Magnesia Binder Preparation from Local Natural and Technogenic Raw Materials

The preparation of magnesia binders based on natural and technogenic mineral was the result of the research. The obtained magnesia binders possess the increased flexural and compressive strength which values are close to ones of natural materials. High flexural and compression strengths are associated with the features of the hardened caustic dolomite containing magnesium oxyhydrochlorides which crystallize as a fiber. The fibrous crystals not only increase the cement strength, but also act as a reinforcing material. The resulting magnesia binder does not require a moist environment at hardening. It is characterized by decorativeness and ecological compatibility, has a neutral hardening product composition.     

The Role of Infrared Spectroscopy and X-Ray Diffraction Analysis in the Investigation of the Influence of Fluorides on the Process of Calcination of Aluminium Hydroxide

The aim of this work was to check the possibility that by use of infrared spectroscopy the influence of fluorides on the calcinations process of aluminum hydroxide can be followed. The DTA method shows it clearly. It was, namely, found that the added fluoride influences the process of polymorphous transformation of the formation of α-Al₂O₃ from Al(OH)₃. According to DTA, IR, and X-ray analyses, it was found that the added fluoride lowers the temperature of the mentioned transformation for some 300 degrees.

For this purpose recorded were IR spectra and X-ray difractograms of pure AI(OH)3 as well as of such samples with added fluoride, in this case of AlF₃, in the range of 0. 1 to 10 per cent. The samples were examined in the temperature range of 298 to 1673 K in different time intervals.     

正极材料LiAl0.08Mn1.92O4单晶颗粒形貌演变及电化学性能

联合元素掺杂和形貌调控策略,采用固相燃烧法和不同焙烧温度处理合成LiAl_0.08Mn_1.92O₄正极材料。实验结果表明,Al掺杂和焙烧温度的变化未改变LiMn₂O₄的相结构,随着温度的升高结晶性增强,颗粒尺寸增大,其中焙烧温度650 ℃是形成截断八面体单晶颗粒形貌的关键点温度,750 ℃是颗粒突然变大的突变温度。650 ℃优化焙烧温度下焙烧的LiAl_0.08Mn_1.92O₄形成了较完整的包含(111)、(110)和(100)晶面的截断八面体单晶颗粒形貌,表现出优良的电化学和动力学性能。在1C下其首次放电比容量为 112.0 mAh·g^-1,循环 500 次后容量保持率为 72.9%,在 5C 和 10C 倍率下,其首次放电比容量可达到 107.1 和 100.4mAh·g^-1,经 2 000次长循环后,容量保持率为 52.2% 和 53.5%。并且具有最小氧化还原峰电位差(ΔE_p2,循环前后分别为 0.109和 0.114 V)、最小电荷转移电阻(R_ct,循环前后分别 106.49和 125.49 Ω)及较大的锂离子扩散系数(D_Li⁺ =1.72×10^-16 cm²·s^-1),表现出较好的电化学可逆性和较快的锂离子扩散速率。Al掺杂和单晶截断八面体颗粒形貌既有效抑制了LiMn₂O₄的Jahn-Teller畸变,又降低了Mn溶解,提高了材料的倍率性能和长循环寿命。     

柠檬酸凝胶法合成Ni-ZrO_2催化剂及其低温浆态床甲烷化性能研究

采用柠檬酸凝胶法制备不同温度焙烧的Ni-ZrO_2催化剂,考察了催化剂的表面性质和结构对低温浆态床CO甲烷化性能的影响.结果表明,随着焙烧温度的升高,催化剂的比表面积和孔容逐渐减小,金属Ni分散度先增加后减小,Ni晶粒先减小后增大.450℃焙烧的Ni-ZrO_2催化剂金属Ni分散度最高、Ni物种与载体ZrO_2的相互作用最强、对反应物CO分子的吸附作用适中且脱附量大,在260℃、1.0 MPa和H_2/CO摩尔比为3的条件下,CO转化率达到61.6%,且催化活性稳定,750℃焙烧的催化剂反应后金属Ni团聚且晶粒长大,导致催化剂失活.     

Transesterification of canola oil over Li/Ca-La mixed oxide catalyst: Kinetics and calcination temperature investigations

In this research, a solid 1%Li/Ca-La mixed oxide catalyst was prepared using co-precipitation method followed by wet impregnation. The prepared catalyst was used in the transesterification reaction of canola oil and methanol for biodiesel synthesis. The effects of calcination and reaction temperatures were investigated on the activity of the catalyst. In addition, rate of the reaction was studied through a kinetic model for which parameters were determined. Surface properties and structure of the catalyst were characterized through the powder X-ray diffraction (XRD), thermogravimetry/derivative thermogravimetry (TG/DTG), and Fourier transform infrared spectroscopy analysis. All these emphasized that the performance of the catalyst corresponded to the generation of the active sites and their thermal activation.     

Multicyclic study on the carbonation of CaO using different limestones

Different samples of limestones, with small differences in their stoichiometry, have been studied comparatively. The carbonation reaction has been studied for a large area of isothermal temperatures. The conditions for the multicyclic experiments of calcination/carbonation were: isothermal temperature 670°C, heating time 60 min and carrier gas CO₂. The final carbonation conversion depends mainly on the isothermal temperature of the carbonation reaction and the heating time. The final temperature of the calcination reaction depends on the percentage of CaO that it has not been conversed to CaCO₃ in the repeated carbonation experiments. The quantity of CaO that has not been carbonated, in the same sample, affects the values of the coefficients of the kinetic model that fit the calcination reaction. In the multicyclic experiments the carbonation conversion for two of the four studied samples, was high enough in comparison to other samples of calcite. At sample A the reduction of the carbonation conversion during the first five cycles is less than it is at other samples from the literature. Under the above experimental conditions — isothermal temperature and heating time — specific samples consisted mainly of calcite can absorb larger quantities of CO₂ than samples consisted mainly of dolomite.     

煅烧温度对湿化学法制备AlN粉体的影响

以六水合氯化铝和尿素为原料,甲醇为溶剂,在NH₃气氛下通过湿化学法制备AlN粉体,并采用X射线衍射仪、扫描电子显微镜和激光粒度仪对产物进行表征。结果表明:煅烧温度在900 ℃以上可获得六方AlN粉体;煅烧温度为1 000 ℃时获得的AlN粉体具有球形特征,粉体的平均晶粒尺寸为17.0 nm,平均粒径为159.5 nm。使用透射电子显微镜进一步表征了AlN粉体的微观结构。拉曼光谱结合能谱分析表明,存在于AlN粉体中的非晶杂质不是残留的含碳副产物,而是粉体表面水解产生的氢氧化铝。     

含铜类水滑石催化材料热分解过程的研究

共沉淀法合成了Cu0.13Mg0 6Al0.27(OH)2(CO3)0.135·xH2O类水滑石物质 (CuHTlc) ,采用XRD、DTA TG、BET、TEM和27AlMASNMR技术对其热分解过程进行了表征。结果表明 ,在较低焙烧温度时 (低于300℃ ),氢氧根和层间水部分脱除 ,但水滑石仍保持其层状结构 ;500℃时 ,其层状结构被完全破坏 ,出现氧化镁晶相结构 ,随着焙烧温度的进一步升高 ,尖晶石晶相生成。500℃时的焙烧产物具有最大比表面 (193m2·g-1)。当温度高于500℃ ,焙烧产物组成可表示为Cu0.13Mg0.6Al0.27O0.135,CuHTlc的热分解过程可表示为 :Cu0.13Mg0.6Al0.27(OH)2(CO3)0.135·xH2O→Cu0.13Mg0.6Al0.27O0.135 (1 x)H2O 0.135CO2。     

无烟粉煤催化气化含碱灰渣的锻烧无害化

报道了福建劣质无烟粉煤催化气化含碱灰渣在一内径φ32mm的实验室固定床模试装置中的煅烧研究。对水蒸汽油催化和混合气（空气/水蒸汽）催化气化的两种含碱灰渣进行煅烧处理,生成了难溶性的硅酸复盐。当煅烧温度870℃-900℃、煅烧时间25min-30min,可以达到85W/%以上的脱碱率;而3W/%脱碱助剂的加入,可使脱碱率提高到95W/%以上,实现了含碱灰渣的煅烧无害化。粉煤催化气化制度与含碱灰渣煅烧制度的一致性提供了科学地实现“催化气化-灰渣煅烧”集成式流化床新工艺的理论依据,加速了催化气化的工业化进程。     

煅烧温度对Mn改性γ-Fe2O3催化剂结构及低温SCR脱硝活性的影响

采用共沉淀法,在不同煅烧温度下制备一系列Mn改性γ-Fe₂O₃催化剂(Fe_0.7Mn_0.3O_z),研究了煅烧温度对Fe_0.7Mn_0.3O_z催化剂低温SCR脱硝活性的影响,并借助XRD、N₂吸附-脱附、EDS及SEM等手段对催化剂进行表征。结果表明,350 ℃煅烧所得Fe_0.7Mn_0.3O_z催化剂的低温SCR活性最佳,在70 ℃时取得92%的NO_x转化率,100~200 ℃可维持100%的NO_x转化率,而450 ℃煅烧所得催化剂的低温SCR活性最低;煅烧温度为350 ℃时,催化剂具有最大的比表面积和比孔容、发达的孔隙结构及适当结晶度的γ-Fe₂O₃,而煅烧温度为400或450 ℃时,催化剂发生烧结且有α-Fe₂O₃生成,不利于低温SCR反应的进行,因此,Fe_0.7Mn_0.3O_z催化剂的最佳煅烧温度为350 ℃。