous LiFe0.99Mo0.01PO4/C is about 160 mAh/g at 0.1C, 135 mAh/g at 1C and 90 mAh/g at 5C, respectively. The capacity fading is neglectable.

Synthesis and catalytic performance of bimetallic NiMo-and NiW-ZSM-5/MCM-41 composites for production of liquid biofuels

This work presents a synthesis of bimetallic NiMo and NiW modified ZSM-5/MCM-41 composites and their heterogeneous catalytic conversion of crude palm oil( CPO) to biofuels. The ZSM-5/MCM-41 composites were synthesized through a self-assembly of cetyltrimethylammonium bromide( CTAB) surfactant with silica-alumina from ZSM-5 zeolite,prepared from natural kaolin by the hydrothermal technique. Subsequently,the synthesized composites were deposited with bimetallic NiMo and NiW by impregnation method. The obtained catalysts presented a micro-mesoporous structure,confirmed by XRD,SEM,TEM,EDX,NH_3-TPD,XRF and N_2 adsorption-desorption measurements. The results of CPO conversion demonstrate that the catalytic activity of the synthesized catalysts decreases in the series of NiMo-ZSM-5/MCM-41 > NiW-ZSM-5/MCM-41 > Ni-ZSM-5/MCM-41 > Mo-ZSM-5/MCM-41 > W-ZSM-5/MCM-41 > NiMo-ZSM-5 > NiW-ZSM-5 > ZSM-5/MCM-41 > ZSM-5 > MCM-41. It was found that the bimetallic NiMo-and NiW-ZSM-5/MCM-41 catalysts give higher yields of liquid hydrocarbons than other catalysts at a given conversion. Types of hydrocarbon in liquid products,identified by simulated distillation gas chromatography-flame ionization detector( SimDis GC-FID),are gasoline( 150-200 ℃; C5-12),kerosene( 250-300 ℃; C5-20) and diesel( 350 ℃; C7-20).Moreover,the conversion of CPO to biofuel products using the NiMo-and NiW-ZSM-5/MCM-41 catalysts offers no statistically significant difference( P> 0.05) at 95% confidence level,evaluated by SPSS analysis.

Metal-Ceramic Smart Composite in Ti(C,N)-Ni-Mo-W System

Goal: Low wolfram-containing cutting composite was obtained by fusion of titanium carbonitride and high melting temperature binding metallic phase. Method: The composite was obtained via compaction and further sintering in vacuum furnace at 1600°C under 10-3 Pa pressure. Phase analysis was performed on X-ray apparatus “DRON-3”;microstructure was determined by electron microscope NANOLAB-7, microhardness by MUCKE-mark microhardness meter;relative resistance of cutters was evaluated at similar modes of cutting according to distances they passed;experiments were carried out on turning lathe. Results: Physical-mechanical characteristics of the obtained composite are: σbend, = 1000 - 1150 MPa, σbend1000°C = 600 MPa, HV = 14 GPa;HV1000°C = 6.5 GPa. High speeds of cutting and high temperatures resistance of cutters made by the obtained composites exceeds 1.5 - 2-folds that of cutters made of the known BK8 and KNT20 hard alloys. Conclusion: Its application is recommended in hot steel treatment by cutting, for removal of the so-called burrs, as well as in steel treatment by cutting during pure and semi-pure operations. It can also be used in jet engines, chemical industry apparatuses, electric-vacuum devices, in industry of responsible details of rockets, nuclear reactors, flying apparatuses.

银铜侧向复合材料界面结合机理分析

本文采用“包覆锭坯+扩散烧结+冷轧复合”联合工艺制备了银铜侧向复合带材,利用金相显微镜(OM)、扫描电镜(SEM)和能谱仪(EDS)观察分析银铜复合界面结构和元素分布,并分析其银铜复合界面的结合机理。结果表明,银铜复合界面形成过程为:1)银铜接触界面处凹凸不平的表面在轧制力的作用下相互咬合,形成机械结合界面;2)接触面在轧制力的作用下,银铜表面氧化膜破裂,新鲜表面质点间在轧制变形热的作用下产生原子结合;3)在扩散烧结过程中,银铜界面处的原子在高温作用下被激活,银铜原子相互扩散,在界面处发生银铜共晶反应形成液相金属层,随着烧结时间的延长,其共晶反应液相层厚度逐渐增加,随后冷凝结晶,使银铜实现侧向冶金结合。4)在后续中间退火过程中,共晶层与两侧的铜、银基体相互扩散,铜、银原子向更深的方向逐渐扩散,在靠近共晶层铜侧和银侧逐步形成固溶体层,使银与铜的结合强度进一步提高。银铜侧向复合界面结合机理包含机械咬合结合、接触共晶反应自钎焊结合和原子扩散结合3种,复合界面结合强度较好,剪切强度达220 MPa。

新型球形高纯度介孔硅胶复合材料在茂金属聚乙烯催化剂中的应用

以工业原料水玻璃和硫酸为主要原料,通过球磨打浆技术､高效节能环保除杂质技术和具有尾气回收系统的离心喷雾干燥技术制备出2种日产量12000 kg的用于聚乙烯催化剂的载体高纯度球形介孔硅胶复合材料。2种复合材料在硅胶无序堆积孔中均拥有有序的介孔孔道且球体度均匀,二氧化硅纯度均在99.5%以上。新型材料在负载聚乙烯催化剂后仍然保持良好微观形貌及其特有的介孔材料孔道结构。高压乙烯聚合小试试验结果表明,2种催化剂对乙烯聚合的活性均高于工业用催化剂的活性,催化反应后得到的聚乙烯粉料的重要物性参数均优于工业用948硅胶粉料。

球形黏土介孔复合材料在聚乙烯茂金属催化剂中的应用

采用离心喷雾干燥机合成公斤级球形黏土(海泡石、硅藻土和凹凸棒石)介孔复合材料。并对球形黏土介孔材料进行X射线衍射结构分析、比表面积-孔径分布和透射电镜测试,表明球形黏土介孔材料具有介孔结构和高度有序孔道。扫描电镜分析结果表明,3种新材料球体度均匀、分散性好。研究雾化器转速和反应物配比对球形黏土介孔复合材料粒形的影响,得到最佳喷雾干燥条件。考察海泡石、硅藻土和凹凸棒石球形黏土介孔复合材料负载聚乙烯催化剂的组成、结构和微观形貌。结果表明,3种黏土介孔复合材料在负载聚乙烯催化剂后仍然保持较好的微观形貌及其特有的介孔材料孔道结构。离心喷雾干燥制备球形介孔材料的实验优化条件:进、出口温度200℃和100℃,黏土介孔浆料浓度30%,雾化器转速12000 r·min^(-1)。以3种介孔复合材料作为载体负载聚乙烯催化剂进行高压乙烯聚合小试试验,结果表明,3种催化剂对乙烯聚合的活性(4000~4300)gPE·(gcat·h)^(-1)均优于当前工业用载体955硅胶负载同样茂金属后的乙烯聚合的活性1005 gPE·(gcat·h)^(-1)。聚乙烯粉料重要物性参数堆密度、熔融指数、平均粒径D50及碎粉率均优于工业用955硅胶得到的粉料物性。

玛瑙球磨法制备微米介孔球状材料催化剂及其应用

利用玛瑙球磨法合成出一种负载酸催化剂三氟甲磺酸铜的微米级球状介孔材料,研究了催化剂的微观结构、微观形貌和催化反应活性。通过对环己酮和乙二醇的催化反应表明,样品作为催化剂具有较高活性。初次使用时环己酮转化率为97%,环己酮缩酮的选择性为99%,经过4次使用后依旧具有较高催化活性-环己酮转化率为96%。环己酮缩酮的选择性为99%,远远高于工业用硫酸催化剂的环己酮转化率(90%)和环己酮缩酮的选择性(91%)。

高地温对超细复合掺合料胶凝体系的影响

通过实验室近似模拟高海拔地区高地温环境,研究超细复合掺合料对水泥基胶凝材料力学性能、体积稳定性、孔结构的影响,分析在不同温度下超细复合掺合料对水泥的最优取代率,结合微观手段分析超细复合掺合料最优掺量时胶凝体系的反应机理。结果表明:掺加超细复合掺合料能提高水泥基胶凝材料的力学性能,随着养护龄期的延长,最优取代率的抗压强度能够提高10%~21%,在高温下强度增长缓慢;超细复合掺合料体系的收缩率表现优于纯水泥体系,在适当高温环境下可保持体系稳定,但80℃的养护温度会增大体系的体积收缩率;超细复合掺合料能降低体系的平均孔径,提高密实度,生成更多钙矾石、水化硅酸钙等水化产物。

Atomistic simulations for adsorption and separation of flue gas in MFI zeolite and MFI/MCM-41 micro/mesoporous composite

Adsorption of pure CO_(2) and N2 and separation of CO_(2)/N2 mixture in MFI zeolite and MFI/MCM-41 micro/mesoporous composite have been studied by using atomistic simulations.Fully atomistic models of MFI and MFI/MCM-41 are constructed and characterized.A bimodal pore size distribution is observed in MFI/MCM-41 from simulated small-and broad-angle X-ray diffrac-tion patterns.The density of MFI/MCM-41 is lower than MFI,while its free volume and specific surface area are greater than MFI due to the presence of mesopores.CO_(2) is preferentially adsorbed than N2,and thus,the loading and isosteric heat of CO_(2) are greater than N2 in both MFI and MFI/MCM-41.CO_(2) isotherm in MFI/MCM-41 is similar to that in MFI at low pressures,but resembles that in MCM-41 at high pressures.N2 shows similar amount of loading in MFI,MCM-41 and MFI/MCM-41.The selectivity of CO_(2) over N2 in the three adsorbents decreases in the order of MFI>MFI/MCM-41>MCM-41.With increasing pressure,the selectivity increases in MFI and MFI/MCM-41,but decreases in MCM-41.The self-diffusivity of CO_(2) and N2 in MFI decreases as loading increases,while in MFI/MCM-41,itfirst increases and then drops.

Recent development of LiNi_xCo_yMn_zO_2:Impact of micro/nano structures for imparting improvements in lithium batteries

The recent advancement in the design,synthesis,and fabrication of micro/nano structured LiNixCoyMnzO2 with one-,two-,and three-dimensional morphologies was reviewed.The major goal is to highlight LiNixCoyMnzO2 materials,which have been utilized in lithium ion batteries with enhanced energy and power density,high energy efficiency,superior rate capability and excellent cycling stability resulting from the doping,surface coating,nanocomposites and nano-architecturing.

铝基核壳材料AP/Al的制备及性能研究

以AP和铝粉为原料,采用“AP预处理+表面沉积”两步法工艺制备了以铝粉为“壳”的铝基核壳材料AP/Al;采用SEM-EDS、粒度分析、密度测试等方法表征了AP/Al的表面形貌、元素分布、粒度分布和密度等物理特性,对比测试了铝基核壳材料AP/Al的感度性能、热分解性能、爆热及残渣活性铝含量并与AP/Al物理混合物进行了对比;运用Flynn-Wall-Ozawa方程计算了AP/Al物理混合物及铝基核壳材料AP/Al的分解活化能,并通过高速摄像机记录了铝基核壳材料AP/Al的燃烧特性。结果表明,铝基核壳材料AP/Al是以AP为“核芯”、铝粉为“壳”,密度为2.0485 g/cm^(3)的类球形颗粒;相比于物理混合物,铝基核壳材料AP/Al静电火光感度由27.94 mJ提高至102.88 mJ,AP低温分解和高温分解活化能分别提升10.9和9.0 kJ/mol,爆热值未出现明显降低(物理混合物为9298.4 J/g,铝基核壳材料AP/Al为9260.6 J/g),但铝基核壳材料AP/Al残渣中活性铝质量分数降低90%以上;有别于传统铝粉燃烧的拖拽火焰,铝基核壳材料AP/Al燃烧时,铝液滴溅射大量细颗粒铝珠,且燃烧火焰更加均匀、明亮。

面向高性能摩擦纳米发电机的电介质材料

摩擦纳米发电机(triboelectric nanogenerator,TENG)作为微纳电源或自取能传感器近年来在多领域表现出广阔的应用潜力.TENG的输出性能提升与作为摩擦起电层的电介质材料接触起电特性密切相关.本文首先介绍了TENG及其电介质摩擦起电层的相关基础理论和模型;其次,阐述了TENG电介质材料的选材、改性(表面改性、体改性)和结构设计策略,其中表面改性和体改性涉及表面粗糙度控制、官能团调控、电介质材料介电参数优化,在电介质的结构设计方面,重点介绍了电荷传输层、捕获层、阻挡层的原理及通过多层结构来提高TENG介电性能的典型方法;最后,强调了本领域发展面临的挑战和未来发展趋势,为面向高性能TENG的纳米电介质材料开发提供参考.

微反应技术在含能材料制备中的应用研究

介绍了硝基芳烃、硝酸酯、硝胺及其他类含能材料的微反应合成,对现有的单质含能材料的微反应合成工艺进行分类叙述,点明了微反应技术可以显著提高产物收率和选择性、减少反应时间以及增加传质和传热效率等优势,并对微反应合成中的堵塞等焦点问题进行了分析;同时阐述了微反应技术在微纳米含能材料制备及复合含能材料制备中的应用,突出了微反应技术在含能材料粒径、形貌调控及连续化制备等方面的优势,并对现有的技术难点进行了总结,对未来的研究方向进行了展望。指出将微反应技术与数值模拟相结合进行反应及传热结构优化设计、探索反应机理,是微反应技术在含能材料制备领域的重要研究方向。附参考文献80篇。

基于零膨胀介孔PbTiO_(3)/石墨烯复合陶瓷的热膨胀系数调控与微纳研究

随着军事和民用技术的快速发展,对航空、户外等领域所用器件在复杂环境下的稳定性提出了更为严格的要求。这些器件经常需要在较大的温度变化范围内工作,而温度变化所带来的材料体积变化是器件结构受损,功能失效的重要原因之一。因此,如航空航天设备中所用的精密结构件不仅需要具有优秀的导电、导热性能,还需要保证其在温度变化过程中具有较低的热膨胀系数。因此,研究制备具有近零膨胀性能的材料便成为解决这些问题的重要方法之一。在本研究中,作者通过改变烧结温度,制备出一系列介孔铁电PbTiO_(3)(PTO)陶瓷,通过测试结果展示了材料的热导率、热膨胀系数与烧结温度的关系。进一步通过三维重构技术(Tomography)与高角度环形暗场像(high angle annular dark field,HAADF),分析了改变烧结温度对于介孔尺寸、分布密度的影响,以及单个介孔表面附近的铁电屏蔽效应影响范围,从而解释了烧结温度的变化与介孔的分布密度、尺寸大小以及热膨胀行为之间的紧密联系。随着烧结温度的降低,介孔对材料铁电屏蔽效应的总区域占比逐渐升高,从而使材料正膨胀系数增大,导致材料表现出近零膨胀。为进一步提高材料的热导率,提升材料的多功能性,将这一材料与石墨烯进行复合,通过改变烧结温度与石墨烯的复合比例,进一步使材料的热膨胀系数趋近于零膨胀,并通过调整烧结温度与复合比例,得到膨胀系数低至7×10^(-7)℃^(-1),热导率比单相陶瓷提升约65%的近零膨胀复合陶瓷。这种材料可以在芯片封装,航天器外壳,通讯设备等材料领域得到进一步广泛应用的空间。

NaY分子筛复合材料及其催化裂化催化剂性能

以高岭土和水玻璃为原料,采用水热法原位晶化合成了NaY分子筛复合材料,通过离子交换法改性并制备出催化裂化催化剂,利用X射线荧光仪、N2吸附-脱附仪、扫描电子显微镜等仪器对试样进行结构表征,在固定流化床微型反应器装置上进行催化剂裂化反应性能评价。结果表明:该NaY分子筛复合材料的外比表面积为93.70 m^(2)/g,介孔孔容为0.19 cm^(3)/g,颗粒直径约在300~500 nm;改性后复合材料的介孔主要分布在2~20 nm,且为双孔分布,分布峰分别为3.8,5.6 nm;与常规NaY型分子筛催化剂相比,采用该NaY型分子筛复合材料所制备的催化剂其反应转化率、液化气和总液体收率依次提高6.18,5.16,1.61个百分点,重油收率下降3.34个百分点,生焦因子下降0.80。

道路声屏障组合吸声结构设计与评估

声屏障在道路交通噪声污染防治中得到了广泛应用,但同时面临材料吸声性能有限、轻量化程度有待提升等问题。为了更好地提升道路声屏障的降噪效果,需要研究组合吸声结构的声学性能及其影响因素。建立了二维阻抗管有限元模型,与实验数据进行对比验证了其可靠性。基于有限元仿真构建了微穿孔板-双层多孔吸声材料-空腔组合吸声结构,研究了几何参数对组合结构的吸声性能的影响,并在实际道路场景中进行了仿真分析。结果表明,微穿孔板的孔径和厚度减小,组合结构在中高频段的吸声效果提升;穿孔率减小,组合结构在低频段的吸声性能提升,但是中高频吸声性能显著降低;多孔吸声材料厚度的增加能提升组合结构中高频吸声系数。在多孔吸声材料背后合理设置空腔并不会降低组合结构的声学性能。穿孔率3%,孔径0.4 mm,板厚1 mm的微穿孔板与3 cm聚酯纤维+3 cm三聚氰胺+2 cm空腔的组合吸声结构降噪效果较好,将其作为吸声型声屏障的材料。吸声型和隔声型声屏障插入损失的规律基本一致,采用组合吸声结构的吸声型声屏障较隔声型声屏障插入损失提升1~2 dB,能够较好地控制中低频交通噪声,具有实际工程价值。

改性聚醚醚酮三层复合材料摩擦磨损性能研究

通过喷涂-轧制复合工艺制备了不同质量分数聚四氟乙烯(PTFE)微粉改性的聚醚醚酮(PEEK)基三层复合材料,采用箱式炉对复合材料试样进行了烧结,对试样进行干摩擦端面摩擦磨损试验,研究了PTFE添加量对PEEK基三层复合材料摩擦学性能的影响,对试样显微硬度、结合强度、摩擦系数、磨损量、表面以及磨痕形貌进行了表征。结果表明:PTFE含量增加会降低PEEK涂层的硬度和结合强度,同时会显著降低PEEK涂层的干摩擦系数,但PTFE含量增加到40%后,表面显微组织能观察到PTFE团聚严重,使干摩擦系数和磨损量先减小后增大,磨痕显微组织则表明样品由黏着磨损转为磨粒磨损。